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APPLIED SOLID MECHANICS
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APPLIED SOLID MECHANICS
Much of the world around us, both natural and man-made, is built from and held together by solid materials. Understanding how they behave is the task of solid mechanics, which can in turn be applied to a wide range of areas from earthquake mechanics and the construction industry to biomechanics. The variety of materials (such as metals, rocks, glasses, sand, flesh and bone) and their properties (such as porosity, viscosity, elasticity, plasticity) are reflected by the concepts and techniques needed to understand them, which are a rich mixture of mathematics, physics, experiment and intuition. These are all brought to bear in this distinctive book, which is based on years of experience in research and teaching. Theory is related to practical applications, where surprising phenomena occur and where innovative mathematical methods are needed to understand features such as fracture. Starting from the very simplest situations, based on elementary observations in engineering and physics, models of increasing sophistication are derived and applied. The emphasis is on problem solving and on building an intuitive understanding, rather than on a technical presentation of theoretical topics. The text is complemented by over 100 carefully chosen exercises, and the minimal prerequisites make it an ideal companion for mathematics students taking advanced courses, for those undertaking research in the area or for those working in other disciplines in which solid mechanics plays a crucial role.
Cambridge Texts in Applied Mathematics Editorial Board Mark Ablowitz, University of Colorado, Boulder S. Davis, Northwestern University E. J. Hinch, University of Cambridge Arieh Iserles, University of Cambridge John Ockendon, University of Oxford Peter Olver, University of Minnesota
APPLIED SOLID MECHANICS PETER HOWELL University of Oxford
GREGORY KOZYREFF Fonds de la Recherche Scientifique—FNRS and Universit´e Libre de Bruxelles
JOHN OCKENDON University of Oxford
CAMBRIDGE UNIVERSITY PRESS
Cambridge, New York, Melbourne, Madrid, Cape Town, Singapore, São Paulo Cambridge University Press The Edinburgh Building, Cambridge CB2 8RU, UK Published in the United States of America by Cambridge University Press, New York www.cambridge.org Information on this title: www.cambridge.org/9780521854894 © P. D. Howell, G. Kozyreff and J. R. Ockendon 2009 This publication is in copyright. Subject to statutory exception and to the provision of relevant collective licensing agreements, no reproduction of any part may take place without the written permission of Cambridge University Press. First published in print format 2008
ISBN-13
978-0-511-50639-0
eBook (EBL)
ISBN-13
978-0-521-85489-4
hardback
ISBN-13
978-0-521-67109-5
paperback
Cambridge University Press has no responsibility for the persistence or accuracy of urls for external or third-party internet websites referred to in this publication, and does not guarantee that any content on such websites is, or will remain, accurate or appropriate.
Contents
List of illustrations Prologue
page viii xiii
Modelling solids 1.1 Introduction 1.2 Hooke’s law 1.3 Lagrangian and Eulerian coordinates 1.4 Strain 1.5 Stress 1.6 Conservation of momentum 1.7 Linear elasticity 1.8 The incompressibility approximation 1.9 Energy 1.10 Boundary conditions and well-posedness 1.11 Coordinate systems Exercises
1 1 2 3 4 7 10 11 13 14 16 19 24
Linear elastostatics 2.1 Introduction 2.2 Linear displacements 2.3 Antiplane strain 2.4 Torsion 2.5 Multiply-connected domains 2.6 Plane strain 2.7 Compatibility 2.8 Generalised stress functions 2.9 Singular solutions in elastostatics 2.10 Concluding remark Exercises
28 28 29 37 39 42 47 68 70 82 93 93
v
vi
Contents
Linear elastodynamics 3.1 Introduction 3.2 Normal modes and plane waves 3.3 Dynamic stress functions 3.4 Waves in cylinders and spheres 3.5 Initial-value problems 3.6 Moving singularities 3.7 Concluding remarks Exercises
103 103 104 121 124 132 138 143 143
Approximate theories 4.1 Introduction 4.2 Longitudinal displacement of a bar 4.3 Transverse displacements of a string 4.4 Transverse displacements of a beam 4.5 Linear rod theory 4.6 Linear plate theory 4.7 Von K´ arm´an plate theory 4.8 Weakly curved shell theory 4.9 Nonlinear beam theory 4.10 Nonlinear rod theory 4.11 Geometrically nonlinear wave propagation 4.12 Concluding remarks Exercises
150 150 151 152 153 158 162 172 177 187 195 198 204 205
Nonlinear elasticity 5.1 Introduction 5.2 Stress and strain revisited 5.3 The constitutive relation 5.4 Examples 5.5 Concluding remarks Exercises
215 215 216 221 233 239 239
Asymptotic analysis 6.1 Introduction 6.2 Antiplane strain in a thin plate 6.3 The linear plate equation 6.4 Boundary conditions and Saint-Venant’s principle 6.5 The von K´ arm´an plate equations 6.6 The Euler–Bernoulli plate equations 6.7 The linear rod equations 6.8 Linear shell theory
245 245 246 248 253 261 267 273 278
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Contents
vii
6.9 Concluding remarks Exercises
282 283
Fracture and contact 7.1 Introduction 7.2 Static brittle fracture 7.3 Contact 7.4 Concluding remarks Exercises
287 287 288 309 320 321
Plasticity 8.1 Introduction 8.2 Models for granular material 8.3 Dislocation theory 8.4 Perfect plasticity theory for metals 8.5 Kinematics 8.6 Conservation of momentum 8.7 Conservation of energy 8.8 The flow rule 8.9 Simultaneous elasticity and plasticity 8.10 Examples 8.11 Concluding remarks Exercises
328 328 330 337 344 358 360 360 362 364 365 370 372
More general theories 9.1 Introduction 9.2 Viscoelasticity 9.3 Thermoelasticity 9.4 Composite materials and homogenisation 9.5 Poroelasticity 9.6 Anisotropy 9.7 Concluding remarks Exercises Epilogue
378 378 379 388 391 408 413 417 417 426
Appendix References Index
428 440 442
Orthogonal curvilinear coordinates
Illustrations
1.1 1.2 1.3 1.4 1.5 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 2.10 2.11 2.12 2.13 2.14 2.15 2.16 3.1 3.2 3.3 3.4 3.5 3.6 3.7
A reference tetrahedron. page 8 The forces acting on a small two-dimensional element. 9 A small pill-box-shaped region at the boundary between two elastic solids. 18 Forces acting on a polar element of solid. 22 A system of masses connected by springs. 25 A unit cube undergoing (a) uniform expansion, (b) one-dimensional shear, (c) uniaxial stretching. 30 A uniform bar being stretched under a tensile force. 32 A paper model with negative Poisson’s ratio. 33 A strained plate. 34 A bar in a state of antiplane strain. 38 A twisted bar. 39 A uniform tubular torsion bar. 43 The cross-section of (a) a circular cylindrical tube; (b) a cut tube. 44 The unit normal and tangent to the boundary of a plane region. 49 A plane annulus being inflated by an internal pressure. 53 A plane rectangular region subject to tangential tractions on its faces. 57 The tractions applied to the edge of a semi-infinite strip. 59 The surface displacement of a half-space and corresponding surface pressure. 65 83 A family of functions δε (x) that approach a delta-function as ε → 0. Contours of the maximum shear stress created by a point force acting at the origin. 85 Four point forces. 91 Plots of the first three Bessel functions. 108 A P -wave reflecting from a rigid boundary. 116 A layered elastic medium. 117 Dispersion relation for symmetric and antisymmetric Love waves. 120 Illustration of flexural waves. 128 The one-dimensional fundamental solution. 134 The two-dimensional fundamental solution. 135
viii
List of illustrations 3.8 3.9 3.10 3.11 3.12 3.13 4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 4.9 4.10 4.11 4.12 4.13 4.14 4.15 4.16 4.17 4.18 4.19 4.20
4.21
4.22 4.23 4.24 4.25 4.26 4.27
ix
The cone x2 + y 2 = c2 t2 tangent to the plane k1 x + k2 y = ωt. 138 The two-sheeted characteristic cone for the Navier equation. 138 The response of a string to a point force moving at speed V . 139 Wave-fronts generated by a moving force on an elastic membrane. 141 P -wave- and S -wave-fronts generated by a point force moving at speed V in plane strain. 142 Group velocity versus wave-number for symmetric and antisymmetric Love waves. 146 The forces acting on a small length of a uniform bar. 151 The forces acting on a small length of an elastic string. 153 The forces and moments acting on a small segment of an elastic beam. 154 The end of a beam under clamped, simply supported and free conditions.155 The first three buckling modes of a clamped elastic beam. 157 The internal force components in a thin elastic rod. 159 Cross-section through a rod showing the bending moment components. 159 Examples of cross-sections in the (y, z)-plane and their bending stiffnesses. 161 The forces acting on a small section of an elastic plate. 163 The bending moments acting on a section of an elastic plate. 164 The displacement of a simply supported rectangular plate sagging under gravity. 169 (a) A cylinder, (b) a cone, (c) another developable surface, (d) a hyperboloid. 175 Typical surface shapes with (a) zero, (b) negative and (c) positive Gaussian curvature. 179 Deformations of a cylindrical shell. 184 Deformations of an anticlastic shell. 185 Deformations of a synclastic shell. 186 A beam (a) before and (b) after bending; (c) a close-up of the displacement field. 187 (a) The forces and moments acting on a small segment of a beam. (b) The sign convention for the forces at the ends of the beam. 188 (a) Final angle of a diving board versus applied force parameter. (b) Deflection of a diving board for various values of the force parameter.191 (a) Response diagram of the amplitude of the linearised solution for a buckling beam versus the force parameter. (b) Corresponding response of the weakly nonlinear solution. 193 (a) Pitchfork bifurcation diagram of leading-order amplitude versus forcing parameter. (b) The corresponding diagram when asymmetry is introduced. 195 A system of pendulums attached to a twisting rubber band. 199 A kink propagating along a series of pendulums attached to a rod. 200 Travelling wave solution of the nonlinear beam equations. 201 A beam clamped near the edge of a table. 206 A beam supported at two points. 207 The first three buckling modes of a vertically clamped beam. 213
x 5.1 5.2 5.3 5.4 5.5 5.6 6.1 6.2 7.1 7.2 7.3 7.4 7.5 7.6 7.7 7.8 7.9 7.10 7.11 7.12 7.13 7.14 7.15 7.16 7.17 7.18 8.1 8.2 8.3 8.4 8.5 8.6 8.7 8.8 8.9 8.10 8.11 8.12
List of illustrations The deformation of a small scalene cylinder. Typical force–strain graphs for uniaxial tests on various materials. A square membrane subject to an isotropic tensile force. Response diagrams for a biaxially-loaded incompressible sheet of Mooney–Rivlin material. Scaled pressure inside a balloon as a function of the stretch for various values of the Mooney–Rivlin parameter. Gas pressure inside a cavity as a function of inflation coefficient for various values of the Mooney–Rivlin parameter. The edge of a plate subject to tractions. The geometry of a deformed two-dimensional plate. Definition sketch of a thin crack. Definition sketch for contact between two solids. (a) A Mode III crack. (b) A cross-section in the (x, y)-plane. √ Definition sketch for the function z 2 − c2 . Displacement field for a Mode III crack. (a) A planar Mode II crack. (b) The regularised problem of a thin elliptical crack. Contour plot of the maximum shear stress around a Mode II crack. The displacement of a Mode II crack under increasing shear stress. A Mode I crack. Contour plot of the maximum shear stress around a Mode I crack. The displacement of a Mode I crack under increasing normal stress. Solution for the contact between a string and a level surface. Three candidate solutions for a contact problem. The contact between a beam and a horizontal surface under a uniform pressure. Contact between a rigid body and an elastic half-space. The penetration of a quadratic punch into an elastic half-space. A flexible ruler flattened against a table. A wave travelling along a rope on the ground. A typical stress–strain relationship for a plastic material. The stress–strain relationship for a perfectly plastic material. The forces acting on a particle at the surface of a granular material. The normal force and frictional force acting on a surface element inside a granular material. The Mohr circle. The triaxial stress factor versus angle of friction. An antiplane cut-and-weld operation. The displacement field in an edge dislocation. An edge dislocation in a square crystal lattice. A moving edge dislocation. The normalised torque versus twist applied to an elastic-plastic cylindrical bar. The normalised torque versus twist applied to an elastic-plastic cylindrical bar, showing the recovery phase.
218 233 234 235 236 238 254 269 288 288 290 292 293 297 301 303 304 306 307 310 311 314 317 319 326 326 329 330 331 332 333 336 339 340 341 342 347 348
List of illustrations 8.13 8.14
xi
The free-boundary problem for an elastic-perfectly plastic torsion bar. 349 Residual shear stress in a gun barrel versus radial distance for different values of the maximum internal pressurisation. 352 8.15 The Tresca yield surface. 355 8.16 The von Mises yield surface. 356 8.17 The Coulomb yield surface. 358 8.18 L¨ uders bands in a thin sheet of metal. 369 8.19 The Mohr surface for three-dimensional granular flow. 373 8.20 The normalised torque versus twist applied to an elastic-plastic cylindrical bar undergoing a loading cycle. 375 9.1 (a) A spring; (b) a dashpot; (c) a spring and dashpot connected in parallel; (d) a spring and dashpot connected in series. 380 9.2 (a) Applied tension as a function of time. (b) Resultant displacement of a linear elastic spring. (c) Resultant displacement of a linear dashpot.381 9.3 Displacement of a Voigt element due to the applied tension shown in Figure 9.2(a). 382 9.4 Displacement of a Maxwell element due to the applied tension shown in Figure 9.2(a). 383 9.5 (a) The variation of Young’s modulus with position in a bar. (b) The corresponding longitudinal displacement. 392 9.6 (a) The variation of Young’s modulus with position in a bar. (b) The corresponding longitudinal displacement. 395 9.7 A periodic microstructured shear modulus. 396 9.8 A symmetric, piecewise constant shear modulus distribution. 400 9.9 Some modulus distributions that are antisymmetric about the diagonals of a square. 402 9.10 Dimensionless wavenumber versus the Young’s modulus non-uniformity parameter. 407 9.11 The one-dimensional squeezing of a sponge. 411 9.12 Dimensionless stress applied to a sponge versus dimensionless time for different values of the P´eclet number. 412 9.13 A Jeffreys viscoelastic element. 418 9.14 A system of masses connected by springs and dashpots in parallel. 418 9.15 A system of masses connected by springs and dashpots in series. 419 9.16 Dimensionless wavenumber versus Young’s modulus contrast for a piecewise uniform bar. 424 A1.1 A small reference box. 432 A1.2 Cylindrical polar coordinates. 437 A1.3 Spherical polar coordinates. 438
Prologue
Although solid mechanics is a vitally important branch of applied mechanics, it is often less popular, at least among students, than its close relative, fluid mechanics. Several reasons can be advanced for this disparity, such as the prevalence of tensors in models for solids or the especial difficulty of handling nonlinearity. Perhaps the most daunting prospect for the student is the multitude of different behaviours that can occur and cause elementary theories of elasticity to become irrelevant in practice. Examples include fracture, buckling and plasticity, and these pose intellectual challenges in solid mechanics that are every bit as fascinating as concepts like flight, shock waves and turbulence in fluid dynamics. Our principal objective in this book is to demonstrate this fact to undergraduate and beginning graduate students. We aim to give the subject as wide an accessibility as possible to mathematically-minded students and to emphasise the interesting mathematical issues that it raises. We do this by relating the theory to practical applications where surprising phenomena occur and where innovative mathematical methods are needed. Our layout is essentially pragmatic. Although more advanced texts in solid mechanics often begin with quite general theories founded on basic mechanical and thermodynamic principles, we start from the very simplest models, based on elementary observations in engineering and physics, and build our way towards models that are the basis for current applied research in solid mechanics. Hence, we begin by deriving the basic Navier equations of linear elasticity, before illustrating the mathematical techniques that allow these equations to be solved in many different practically relevant situations, both static and dynamic. We then proceed to describe some approximate theories for the elastic deformation of thin solids, namely bars, strings, beams, rods, plates and shells. We soon discover that many everyday phenomena, such as the buckling of a beam under a compressive load, cannot be fully described xiii
xiv
Prologue
using linear theories. We therefore give a brief exposition of the general theory of nonlinear elasticity, and then show how formal asymptotic methods allow simplified linear and weakly nonlinear models to be systematically deduced. Although we regard such asymptotic techniques as invaluable to any applied mathematician, these last two topics may both be omitted on a first reading without loss of continuity. We go on to present simple models for fracture and contact, comparing and contrasting these apparently similar phenomena. Next, we show how plasticity theory can be used to describe situations where a solid yields under a sufficiently high stress. Finally, we show how elasticity theory may be generalised to include further physical effects, such as thermal stresses, viscoelasticity and porosity. These “combined fields” of solid mechanics are increasingly finding applications in industrial and medical processes, and pose ever more elaborate modelling questions. Despite the breadth of the models and relevant techniques that will emerge in this book, we will usually try to present the theoretical developments ab initio. Nonetheless, the book is very far from being self-contained. Any student who aspires to becoming a solid mechanics specialist will have to delve further into the literature, and we will provide references to help with this. We assume only that the reader has a reasonable familiarity with the calculus of several variables. Fluency with the more advanced techniques required for Chapters 6 and 7, in particular, will readily be acquired by a student who works through the exercises in the early Chapters, especially those cited in the text. Indeed, we firmly believe that solid mechanics provides a wonderful arena in which to build an understanding of such important mathematical areas as linear algebra, partial differential equations, complex variable theory, differential geometry and the calculus of variations. Our hope is that, having read this book, a student should be able to confront any practical problem that may be encountered in everyday solid mechanics with at least some idea of the basic mathematical modelling that will be required. During the writing of this book, we received a great deal of help and inspiration as a result of discussions with David Allwright, Jon Chapman, Sam Howison, L. Mahadevan, Roman Novokshanov and Domingo Salazar, as well as many other colleagues and students too numerous to thank individually. We would like to express our particular gratitude to Gareth Jones, Hilary Ockendon and Tom Witelski who gave invaluable advice on draft Chapters. We are also indebted to David Tranah and his colleagues at Cambridge University Press for helping to make this book a reality.
1 Modelling solids
1.1 Introduction In everyday life we regularly encounter physical phenomena that apparently vary continuously in space and time. Examples are the bending of a paper clip, the flow of water or the propagation of sound or light waves. Such phenomena can be described mathematically, to lowest order, by a continuum model, and this book will be concerned with that class of continuum models that describes solids. Hence, at least to begin with, we will avoid all consideration of the “atomistic” structure of solids, even though these ideas lead to great practical insight and also to some beautiful mathematics. When we refer to a solid “particle”, we will be thinking of a very small region of matter but one whose dimension is nonetheless much greater than an atomic spacing. For our purposes, the diagnostic feature of a solid is the way in which it responds to an applied system of forces and moments. There is no hard-andfast rule about this but, for most of this book, we will say that a continuum is a solid when the response consists of displacements distributed through the material. In other words, the material starts at some reference state, from which it is displaced by a distance that depends on the applied forces. This is in contrast with a fluid, which has no special rest state and responds to forces via a velocity distribution. Our modelling philosophy is straightforward. We take the most fundamental pieces of experimental evidence, for example Hooke’s law, and use mathematical ideas to combine this evidence with the basic laws of mechanics to construct a model that describes the elastic deformation of a continuous solid. Following this simple approach, we will find that we can construct solid mechanics theories for phenomena as diverse as earthquakes, ultrasonic testing and the buckling of railway tracks. 1
2
Modelling solids
By basing our theory on Hooke’s law, the simplest model of elasticity, for small enough forces and displacements, we will first be led to a system of differential equations that is both linear, and therefore mathematically tractable, and reversible for time-dependent problems. By this we mean that, when forces and moments are applied and then removed, the system eventually returns to its original state without any significant energy being lost, i.e. the system is not dissipative. Reversibility may apply even when the forces and displacements are so large that the problem ceases to be linear; a rubber band, for example, can undergo large displacements and still return to its initial state. However, nonlinear elasticity encompasses some striking new behaviours not predicted by linear theory, including the possibility of multiple steady states and buckling. For many materials, experimental evidence reveals that even more dramatic changes can take place as the load increases, the most striking phenomenon being that of fracture under extreme stress. On the other hand, as can be seen by simply bending a metal paper clip, irreversibility can readily occur and this is associated with plastic flow that is significantly dissipative. In this situation, the solid takes on some of the attributes of a fluid, but the model for its flow is quite different from that for, say, water. Practical solid mechanics encompasses not only all the phenomena mentioned above but also the effects of elasticity when combined with heat transfer (leading to thermoelasticity) and with genuine fluid effects, in cases where the material flows even in the absence of large applied forces (leading to viscoelasticity) or when the material is porous (leading to poroelasticity). We will defer consideration of all these combined fields until the final chapter. 1.2 Hooke’s law Robert Hooke (1678) wrote “it is . . . evident that the rule or law of nature in every springing body is that the force or power thereof to restore itself to its natural position is always proportionate to the distance or space it is removed therefrom, whether it be by rarefaction, or separation of its parts the one from the other, or by condensation, or crowding of those parts nearer together.”
Hooke’s observation is exemplified by a simple high-school physics experiment in which a tensile force T is applied to a spring whose natural length is L. Hooke’s law states that the resulting extension of the spring is proportional to T : if the new length of the spring is , then T = k( − L),
(1.2.1)
where the constant of proportionality k is called the spring constant.
1.3 Lagrangian and Eulerian coordinates
3
Hooke devised his law while designing clock springs, but noted that it appears to apply to all “springy bodies whatsoever, whether metal, wood, stones, baked earths, hair, horns, silk, bones, sinews, glass and the like.” In practice, it is commonly observed that k scales with 1/L; that is, everything else being equal, a sample that is initially twice as long will stretch twice as far under the same force. It is therefore sensible to write (1.2.1) in the form −L , (1.2.2) T = k L where k is the elastic modulus of the spring, which will be defined more rigorously in Chapter 2. The dimensionless quantity ( − L)/L, measuring the extension relative to the initial length, is called the strain. Equation (1.2.2) is the simplest example of the all-important constitutive law relating the force to displacement. As shown in Exercise 1.3, it is possible to construct a one-dimensional continuum model for an elastic solid from this law, but, to generalise it to a three-dimensional continuum, we first need to generalise the concepts of strain and tension.
1.3 Lagrangian and Eulerian coordinates Suppose that a three-dimensional solid starts, at time t = 0, in its rest state, or reference state, in which no macroscopic forces exist in the solid or on its boundary. Under the action of any subsequently applied forces and moments, the solid will be deformed such that, at some later time t, a “particle” in the solid whose initial position was the point X is displaced to the point x (X, t). This is a Lagrangian description of the continuum: if the independent variable X is held fixed as t increases, then x(X, t) labels a material particle. In the alternative Eulerian approach, we consider the material point which currently occupies position x at time t, and label its initial position by X(x, t). In short, the Eulerian coordinate x is fixed in space, while the Lagrangian coordinate X is fixed in the material. The displacement u(X, t) is defined in the obvious way to be the difference between the current and initial positions of a particle, that is u(X, t) = x(X, t) − X.
(1.3.1)
Many basic problems in solid mechanics amount to determining the displacement field u corresponding to a given system of applied forces. The mathematical consequence of our statement that the solid is a continuum is that there must be a smooth one-to-one relationship between X and x, i.e. between any particle’s initial position and its current position.
4
Modelling solids
This will be the case provided the Jacobian of the transformation from X to x is bounded away from zero: ∂xi . (1.3.2) 0 < J < ∞, where J = det ∂Xj The physical significance of J is that it measures the change in a small volume compared with its initial volume: dx1 dx2 dx3 = J dX1 dX2 dX3 ,
or
dx = J dX
(1.3.3)
as shorthand. The positivity of J means that we exclude the possibility that the solid turns itself inside-out. We can use (1.3.3) to derive a kinematic equation representing conservation of mass. Consider a moving volume V (t) that is always bounded by the same solid particles. Its mass at time t is given, in terms of the density ρ(X, t), by ρ dx = ρJ dX. (1.3.4) M (t) = V (t)
V (0)
Since V (t) designates a fixed set of material points, M (t) must be a constant, namely its initial value M (0): ρJ dX = M (t) = M (0) = ρ0 dX, (1.3.5) V (0)
V (0)
where ρ0 is the density in the rest state. Since V is arbitrary, we deduce that ρJ = ρ0 .
(1.3.6)
Hence, we can calculate the density at any time t in terms of ρ0 and the displacement field. The initial density ρ0 is usually taken as constant, but (1.3.6) also applies if ρ0 = ρ0 (X).
1.4 Strain To generalise the concept of strain introduced in Section 1.2, we consider the deformation of a small line segment joining two neighbouring particles with initial positions X and X + δX. At some later time, the solid deforms such that the particles are displaced to X + u(X, t) and X + δX + u(X + δX, t) respectively. Thus we can use Taylor’s theorem to show that the line element
1.4 Strain
5
δX that joins the two particles is transformed to δx = δX + u(X + δX, t) − u(X, t) = δX + (δX · ∇)u(X, t) + · · · , (1.4.1) where (δX · ∇) = δX1
∂ ∂ ∂ + δX2 + δX3 . ∂X1 ∂X2 ∂X3
(1.4.2)
Let L = |δX| and = |δx| denote the initial and current lengths respectively of the line segment; the difference − L is known as the stretch. Then, to lowest order in L, 2 = |δX + (δX · ∇)u(X, t)|2 .
(1.4.3)
Although we will try in subsequent chapters to minimise the use of suffices, it is helpful at this stage to introduce components so that X = (Xi ) = (X1 , X2 , X3 )T and similarly for u. Then (1.4.3) may be written in the form 3 2 − L2 = 2 Eij δXi δXj , (1.4.4) i,j=1
where 1 Eij = 2
∂uk ∂uk ∂uj ∂ui + + ∂Xj ∂Xi ∂Xi ∂Xj 3
.
(1.4.5)
k=1
By way of introduction to some notation that will be useful later, we point out that (1.4.4) may be written in at least two alternative ways. First, we may invoke the summation convention, in which one automatically sums over any repeated suffix. This avoids the annoyance of having to write explicit summation, so (1.4.4) is simply ∂uj 1 ∂ui ∂uk ∂uk 2 2 . + + = L + 2Eij δXi δXj , where Eij = 2 ∂Xj ∂Xi ∂Xi ∂Xj (1.4.6) Second, we note that 2 − L2 is a quadratic form on the symmetric matrix E whose components are (Eij ): 2 − L2 = 2 δX T E δX.
(1.4.7)
It is clear from (1.4.4) that the stretch is measured by the quantities Eij ; in particular, the stretch is zero for all line elements if and only if Eij ≡ 0. It is thus natural to identify Eij with the strain. Now let us ask: “what happens when we perform the same calculation in a coordinate system rotated by an
6
Modelling solids
orthogonal matrix P = (pij )?” Intuitively, we might expect the strain to be invariant under such a rotation, and we can verify that this is so as follows. The vectors X and u are transformed to X and u in the new coordinate system, where X = P X,
u = P u.
(1.4.8)
Since P is orthogonal, (1.4.8) may be inverted to give X = P T X . Alternatively, using suffix notation, we have Xβ = pjβ Xj ,
ui = piα uα .
The strain in the new coordinate system is denoted by ∂uj ∂uk ∂uk 1 ∂ui , + + Eij = 2 ∂Xj ∂Xi ∂Xi ∂Xj
(1.4.9)
(1.4.10)
which may be manipulated using the chain rule, as shown in Exercise 1.4, to give Eij = piα pjβ Eαβ .
(1.4.11)
In matrix notation, (1.4.11) takes the form E = P EP T ,
(1.4.12)
so the 3 × 3 symmetric array (Eij ) transforms exactly like a matrix representing a linear transformation of the vector space R3 . Arrays that obey the transformation law (1.4.11) are called second-rank Cartesian tensors, and E = (Eij ) is therefore called the strain tensor.† Almost as important as the fact that E is a tensor is the fact that it can vanish without u vanishing. More precisely, if we consider a rigid-body translation and rotation u = c + (Q − I)X,
(1.4.13)
where I is the identity matrix while the vector c and orthogonal matrix Q are constant, then E is identically zero. This result follows directly from substituting (1.4.13) into (1.4.6) and using the fact that QQT = I, and confirms our intuition that a rigid-body motion induces no deformation. †
The word “tensor” as used here is effectively synonymous with “matrix”, but it is easy to generalise (1.4.11) to a tensor with any number of indices. A vector, for example, is a tensor with just one index.
1.5 Stress
7
1.5 Stress In the absence of any volumetric (e.g. gravitational or electromagnetic) effects, a force can only be transmitted to a solid by being applied to its boundary. It is, therefore, natural to consider the force per unit area or stress applied at that boundary. To do so, we now analyse an infinitesimal surface element, whose area and unit normal are da and n respectively. If it is contained within a stressed medium, then the material on (say) the side into which n points will exert a force df on the element. (By Newton’s third law, the material on the other side will also exert a force equal to −df .) In the expectation that the force should be proportional to the area da, we write df = σ da,
(1.5.1)
where σ is called the traction or stress acting on the element. Perhaps the most familiar example is that of an inviscid fluid, in which the stress is related to the pressure p by σ = −pn.
(1.5.2)
This expression implies that (i) the stress acts only in a direction normal to the surface element, (ii) the magnitude of the stress (i.e. p) is independent of the direction of n. In an elastic solid, neither of these simplifying assumptions holds; we must allow for stress which acts in both tangential and normal directions and whose magnitude depends on the orientation of the surface element. First consider a surface element whose normal points in the x1 -direction, and denote the stress acting on such an element by τ 1 = (τ11 , τ21 , τ31 )T . By doing the same for elements with normals in the x2 - and x3 -directions, we generate three vectors τ j (j = 1, 2, 3), each representing the stress acting on an element normal to the xj -direction. In total, therefore, we obtain nine scalars τij (i, j = 1, 2, 3), where τij is the i-component of τ j , that is τ j = τij ei ,
(1.5.3)
where ei is the unit vector in the xi -direction. The scalars τij may be used to determine the stress on an arbitrary surface element by considering the tetrahedron shown in Figure 1.1. Here ai denotes the area of the face orthogonal to the xi -axis. The fourth face has area a = a21 + a22 + a23 ; in fact if this face has unit normal n as shown, with components (ni ), then it is an elementary exercise in trigonometry to show that ai = ani .
8
Modelling solids
x3
a1 n a2 x2
a3 x1 Fig. 1.1 A reference tetrahedron; ai is the area of the face orthogonal to the xi -axis.
The outward normal to the face with area a1 is in the negative x1 -direction and the force on this face is thus −a1 τ 1 . Similar expressions hold for the faces with areas a2 and a3 . Hence, if the stress on the fourth face is denoted by σ, then the total force on the tetrahedron is f = aσ − aj τ j .
(1.5.4)
When we substitute for aj and τ j , we find that the components of f are given by fi = a (σi − τij nj ) .
(1.5.5)
Now we shrink the tetrahedron to zero volume. Since the area a scales with 2 , where is a typical edge length, while the volume is proportional to 3 , if we apply Newton’s second law and insist that the acceleration be finite, we see that f /a must tend to zero as → 0.† Hence we deduce an †
Readers of a sensitive disposition may be slightly perturbed by our glibly letting the dimensional variable tend to zero: if is reduced indefinitely then we will eventually reach an atomic scale on which the solid can no longer be treated as a continuum. We reassure such readers that (1.5.6) can be more rigorously justified provided the macroscopic dimensions of the solid are large compared to any atomistic length-scale.
1.5 Stress
9
τ22 τ12 τ21 τ11 δx2
G
τ11
x2 δx1
τ21
τ12 x1
τ22
Fig. 1.2 The forces acting on a small two-dimensional element.
expression for σ: σi = τij nj ,
or σ = τ n.
(1.5.6)
This important result enables us to find the stress on any surface element in terms of the nine quantities (τij ) = τ . Now let us follow Section 1.4 and examine what happens to τij when we rotate the axes by an orthogonal matrix P . In the new frame, (1.5.6) will become σ = τ n
(1.5.7)
where, since σ and n are vectors, they transform according to σ = P σ,
n = P n.
(1.5.8)
It follows that τ n = (P τ P T )n and so, since n is arbitrary, τ = P τ P T,
or τij = piα pjβ ταβ .
(1.5.9)
Thus τij , like Eij , is a second-rank tensor, called the Cauchy stress tensor. We can make one further observation about τij by considering the angular momentum of the small two-dimensional solid element shown in Figure 1.2. The net anticlockwise moment acting about the centre of mass G is (per unit length in the x3 -direction) 2 (τ21 δx2 )
δx1 δx2 − 2 (τ12 δx1 ) , 2 2
10
Modelling solids
where τ21 and τ12 are evaluated at G to lowest order. By letting the rectangle shrink to zero (see again the footnote on page 8), and insisting that the angular acceleration be finite, we deduce that τ12 = τ21 . This argument can be generalised to three dimensions (see Exercise 1.5) and it shows that τij ≡ τji
(1.5.10)
for all i and j, i.e. that τij , like Eij , is a symmetric tensor. 1.6 Conservation of momentum Now we derive the basic governing equation of solid mechanics by applying Newton’s second law to a material volume V (t) that moves with the deforming solid: ∂ui d ρ dx = gi ρ dx + τij nj da. (1.6.1) dt V (t) ∂t V (t) ∂V (t) The terms in (1.6.1) represent successively the rate of change of momentum of the material in V (t), the force due to an external body force g, such as gravity, and the traction exerted on the boundary of V , whose unit normal is n, by the material around it. We differentiate under the integral (using the fact that ρ dx = ρ0 dX is independent of t) and apply the divergence theorem to the final term to obtain ∂τij ∂ 2 ui ρ dx = gi ρ dx + dx. (1.6.2) 2 V (t) ∂t V (t) V (t) ∂xj Assuming each integrand is continuous, and using the fact that V (t) is arbitrary, we arrive at Cauchy’s momentum equation: ρ
∂τij ∂ 2 ui = ρgi + . 2 ∂t ∂xj
(1.6.3)
This may alternatively be written in vector form by adopting the following notation for the divergence of a tensor: we define the ith component of ∇ · τ to be ∂τji (∇ · τ )i = . (1.6.4) ∂xj Since τ is symmetric, we may thus write Cauchy’s equation as ∂2u = ρg + ∇ · τ. (1.6.5) ∂t2 This equation applies to any continuous medium for which a displacement u and stress tensor τ can be defined. The distinction between solid, fluid ρ
1.7 Linear elasticity
11
or some other continuum comes when we impose an empirical constitutive relation between τ and u. For solids, (1.6.5) already confronts us with a distinctive fundamental difficulty. The most obvious generalisation of Hooke’s law is to suppose that a linear relationship exists between the stress τ and the strain E. But we now recall that E was defined in Section 1.4 in terms of the Lagrangian variables X; indeed, the time derivative in (1.6.5) is taken in a Lagrangian frame, with X fixed. On the other hand, the stress tensor τ has been defined relative to Eulerian coordinates and is differentiated in (1.6.5) with respect to the Eulerian variable x. It is not immediately clear, therefore, how the stress and strain, which are defined in different frames of reference, may be self-consistently related. We will postpone the full resolution of this difficulty until Chapter 5 and, for the present, restrict our attention to linear elasticity in which, as we shall see, the two frames are essentially identical.
1.7 Linear elasticity The theory of linear elasticity follows from the assumption that the displacement u is small relative to any other length-scale. This assumption allows the theory developed thus far to be simplified in several ways. First, it means that ∂ui /∂Xj is small for all i and j. Second, we note from (1.3.1) that x and X are equal to lowest order in u. Hence, if we only consider leading-order terms, there is no need to distinguish between the Eulerian and Lagrangian variables: we can simply replace X by x and ∂ui /∂Xj by ∂ui /∂xj throughout. A corollary is that the Jacobian J is approximately equal to one, so (1.3.6) tells us that the density ρ is fixed, to leading order, at its initial value ρ0 . Finally, we can use the smallness of ∂ui /∂xj to neglect the quadratic term in (1.4.5) and hence obtain the linearised strain tensor ∂uj 1 ∂ui Eij ≈ eij = + . (1.7.1) 2 ∂xj ∂xi Much of this book will be concerned with this approximation. Therefore, and with a slight abuse of notation, we will write E = (eij ). Remembering (1.4.13), we note that it is possible to approximate E by (1.7.1) even when u is not small compared with X, just as long as u is close to a rigid-body translation and rotation. This situation is called geometric nonlinearity and we will encounter it frequently in Chapters 4 and 6. It occurs because Eij is identically zero for rigid-body motions of the solid given by (1.4.13); however eij does not vanish for such rigid-body motions,
12
Modelling solids
but rather for displacements of the form u = c + ω × x,
(1.7.2)
where c and ω are constant (see Exercise 1.6). Assuming the validity of (1.7.1), we can now generalise Hooke’s law by postulating a linear relationship between the stress and strain tensors. We assume that τ is zero when E is; in other words the stress is zero in the reference state. This is not the case for pre-stressed materials, and we will consider some of the implications of so-called residual stress in Chapter 8. Even with this assumption, we apparently are led to the problem of defining 81 material parameters Cijk (i, j, k, = 1, 2, 3) such that τij = Cijk ek .
(1.7.3)
The symmetry of τij and eij only enables us to reduce the number of unknowns to 36. This can be reduced to a more manageable number by assuming that the solid is isotropic, by which we mean that it behaves the same way in all directions. This implies that Cijk must satisfy Cijk pii pjj pkk p ≡ Ci j k
(1.7.4)
for all orthogonal matrices P = (pij ). It can be shown (see, for example, Ockendon & Ockendon, 1995, pp. 7–9) that this is sufficient to reduce the specification of Cijk to just two scalar quantities λ and µ, such that Cijk = λδij δk + 2µδik δj ,
(1.7.5)
where δij is the usual Kronecker delta, which represents the identity matrix; consequently, τij = λ (ekk ) δij + 2µeij .
(1.7.6)
This relation can also be inverted to give the strain corresponding to a given stress, that is 1 λ(τkk ) (1.7.7) eij = τij − δij . 2µ (3λ + 2µ) In Chapter 9 we will consider solids, such as wood or fibre-reinforced materials, that are not isotropic, and for which (1.7.6) must be generalised. The material parameters λ and µ are known as the Lam´e constants, and µ is called the shear modulus.As we shall see in Chapter 2, λ and µ measure a material’s ability to resist elastic deformation. They have the units of pressure; typical values for a few familiar solid materials are given in Table 1.1. It will be observed that these values may be very large for relatively “hard”
1.8 The incompressibility approximation
Cartilage Rubber Polystyrene Granite Glass Copper Steel Diamond
λ (GPa)
µ (GPa)
3 × 10−5 0.04 2.3 10 28 86 100 270
9 × 10−5 0.003 1.2 30 28 37 78 400
13
Table 1.1 Typical values of the Lam´e constants λ and µ for some everyday materials (1 GPa = 109 N m−2 = 104 atmospheres; a typical car tyre pressure is two atmospheres). materials, the significance being that tractions much less than these values will result in small deformations, so that linear elasticity is valid. Now we substitute our linear constitutive relation (1.7.6) into the momentum equation (1.6.3) and replace X with x to obtain the Navier equation, also known as the Lam´e equation, ∂2u = ρg + (λ + µ) grad div u + µ∇2 u. (1.7.8) ∂t2 Recall that ρ does not vary to leading order, so (1.7.8) comprises three equations for the three components of u. It may alternatively be written in component form ρ
ρ
∂ 2 uj ∂ 2 ui ∂ 2 ui = ρg + (λ + µ) + µ , i ∂t2 ∂xi ∂xj ∂x2j
(1.7.9)
where the final ∂x2j is treated as a repeated suffix, or ∂2u = ρg + (λ + 2µ) grad div u − µ curl curl u, ∂t2 where we have used the well-known vector identity ρ
“del squared equals grad div minus curl curl.”
(1.7.10)
(1.7.11)
1.8 The incompressibility approximation There is an interesting and important class of materials that, although elastic, are virtually incompressible, so they may be sheared elastically but are highly resistant to tension or compression. In linear elasticity, this amounts to saying that the Lam´e constant λ is much larger than the shear modulus µ.
14
Modelling solids
The values given in Table 1.1 show that rubber has this property, as do many biomaterials such as muscle. If a material is almost incompressible, we can set 1 λ = , µ ε
(1.8.1)
where ε is a small parameter. From (1.7.8), we expect that, in the limit ε → 0, div u will be of order ε. Hence, if we define a scalar function p such that µ (1.8.2) pε = − div u, ε then pε will approach a finite limit p as ε → 0. When we now substitute (1.8.1) and (1.8.2) into the Navier equation (1.7.8) and let ε → 0, we obtain ∂2u = ρg − ∇p + µ∇2 u, ∂t2 along with the limit of (1.8.2), that is ρ
div u = 0.
(1.8.3a)
(1.8.3b)
The condition (1.8.3b) means that each material volume is conserved during the deformation, and it imposes an extra constraint on the Navier equation. The extra unknown p, representing the isotropic pressure in the medium, gives us the extra freedom we need to satisfy this constraint. 1.9 Energy We can obtain an energy equation from (1.6.3) by taking the dot product with ∂u/∂t and integrating over an arbitrary volume V : ∂τij ∂ui ∂ui ∂ 2 ui ∂ui dx = dx + dx. (1.9.1) ρ 2 ρgi ∂t ∂t ∂t V V V ∂xj ∂t The final term may be rearranged, using the divergence theorem, to ∂τij ∂ui ∂eij ∂ui τij dx = τij nj da − dx. (1.9.2) ∂t V ∂xj ∂t ∂V ∂t V
1.9 Energy
15
Hence (1.9.1) may be written in the form d dt
V
1 ∂u 2 ρ dx + W dx 2 ∂t V ∂ui ∂ui dx + τij nj da, (1.9.3) ρgi = ∂t V ∂V ∂t
where W is a scalar function of the strain components that is chosen to satisfy ∂W = τij . ∂eij
(1.9.4)
With τij given by (1.7.6), we can integrate (1.9.4) to determine W up to an arbitrary constant as 1 1 W = τij eij = λ (ekk )2 + µ (eij eij ). 2 2
(1.9.5)
Here the summation convention is invoked such that (ekk )2 is the square of the trace of E, while (eij eij ) is the sum of the squares of the components of E. The first term in braces in (1.9.3) is the net kinetic energy in V , while the terms on the right-hand side represent the rate of working of the external body force g and the tractions on ∂V respectively. Hence, in the absence of other energy sources resulting from, say, chemical or thermal effects, we can interpret equation (1.9.3) as a statement of conservation of energy. The difference between the rate of working and the rate of change of kinetic energy is the rate at which elastic energy is stored in the material as it deforms; W is therefore called the strain energy density. This is analogous to the energy stored in a stretched spring (see Exercise 1.1) and, at a fundamental scale, is a manifestation of the energy stored in the bonds between the atoms. If µ, λ > 0, we can easily see from (1.9.5) that W is a non-negative function of the strain components, whose unique global minimum is attained when eij = 0. In fact, Exercise 1.7 demonstrates that it is only necessary to have µ, (λ + 2µ/3) > 0. The net conservation of energy implied by (1.9.3) reflects the fact that the Navier equation is not dissipative. Furthermore, even without the constitutive relation (1.7.6), the steady Navier equation is a necessary condition for the net gravitational and strain energy in an elastic body D, namely U= W − ρg · u dx, (1.9.6) D
16
Modelling solids
to be minimised, as shown in Exercise 1.8. However, the situation changes when thermal effects are important, as we will see in Chapter 9.
1.10 Boundary conditions and well-posedness Suppose that we wish to solve (1.7.8) for u(x, t) when t is positive and x lies in some prescribed domain D. We now ask: “what sort of boundary conditions may be imposed on ∂D to obtain a well-posed mathematical problem, in other words, one for which a solution u exists, is unique and depends continuously on the boundary data?” For boundary-value problems in linear elasticity, it is generally far easier to discuss questions of uniqueness than it is to prove existence. Hence in this section we will focus only on establishing uniqueness. In elastostatic problems, in which the left-hand side of (1.7.8) is zero, the Navier system is, roughly speaking, a generalisation of a scalar elliptic equation. By analogy, it seems appropriate for either u or three linearly independent scalar combinations of u and ∂u/∂n to be prescribed on ∂D. In many physical problems, we specify either the displacement u or the traction τ n everywhere on the boundary, and we will now examine each of these in turn. First consider a solid body D on whose boundary the displacement is prescribed, that is u = ub (x)
on ∂D.
(1.10.1)
Inside D, u satisfies the steady Navier equation ∂τij + ρgi = 0, ∂xj
(1.10.2)
and we will now show that, if a solution u of (1.7.6), (1.10.2) with the boundary condition (1.10.1) exists, then it is unique. Suppose that two solutions u(1) and u(2) exist and let u = u(1) −u(2) . Thus u satisfies the homogeneous problem, with ub = g = 0. Now, by multiplying (1.10.2) by ui , integrating over D and using the divergence theorem, we obtain ui τij nj da = eij τij dx = 2 W dx, (1.10.3) ∂D
D
D
where W is given by (1.9.5). The left-hand side of (1.10.3) is zero by the boundary conditions, while the integrand W on the right-hand side is nonnegative and must, therefore, be zero. It follows that the strain tensor eij
1.10 Boundary conditions and well-posedness
17
is identically zero in D, and the displacement can therefore only be a rigidbody motion (i.e. a uniform translation and rotation; see Exercise 1.6). Since u is zero on ∂D, we deduce that it must be zero everywhere and, hence, that u(1) ≡ u(2) . Now we attempt the same calculation when the surface traction, rather than the displacement, is specified: τ n = σ(x)
on ∂D.
(1.10.4)
Like the Neumann problem for a scalar elliptic partial differential equation (Ockendon et al., 2003, p. 154), the Navier equation only admits solutions satisfying (1.10.4) if so-called solvability conditions are satisfied. If we integrate (1.10.2) over D and use the divergence theorem, we find that τij nj da + ρgi dx = 0 (1.10.5) ∂D
and hence that
D
σ da +
∂D
ρg dx = 0.
(1.10.6)
D
This represents a net balance between the forces, namely surface traction and gravity, acting on D. An analogous balance between the moments acting on D may also be obtained by taking the cross product of x with (1.10.2) before integrating, to give x×σ da + ρx×g dx = 0, (1.10.7) ∂D
D
as shown in Exercise 1.9. As well as representing physical balances on the system, (1.10.6) and (1.10.7) may be interpreted as instances of the Fredholm Alternative (see Ockendon et al., 2003, p. 43). Now suppose the solvability conditions (1.10.6) and (1.10.7) are satisfied and that two solutions u(1) and u(2) of (1.10.2) and the boundary condition (1.10.4) exist. As before, the difference u = u(1) − u(2) satisfies the homogeneous version of the problem, with g and σ set to zero. By an argument analogous to that presented above, we deduce that the strain tensor eij must be identically zero. However, since u is now not specified on ∂D, we can only infer from this that the displacement is a rigid-body motion, as shown in Exercise 1.6. Thus the solution of (1.10.2) subject to the applied traction (1.10.4) is determined only up to the addition of an arbitrary translation and rotation. As well as the boundary conditions (1.10.1) and (1.10.4), there are generalisations in which the traction is specified on some parts of the boundary
18
Modelling solids n
solid 2 solid 1
Fig. 1.3 A small pill-box-shaped region at the boundary between two elastic solids.
and the displacement on others, for example in contact problems and in fracture, as described in Chapter 7. Another common generalisation of (1.10.1) and (1.10.4) occurs when two solids with different elastic moduli are bonded together across a common boundary ∂D, as shown in Figure 1.3. Then the displacement vectors are the same on either side of ∂D and, by balancing the stresses on the small pill-box-shaped region shown in Figure 1.3, we see that τ (1) n = τ (2) n,
(1.10.8)
where τ (1) and τ (2) are the values of τ on either side of the boundary. Thus there are six continuity conditions across such a boundary. On the other hand, if two unbonded solids are in smooth contact, only the normal displacement is continuous across ∂D. However, this loss of information is compensated by the fact that the four tangential components of τ (1) n and τ (2) n are zero and the normal components of these tractions are continuous. Frictional contact between rough unbonded surfaces poses serious modelling challenges, as we will see in Chapter 7. For elastodynamic problems, we may anticipate that (1.7.8) admits wavelike solutions. It may, therefore, be viewed as a generalisation of a scalar wave equation, such as the familiar equation
∂2w ∂2w = T ∂t2 ∂x2
(1.10.9)
which describes small transverse waves on a string with tension T and line density (see Section 4.3). We will examine elastic waves in more detail in Chapter 3 but, in the meantime, we expect to prescribe Cauchy initial conditions for u and ∂u/∂t at t = 0, as well as elliptic boundary conditions such as (1.10.1) or (1.10.4).
1.11 Coordinate systems
19
1.11 Coordinate systems In the next two chapters, we will construct some elementary solutions of the Navier equation (1.7.8). In doing so, it is often useful to employ coordinate systems particularly chosen to fit the geometry of the problem being considered. A detailed derivation of the Navier equation in an arbitrary orthogonal coordinate system may be found in the Appendix. Here we state the main results that will be useful in subsequent chapters for the three most popular coordinate systems, namely Cartesian, cylindrical polar and spherical polar coordinates. All three of these coordinate systems are orthogonal ; in other words the tangent vectors obtained by varying each coordinate in turn are mutually perpendicular. This means that the coordinate axes at any fixed point are orthogonal and may thus be obtained by a rotation of the usual Cartesian axes. Under the assumptions of isotropic linear elasticity, the Cartesian stress and strain components are related by (1.7.6), which is invariant under any such rotation. Hence the constitutive relation (1.7.6) applies literally to any orthogonal coordinate system.
1.11.1 Cartesian coordinates First we write out in full the results derived thus far using the usual Cartesian coordinates (x, y, z). To avoid the use of suffices, we will denote the displacement components by u = (u, v, w)T . It is also conventional to label the stress components by {τxx , τxy , . . .} rather than {τ11 , τ12 , . . .}, and similarly for the strain components. The linear constitutive relation (1.7.6) gives τxx = (λ + 2µ)exx + λeyy + λezz ,
τxy = 2µexy ,
τyy
= λexx + (λ + 2µ)eyy + λezz ,
τxz = 2µexz ,
τzz
= λexx + λeyy + (λ + 2µ)ezz ,
τyz = 2µeyz ,
(1.11.1)
where ∂u , ∂x ∂v , eyy = ∂y ∂w ezz = , ∂z exx =
∂u ∂v + , ∂y ∂x ∂v ∂w 2eyz = + , ∂z ∂x ∂u ∂w 2exz = + , ∂z ∂x 2exy =
(1.11.2)
20
Modelling solids
and the three components of Cauchy’s momentum equation are ∂τxy ∂τxz ∂2u ∂τxx + + , = ρgx + ∂t2 ∂x ∂y ∂z ∂τyy ∂τyz ∂τxy ∂2v ρ 2 = ρgy + + + , ∂t ∂x ∂y ∂z ∂τyz ∂τzz ∂2w ∂τxz + + , ρ 2 = ρgz + ∂t ∂x ∂y ∂z ρ
(1.11.3)
where the body force is g = (gx , gy , gz )T . In terms of the displacements, the Navier equation reads (assuming that λ and µ are constant) ∂ ∂2u (∇ · u) + µ∇2 u, = ρgx + (λ + µ) 2 ∂t ∂x ∂2v ∂ ρ 2 = ρgy + (λ + µ) (∇ · u) + µ∇2 v, ∂t ∂y 2 ∂ w ∂ ρ 2 = ρgz + (λ + µ) (∇ · u) + µ∇2 w. ∂t ∂z ρ
(1.11.4)
1.11.2 Cylindrical polar coordinates We define cylindrical polar coordinates (r, θ, z) in the usual way and denote the displacements in the r-, θ- and z-directions by ur , uθ and uz respectively. The stress components are denoted by τij where now i and j are equal to either r, θ or z and, as in Section 1.5, τij is defined to be the i-component of stress on a surface element whose normal points in the jdirection. As noted above, the constitutive relation (1.7.6) applies directly to this coordinate system, so that τrr = (λ + 2µ)err + λeθθ + λezz ,
τrθ = 2µerθ ,
τθθ = λerr + (λ + 2µ)eθθ + λezz ,
τrz = 2µerz ,
τzz = λerr + λeθθ + (λ + 2µ)ezz ,
τθz = 2µeθz ,
(1.11.5)
where the strain components are now given by ∂ur , ∂r 1 ∂uθ + ur , = r ∂θ ∂uz , = ∂z
∂uθ uθ 1 ∂ur + − , r ∂θ ∂r r ∂uz ∂ur + , = ∂z ∂r 1 ∂uz ∂uθ + . (1.11.6) = ∂z r ∂θ
err =
2erθ =
eθθ
2erz
ezz
2eθz
1.11 Coordinate systems
21
The three components of Cauchy’s momentum equation (1.6.3) read ∂ 2 ur ∂τrz τθθ 1 ∂ 1 ∂τrθ (rτrr ) + + − , = ρgr + 2 ∂t r ∂r r ∂θ ∂z r ∂ 2 uθ ∂τθz τrθ 1 ∂ 1 ∂τθθ ρ 2 = ρgθ + (rτrθ ) + + + , ∂t r ∂r r ∂θ ∂z r ∂ 2 uz ∂τzz 1 ∂ 1 ∂τθz ρ 2 = ρgz + (rτrz ) + + , ∂t r ∂r r ∂θ ∂z ρ
(1.11.7)
where the body force is g = gr er + gθ eθ + gz ez . Written out in terms of displacements, these become ∂ 2 ur ∂ ur 2 ∂uθ 2 ρ 2 = ρgr + (λ + µ) (∇ · u) + µ ∇ ur − 2 − 2 , ∂t ∂r r r ∂θ ∂ 2 uθ (λ + µ) ∂ uθ 2 ∂ur 2 (∇ · u) + µ ∇ uθ − 2 + 2 , ρ 2 = ρgθ + ∂t r ∂θ r r ∂θ ∂ 2 uz ∂ ρ 2 = ρgz + (λ + µ) (∇ · u) + µ∇2 uz , (1.11.8) ∂t ∂z where 1 ∂uθ ∂uz 1 ∂ (rur ) + + , r ∂r r ∂θ ∂z 1 ∂ ∂ui 1 ∂ 2 ui ∂ 2 ui ∇2 u i = + r + 2 r ∂r ∂r r ∂θ2 ∂z 2
∇·u =
(1.11.9)
are the divergence of u and the Laplacian of ui respectively, expressed in cylindrical polars. Detailed derivations of (1.11.6) and (1.11.7) are given in the Appendix. Notice the undifferentiated terms proportional to 1/r which are not present in the corresponding Cartesian expressions (1.11.2) and (1.11.3). The origin of these terms may be understood in two dimensions (r, θ) by considering the equilibrium of a small polar element as illustrated in Figure 1.4, in which ∂ταβ + ··· , ∂r ∂ταβ + ··· , + δθ ∂θ
τ˜αβ = ταβ (r + δr, θ) = ταβ + δr τˆαβ = ταβ (r, θ + δθ) = ταβ
(1.11.10)
when we expand using Taylor’s theorem. Summing the resultant forces in the r- and θ-directions to zero results in τ˜rr (r + δr) δθ − τrr rδθ − τˆθθ δr sin δθ + τˆrθ δr cos δθ − τrθ δr = 0, τˆθθ δr cos δθ − τθθ δr + τˆrθ δr sin δθ + τ˜rθ (r + δr) δθ − τrθ rδθ = 0.
(1.11.11)
22
Modelling solids
τˆrθ
τ˜rr
τ˜rθ τˆθθ
eθ
τrθ
τrr r δθ
er
δr
τrθ
τθθ
Fig. 1.4 Forces acting on a polar element of solid.
Now letting δθ, δr → 0 and using (1.11.10), we obtain 1 ∂τrθ τrr − τθθ ∂τrθ 1 ∂τθθ 2τrθ ∂τrr + + = 0, + + = 0, (1.11.12) ∂r r ∂θ r ∂r r ∂θ r which are the components of the two-dimensional steady Navier equation in plane polar coordinates with no body force; cf (1.11.7). The stress component τθθ is the so-called hoop stress in the θ-direction that results from inflating an elastic object radially; we will see an explicit example of hoop stress in Section 2.6. 1.11.3 Spherical polar coordinates The spherical polar coordinates (r, θ, φ) are defined in the usual way, such that the position vector of any point is given by r sin θ cos φ r(r, θ, φ) = r sin θ sin φ . (1.11.13) r cos θ Again, we can apply the constitutive relation (1.7.6) literally, to obtain τrr = (λ + 2µ)err + λeθθ + λeφφ ,
τrθ = 2µerθ ,
τθθ = λerr + (λ + 2µ)eθθ + λeφφ ,
τrφ = 2µerφ ,
τφφ = λerr + λeθθ + (λ + 2µ)eφφ ,
τθφ = 2µeθφ .
(1.11.14)
1.11 Coordinate systems
23
The linearised strain components are now given by ∂uθ uθ ∂ur 1 ∂ur , 2erθ = + − , ∂r r ∂θ ∂r r ∂uφ uφ 1 ∂uθ 1 ∂ur 2erφ = + ur , + − , = r ∂θ r sin θ ∂φ ∂r r uφ cot θ ur uθ cot θ 1 ∂uφ 1 ∂uφ 1 ∂uθ + + , 2eθφ = + − . = r sin θ ∂φ r r r sin θ ∂φ r ∂θ r (1.11.15)
err = eθθ eφφ
Cauchy’s equation of motion leads to the three equations 1 ∂(sin θτrθ ) 1 ∂(r2 τrr ) ∂ 2 ur + = ρg + r 2 2 ∂t r ∂r r sin θ ∂θ τθθ + τφφ 1 ∂τrφ − , + r sin θ ∂φ r 1 ∂(sin θτθθ ) ∂ 2 uθ 1 ∂(r2 τrθ ) + ρ 2 = ρgθ + 2 ∂t r ∂r r sin θ ∂θ τrθ − cot θτφφ 1 ∂τθφ + , + r sin θ ∂φ r ∂ 2 uφ 1 ∂(sin θτθφ ) 1 ∂(r2 τrφ ) + ρ 2 = ρgφ + 2 ∂t r ∂r r sin θ ∂θ τrφ + cot θτθφ 1 ∂τφφ + , + r sin θ ∂φ r ρ
(1.11.16)
where the body force is g = gr er +gθ eθ +gφ eφ . Again, (1.11.15) and (1.11.16) may be derived using the general approach given in the Appendix or more directly by analysing a small polar element. In terms of displacements, the Navier equation reads ρ
ρ
∂ 2 ur ∂ = ρgr + (λ + µ) (∇ · u) 2 ∂t ∂r ∂ 2ur 2 2 ∂uφ 2 (uθ sin θ) − 2 , + µ ∇ ur − 2 − 2 r r sin θ ∂θ r sin θ ∂φ
(λ + µ) ∂ ∂ 2 uθ (∇ · u) = ρgθ + ∂t2 r ∂θ uθ 2 ∂ur 2 cos θ ∂uφ 2 − 2 2 − 2 2 , + µ ∇ uθ + 2 r ∂θ r sin θ r sin θ ∂φ
24
ρ
Modelling solids
∂2u
φ ∂t2
(λ + µ) ∂ (∇ · u) = ρgφ + r sin θ ∂φ uφ 2 cos θ ∂uθ 2 ∂ur 2 + µ ∇ uφ + 2 , + 2 2 − 2 2 r sin θ ∂φ r sin θ ∂φ r sin θ
(1.11.17)
where 1 ∂uφ 1 ∂ 2 1 ∂ (sin θuθ ) + , r ur + 2 r ∂r r sin θ ∂θ r sin θ ∂φ 1 ∂ ∂ui 1 ∂ ∂ui 1 ∂ 2 ui ∇2 u i = 2 . r2 + 2 sin θ + 2 2 r ∂r ∂r r sin θ ∂θ ∂θ r sin θ ∂φ2 (1.11.18)
∇·u=
Exercises 1.1
A light spring of natural length L and spring constant k hangs freely with a mass m attached to one end and the other end fixed. Show that the length of the spring satisfies the differential equation m Deduce that 1 m 2
1.2
1.3
d dt
2
d2 + k( − L) − mg = 0. dt2 1 + k( − L)2 + mg(L − ) = const. 2
and interpret this result in terms of energy. A string, stretched to a tension T along the x-axis, undergoes small transverse displacements such that its position at time t is given by the graph z = w(x, t). Given that w satisfies the wave equation (1.10.9), where is the mass per unit length of the string, show that, if x = a and x = b are any two points along the string,
b ∂w ∂w b 1 ∂w 2 d 1 b ∂w 2 dx + T dx = T . dt 2 a ∂t ∂x ∂x ∂t a a 2 Interpret this result in terms of conservation of energy. A system of masses m along the x-axis at positions Xn = nL (n = 0, 1, 2, . . .) are linked by springs satisfying Hooke’s law (1.2.1), as shown in Figure 1.5. If each mass is displaced by a distance un (t), show that the tension Tn joining Xn to Xn+1 satisfies Tn − Tn−1 = m
d2 un , dt2
where
Tn = k (un+1 − un ).
Exercises Tn−1
Tn−1
m
Tn
25 Tn
m
un−1
un
m un+1
Fig. 1.5 A system of masses connected by springs along the x-axis.
Deduce that m
d2 un = k (un+1 − 2un + un−1 ) dt2
and show that this is a spatial discretisation of the partial differential equation ∂2u ∂2u = c2 , 2 ∂t ∂X 2
1.4
1.5
1.6
where X = nL, un (t) = u(X, t) and c2 = kL2 /m. [It is not so easy to use discrete element models in more than one dimension; for example, it can be shown that it is impossible to retrieve the Navier equation as the limit of a lattice of masses joined by springs aligned along three orthogonal axes.] If x, x , u and u are related by (1.4.9), use the chain rule to show that ∂uα ∂ui = piα pjβ . ∂xj ∂xβ Hence establish equation (1.4.11) to show that Eij transforms as a tensor under a rotation of the coordinate axes. [Hint: note that, since P is orthogonal, pkl pkm ≡ δlm .] Consider a volume V (t) that is fixed in a deforming solid body. Show that conservation of angular momentum for V (t) leads to the equation ∂u d x× ρ dx = x×gρ dx + x×(τ n) da. dt ∂t V (t) V (t) ∂V (t) From this and Cauchy’s momentum equation (1.6.3), deduce that τij ≡ τji . Show that the linearised strain eij , given by (1.7.1), is identically zero if and only if u = c + ω×x, where c and ω are spatially-uniform vectors. Show that this approximates the rigid-body motion (1.4.13) when P is close to I. If u is of this form, and known to be zero at three non-collinear points, deduce that c = ω = 0.
26
1.7
1.8
Modelling solids
By writing the linearised strain tensor eij as the sum of a zerotrace contribution eij − (1/3)δij ekk and a purely diagonal contribution (1/3)δij ekk , show that W can be rewritten as 1 1 λ µ 2 eij − δij ekk . + (ekk ) + µ eij − δij ekk W= 2 3 3 3 Deduce that, for W to have a single global minimum at eij = 0, it is sufficient for µ and λ+2µ/3 to be positive. By considering particular values of eij , show that it is also necessary. Suppose a solid body occupies the region D and the displacement u is prescribed on ∂D. Let W − ρg · u dx, U= D
where W is the strain energy density. Show that, if ui is changed by a small virtual displacement ηi , then the corresponding leading-order change in U is ∂ηi τij − ρgi ηi dx. δU = ∂xj D [Hint: use the fact that τij is symmetric.] Use the divergence theorem to show that ∂τij ηi τij nj da − + ρgi ηi dx, δU = ∂xj ∂D D
1.9
1.10
and deduce that the minimisation of U with respect to all displacements satisfying the given boundary condition leads to the steady Navier equation. Deduce also that, if no boundary condition is imposed, the natural boundary condition is the vanishing of the traction τij nj on ∂D. Show also that the minimisation of U subject to the constraint div u ≡ 0 leads to the steady incompressible Navier equation (1.8.3a), where p is a Lagrange multiplier. An elastic body D at rest is subject to a traction τ n = σ(x) on its boundary ∂D. By taking the cross product of x with (1.10.2) before integrating over D, derive (1.10.7) and deduce that the net moment acting on D must be zero. Suppose that u satisfies the steady Navier equation (1.10.2) in a region D and the mixed boundary condition α(x)u+β(x)τ n = f (x) on ∂D. Show that, if a solution exists, it is unique provided α > 0 and β 0.
Exercises
1.11
27
[If α and β take different signs, then there is no guarantee of uniqueness. This is analogous to the difficulty associated with the Robin boundary condition for scalar elliptic partial differential equations (Ockendon et al., 2003, p. 154).] (a) Show that, in plane polar coordinates (r, θ), the basis vectors satisfy deθ der = eθ , = −er . dθ dθ (b) Consider a small line segment joining two particles whose polar coordinates are (r, θ) and (r + δr, θ + δθ). Show that the vector joining the two particles is given to leading order by δX ∼ δrer + rδθeθ . (c) If a two-dimensional displacement field is imposed, with u = ur (r, θ)er (θ) + uθ (r, θ)eθ (θ), show that the line element δX is displaced to ∂ur ∂ur δr + δθ − uθ δθ er δx = δX + ∂r ∂θ ∂uθ ∂uθ δr + δθ + ur δθ eθ . + ∂r ∂θ (d) Hence show that |δx| = |δX| + 2
2
(δr, rδθ)
err erθ
erθ eθθ
δr rδθ
where, to leading order in the displacements, err
∂uθ uθ ∂ur 1 ∂ur 1 , 2erθ = + − , eθθ = = ∂r r ∂θ ∂r r r
∂uθ + ur . ∂θ
[These are the elements of the linearised strain tensor in plane polar coordinates, as in (1.11.6).]
2 Linear elastostatics
2.1 Introduction This chapter concerns steady state problems in linear elasticity. This topic may appear to be the simplest in the whole of solid mechanics, but we will find that it offers many interesting mathematical challenges. Moreover, the material presented in this chapter will provide crucial underpinning to the more general theories of later chapters. We will begin by listing some very simple explicit solutions which give valuable intuition concerning the role of the elastic moduli introduced in Chapter 1. Our first application of practical importance is elastic torsion, which concerns the twisting of an elastic bar. This leads to a class of exact solutions of the Navier equation in terms of solutions of Laplace’s equation in two dimensions. However, as distinct from the use of Laplace’s equation in, say, hydrodynamics or electromagnetism, the dependent variable is the displacement, which has a direct physical interpretation, rather than a potential, which does not. This means we have to be especially careful to ensure that the solution is single-valued in situations involving multiply-connected bars. These remarks remain important when we move on to another class of two-dimensional problems called plane strain problems. These have even more general practical relevance but involve the biharmonic equation. This equation, which will be seen to be ubiquitous in linear elastostatics, poses significant extra difficulties as compared to Laplace’s equation. In particular, we will find that it is much more difficult to construct explicit solutions using, for example, the method of separation of variables. An interesting technique to emerge from both these classes of problems is the use of stress potentials, which are the elastic analogues of electrostatic or gravitational potentials, say, or the stream function in hydrodynamics. We 28
2.2 Linear displacements
29
will find that a large class of elastostatic problems with some symmetry, for example two-dimensional or axisymmetric, can be described using a single scalar potential that satisfies the biharmonic equation. Fully three-dimensional problems are mostly too difficult to be suitable for this chapter. Nonetheless, we will be able to provide a conceptual framework within which to represent the solution by generalising the idea of Green’s functions for scalar ordinary and partial differential equations. The necessary Green’s tensor describes the response of an elastic body to a localised point force applied at some arbitrary position in the body. This idea opens up one of the most distinctive and fascinating aspects of linear elasticity: because of the intricacy of (1.7.8), many different kinds of singular solutions can be constructed using stress functions and Green’s tensors, each being the response to a different kind of localised forcing, and the catalogue of these different responses is a very helpful toolkit for thinking about solid mechanics more generally.
2.2 Linear displacements We will begin by neglecting the body force g so the steady Navier equation reduces to ∇ · τ = (λ + µ) grad div u + µ∇2 u = 0.
(2.2.1)
This vector partial differential equation for u is the starting point for all we will say in this chapter. As discussed in Section 1.10, it needs to be supplemented with suitable boundary conditions, which will vary depending on the situation being modelled. If the displacement u is a linear function of position x, then the strain tensor E is spatially uniform. It follows that the stress tensor τ is also uniform and, therefore, trivially satisfies (2.2.1). Such solutions provide considerable insight into the predictions of (2.2.1) and also give a feel for the significance of the parameters λ and µ. To avoid suffices, we will write u = (u, v, w)T and x = (x, y, z)T .
2.2.1 Isotropic expansion As a first example, suppose u=
α x, 3
(2.2.2)
where α is a constant scalar, which must be small for linear elasticity to be valid. When α > 0, this corresponds to a uniform isotropic expansion of the
30
Linear elastostatics
y
1
1 1
x
z (a) (b)
(c)
1 + α/3 1 + α/3 α 1 + α/3
1+α 1 − αν 1 − αν
Fig. 2.1 A unit cube undergoing (a) uniform expansion (2.2.2), (b) one-dimensional shear (2.2.6), (c) uniaxial stretching (2.2.8).
medium so that, as illustrated in Figure 2.1(a), a unit cube is transformed to a cube with sides of length 1 + α/3. (Of course, if α is negative, the displacement is an isotropic contraction.) Since α is small, the relative change in volume is thus α 3 − 1 ∼ α. (2.2.3) 1+ 3 The strain and stress tensors corresponding to this displacement field are given by α 2 (2.2.4) eij = δij and τij = λ + µ αδij . 3 3 This is a so-called hydrostatic situation, in which the stress is characterised by a scalar isotropic pressure p, and τij = −pδij . The pressure is related to the relative volume change by p = −Kα, where 2 K =λ+ µ 3
(2.2.5)
measures the resistance to expansion or compression and is called the bulk modulus or modulus of compression; from Exercise 1.7, we know that K is positive.
2.2 Linear displacements
31
2.2.2 Simple shear As our next example, suppose u αy u = v = 0 , w 0
(2.2.6)
where α is again a constant scalar. This corresponds to a simple shear of the solid in the x-direction, as illustrated in Figure 2.1(b). The strain and stress tensors are now given by 0 1 0 0 1 0 α E= τ = αµ 1 0 0 . (2.2.7) 1 0 0 , 2 0 0 0 0 0 0 Note that λ does not affect the stress, so the response to shear is accounted for entirely by µ, which is therefore called the shear modulus.
2.2.3 Uniaxial stretching Our next example is uniaxial stretching in which, as shown in Figure 2.1(c), the solid is stretched by a factor α in (say) the x-direction. We suppose, for reasons that will emerge shortly, that the solid simultaneously shrinks by a factor να in the other two directions. The corresponding displacement, strain and stress are x 1 0 0 u = α −νy , E = α 0 −ν 0 , (2.2.8) −νz 0 0 −ν
(1 − 2ν)λ + 2µ 0 0 . τ = α 0 (1 − 2ν)λ − 2νµ 0 0 0 (1 − 2ν)λ − 2νµ
(2.2.9)
This simple solution may be used to describe a uniform elastic bar that is stretched in the x-direction under a tensile force T , as shown in Figure 2.2. Notice that, since the bar is assumed not to vary in the x-direction, the outward normal n to the lateral boundary always lies in the (y, z)-plane. If the curved surface of the bar is stress-free, then the resulting boundary condition τ n = 0 may be satisfied identically by ensuring that τyy = τzz = 0, which occurs if λ . (2.2.10) ν= 2 (λ + µ)
32
Linear elastostatics
y τn = 0 T
x
A
T
z Fig. 2.2 A uniform bar being stretched under a tensile force T .
Hence the bar, while stretching by a factor α in the x-direction, must shrink by a factor να in the two transverse directions; if ν happened to be negative, this would correspond to an expansion. The ratio ν between lateral contraction and longitudinal extension is called Poisson’s ratio. With ν given by (2.2.10), the stress tensor has just one non-zero element, namely τxx = Eα,
(2.2.11)
where E=
µ(3λ + 2µ) λ+µ
(2.2.12)
is called Young’s modulus. If the cross-section of the bar has area A, then the tensile force T applied to the bar is related to the stress by T = Aτxx = AEα;
(2.2.13)
thus AE is the elastic modulus k referred to in (1.2.2). By measuring T , the corresponding extensional strain α and transverse contraction να, one may thus infer the values of E and ν for a particular solid from a bar-stretching experiment like that illustrated in Figure 2.2. The Lam´e constants may then be evaluated using λ=
νE , (1 + ν)(1 − 2ν)
µ=
E . 2(1 + ν)
(2.2.14)
We note that the constitutive relation (1.7.7) can be written in terms of E and ν as Eeij = (1 + ν)τij − ντkk δij .
(2.2.15)
While E is a positive constant with the dimensions of pressure, ν is dimensionless and constrained on physical grounds to lie in the range −1 < ν < 1/2. The lower bound for ν comes from the condition λ+2µ/3 > 0
2.2 Linear displacements
33 (b)
(a)
Fig. 2.3 A paper model with negative Poisson’s ratio. Each line segment is a strip of paper viewed end-on.
required for convexity of the strain energy, as shown in Exercise 1.7. The upper bound ν → 1/2 is approached as λ → ∞, in other words as the material becomes incompressible, as discussed in Section 1.8. For most solids, ν is positive, but it is possible (see Figure 2.3) to construct simple hinged paper models with negative Poisson’s ratio; try extending a crumpled piece of paper! So-called auxetic materials, in which ν < 0, have been developed whose microscopic structure mimics such paper models so they also display negative values of ν and they expand in all directions when pulled in only one (see Lakes, 1987).
2.2.4 Biaxial strain As a final illustrative example, we generalise Section 2.2.3 and consider an elastic plate strained in the (x, y)-plane as illustrated in Figure 2.4. Suppose the plate experiences a linear in-plane distortion while shrinking by a factor γ in the z-direction, so the displacement is given by u ax + by u = v = cx + dy , w −γz
(2.2.16)
and, as in Section 2.2.3, the stress and strain tensors are both constant. Here we choose γ to satisfy the condition τzz = 0 on the traction-free upper and
34
Linear elastostatics Tyy Tyx
y
Txy Txx
z Txx
x
h
Txy
Tyx Tyy
Fig. 2.4 A plate being strained under tensions Txx , Ty y and shear forces Txy , Ty x .
lower surfaces of the plate, so that ν λ (a + d) = (a + d), γ= λ + 2µ 1−ν
(2.2.17)
where ν again denotes Poisson’s ratio. With this choice, and with E again denoting the Young’s modulus, the only non-zero stress components are τxx =
E(a + νd) , 1 − ν2
τxy =
E(b + c) , 2(1 + ν)
τyy =
E(νa + d) . 1 − ν2
(2.2.18)
We denote the net in-plane tensions and shear stresses applied to the plate by Tij = hτij , as illustrated in Figure 2.4. We can use (2.2.18) to relate these to the in-plane strain components by Eh (exx + νeyy ), 1 − ν2 Eh exy , = 1+ν Eh = (νexx + eyy ). 1 − ν2
Txx = Txy = Tyx Tyy
(2.2.19a) (2.2.19b) (2.2.19c)
These will provide useful evidence when constructing more general models for the deformation of plates in Chapter 4. If no force is applied in the y-direction, that is Txy = Tyy = 0, then (2.2.19) reproduces the results of uniaxial stretching, with d = −νa and Txx = Eha. On the other hand, it is possible for the displacement to be purely in the (x, z)-plane, with b = c = d = 0,
τyy =
Eνa , 1 − ν2
τxx =
Ea . 1 − ν2
(2.2.20)
2.2 Linear displacements
35
Thus a transverse stress τyy must be applied to prevent the plate from contracting in the y-direction when we stretch it in the x-direction. Notice also that the effective elastic modulus E/(1 − ν 2 ) is larger than E whenever ν is non-zero, which shows that purely two-dimensional stretching is always more strenuous than uniaxial stretching.
2.2.5 General linear displacements The simple linear examples considered above shed useful light on more general solutions of the Navier equation. Indeed, any displacement field, when expanded in a Taylor series about some point x0 , is linear to leading order: T u(x) = u(x0 ) + ∇u (x0 ) (x − x0 ) + · · · . (2.2.21) Here ∇u is the displacement gradient matrix, whose entries are conventionally defined to be ∇u = (∂uj /∂xi ), and may be written as the sum of symmetric and skew-symmetric parts: ∂uj ∂uj 1 ∂uj 1 ∂ui ∂ui + . (2.2.22) = + − ∂xi 2 ∂xj ∂xi 2 ∂xi ∂xj We recognise the symmetric part of ∇u as the linear strain tensor E, while the skew-symmetric part may be written in the form 0 −ω3 ω2 1 ∇u − ∇uT = ω3 (2.2.23) 0 −ω1 , 2 −ω2 ω1 0 so that, with ω = (ω1 , ω2 , ω3 )T , (2.2.21) becomes u(x) = u0 + ω×(x − x0 ) + E(x − x0 ) + · · · .
(2.2.24)
The terms on the right-hand side represent a small rigid-body translation and rotation, followed by a linear deformation characterised by the matrix E. Since E is real and symmetric, it has real eigenvalues, say {1 , 2 , 3 }, and orthogonal eigenvectors. These eigenvalues are referred to as the principal strains, and the directions defined by the eigenvectors as the principal directions. If we use an orthogonal matrix P to align the coordinate axes with these principal directions, that is x = x 0 + P T x ,
(2.2.25)
then E, u, ω are transformed to E , u , ω such that u = u0 + ω ×x + E x + · · · ,
(2.2.26)
36
Linear elastostatics
where E = P EP T
1 0 0 = 0 2 0 . 0 0 3
(2.2.27)
We can hence think of the strain at any point as comprising three orthogonal expansions or contractions, depending on the signs of {1 , 2 , 3 }, followed by a small rigid-body rotation. Generalising Section 2.2.1, we note that the net relative volume change associated with this expansion/contraction is (1 + 1 )(1 + 2 )(1 + 3 ) − 1 = 1 + 2 + 3 + · · · .
(2.2.28)
The sum of the eigenvalues is the invariant trace of the matrix E so that the relative volume change is Tr (E) = ekk = ∇ · u.
(2.2.29)
With respect to the principal axes, the stress tensor is also diagonal, namely τ1 0 0 τ1 = λ(1 + 2 + 3 ) + 2µ1 , τ = 0 τ2 0 , where τ = λ(1 + 2 + 3 ) + 2µ2 , 2 (2.2.30) 0 0 τ3 τ3 = λ(1 + 2 + 3 ) + 2µ3 , and the eigenvalues {τ1 , τ2 , τ3 } are called the principal stresses. As an illustration, let us re-examine the simple shear of Section 2.2.2. The eigenvalues and corresponding eigenvectors v i of E are readily found to be α , 2 1 v 1 = 1 , 0 1 =
α 2 = − , 2 1 v 2 = −1 , 0
3 = 0, 0 v 3 = 0 . 1
(2.2.31a) (2.2.31b)
Hence the shear is equivalent to an expansion of magnitude α/2 in the direction (1, 1, 0)T plus an equal and opposite contraction in the direction (1, −1, 0)T . In the original non-principal axes, we can decompose the displacement as follows: y x+y x−y αy α α α (2.2.32) u = 0 = −x + x + y − y − x . 2 4 4 0 0 0 0 The terms on the right-hand side represent a rigid-body rotation, an expansion and an orthogonal contraction.
2.3 Antiplane strain
37
In general, the strain tensor E and, therefore, the principal strains i and principal stresses τi are functions of position x. At any such position, the strain and stress tensors are diagonal only with respect to the principal axes; if these axes are rotated by another orthogonal matrix Q, then the strain and stress tensors become E and τ respectively, where E = QE QT ,
τ = Qτ QT .
(2.2.33)
It is easiest to understand the consequence of such a rotation in two dimensions, when we can take cos θ sin θ (2.2.34) Q= −sin θ cos θ and (2.2.33b) becomes τ1 cos2 θ + τ2 sin2 θ (τ1 − τ2 ) sin θ cos θ , τ = (τ1 − τ2 ) sin θ cos θ τ2 cos2 θ + τ1 sin2 θ
(2.2.35)
with an analogous expression for E. It follows that the diagonal elements of the stress tensor, known as the normal stresses, always lie between min(τi ) and max(τi ). However, the off-diagonal shear stress takes its maximum value |τ1 − τ2 |/2 when θ = ±π/4. It is shown in Exercise 2.9 that these properties also hold for threedimensional stress fields. In particular, the maximum shear stress always occurs at an angle of π/4 with two of the principal axes and is given by S = max i,j
|τi − τj | . 2
(2.2.36)
This is often used as a diagnostic to test for failure, since many elastic materials, particularly metals, are susceptible to plastic deformation when subject to excessive shear stress. The so-called Tresca criterion proposes that a material will yield and become plastic when S exceeds some critical yield stress τY. We will show below in Section 2.6.5 how this criterion can be applied to predict the failure of a gun barrel, and a fuller account of plasticity will be given in Chapter 8.
2.3 Antiplane strain The simplest two-dimensional model for elastostatics occurs when the displacement u is unidirectional, u = (0, 0, w)T say, and w depends only on the transverse coordinates (x, y). One way to create this state of antiplane strain is to apply a tangential traction σ(x, y), in the axial direction only,
38
Linear elastostatics
z
surface traction σ D
y
x Fig. 2.5 A bar in a state of antiplane strain.
to the curved boundary of a cylindrical bar, as illustrated in Figure 2.5. Of course, σ(x) must exert no net force or moment on the bar, as pointed out in Section 1.10. With the z-axis parallel to the bar, the stress tensor is 0
τ = 0 ∂w µ ∂x
0 0 µ
∂w ∂y
∂w ∂x ∂w . µ ∂y µ
(2.3.1)
0
At any point of the bar, the traction on an element normal to (cos θ, sin θ, 0)T is µ (cos θ∂w/∂x + sin θ∂w/∂y), whose maximum value as θ varies is µ|∇w|. If we neglect gravity, the Navier equation reduces to the two-dimensional Laplace’s equation ∂2w ∂2w + = ∇2 w = 0, ∂x2 ∂y 2
(2.3.2)
to be solved inside the cross-section D of the bar, which is a region of the (x, y)-plane. Since the bar is uniform, the unit normal n to the curved boundary lies in the (x, y)-plane, so the applied traction is simply a shear force σ in the z-direction that is related to w by σ(x) = τzn = µ
∂w ∂n
on ∂D.
(2.3.3)
2.4 Torsion
z
39
M
M
y
D x Fig. 2.6 A bar being twisted under a moment M .
The solvability condition for the Neumann problem (2.3.2), (2.3.3) is σ ds = 0, (2.3.4) ∂D
which confirms that no net traction may be applied to any cross-section (cf equation (1.10.6)). If, instead of the traction, we were to specify the displacement w on ∂D, we would obtain the Dirichlet boundary condition w = f (x, y)
on ∂D
(2.3.5)
instead of (2.3.3). We note that the strain energy density is W = µ|∇w|2 and that, when the total elastic energy in the bar is minimised using the calculus of variations, (2.3.3) with σ = 0 is the natural boundary condition (as in Exercise 1.8). Despite its simplicity, we will find this model a very useful paradigm when we come to consider fracture in Chapter 7. We note that (2.3.2) also describes the small transverse displacement w(x, y) of a nearly planar membrane under tension (Exercise 2.2); (2.3.3) and (2.3.5) then correspond to prescribing either force or displacement at its boundary. 2.4 Torsion Now consider a bar which, instead of stretching or contracting along its axis, twists under the action of moments applied at its ends. Such torsion bars are often used in car suspensions, and may be described by a displacement field of the form u −Ωyz u = v = Ωxz , (2.4.1) w Ωψ(x, y)
40
Linear elastostatics
where Ω is a constant representing the twist of the bar about its axis. As in Section 2.3, the stress tensor is of the form 0 0 τxz τ = 0 (2.4.2) 0 τyz τxz τyz 0 where, now,
τxz = µΩ
∂ψ −y , ∂x
τyz = µΩ
∂ψ +x . ∂y
(2.4.3)
The Navier equation therefore implies that, as in Section 2.3, ψ satisfies Laplace’s equation ∇2 ψ = 0
in D,
(2.4.4)
where D is the cross-section of the bar. Recall that, since the bar is uniform, its unit normal n lies purely in the (x, y)-plane; if ∂D is parametrised by x = X(s), y = Y (s), where s is arc-length, then n = (dY /ds, −dX/ds, 0)T . Hence, assuming the curved boundary of the bar is stress-free, we must have dY dX − τyz =0 on ∂D, ds ds and the corresponding boundary condition for ψ is τxz
1 d 2 ∂ψ = X +Y2 ∂n 2 ds
on ∂D.
(2.4.5)
(2.4.6)
Notice that the solvability condition for the Neumann problem (2.4.4), (2.4.6) is satisfied identically. Hence, given the shape of the cross-section D, the displacement w = Ωψ is uniquely determined up to an arbitrary constant, corresponding to an arbitrary uniform translation. Once ψ has been found, the moment applied at each end of the bar is given by (xτyz − yτxz ) dxdy = RΩ, (2.4.7) M= D
say, where
∂ψ 2 ∂ψ 2 −y + x +y R=µ x dxdy. ∂y ∂x D
(2.4.8)
The constant of proportionality R between the applied moment M and the resulting twist Ω is called the torsional rigidity of the bar. The quantity R/µ is proportional to the square of the cross-sectional area of the bar and, as we will see shortly, is readily found for simple cross-section shapes.
2.4 Torsion
41
The boundary-value problem (2.4.4), (2.4.6) for ψ may be usefully reformulated as follows. Whenever the stress tensor is of the form (2.4.2) and there is no body force, the steady Navier equation reduces to ∂τyz ∂τxz + = 0. ∂x ∂y
(2.4.9)
We can guarantee that (2.4.9) is satisfied by postulating the existence of a stress function φ (x, y) such that τxz = µΩ
∂φ , ∂y
τyz = −µΩ
∂φ , ∂x
(2.4.10)
where the factors of µΩ are introduced for later convenience. Moreover, it can be shown that the existence of φ is necessary as well as sufficient for solutions of (2.4.9) to exist. In the same way, the existence of a stream function in fluid dynamics guarantees mass conservation, and the existence of a magnetic vector potential ensures that the magnetic field is divergencefree in magnetostatics. Such potentials are never uniquely defined; in our case, φ is unique only up to the addition of an arbitrary constant. By comparing (2.4.10) with (2.4.3), we see that φ and ψ are related by ∂ψ ∂φ = + y, ∂x ∂y
∂ψ ∂φ =− − x. ∂y ∂x
(2.4.11)
Elimination of φ retrieves (2.4.4), while elimination of ψ reveals that φ satisfies Poisson’s equation ∇2 φ = −2
in D.
(2.4.12)
Indeed, it is easy to see from (2.4.11) that ψ and φ+(x2 +y 2 )/2 are harmonic conjugates. The zero-stress boundary condition (2.4.5) implies that φ is constant on ∂D and, without loss of generality, we may take φ=0
on ∂D.
(2.4.13)
The advantage of introducing the stress function φ is that the Neumann problem for ψ has been converted to the Dirichlet problem (2.4.12), (2.4.13), which has a unique solution; exactly the same procedure could have been applied to the antiplane strain problem (2.3.2), (2.3.3). The torque M is then given in terms of φ by ∂φ ∂φ −y φ dxdy, (2.4.14) −x dxdy = 2µΩ M = µΩ ∂x ∂y D D
42
Linear elastostatics
the final step being a consequence of Green’s theorem and (2.4.13). An alternative formula to (2.4.8) for the torsional rigidity is, therefore, φ dxdy. (2.4.15) R = 2µ D
To illustrate the theory of this section we will now find the torsional rigidity of a circular bar firstly using ψ and secondly using φ. If D is the disc r < a, where (r, θ) are the usual plane polar coordinates, then the Neumann problem (2.4.4), (2.4.6) becomes r < a, (2.4.16a) ∇2 ψ = 0, ∂ψ = 0, r = a. (2.4.16b) ∂r It follows that ψ is a constant and, hence, that the torsional rigidity is 2π a 2 πµa4 2 . (2.4.17) R=µ r3 drdθ = x + y dxdy = µ 2 D 0 0 Note that a circular cylinder is the only case in which the right-hand side of (2.4.6) is zero. For any other cross-sectional shape, twisting a bar inevitably results in a non-zero axial displacement w = Ωψ. Alternatively, we may solve the Dirichlet problem (2.4.12), (2.4.13) for φ. Assuming that φ is a function only of r, we have dφ 1 d 2 r = −2, r < a, (2.4.18a) ∇ φ= r dr dr φ = 0,
r = a,
(2.4.18b)
whose solution, bounded as r → 0, is φ=
a2 − r2 . 2
The torsional rigidity is then given by (2.4.15): 2π a πµa4 R=µ , (a2 − r2 )r drdθ = 2 0 0
(2.4.19)
(2.4.20)
which reproduces (2.4.17) as expected. This result can easily be generalised to bars of elliptical cross section (see Exercise 2.4).
2.5 Multiply-connected domains In Section 2.4, we have implicitly assumed that D is simply connected. Many torsion bars are tubular in practice, and the resulting change in topology
2.5 Multiply-connected domains
43
∂Do D ∂Di z
y x Fig. 2.7 A uniform tubular torsion bar, with inner and outer free surfaces given by ∂Di and ∂Do respectively.
makes a big difference to the integration of our mathematical model. We now have to apply the condition (2.4.5) on two stress-free boundaries, namely the inner (∂Di ) and outer (∂Do ) surfaces of the tube, as illustrated in Figure 2.7. As before, we can deduce that φ must be constant on each of these boundaries, but these two constants are not necessarily equal. Hence, we may only choose φ to satisfy φ=0
on ∂Do ,
φ=k
on
∂Di ,
(2.5.1)
where k is a constant. Note that k is not simply additive to φ and hence may not be set to zero without loss of generality. The torsional rigidity is now given by ∂φ ∂φ +y dxdy x R = −µ ∂x ∂y D ∂ ∂ = −µ (xφ) + (yφ) − 2φ dxdy ∂x ∂y D = 2µ φ dxdy + 2µkAi , (2.5.2) D
after using Green’s theorem, where Ai is the area of the hole inside ∂Di . To obtain φ and thus R uniquely, we still have to evaluate the unknown constant k. By working with the stress function φ, we have reduced the torsional rigidity problem to a seemingly innocuous Poisson equation (2.4.12) with
44
Linear elastostatics
y
y (b)
(a) b
a
b
a
x
x
Fig. 2.8 The cross-section of (a) a circular cylindrical tube; (b) a cut tube.
Dirichlet boundary conditions (2.5.1) on the two boundaries of the annular tube. However, we have temporarily lost sight of the displacement field w = Ωψ, which has yet to be determined from (2.4.11). To be physically acceptable, ψ must be a single-valued function of (x, y), which implies that ∂ψ ∂ψ dx + dy ≡ 0 (2.5.3) ∂y C ∂x for all simple closed paths C contained in D. In fact, it is readily shown that (2.5.3) holds for all such paths if it holds when C is the inner boundary ∂Di (see Exercise 2.5). By substituting for ψ in favour of φ, we therefore obtain ∂φ ∂φ ∂φ dy − dx = ds = −2Ai (2.5.4) ∂y ∂D i ∂x ∂D i ∂n where, as before, Ai is the area of the void in the tube cross-section. This constraint gives the extra information needed to determine the constant k and, hence, φ and R. If there are m holes in the cross-section, with φ taking the constant value ki (i = 1, . . . , m) on each hole, then there are m relations of the form (2.5.4) to determine the ki . As an illustration, suppose that D is the circular annulus a < r < b in plane polar coordinates (r, θ), as illustrated in Figure 2.8(a). Assuming that φ is a function of r alone, it must satisfy the boundary-value problem dφ 1 d 2 r = −2, a < r < b, (2.5.5a) ∇ φ= r dr dr φ = k,
r = a,
(2.5.5b)
φ = 0,
r = b,
(2.5.5c)
2.5 Multiply-connected domains
45
whose solution is easily found to be b2 − a2 log (r/b) b2 − r 2 + k− . φ= 2 2 log (a/b)
(2.5.6)
We can determine k by substituting this expression for φ into (2.5.4) to give 2π 2π b2 − a2 ∂φ dφ 2 a dθ = −2πa + ds = k − , dr r=a log (a/b) 2 ∂D i ∂n 0 (2.5.7) while Ai = πa2 , so (2.5.4) tells us that k=
b2 − a2 . 2
(2.5.8)
This value of k eliminates the logarithmic term from (2.5.6), and we might have anticipated that this would be necessary by recalling that ψ and φ+r2 /2 are harmonic conjugates. Since b2 − a2 r2 = const. + k − log r (2.5.9) φ+ 2 2 and −log r is the harmonic conjugate of θ, we deduce that b2 − a2 θ, ψ = const. − k − 2
(2.5.10)
which is evidently a single-valued function only if k satisfies (2.5.8). We therefore find that φ=
b2 − r 2 , 2
(2.5.11)
and it is straightforward to substitute this into (2.5.2) and obtain the torsional rigidity µπ 4 R= (2.5.12) b − a4 . 2 Had we chosen to use ψ instead of φ, we would have discovered that ψ is constant and then quickly reproduced (2.5.12) using (2.4.8). Even in this simple radially symmetric geometry, the bother of finding the arbitrary constant k has outweighed the convenience of introducing a stress function. When considering multiply-connected domains it is therefore often a better idea to return to the physical variable ψ.
46
Linear elastostatics
Notice that (2.5.12) reproduces the result (2.4.17) for a solid circular bar as a tends to zero. On the other hand, if the tube is thin, so a and b are nearly equal, then (2.5.13) R = 2µπa4 ε 1 + O (ε) , where ε = b/a − 1 1. We can now compare this with the torsional rigidity of a tube, such as part of an old bicycle frame, with a thin axial cut, as illustrated in Figure 2.8(b). Here the cross-section is simply connected, so that φ must satisfy ∂φ 1 ∂2φ 1 ∂ 2 r + 2 2 = −2, a < r < b, (2.5.14a) ∇ φ= r ∂r ∂r r ∂θ with φ=0
on r = a, b,
(2.5.14b)
on θ = 0, 2π.
(2.5.14c)
and φ=0
As shown in Exercise 2.6, this problem can be solved exactly by separating the variables. Alternatively, if we assume that the tube is thin, then an approximate solution may be found by performing the rescaling r = a (1 + εξ) ,
(2.5.15)
where ε is again small. To lowest order in ε, (2.5.14a,b) reduces to ∂2φ = −2ε2 a2 , ∂ξ 2
0 < ξ < 1,
(2.5.16a)
with φ=0
on ξ = 0, 1,
(2.5.16b)
whose solution is φ = ε2 a2 ξ(1 − ξ).
(2.5.17)
Notice that (2.5.17) does not satisfy the boundary conditions on θ = 0, 2π. This is because there are so-called boundary layers near the cut where the θ-derivatives must be retained in (2.5.14). For this simply-connected cross-section, we may use (2.4.15) to determine the torsional rigidity and thus obtain, to lowest order in ε, 1 2π 4 3 2 µa ε . φ dξ = (2.5.18) R = 4πµa ε 3 0
2.6 Plane strain
47
Comparing (2.5.18) with (2.5.13), we see that the change in topology caused by introducing the cut has a dramatic influence on the strength of the tube, reducing its torsional rigidity by two orders of magnitude! 2.6 Plane strain 2.6.1 Definition A more common configuration than that of antiplane strain is plane strain, in which a solid is displaced in the (x, y)-plane only, with the displacement being independent of z. Writing u (x, y) u = v (x, y) , (2.6.1) 0 we find that the stress tensor takes the form τxx τxy 0 τ = τxy τyy 0 , 0 0 τzz where τxx τyy
∂u ∂u ∂v + + 2µ , =λ ∂x ∂y ∂x ∂v ∂u ∂v + + 2µ , =λ ∂x ∂y ∂y
∂u ∂v + , =µ ∂y ∂x ∂u ∂v + . =λ ∂x ∂y
(2.6.2)
τxy τzz
(2.6.3a) (2.6.3b)
This configuration arises, for example, when a z-independent traction just in the (x, y)-plane is applied to the curved boundary of a cylindrical bar aligned with the z-axis. The easily-forgotten stress component τzz represents the normal traction that would need to be applied to the ends of such a bar to prevent it expanding or contracting in the z-direction. 2.6.2 The Airy stress function With the stress tensor given by (2.6.2), and gravity neglected, the Navier equation reduces to ∂τxy ∂τxx + = 0, ∂x ∂y
∂τxy ∂τyy + = 0, ∂x ∂y
or, in terms of displacements, 2 2 ∂ u ∂ u ∂2u ∂2v (λ + µ) +µ + + 2 = 0, ∂x2 ∂x∂y ∂x2 ∂y 2 2 2 ∂ u ∂ v ∂ v ∂2v (λ + µ) +µ + + 2 = 0. ∂x∂y ∂y 2 ∂x2 ∂y
(2.6.4)
(2.6.5a) (2.6.5b)
48
Linear elastostatics
By cross-differentiating, it is straightforward to eliminate u and v in turn from (2.6.5) and thus show that each satisfies the biharmonic equation ∇4 u = ∇4 v = 0,
(2.6.6)
where ∇4 refers here to the two-dimensional biharmonic operator: 2 2 ∂ ∂4 ∂ ∂2 ∂2 ∂4 ∂4 4 = + + + 2 + . ∇ = ∂x2 ∂y 2 ∂x2 ∂y 2 ∂x4 ∂x2 ∂y 2 ∂y 4
(2.6.7)
In fact, we can reduce (2.6.5) to a single biharmonic equation by making use of another potential function as follows. By inspection, the integrability condition for the system (2.6.4) is the existence of an Airy stress function A such that τxx =
∂2A , ∂y 2
τxy = −
∂2A , ∂x∂y
τyy =
∂2A . ∂x2
(2.6.8)
In the same way that the stress function φ in (2.4.10) is only defined to within a constant, A is only defined to within a function that is linear in x and y; in other words, any such function may be added to A without contributing to the stress. By using (2.6.3), we obtain the following expressions for the displacement gradients ∂2A ∂2A ∂u = −ν 2 + (1 − ν) 2 , ∂x ∂x ∂y 2 2 ∂ A ∂ A ∂v = (1 − ν) −ν 2, 2µ 2 ∂y ∂x ∂y 2 ∂ A ∂u ∂v + =− . µ ∂y ∂x ∂x∂y 2µ
(2.6.9a) (2.6.9b) (2.6.9c)
Now, by taking ∂ 2 /∂x∂y of (2.6.9c) and using (2.6.9a) and (2.6.9b), we can eliminate u and v and hence find that A satisfies the biharmonic equation: ∇4 A = 0.
(2.6.10)
Moreover, given A, (2.6.9) forms a compatible system of three equations that determine u and v to within a small rigid body displacement in which u = u0 − ωy, v = v0 + ωx, with u0 , v0 and ω constant. We now recall that the general solution of Laplace’s equation in two dimensions may be written in the form φ = Re f (z) , (2.6.11)
2.6 Plane strain
49
y t n D x ∂D (x, y) = X(s), Y (s) Fig. 2.9 The unit normal n and tangent t to the boundary ∂D of a plane region D.
where f is an arbitrary analytic function of z = x + iy. Similarly, the general solution of (2.6.10) has the Goursat representation A = Re z¯f (z) + g (z) ,
(2.6.12)
where z¯ = x − iy, and f , g are analytic (see Exercise 2.7). By choosing different functional forms for f and g, we can use (2.6.12) to construct many exact solutions of the biharmonic equation. However, making this representation satisfy realistic boundary conditions is usually not easy, as we will see in Chapter 7.
2.6.3 Boundary conditions Suppose we wish to solve (2.6.10) in some region D, on whose boundary a prescribed traction σ is imposed, that is τn = σ
on
∂D.
(2.6.13)
As illustrated in Figure 2.9, we parametrise ∂D using (x, y) = X(s), Y (s) , where s is arc-length, so the unit tangent and outward normal vectors are given by X , t= Y
n=
Y , −X
(2.6.14)
50
Linear elastostatics
where is shorthand for d/ds. Using (2.6.8) to write the stress components in terms of A, we thus find that (2.6.13) can be written in the form d ∂A/∂y = σ. (2.6.15) ds −∂A/∂x If no surface traction is applied, that is σ = 0, then it follows from (2.6.15) that ∇A is constant on ∂D. Since, as noted above, an arbitrary linear function of x and y may be added to A without affecting the stresses, we can, in a simply-connected region, take this constant to be zero without loss of generality. Then, by taking the dot product of ∇A with t and n respectively, we deduce that ∂A dA = =0 ds ∂n
(2.6.16)
on ∂D. The former of these tells us that A is constant on ∂D and, again, this constant may, without loss of generality, be set to zero. Finally, we arrive at the boundary conditions ∂A =0 ∂n
A = 0,
(2.6.17)
to be imposed on a stress-free boundary. We note that the divergence theorem on any closed region D yields ∂ 2 ∂A 2 A ∇ A − ∇ A ds ∂n ∂n ∂D div A grad(∇2 A) − div ∇2 A grad A dxdy = D 2 A∇4 A − ∇2 A dxdy. (2.6.18) = D
Hence, if A satisfies the biharmonic equation in D and the boundary conditions (2.6.17) on ∂D, then ∇2 A = 0 and a second use of (2.6.17) reveals that A ≡ 0. This result confirms that the stresses inside a closed body in plane strain are uniquely determined by the tractions applied to the boundary. We can combine (2.6.8) and (2.6.9) to obtain the strain energy density in the form 1 (τxx exx + 2τxy exy + τyy eyy ) 2
2 2 2 2 ∂ A ∂2A ∂2A 1 . (1 − ν) ∇ A + 2 −2 2 = 4µ ∂x∂y ∂x ∂y 2
W=
(2.6.19)
2.6 Plane strain
51
Then the calculus of variations can be used to show that minimisers of the net strain energy W dxdy U= D
in a closed region D satisfy the biharmonic equation (2.6.10). When the displacement rather than the stress is prescribed on a boundary in plane strain, the usefulness of the stress function A is diminished. This is because the displacements are related to A by (2.6.9), so boundary conditions for u and v cannot usually be expressed simply in terms of A. We will show in Section 2.8 that other stress functions can be defined that are better suited to such problems. 2.6.4 Plane strain in a disc As a first illustrative example, let us consider plane strain in a circular region r < a on whose boundary r = a a prescribed traction is applied. We begin by deriving the relations between the Airy stress function and the stress components in polar coordinates. Recalling (1.11.7) with gi = 0 and all variables depending only on r and θ, we try writing τθθ =
∂2A . ∂r2
(2.6.20a)
Then (1.11.7b) gives −∂ 3 A/∂r2 ∂θ = 2τrθ + r∂τrθ /∂r, which suggests that we write τrθ = ∂B/∂r. Since ∂ 2 /∂r2 (rB) is now equal to −∂ 3 A/∂r2 ∂θ, we find that ∂ 1 ∂A , (2.6.20b) τrθ = − ∂r r ∂θ and then (1.11.7a) gives 1 ∂ 2 A 1 ∂A . (2.6.20c) + r2 ∂θ2 r ∂r Equations (2.6.20) are the analogues of (2.6.8) in plane polar coordinates. The biharmonic equation for A reads 2 2 1 ∂2 ∂ 1 ∂ 4 + + A = 0. (2.6.21) ∇ A= ∂r2 r ∂r r2 ∂θ2 τrr =
We will only consider here cases where a purely normal pressure P is applied, so the boundary conditions on r = a are ∂ A 1 ∂ 2 A 1 ∂A = −P, =0 on r = a; (2.6.22) + r2 ∂θ2 r ∂r ∂r r
52
Linear elastostatics
we obtain the latter equation by integrating the condition τrθ = 0 with respect to θ. The simplest case occurs if P is constant, so we expect the displacement to be purely radial and A to be a function of r alone. The problem thus reduces to 2 2 1 d d + A = 0, (2.6.23) dr2 r dr subject to the boundary conditions A=r
dA = −P a2 dr
on r = a.
(2.6.24)
It is then straightforward to solve (2.6.23) in the form A = c1 r2 + c2 + c3 r2 log r + c4 log r.
(2.6.25)
For the stresses to exist throughout the circle, we require A to be twice differentiable as r → 0 and hence, applying the boundary conditions (2.6.24), we obtain P 2 (2.6.26) r + a2 . A=− 2 If P is not assumed to be constant, then we can solve the problem by separating the variables in polar coordinates, using the fact that A must be a 2π-periodic function of θ. Seeking a solution of (2.6.21) in the form A(r, θ) = f (r) sin(nθ), where n is a positive integer, we find that 2 2 n2 1 d d − 2 + f = 0. dr2 r dr r
(2.6.27)
(2.6.28)
This Euler differential equation admits the solution f (r) = rk , where k satisfies 2 (2.6.29) k − n2 (k − 2)2 − n2 = 0. We must again ensure that the stress components (2.6.20) are well defined as r → 0, and now this restricts us to the solutions k = n, n + 2, that is f (r) = c1 rn+2 + c2 rn ,
(2.6.30)
where the ci are again arbitrary constants. For the special case n = 1, the only physically acceptable solution is f (r) = c1 r3 .
(2.6.31)
2.6 Plane strain
r=a
53
r=b
P
Fig. 2.10 A plane annulus being inflated by an internal pressure P .
We can take a linear combination of separable solutions that satisfy (2.6.24) and the radially-symmetric solution (2.6.26) to obtain 2 r + a2 A0 A=− 4 ∞ rn 1 rn+2 + − An cos(nθ) + Bn sin(nθ) , (2.6.32) n−2 n 2 (n − 1)a (n + 1)a n=2
where An and Bn are the Fourier coefficients of P , that is 1 2π 1 2π P (θ) cos(nθ) dθ, Bn = P (θ) sin(nθ) dθ. An = π 0 π 0
(2.6.33)
Notice that the n = 1 term does not appear in the series in (2.6.32), so it is possible to satisfy the boundary condition (2.6.22) only if 2π cos θ P (θ) dθ = 0. (2.6.34) sin θ 0 This is simply a manifestation of the solvability condition (1.10.6) and states that the net force on the disc must be zero.
2.6.5 Plane strain in an annulus Our next example concerns the inflation of a circular annulus a < r < b under an applied internal pressure P , as illustrated in Figure 2.10. This practical and important instance of plane strain might model, for example, the response of a gun barrel or a diving cylinder, or even the skin of a Belgian sausage. We will only consider here a constant pressure P , the techniques of the previous section again being appropriate when the pressure depends on θ.
54
Linear elastostatics
Assuming that A is a function of r alone, it is given by (2.6.25), but, since we are now solving in the annular region a < r < b, there is no a priori justification for eliminating the logarithmic terms that cause the stress to be ill-behaved as r → 0. We therefore have four arbitrary constants ci in (2.6.25) to be determined from the boundary conditions. The condition of zero traction on the outer boundary r = b means, as explained in Section 2.6.3, that we may without loss of generality set dA =0 on r = b. (2.6.35a) dr With A independent of θ, τrθ is identically zero, so the specified internal pressure gives us just one more boundary condition, namely A=
1 dA = −P r dr
on r = a.
(2.6.35b)
As in Section 2.5, the vital fourth relation needed to determine the constants ci comes from the realisation that the annulus is multiply connected. We need A(r) to be such that the displacement ur (r) exists and is singlevalued, where, from the constitutive relations (1.11.5), dur ur d2 A ur 1 dA dur = (λ + 2µ) +λ , + (λ + 2µ) . (2.6.36) =λ r dr dr r dr2 dr r By cross-differentiation, we find that that the compatibility condition for ur to exist is d3 A 1 d2 A 1 dA = 0, (2.6.37) + − 2 dr3 r dr2 r dr which is satisfied by (2.6.25) only if c3 = 0. The boundary conditions (2.6.35) may then be used to evaluate the remaining three constants and hence show that r 2 P a2 b2 P a2 2 − a log − A= r . (2.6.38) 2 (b2 − a2 ) b2 − a2 b In a plane strain problem with multiple traction-free holes, we would have ∂A (2.6.39) = Ki ∂n on the ith hole, where the constants ki and Ki must be determined by ensuring that both displacement components (u, v) are single-valued around each hole. As noted in Section 2.5, the utility of introducing a stress function in such cases is negated by the difficulty of solving for all the arbitrary constants, and it is often preferable to work with physical variables in A = ki ,
2.6 Plane strain
55
multiply-connected domains. By way of illustration, had we posed the annular problem above in terms of the radial displacement ur (r) rather than A, we would have obtained the considerably more tractable problem d 1 d (rur ) = 0, a < r < b, (2.6.40a) dr r dr ur dur + λ = −P, r = a, (2.6.40b) (λ + 2µ) dr r ur dur + λ = 0, r = b. (2.6.40c) (λ + 2µ) dr r This quickly yields the solution r b2 P a2 + , (2.6.41) ur = 2 (b2 − a2 ) λ + µ µr and we can then recover the stress components using the constitutive relations (1.11.5). In our radially symmetric geometry, τrθ is zero and the only non zero stresses are the radial stress τrr , the hoop stress τθθ and the axial stress τzz , given respectively by b2 b2 P a2 P a2 2νP a2 1 − , τ 1 + , τ = = , τrr = 2 zz θθ b − a2 r2 b2 − a2 r2 b2 − a2 (2.6.42) where ν denotes Poisson’s ratio, as usual. These results are in accordance with (2.6.38). We can now use the above solution to predict the failure of a gun barrel as P increases. As explained in Section 2.2.5, the Tresca criterion predicts that the material will fail when |τi − τj | = τY , (2.6.43) S = max i,j 2 where τY is the yield stress and τi are the principal stresses. Here the stress tensor is diagonal, so τi are just the three stress components given in (2.6.42). If we assume that the material has positive Poisson’s ratio† then, since ν < 1/2 and r < b, we can deduce from (2.6.42) the inequalities τrr < 0 < τzz < τθθ ,
(2.6.44)
and so the maximum shear stress is S= †
P a2 b2 τθθ − τrr = 2 . 2 (b − a2 ) r2
(2.6.45)
for an auxetic material with ν < 0, the second inequality in (2.6.44) is reversed and the maximum shear stress may be τ θ θ − τ z z instead of (2.6.45)
56
Linear elastostatics
This is maximised at r = a, so we would expect a gun barrel always to yield first on its inner surface, along a generator. We can also use (2.6.45) to predict the maximum pressure P ∗ that the barrel can withstand, namely a2 ∗ (2.6.46) P = τY 1 − 2 . b Notice in particular how the barrel becomes more susceptible to failure as its thickness b − a is reduced. It turns out that this is a canonical problem for the theory of plasticity, as will be explained in Chapter 8. 2.6.6 Plane strain in a rectangle In Section 2.6.4, we showed how plane strain in a disc can be solved by separating the variables in polar coordinates. On the face of it, the procedure was only slightly more complicated than that for solving Laplace’s equation, the extra complication arising from the application of two boundary conditions rather than one on r = a. In other geometries, however, solving the biharmonic equation generally involves serious practical difficulties that are not encountered with Laplace’s equation. To illustrate the problems that may occur, we will now consider plane strain in a cylinder with rectangular cross-section |x| < a, |y| < b. For simplicity, we suppose that the faces are subject to purely tangential tractions, that is τxx = 0,
τxy = g± (y)
on x = ±a,
(2.6.47a)
τyy = 0,
τxy = f± (x)
on y = ±b,
(2.6.47b)
as shown schematically in Figure 2.11. Of course the applied tractions must exert no net force or moment, so that b a f+ (x) − f− (x) dx = g+ (y) − g− (y) dy = 0, (2.6.48a) b
−a a
−a
f+ (x) + f− (x) dx − a
−b b
−b
g+ (y) + g− (y) dy = 0.
(2.6.48b)
The Airy stress function therefore satisfies the biharmonic equation subject to A = 0, A = 0,
∂2A = −g± (y) ∂x∂y ∂2A = −f± (x) ∂x∂y
on x = ±a,
(2.6.49a)
on y = ±b,
(2.6.49b)
after integrating the normal stress conditions as in Section 2.6.3.
2.6 Plane strain
57
y f+ g+ b a
x
g− f− Fig. 2.11 A plane rectangular region subject to tangential tractions on its faces.
The seemingly simplest solution procedure is to separate the variables, writing A(x, y) = F (x)G(y) where F G G F +2 + = 0. F F G G
(2.6.50)
For any fixed value of y, this is a linear, constant-coefficient, fourth-order ordinary differential equation for F (x), which suggests writing F as a combination of exponentials eαx . This leads to G + 2α2 G + α4 G = 0
(2.6.51)
and hence to solutions of the form A = a1 y cos (αy) + a2 y sin (αy) + a3 cos (αy) + a4 sin (αy) eαx + b1 y cos (αy) + b2 y sin (αy) + b3 cos (αy) + b4 sin (αy) e−αx . (2.6.52) Clearly a second class of separable solutions arises from exchanging the roles of x, y. All these solutions can also be derived from (2.6.12) by putting f = Aeαz + Be−αz , g = Ceαz + De−αz . We now need to select from (2.6.52) functions which satisfy A = 0 on |x| = a and on |y| = b. For simplicity, we suppose that the tangential tractions f± (x) and g± (y) are both odd functions. We can thus assume that A is an even function of x and y, which is analogous to seeking a Fourier cosine series representation for solutions of Laplace’s equation. After a little experimentation, we find that α must be of the form (n+1/2)π/a or (n+1/2)π/b, for some integer n. By interchanging x and y, we can therefore construct a
58
Linear elastostatics
solution of the form nπy nπx A= An Fn (x) cos + Bn Gn (y) cos , 2b 2a
(2.6.53)
n odd
where An and Bn are constants and the functions Fn and Gn are defined by nπa nπx nπa nπx Fn (x) = a sinh cosh − x cosh sinh , (2.6.54a) 2b 2b 2b 2b nπy nπy nπb nπb cosh sinh − y cosh . (2.6.54b) Gn (y) = b sinh 2a 2a 2a 2a In contrast to more elementary Fourier series examples, we now encounter a serious difficulty when we try to determine An and Bn in terms of the applied tractions. Considering x = a, for example, we find that nπy nπ πn g+ (y) = aFn (a)An sin + b sin Bn Gn (y) , (2.6.55) 2ab 2b 2 n odd
but {sin(nπy/2b), Gn (y)} do not form an orthogonal set on −b < y < b. Hence, if we were to multiply (2.6.55) by Gm (y) and integrate over |y| < b in the usual Fourier series procedure, we would end up with an infinite system of equations for the constants An and Bn . We will discuss this difficulty further below. 2.6.7 Plane strain in a semi-infinite strip We now present an example which is technically easier than the rectangular geometry discussed above and which has wide significance in the theory of linear elasticity. We consider plane strain in the semi-infinite strip 0 < x < ∞, −h/2 < y < h/2, with zero stress on y = ±h/2 and with prescribed tractions τxx = σx (y),
τxy = σy (y)
(2.6.56)
on x = 0, as illustrated in Figure 2.12. Then the Airy stress function satisfies the biharmonic equation along with the boundary conditions ∂2A (0, y) = σx (y), ∂y 2
∂2A (0, y) = −σy (y), ∂x∂y
(2.6.57)
and, as in Section 2.6.3, we can choose A such that A(x, h/2) =
∂A (x, h/2) = 0. ∂y
(2.6.58)
However, because the end x = 0 is not traction-free, we cannot use the same conditions on the other face y = −h/2. All we can safely deduce from the
2.6 Plane strain
59
y stress free
x
τxx = σx (y)
τxy = σy (y)
stress free
Fig. 2.12 The tractions applied to the edge of a semi-infinite strip.
zero-stress condition is that ∂2A ∂2A (x, −h/2) = 0, (x, −h/2) = ∂x2 ∂x∂y
(2.6.59a)
which implies that A(x, −h/2) = a + bx,
∂A (x, −h/2) = c, ∂y
(2.6.59b)
where a, b and c are constants. We can calculate these constants by insisting that A and ∇A be continuous at the corners (0, ±h/2); otherwise we would, in general, have point forces or moments acting there, rather than just jump discontinuities in the tractions. By integrating (2.6.57) with respect to y, we find that h/2 h/2 h/2 ∂A ∂A A= = =− (η − y)σx (η) dη, σy (η) dη, σx (η) dη ∂x ∂y y y y (2.6.60) on x = 0, and we deduce that h/2 (y + h/2) σx (y) dy, b = a= −h/2
h/2 −h/2
σy (y) dy, c = −
h/2
−h/2
σx (y) dy. (2.6.61)
We would like to try to solve this problem by separating the variables, as in Section 2.6.6, but this is difficult because of the inhomogeneous boundary condition (2.6.59b). However, we note that the function A∞ (x, y) =
(h − 2y)2 4a(h + y) + 4bx(h + y) + ch(h + 2y) 3 8h
(2.6.62)
60
Linear elastostatics
satisfies both the biharmonic equation and the boundary conditions (2.6.58), (2.6.59). Hence, if we set ˜ A = A∞ + A,
(2.6.63)
˜ is biharmonic and satisfies homogeneous boundary conditions then A ˜ ˜ ∂A ∂A ˜ ˜ (x, −h/2) = A(x, h/2) = (x, h/2) = 0. A(x, −h/2) = ∂y ∂y
(2.6.64)
Using (2.6.52), we can write the solution as a superposition of functions of the form ˜ = a1 y cos (αy) + a2 y sin (αy) + a3 cos (αy) + a4 sin (αy) e−αx , (2.6.65) A with Re(α) > 0. The boundary conditions (2.6.64) lead to four homogeneous linear equations of the form h ± cos 2
αh 2
h a1 + sin 2
αh 2
a2 + cos
αh 2
a3 ± sin
αh 2
a4 = 0,
(2.6.66a) αh αh αh αh αh αh sin cos − a1 ± sin + a2 cos 2 2 2 2 2 2 αh αh a3 + α cos a4 = 0, ∓ α sin 2 2 (2.6.66b) which admit nontrivial solutions for the constants ai only if the relevant determinant is zero. This eventually leads to the transcendental equation† sin (αh) = ±αh,
(2.6.67)
and the “eigenvalues” α satisfying (2.6.67) are complex. This occurs because the ordinary differential equation (2.6.51), along with the boundary conditions G = G = 0 at y = ±h/2 is not a self-adjoint eigenvalue problem, in contrast with the St¨ urm–Liouville problems which would be encountered were we solving Laplace’s equation. This has the additional implication that †
the calculation is much simpler if the problem is posed on the strip 0 < y < h
2.6 Plane strain
61
the “eigenfunctions” are not mutually orthogonal, which seriously complicates the task of fitting the initial conditions, as in (2.6.55). Had we instead imposed the conditions A = ∂ 2 A/∂y 2 = 0 on y = ±h/2, we would have found that the eigenvalues are real and the eigenfunctions are orthogonal trigonometric functions. We will see a practically relevant example of this in Section 4.6 but, unfortunately, specifying ∂ 2 A/∂n2 on the boundary has no obvious physical significance in plane strain. ˜ can in fact be A completeness argument can be given to show that A expressed as a sum of terms of the form (2.6.65), with Re(α) > 0, although, because of the difficulties described above, the coefficients can only be computed numerically by inverting an infinite matrix. Thus, whatever tractions ˜ will decay exponentially as x → ∞. The stress far are imposed on x = 0, A from the edge of the strip will then be characterised entirely by the stress function A∞ , which corresponds to a far-field stress, as x → ∞, τxx →
12y(a + bx) + h(6y − h)c , h3
τxy →
3b 2 2 − 4y h , 2h3
τyy → 0. (2.6.68)
The net tensile force T , shear force N and bending moment M exerted on any section x = const. by the stress field (2.6.68) are given by h/2 h/2 τxx dy = −c, N (x) = τxy dy = b, (2.6.69a) T (x) = −h/2
−h/2
h/2
M (x) = −h/2
yτxx dy = a + bx +
ch . 2
(2.6.69b)
From (2.6.61), we deduce that T , N and M satisfy the differential equation dM = N, dx and the boundary conditions h/2 T (0) = σx (y) dy,
(2.6.70)
h/2
N (0) =
−h/2
−h/2
σy (y) dy,
(2.6.71a)
h/2
M (0) = −h/2
yσx (y) dy.
(2.6.71b)
Note that (2.6.71) does not correspond to setting x = 0 as in (2.6.57); rather it is the matching condition between (2.6.68) and the solution for A in the form (2.6.63). The only information about the tractions applied to x = 0 that is preserved as x → ∞ is the value of the scalars T , N and M , which
62
Linear elastostatics
correspond to the net force and moment exerted on the edge of the strip. It follows that any system of tractions σx (y), σy (y) applied to the edge of an elastic strip is indistinguishable from a different set of tractions which exerts the same net force and moment, just as long as we are sufficiently far from the edge. This phenomenon occurs quite generally in elasticity and is known as Saint-Venant’s principle: any localised system of tractions applied to a sufficiently large elastic body may be characterised in the far field purely by its net force and moment. We will return to this important fact in Chapters 4 and 6, when considering the boundary conditions to be imposed on thin solids such as plates and rods, and we will also re-encounter the relation (2.6.70) between the shear force and bending moment. Finally, let us examine the far-field displacement by using (2.6.62) and (2.6.9). From (2.6.9), we find that u and v satisfy −
2µ ∂u 2µ ∂v = = ν ∂y 1 − ν ∂x ∂u ∂v + = µ ∂y ∂x
T 12M (x)y + , h h3 3N 2 2 h . − 4y 2h3
(2.6.72a) (2.6.72b)
We can eliminate u by differentiating (2.6.72b) with respect to x to obtain 6(1 − ν) ∂2u ∂2v =− M (x). (2.6.73) =− ∂x2 ∂x∂y µh3 This relationship between the bending moment and the curvature of the displaced strip will also prove very useful in Chapter 4. 2.6.8 Plane strain in a half-space As long as we are deft with Fourier transforms, all the difficulties associated with the separability of solutions melt away when we consider a half-space, say y > 0, with prescribed traction τyy = −P (x),
τxy = σ(x)
on y = 0.
(2.6.74)
Assuming that P and σ decrease sufficiently rapidly as |x| → ∞, we define the Fourier transform ∞ ! A (x, y) eikx dx. (2.6.75) A (k; y) = −∞
Assuming further that this integral converges, we also recall the inversion formula ∞ 1 ˆ −ikx dx. Ae (2.6.76) A= 2π −∞
2.6 Plane strain
63
From the biharmonic equation (2.6.10) we find that 2 2 d 2 !=0 A y > 0, −k dy 2
(2.6.77a)
and, from (2.6.74), ˆ = P!(k) k2 A ! dA =σ !(k) ik dy !→0 A
y = 0,
(2.6.77b)
y = 0,
(2.6.77c)
y → ∞.
(2.6.77d)
! is readily solved to give This ordinary differential equation for A iy 1 + y|k| != !(k) e−y|k| . P!(k) − σ A k2 k
(2.6.78)
The presence of inverse powers of k in (2.6.78) indicates that the integral in (2.6.75) fails to converge unless k is a complex variable. However, we can avoid the use of complex k by inverting the formulae for the stress components. For simplicity, we just consider the case σ = 0, when we deduce that τ!xx = −P!(k) (1 − y|k|) e−|k|y , τ!xy = P!(k)iyke−|k|y ,
(2.6.79b)
τ!yy = −P!(k) (1 + y|k|) e
(2.6.79c)
−|k|y
,
(2.6.79a)
which, as shown in Exercise 2.11(a), may be inverted as convolutions of the form 2 ∞ s2 y ds P (x − s) , (2.6.80a) τxx = − π −∞ (s2 + y 2 )2 2 ∞ sy 2 ds P (x − s) , (2.6.80b) τxy = − π −∞ (s2 + y 2 )2 2 ∞ y 3 ds P (x − s) . (2.6.80c) τyy = − π −∞ (s2 + y 2 )2 We can now use (2.6.9) to calculate the displacements. For example, v! satisfies 2µ
2! d! v ! − ν d A = ((2ν − 1) − y|k|) Pˆ (k)e−y|k| , = −(1 − ν)k 2 A dy dy 2
(2.6.81)
64
Linear elastostatics
which may be integrated, in the case σ = 0, to obtain 1−ν ! 2µ! v = y+2 P (k) e−y|k| . |k|
(2.6.82)
Again, this is awkward to invert as it stands (because of the |k| in the denominator) and it is easier first to differentiate with respect to x. As shown in Exercise 2.11(b), this leads to 1 ∞ (1 − ν)s2 + (2 − ν)y 2 ∂v =− P (x − s)s ds. (2.6.83) µ ∂x π −∞ (s2 + y 2 )2 Alternatively, we can also obtain (2.6.83) from the identity E
∂τyy ∂τxy ∂τxx ∂2v − +ν , = 2(1 + ν) ∂x2 ∂x ∂y ∂y
(2.6.84)
by using (2.6.80) and then integrating with respect to x. The displacement v0 (x) = v(x, 0) of the surface caused by the imposed pressure can now be found by carefully letting y tend to zero, as shown in Exercise 2.12. When we do so, the right-hand side of (2.6.83) reduces to the singular integral 1 ∞ P (s) ds dv0 = (1 − ν) − = (1 − ν)H[P ], (2.6.85) µ dx π −∞ s − x " where H[P ] is called the Hilbert transform of P , − being the principal value integral defined in Exercise 2.12. As shown # $in Exercise 2.13, this transform may be inverted using the formula H H[f ] ≡ −f , and hence we can calculate the pressure required to achieve a given surface displacement v0 (x), namely # $ µ P =− H v0 . (2.6.86) 1−ν As an illustrative example, the surface displacement a 1 + x2 /L2
(2.6.87a)
1 − x2 /L2 µa , (1 − ν)L (1 + x2 /L2 )2
(2.6.87b)
v0 (x) = corresponds to a surface pressure P (x) =
and both are plotted in Figure 2.13. Notice that in some parts a negative pressure must be applied to obtain the given bounded surface displacement.
2.6 Plane strain
65
1
0.8
0.6
v0 /a
0.4
(1 − ν)LP/µa
0.2
-4
-2
2
4
x/L
Fig. 2.13 The surface displacement v0 (x) of a half-space and corresponding surface pressure P (x) defined by (2.6.87).
One can deduce generally from (2.6.85) that it is only possible to achieve a localised displacement, with v0 → 0 as x → ±∞, if ∞ P (x) dx = 0, (2.6.88) −∞
and it is therefore necessary for P to change sign. This phenomenon is an artefact of plane strain which results from the artificial constraint of zero transverse strain, and we will see in Section 2.9.3 that it does not occur in radially symmetric problems. The general question of the indentation produced by traction applied to the boundary of a half-plane will be discussed further in connection with “punch” problems in Chapter 7.
2.6.9 Plane strain with a body force The Airy stress function approach can easily be extended to plane strain under the action of a body force that is conservative. If −g may be written as the gradient of a potential V (x, y), then the two-dimensional Navier equation takes the form ∂τxy ∂V ∂τxx + =ρ , ∂x ∂y ∂x
∂τxy ∂τyy ∂V + =ρ , ∂x ∂y ∂y
(2.6.89)
and (2.6.8) therefore generalises to τxx = ρV +
˜ ∂2A , ∂y 2
τxy = −
˜ ∂2A , ∂x∂y
τyy = ρV +
˜ ∂2A . ∂x2
(2.6.90)
66
Linear elastostatics
˜ satisfies the Now when we eliminate the displacements, we discover that A inhomogeneous biharmonic equation 1 − 2ν 4˜ ∇2 V = 0. (2.6.91) ∇ A+ 1−ν This result makes it appear that gravity, which is modelled by setting ˜ since ∇2 V = 0. However, if traction conditions V = gy, has no effect on A, for τ are given, V will enter when (2.6.90) is used to transform these con˜ In other words, the substitution (2.6.90) ditions into boundary data for A. eliminates the body force from the problem, but replaces it with boundary tractions. This substitution is often useful in solving elastostatic problems numerically. As an illustration, let us try to find the stress in the elastic medium surrounding a tunnel, a problem of importance say to civil engineers involved with underground railways. Supposing that the tunnel is circular, with radius a, and at a depth H, we incorporate gravity into the plane polar stress components (2.6.20) by setting ˜ ˜ 1 ∂2A 1 ∂A , τrr = ρg (r sin θ − H) + 2 2 + r ∂θ r ∂r ˜ ∂ 1 ∂A , τrθ = − ∂r r ∂θ τθθ = ρg (r sin θ − H) +
˜ ∂2A , ∂r2
(2.6.92a) (2.6.92b) (2.6.92c)
where the depth is −y = H−r sin θ. As shown above, the modified Airy stress function satisfies the biharmonic equation, and the zero-traction conditions τrr = τrθ = 0 on the tunnel wall lead to ˜ ˜ ˜ 1 ∂2A 1 ∂A ∂ A = 0, = ρg (H − r sin θ) (2.6.93) + ∂r r r2 ∂θ2 r ∂r on r = a. ˜ By eliminating ∂ A/∂r from the boundary conditions (2.6.93), we obtain ˜ ∂2A ˜ = ρga2 (H − a sin θ) +A ∂θ2
on r = a.
(2.6.94)
˜ θ), whose general This is effectively an ordinary differential equation for A(a, solution is 3 ˜ θ) = ρga2 H + ρga θ cos θ + Aa cos θ + Ba sin θ, A(a, 2
(2.6.95a)
2.6 Plane strain
67
where A and B are arbitrary constants, and (2.6.93) then gives us the second condition ˜ ρga2 ∂A = ρgaH + θ cos θ + A cos θ + B sin θ ∂r 2
on r = a.
(2.6.95b)
These boundary conditions suggest that we try a solution of the form ˜ = f1 (r) + f2 (r)θ cos θ + f3 (r) cos θ + f4 (r) sin θ. A
(2.6.96)
The functions fj (r) can, in principle, be found by substituting (2.6.96) into the biharmonic equation and into the boundary conditions (2.6.95). We now make the important simplifying assumption that H a so that, rather than imposing traction-free boundary conditions on y = 0, we simply ensure that ˜ decay sufficiently rapidly as r → ∞ for the far-field the derivatives of A ˜ is only defined up to an stress field to be hydrostatic. We also recall that A arbitrary linear function of x and y, so we can ignore terms proportional to r cos θ and r sin θ to obtain 2 ˜ = ρga2 H 1 + log(r/a) + ρga rθ cos θ A 2 a2 A cos θ + B sin θ + + 2r log r . (2.6.97) r 1 + 2 log a
We do not yet have a unique solution, since the constants A and B still appear to be arbitrary. As in Section 2.6.5, the key to closing the problem in this multiply-connected domain is to ensure that the displacement field is single-valued. As shown in Exercise 2.15, this condition allows us to determine both remaining constants, and we find that A = 0,
B=
ρga2 (1 − 2ν)(1 + 2 log a) . 8(1 − ν)
(2.6.98)
We thus evaluate the stress components as τrr τrθ τθθ
(1 − 2ν) a2 a2 −H + r sin θ 1 + , = ρg 1 − 2 r 4(1 − ν) r2 a2 ρga2 cos θ (1 − 2ν) 1− 2 , =− r 4(1 − ν) r 2 (1 − 2ν) a2 sin θ a . −H + = ρgr sin θ + ρg 1 + 2 r 4(1 − ν) r
(2.6.99a) (2.6.99b) (2.6.99c)
68
Linear elastostatics
Evidently, τrr and τrθ are both zero on r = a, as required, and the non-zero hoop stress on the tunnel is given by τθθ = −2ρgH +
3 − 4ν ρga sin θ 2(1 − ν)
on r = a.
(2.6.100)
Hence a small tunnel suffers twice as much compressive stress as would occur in its absence. Moreover, the minimum compressive stress occurs at θ = π/2, which is the roof of the tunnel, while the maximum compressive stress is at the bottom θ = −π/2. In fact, it can be shown that this final result remains valid for all values of H and a (see Mindlin, 1939).
2.7 Compatibility In Section 1.6, Newton’s second law led us to write down the equation ∂τij + ρgi = 0 ∂xj
(2.7.1)
for the stress tensor in elastostatics in the presence of a body force gi . Viewed as a system of equations for the stress components, (2.7.1) is underdetermined, comprising just three equations for six unknowns. It was only by using the constitutive relations (1.7.6), ∂uj ∂uk ∂ui δij + µ (2.7.2) + τij = λ (ekk ) δij + 2µeij = λ ∂xk ∂xj ∂xi that we were able to obtain a closed system of the three Navier equations for the three components of displacement. It follows that, given τij , (2.7.2) is itself an over-determined system for the displacements. If we were in the very fortunate position of knowing all the stress components τij , which of course must satisfy (2.7.1), then it would be straightforward to obtain the corresponding linearised strain tensor from (2.2.15). Thus, given τij , we could view our expression ∂uj 1 ∂ui (2.7.3) + eij = 2 ∂xj ∂xi as a system of equations for the displacement components ui , rather than a definition of eij . In this light, however, (2.7.3) is a set of six partial differential equations for the three displacements ui , and this imposes on eij severe restrictions, called compatibility conditions. Since these conditions will soon be seen to have considerable theoretical and practical importance, we will now derive them.
2.7 Compatibility
69
T
First consider a plane strain problem, in which u = u(x, y), v(x, y), 0 and ∂u 1 ∂u ∂v ∂v , exy = + , eyy = . (2.7.4) exx = ∂x 2 ∂y ∂x ∂y Since the three strain components are functions of just two displacements, (2.7.4) is over-determined when viewed as a system of equations for (u, v). However, whenever u is a twice continuously differentiable single-valued function, we must have ∂ 2 u/∂x∂y ≡ ∂ 2 u/∂y∂x and similarly for v. It then follows from cross-differentiation that ∂ 2 eyy ∂ 2 exy ∂ 2 exx + − 2 = 0. ∂y 2 ∂x∂y ∂x2
(2.7.5a)
Equation (2.7.5a) is the compatibility condition which ensures that (2.7.4) can be solved for single-valued functions u and v. In three dimensions, the same argument applies to the in-plane displacements in the (x, z)- and (y, z)-planes, yielding ∂ 2 eyy ∂ 2 eyz ∂ 2 ezz + − 2 = 0, (2.7.5b) ∂z 2 ∂y∂z ∂y 2 ∂ 2 ezx ∂ 2 exx ∂ 2 ezz − 2 = 0, (2.7.5c) + ∂x2 ∂z∂x ∂z 2 and it might look as if we have then found all the compatibility conditions needed for the existence of u, v and w. However, we also have to ensure that displacements transverse to each coordinate plane exist and are singlevalued, so that, for example, ∂ 2 w/∂x∂y ≡ ∂ 2 w/∂y∂x. Once we take this into account, we obtain the additional three compatibility relations ∂exy ∂eyz ∂ ∂exz ∂ 2 exx = + − , (2.7.5d) ∂y∂z ∂x ∂y ∂z ∂x ∂ 2 eyy ∂eyz ∂ ∂eyx ∂ezx = + − , (2.7.5e) ∂z∂x ∂y ∂z ∂x ∂y ∂exy ∂ 2 ezz ∂ ∂ezy ∂ezx = + − . (2.7.5f) ∂x∂y ∂z ∂x ∂y ∂z We thus have a total of six compatibility conditions, which now seems excessive for a system of six equations in the three unknowns ui . In fact, only three of the equations are independent, in the sense that cross-differentiation to eliminate all but three unknowns from (2.7.5) inevitably leads to just one independent equation. However, all six compatibility conditions are necessary for a single-valued displacement to exist. This situation is analogous
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Linear elastostatics
to that which arises when considering a vector field u which is the gradient of a potential. In this case, it is necessary that all three components of curl u vanish, although only two components of curl u are independent in the above sense. Our situation is a generalisation of this statement, since, as shown in Exercise 2.21, the compatibility conditions (2.7.5) are equivalent to the components of the tensor equation 0 −∂/∂z ∂/∂y curl (curl E)T = 0, where curl = ∂/∂z 0 −∂/∂x . (2.7.6) −∂/∂y ∂/∂x 0 We also remark that any three independent compatibility equations for eij are just as under-determined as the three equilibrium equations (2.7.1) are for τij . Hence, the fact that the compatibility conditions ensure the existence of three physically acceptable displacement components suggests that (2.7.1) will similarly guarantee the existence of three scalar stress functions. We have already encountered an application of this idea to plane strain in Section 2.6, and we will show below in Section 2.8 how it may be generalised to non-planar problems. It is important to note that, if eij does not satisfy (2.7.5), then there is no physically acceptable displacement field that gives rise to such a strain and it is, therefore, incompatible with linear elasticity. In Section 2.9.4 we will discuss one physical interpretation of incompatibility in detail. Meanwhile, we simply conjecture that, if we are presented with an elastic material which has been deformed under the action of, say, some non-zero boundary tractions, then, when the tractions are removed, the necessary and sufficient condition for the material to return to its pristine unstrained state is that the strain field in it satisfies (2.7.5), and we will see specific examples of this in Section 8.4.
2.8 Generalised stress functions 2.8.1 General observations By taking the divergence of the steady Navier equation (2.2.1) in the absence of body forces, we see that div u must be a harmonic function: ∇2 (div u) = 0.
(2.8.1)
If instead we take the curl of (2.2.1), we find that curl3 u = 0.
(2.8.2)
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71
and so, by taking the curl once more and using (2.8.1), we obtain ∇4 u = 0.
(2.8.3)
Each Cartesian component of the displacement must therefore satisfy the biharmonic equation, as shown in Section 2.6 for plane strain. We emphasise that (2.8.3) can only be written component-wise as 4 ∇ u ∇4 u = ∇4 v = 0 (2.8.4) 4 ∇ w in Cartesian coordinates; in any other coordinate systems we must use the identity (1.7.11). Alternatively, we may use the Helmholtz representation to write u as the sum of a gradient and a curl: u = ∇φ + ∇×A,
with
∇ · A = 0.
(2.8.5)
(It may be shown that this decomposition applies to any continuously differentiable vector field u.) Substitution of (2.8.5) into (2.2.1) reveals that the potential functions φ and A must also satisfy the biharmonic equation ∇4 φ = 0,
∇4 A = 0.
(2.8.6)
These results all suggest that we may be able to construct large classes of solutions of (2.2.1) by considering suitable harmonic or biharmonic scalar problems. We have already seen some examples of this approach in plane and antiplane strain (Sections 2.3–2.6) and we will now show how analogous ideas may be applied in some other commonly-occurring configurations. 2.8.2 Plane strain revisited We begin by re-examining the theory of plane strain in the light of the concept of compatibility developed in Section 2.7. As we showed in Section 2.6, the two conservation laws ∂τxy ∂τxx + = 0, ∂x ∂y
∂τxy ∂τyy + =0 ∂x ∂y
(2.8.7)
imply the existence of an Airy stress function A. We then eliminated the displacement components to deduce that A satisfies the biharmonic equation. We thus implicitly assumed compatibility of the stress tensor with a physically acceptable displacement field. We can make this procedure more systematic by making use of the plane compatibility condition (2.7.5a) which, when written in terms of the stress
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Linear elastostatics
components, is ∂ 2 τyy ∂ 2 τxy ∂ 2 τxx + − 2 − ν∇2 (τxx + τyy ) = 0. ∂y 2 ∂x∂y ∂x2
(2.8.8)
Now (2.8.7) and (2.8.8) form a closed system of partial differential equations for the stress components (τxx , τxy , τyy ). If, as in Section 2.6, we write τxx =
∂2A , ∂y 2
τxy = −
∂2A , ∂x∂y
τyy =
∂2A , ∂x2
(2.8.9)
then the stress balance equations (2.8.7) are satisfied identically, and substitution of (2.8.9) into (2.8.8) quickly retrieves the biharmonic equation for A. It is worth noting that an inhomogeneous equation for A of the form ∇4 A = f
(2.8.10)
does not, as might have been suspected from (2.6.91), correspond to the imposition of a body force. The mere existence of A implies that (2.8.7) are satisfied, so there is no such force. Instead the right-hand side f of (2.8.10) corresponds to a distribution of incompatibility through the material, and we will discuss in Section 2.9.4 and Chapter 8 what the physical significance of such a configuration might be. Now let us suppose that we do impose a body force in, say, the x-direction so that the first Navier equation (2.8.7a) is modified to ∂τxy ∂τxx + = −f. ∂x ∂y
(2.8.11)
Now there is no longer an Airy stress function, but we can instead try to obtain an integrability condition from the two remaining homogeneous equations (2.8.7b) and (2.8.8). From (2.8.7b) we deduce the existence of a function A1 (x, y) such that τxy =
∂A1 , ∂y
τyy = −
∂A1 , ∂x
so the compatibility condition (2.8.8) becomes 2 2 ∂ ∂ 2 2 ∂A1 = 0. − ν∇ τxx − + (1 − ν)∇ ∂y 2 ∂y 2 ∂x
(2.8.12)
(2.8.13)
To write this in conservation form, we first let A2 be such that τxx = ∂A2 /∂x, so that, without loss of generality, 2 2 ∂ ∂ 2 2 − ν∇ A2 − + (1 − ν)∇ A1 = 0. (2.8.14) ∂y 2 ∂y 2
2.8 Generalised stress functions
73
We must now spot that, if we set A2 = A1 + ∇2 L, then (2.8.14) is satisfied identically by 2 ∂ 2 L. (2.8.15) − ν∇ A1 = ∂y 2 The existence of the Love function L, also known as the Love stress function or the Love strain function, guarantees that the strain field is compatible and the stress balance in the y-direction is satisfied. It is related to the stress components by 2 ∂ ∂ ∂A2 2 (2.8.16a) = + (1 − ν)∇ L, τxx = ∂x ∂x ∂y 2 2 ∂ ∂ ∂A1 2 τxy = (2.8.16b) = − ν∇ L, ∂y ∂y ∂y 2 2 ∂ ∂ ∂A1 τyy = − (2.8.16c) =− − ν∇2 L, ∂x ∂x ∂y 2 and, when we finally substitute these into the x-momentum equation (2.8.11), we find that L is such that ∂τxy ∂τxx + = (1 − ν)∇4 L = −f. ∂x ∂y
(2.8.17)
Even though the Love function is ideally suited to problems with a unidirectional body force, the derivation given above remains valid if there is no body force, in which case f ≡ 0 and L satisfies the biharmonic equation. Hence, since L is also easily related to the stress components by (2.8.16), it provides an alternative to the Airy stress function for plane strain problems; indeed it can be shown that ∂L/∂x differs from A by a harmonic function. More importantly, when we try to find u and v using ∂u = (1 − ν)τxx − ντyy , ∂x ∂u ∂v + = τxy , µ ∂y ∂x ∂v = (1 − ν)τyy − ντxx , 2µ ∂y 2µ
(2.8.18a) (2.8.18b) (2.8.18c)
the resulting system is guaranteed to be integrable, by our construction of L. Indeed, apart from a rigid body displacement, we may obtain the explicit formulae ∂2L 1 ∂2L 1 2 . (2.8.19) , v = − (1 − 2ν)∇ L + u= 2µ ∂y 2 2µ ∂x∂y
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Linear elastostatics
Hence, in principle, the difficulties associated with posing displacement boundary conditions in the Airy stress function formulation can be avoided: all you need is Love. We note that, for a given displacement field, L is determined uniquely up to terms linear in x, y; rigid body displacements create quadratic terms in L and cubic terms proportional to νy 3 − 3(1 − ν)x2 y. For a more direct, though perhaps less instructive, derivation of (2.8.19) we note that the second Navier equation (2.6.5b), written out in terms of the displacements, may be rearranged to ∂2 ∂2u 2 (2.8.20) + (1 − 2ν)∇ + 2 v = 0. ∂x∂y ∂y Now we can argue that (2.8.19) is just the integrability condition for (2.8.20). However, this intuitively appealing derivation is deceptively simple; it is clear that (2.8.19) guarantees (2.8.20) but we have not proved the converse. Finally, we note that our derivation of the Love function depended on initially disregarding the x-momentum equation. If we had instead discarded the y-momentum equation, or considered a body force in the y-direction, we would have obtained a different but mathematically equivalent formulation for L. Clearly we can thus define a one-parameter family of Love functions corresponding to an arbitrarily-oriented unidirectional body force.
2.8.3 Plane stress Plane strain is characterised by the fact that the strain tensor E is purely two-dimensional, that is exz = eyz = ezz = 0. Now we instead look for a state of plane stress, in which the only non-zero components of the stress tensor are τxx , τxy and τyy . Such a state might exist, for example, in a plate with no applied traction on its faces and suitably chosen loading conditions on its edges; indeed we will meet exactly this configuration again in Chapters 4 and 6. It contrasts with plane strain, where, as we recall from Section 2.6, the normal stress τzz is in general non-zero. We again introduce an Airy stress function A as in (2.6.8), although now we must allow A to be a function of x, y and z. We can still use the compatibility condition (2.7.5a) to deduce that A satisfies the two-dimensional biharmonic equation 2 2 2 ∂ ∂ 4 % A= + 2 A = 0, (2.8.21) ∇ ∂x2 ∂y the tilde denoting that ∂ 2 /∂z 2 has been omitted from the Laplacian. However, this is now insufficient to determine the z-dependence of A, and so we
2.8 Generalised stress functions
75
must ensure that all five remaining compatibility conditions are also satisfied. To this end we find that the non-zero strain components are given by ∂2A ∂2A − ν , ∂y 2 ∂x2 ∂2A , Eexy = (1 + ν)τxy = −(1 + ν) ∂x∂y ∂2A ∂2A Eeyy = τyy − ντxx = − ν , ∂x2 ∂y 2 % 2 A; Eezz = −ν (τxx + τyy ) = −ν ∇ Eexx = τxx − ντyy =
(2.8.22a) (2.8.22b) (2.8.22c) (2.8.22d)
note in particular that ezz is in general non-zero, in contrast with plane strain. First considering (2.7.5d) and (2.7.5e), we obtain ∂2 % 2 ∂2 % 2 ∇ A = ∇ A = 0, (2.8.23) ∂x∂z ∂y∂z from which we deduce that % 2 A = f (z) + φ(x, y), ∇
(2.8.24)
% 2 φ = 0 and f is arbitrary. Next, by adding (2.7.5c) and (2.7.5b), we where ∇ obtain ∂ 2 % 2 d2 f (2.8.25) ∇ A = 2 = 0, ∂z 2 dz so, without loss of generality, we may set f (z) = βz for some constant β. Finally, taking (2.7.5c), (2.7.5b) and (2.7.5f) individually, we find that ∂2A ∂2A ∂2 ∂2 (1 + ν) (1 + ν) + νφ = + νφ ∂x2 ∂z 2 ∂x∂y ∂z 2 2 2 ∂ A ∂ (1 + ν) 2 + νφ = 0. (2.8.26) = ∂y 2 ∂z Since terms linear in x and y do not contribute to the stress, we lose no generality in setting (1 + ν)
∂2A + νφ = 0, ∂z 2
(2.8.27)
and it follows that A may be written in the form A=−
νφ(x, y)z 2 + zχ1 (x, y) + χ0 (x, y), 2(1 + ν)
(2.8.28)
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Linear elastostatics
where % 2 χ0 = φ, ∇
% 2 φ = 0, ∇
% 2 χ1 = β = const.. ∇
(2.8.29)
This rather unwieldy representation in terms of three stress potentials φ, χ0 and χ1 is one of the few ways in which three-dimensional stress fields can be generated analytically. A simple example is that of biaxial strain, introduced in Section 2.2.4, which may be reproduced by setting χ1 to be zero and χ0 to be a suitable quadratic function of x and y. Another case is obtained by choosing φ = 0, χ0 = 0 and χ1 = −Eκy 2 /2, so that β = −Eκ and τxx = −Eκz,
τyy = τxy = 0,
while the corresponding displacement field is −2xz κ . u= 2νyz 2 2 2 2 x − νy + νz
(2.8.30a)
(2.8.30b)
This solution represents bending of a beam about the y-axis, and will provide a useful check on the approximate beam theory to be developed in Chapters 4 and 6.
2.8.4 Axisymmetric geometry The Love function was first introduced for axisymmetric stress fields, (Love, 1944, Article 188). Indeed, in cylindrical coordinates, the Navier equation does not take the conservation form required for an analogue of the Airy stress function to be defined. Although technically tedious, the derivation of the axisymmetric Love function follows the same conceptual procedure as for the plane strain Love function described in Section 2.8.2. We will instead follow the more direct, although slightly cavalier, approach suggested at the end of Section 2.8.2. Let us consider an axisymmetric problem, in which the displacement takes the form u = ur (r, z)er + uz (r, z)ez
(2.8.31)
and there is a unidirectional body force in the z-direction. The homogeneous er -component of the Navier equation, given by (1.11.8), may be written in the form 2 ∂ 1 1 ∂ ∂2 ∂ 2 uz + 2(1 − ν) − + + (1 − 2ν) 2 ur = 0. (2.8.32) ∂r∂z ∂r2 r ∂r r2 ∂z
2.8 Generalised stress functions
77
When seeking an integrability condition for this equation, we must keep in mind that the differential operators acting on uz and ur do not commute. Instead, for any suitably differentiable function f (r, z), the relation ∂ 1 ∂f 1 ∂2f 1 ∂ 1 ∂f 1 ∂f = = − (2.8.33) − 2 ∂r r ∂r r ∂r2 r ∂r r ∂r r2 ∂r implies that 2 2 ∂ ∂2 ∂ f 1 1 ∂ 2(1 − ν) − 2 + (1 − 2ν) 2 + 2 ∂r r ∂r r ∂z ∂r∂z 2 2 ∂2 ∂ ∂ 1 ∂ 2(1 − ν) + (1 − 2ν) 2 f. (2.8.34) = + ∂r∂z ∂r2 r ∂r ∂z Since the right-hand side may be written as ∂2 1 ∂ ∂ 2 (1 − 2ν)∇ + r f, ∂r∂z r ∂r ∂r we may infer from (2.8.32) the existence of a function L(r, z) such that ∂L 1 ∂2L 1 1 ∂ 2 ur = − , uz = (1 − 2ν)∇ L + r . (2.8.35) 2µ ∂r∂z 2µ r ∂r ∂r With this displacement, it is straightforward to evaluate the stress components from (1.11.5) as ∂ ∂2L 2 τrr = − − ν∇ L , (2.8.36a) ∂z ∂r2 ∂L ∂ 1 ∂ τrz = r − ν∇2 L , (2.8.36b) ∂r r ∂r ∂r ∂L ∂ 1 ∂ 2 r + (1 − ν)∇ L , (2.8.36c) τzz = ∂z r ∂r ∂r ∂ 1 ∂L (2.8.36d) − + ν∇2 L . τθθ = ∂z r ∂r Now to obtain an equation for L, we must substitute these into the ez -component of the Navier equation, which reads 1 ∂ ∂τzz (rτrz ) + = −f, (2.8.37) r ∂r ∂z where the body force is f ez per unit volume. After a lengthy algebraic manipulation, we find that L satisfies (1 − ν)∇4 L = −f,
(2.8.38)
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Linear elastostatics
which is identical to the equation (2.8.17) for the planar Love function. We will now show that this is no accident and, in Section 2.9, we will further show how to use Love functions to construct solutions of the Navier equation corresponding to point forces.
2.8.5 The Galerkin representation We will now show briefly how the planar and axisymmetric Love functions may be viewed as instances of a more widely-applicable theory. We start from the three-dimensional Navier equation in the form (λ + µ) grad div u + µ∇2 u = −f ,
(2.8.39)
where the body force f per unit volume is no longer presumed to be unidirectional. To obtain the Galerkin representation, we make the “out-of-the-blue” hypothesis that the displacement can be written in the form u = a∇2 B − b grad div B,
(2.8.40)
for some vector field B(x) and suitably chosen constants a and b.† The advantage of this representation is that, when we substitute (2.8.40) into (2.8.39), we find that B satisfies (λ + 2µ)(a − b) (grad div)2 B + µa curl4 B = −f ,
(2.8.41)
and the differential operator on the left-hand side may be made proportional to the biharmonic operator by choosing λ + 2µ a = = 2(1 − ν). b λ+µ
(2.8.42)
If we also (arbitrarily) set b = 1/2µ, then we find that B satisfies (1 − ν)∇4 B = −f ,
(2.8.43)
2µu = 2(1 − ν)∇2 B − grad div B.
(2.8.44)
and (2.8.40) reads
The planar and cylindrical Love functions may now be obtained by supposing that B = L(x, y)i or B = L(r, z)ez respectively. Evidently each will only satisfy (2.8.43) if the body force f shares the corresponding symmetry. †
This is reasonable since we expect the curl of (2.8.40) to determine curl B given u, and, if B = ∇ϕ, (2.8.40) is effectively a Poisson equation for ϕ. Note also that, in view of (1.7.11), (2.8.44) may be viewed as an example of a Helmholtz representation (2.8.5).
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79
However, in cases where there is no body force, (2.8.43) opens up the possibility of finding a wealth of scalar stress functions describing problems with various symmetries, simply by posing suitable forms for B.
2.8.6 Papkovich–Neuber potentials Next we will show that (2.8.44) can be used to obtain an extremely useful representation for u that avoids all mention of the biharmonic operator and only involves solutions of Laplace’s equation or Poisson’s equation. We can obtain an immediate simplification by defining Ψ = ∇2 B,
(2.8.45)
so that (2.8.43) becomes ∇2 Ψ = −
f . 1−ν
Now, using the vector identity (1.7.11), we easily find that ∇2 (div B) ≡ div ∇2 B = div Ψ,
(2.8.46)
(2.8.47)
so that, disappointingly, div B turns out not to be a harmonic function. However, the well-known (and easily proved) identity 1 1 div Ψ ≡ ∇2 (x · Ψ) − x · ∇2 Ψ 2 2 allows us to write (2.8.47) in the form 1 x·f ∇2 div B − (x · Ψ) = 2 2(1 − ν)
(2.8.48)
(2.8.49)
and prompts us to define 1 φ = div B − x · Ψ, 2
(2.8.50)
so that φ satisfies a simple Poisson equation. The definitions (2.8.45) and (2.8.50) transform (2.8.44) into the Papkovich–Neuber representation 1 (2.8.51) 2µu = 2(1 − ν)Ψ − grad φ + x · Ψ . 2 When there is no body force, φ and the Cartesian components of Ψ all satisfy Laplace’s equation. In other words, we have replaced the job of finding three scalar biharmonic functions (the components of B) with that of finding four scalar harmonic functions. In plane strain, we can represent the displacement in terms of a single biharmonic Love function, while three
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Linear elastostatics
Papkovich–Neuber potentials are required, namely φ and two components of Ψ. Nevertheless, Laplace’s equation is susceptible to so many more solution techniques than the biharmonic equation that (2.8.51) can prove extremely useful, as we will see in Section 2.9.3 for an axisymmetric point force problem and in Chapter 7 for crack problems. To illustrate the Papkovich–Neuber potentials in antiplane strain problems with u = (0, 0, w(x, y))T , we simply take T z ∂ψ ∂ψ ∂ψ ∂ψ and φ = Ψ= z ,z , (3 − 4ν)ψ x +y −ψ , ∂x ∂y 2 ∂x ∂y (2.8.52) whence, after a simple calculation, (2.8.51) gives T 2µu = 0, 0, 4(1 − ν)(1 − 2ν)ψ ,
(2.8.53)
with the anticipated result that ∇2 w = 0. Concerning plane strain, we anticipate that T φ = φ(x, y) and Ψ = ψ1 (x, y), ψ2 (x, y), 0 ,
(2.8.54)
so that (2.8.51) gives
1 ∂ φ + (xψ1 + yψ2 ) 2µu = 2(1 − ν)ψ1 − ∂x 2 ∂ 1 2µv = 2(1 − ν)ψ2 − φ + (xψ1 + yψ2 ) ∂y 2
and
(2.8.55a) (2.8.55b)
∂2φ ∂2 − (xψ1 + yψ2 ). ∂x∂y ∂x∂y (2.8.56) Hence (2.6.9c) suggests that we choose ∂ψ1 /∂y + ∂ψ2 /∂x to be zero and this in turn suggests that we take ψ1 and ψ2 to be harmonic conjugates. Then (2.6.9c) gives the Goursat representation 2µ
∂u ∂v + ∂y ∂x
= 2(1 − ν)
∂ψ1 ∂ψ2 + ∂y ∂x
−2
1 A = φ + (xψ1 + yψ2 ), 2
(2.8.57)
which is equivalent to (2.6.12). However, the use of φ and harmonic conjugates ψ1 and ψ2 to represent A is far from unique, and we could equally well set ψ1 = 0 and y 1 A = φ + yψ2 − (1 − ν) ψ2 (x, y ) dy , (2.8.58) 2
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81
where ψ2 is a harmonic function. This representation will be found to be very useful in Chapter 7. The uniqueness of the Papkovich–Neuber representation is discussed in Barber (1993, Section 15.4).
2.8.7 Maxwell and Morera potentials We recall our observation in Section 2.7 that the equilibrium Navier equation (2.7.1) comprises just three equations in the six stress components. In three dimensions, we would therefore expect to need three scalar potentials to ensure integrability of (2.7.1) with gi = 0. As usual, there is some freedom in selecting a particular set of stress functions. One well-known possibility is the Maxwell stress functions χi , defined by τxx =
∂ 2 χ3 ∂ 2 χ2 + , ∂y 2 ∂z 2
τxy = −
∂ 2 χ3 , ∂x∂y
τyy =
∂ 2 χ1 ∂ 2 χ3 + , ∂z 2 ∂x2
τyz = −
∂ 2 χ1 , ∂y∂z
τzz =
∂ 2 χ2 ∂ 2 χ1 + , ∂x2 ∂y 2 (2.8.59a)
τzx = −
∂ 2 χ2 . ∂z∂x
(2.8.59b)
It is easy to verify that the steady Navier equation with no body force is identically satisfied for any stress field of this form. Another popular choice is the Morera stress functions ψi , for which ∂ψ1 ∂ψ2 ∂ 2 ψ1 ∂ ∂ψ3 , τxy = − − , (2.8.60a) τxx = 2 ∂y∂z ∂z ∂z ∂x ∂y ∂ψ2 ∂ψ3 ∂ 2 ψ2 ∂ ∂ψ1 τyy = 2 , τyz = − − , (2.8.60b) ∂z∂x ∂x ∂x ∂y ∂z ∂ψ3 ∂ψ1 ∂ 2 ψ3 ∂ ∂ψ2 τzz = 2 , τzy = − − . (2.8.60c) ∂x∂y ∂y ∂y ∂z ∂x At first glance, little is gained by formulating three-dimensional problems in terms of three stress functions rather than just using the three components of the displacement u. However, we will now show that these potentials suggest a useful unification of all the stress functions that we have thus far encountered. In general, given any symmetric matrix field A(x), we can construct a symmetric stress tensor τ (x) with zero divergence using the formula τij =
k,l,m,n
ikl jmn
∂ 2 Akm , ∂xl ∂xn
(2.8.61)
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Linear elastostatics
where ijk is the alternating symbol. Using (2.7.6), we can formally write (2.8.61) in the form τ = curl (curl A)T ,
(2.8.62)
which makes it clear that the tensor τ thus defined is symmetric and identically satisfies div τ ≡ 0. All the stress functions we have used in this chapter can now be viewed simply as particular choices of the matrix A. For example, the Maxwell and Morera functions are obtained by choosing χ1 0 0 0 ψ3 ψ2 A = 0 χ2 0 , or A = − ψ3 0 ψ1 , (2.8.63) 0 0 χ3 ψ2 ψ1 0 respectively. The Airy stress function for plane strain (or plane stress) is obtained by setting χ1 = χ2 = 0, χ3 = A, while the antiplane stress function φ from Section 2.4 corresponds to χ3 = 0, ∂χ1 /∂x − ∂χ2 /∂y = Ωµφ(x, y). The Love function L does not fall into the same category, since its existence relies on the compatibility conditions as well as one component of the equilibrium equation. This is why it is often referred to as a strain function rather than a stress function. Finally, we note the strong analogy between the equations (2.8.59), (2.8.60) satisfied by the Maxwell and Morera stress potentials and the compatibility conditions that we found for the strain components in Section 2.7. The formulation (2.8.62) shows that this resemblance is no accident. By using (2.7.6), we can obtain the compatibility condition for τ , namely T = 0, (2.8.64) curl curl (1 + ν)τ − ντkk I and the equations satisfied by the Maxwell functions χi , for example, can then be found by substituting for τ from (2.8.62). 2.9 Singular solutions in elastostatics 2.9.1 The delta-function In potential theory, it is often helpful to introduce point singularities such as point charges or dipoles in electrostatics or point masses in gravitation. In inviscid fluid dynamics it is also common to discuss singular solutions describing sources and vortices, in the latter of which the singularity is localised on a line rather than a point. As we shall see, such fundamental solutions are very useful building blocks for constructing more general solutions.
2.9 Singular solutions in elastostatics
83
δε (x) 1.2
1
0.8
ε = 0.25
0.6
ε = 0.5
0.4
ε = 1.0
0.2
-4
-3
-2
-1
1
2
3
4
x
Fig. 2.14 A family of functions δε (x) that approach a delta-function as ε → 0.
We begin with an informal discussion of the Dirac delta-function, which will be used henceforth in describing various point and line singularities. In one dimension, we can view the delta-function as the singular limit of a one-parameter family of well-defined positive functions. For example, the family of functions ε (2.9.1) δε (x) = 2 π (x + ε2 ) have the property that
∞ −∞
δε (x) dx ≡ 1
(2.9.2)
for any ε > 0, although δε (x) → 0 as ε → 0 at any fixed non-zero value of x, as illustrated in Figure 2.14. If we “define” δ(x) = limε→0 δε (x), then δ(x) is zero everywhere except at x = 0, but has unit area. (It therefore is not really a function and is called either a generalised function or a distribution.) Although some care is needed to formalise such a definition mathematically, we can use it to deduce the important property that ∞ δ(x − ξ)ψ(ξ) dξ = ψ(x) (2.9.3) −∞
for any suitably smooth test function ψ. We can then define a multidimensional delta-function δ(x) as a product of one-dimensional delta-functions, for example δ(x) = δ(x)δ(y)δ(z),
(2.9.4)
84
Linear elastostatics
in three dimensions. By construction, this function possesses a property analogous to (2.9.3), that is δ(x − ξ)ψ(ξ) dξ = ψ(x). (2.9.5) R3
By way of illustration, a point charge in electrostatics and a point mass in gravitation are both described by Poisson’s equation with a localised righthand side, namely ∇2 φ = −δ(x).
(2.9.6)
Suitable singular solutions of this equation can be constructed using the following key results, derived in Exercise 2.23: |x| one dimension: ∇2 = δ(x), (2.9.7a) 2 2 1 2 2 = δ(x)δ(y), (2.9.7b) log x + y two dimensions: ∇ 2π −1 2 three dimensions: ∇ = δ(x)δ(y)δ(z). (2.9.7c) 4π x2 + y 2 + z 2
2.9.2 Point and line forces Let us first consider plane strain subject to a point force (really a line force in (x, y, z)-space) of magnitude f in the x-direction at the origin. This situation is described by applying a point body force to the two-dimensional Navier equation, that is ∂τxy ∂τxx + = −f δ(x)δ(y), ∂x ∂y
∂τxy ∂τyy + = 0. ∂x ∂y
(2.9.8)
As described in Section 2.8.2, this problem may conveniently be posed in terms of a Love function L satisfying (1 − ν)∇4 L = −f δ(x)δ(y).
(2.9.9)
Now we can read off from (2.9.7b) a suitable radially-symmetric solution for ∇2 L, namely 1 d dL f 2 log r, (2.9.10) ∇ L= r =− r dr dr 2π(1 − ν)
2.9 Singular solutions in elastostatics
85
y
x
Fig. 2.15 Contours of the maximum shear stress S created by a point force acting at the origin. Here ν = 1/4 and f /S = 0.2, 0.4, . . . , 2.0.
up to an arbitrary constant, where r2 = x2 + y 2 . Integrating with respect to r and neglecting another arbitrary constant, we obtain the Love function L=−
f r2 (log r − 1). 8π(1 − ν)
(2.9.11)
The displacement field is then found by substitution into (2.8.19) to give 2 x − y2 − (3 − 4ν) log r f , 2r2 (2.9.12) u= xy 8πµ(1 − ν) r2 and the stress is recovered from (2.8.16) as f −(3 − 2ν)x3 − (1 − 2ν)xy 2 −(3 − 2ν)x2 y − (1 − 2ν)y 3 . τ= 4π (1 − ν) r4 −(3 − 2ν)x2 y − (1 − 2ν)y 3 (1 − 2ν)x3 − (1 + 2ν)xy 2 (2.9.13) We can hence find the maximum shear stress S defined in (2.2.36), by calculating the eigenvalues τi of τ : S=
f |τ1 − τ2 | = 4(1 − ν)2 x2 + (1 − 2ν)2 y 2 . 2 2 2π(1 − ν)r
(2.9.14)
Typical contours of this function are plotted in Figure 2.15 (with ν = 1/4). The shear stress becomes unbounded as the point force at the origin is approached, and we would expect the material to yield plastically on that surface at which S reaches a critical value. The response to a point force in three dimensions may be found in an analogous fashion by using the axisymmetric Love function; see Exercise 2.19. Such problems become very much harder if we attempt to impose any boundary conditions, and analytical solutions are usually impossible to find unless the geometry is very simple. One relatively straightforward example
86
Linear elastostatics
concerns plane strain in the half-space y > 0 with a stress-free boundary at y = 0 and a point force in the x-direction applied at the point (0, h). We recall that, for corresponding half-space problems in potential theory, the method of images provides a simple solution procedure, and it seems sensible to try and apply a suitable generalisation here. If the tensor field defined by (2.9.13) is denoted by τ0 (x, y), then the stress due to the point force at (0, h) is given by τ0 (x, y − h). At first sight, it seems that we can solve the half-space problem by superimposing this and the response to an identical point force at (0, −h). However, when we add these contributions together, we find a stress field in which τxy is zero at y = 0 but τyy is not. We therefore seek a solution of the form 2 ˜ ˜ ∂ A ∂2A − ∂y 2 ∂x∂y (2.9.15) τ = τ0 (x, y − h) + τ0 (x, y + h) + , 2 ˜ ˜ ∂2A ∂ A − ∂x∂y ∂x2 ˜ now satisfies the two-dimensional biharmonic equation in y > 0 where A and the boundary conditions # $ ˜ ˜ f x (1 + 2ν)h2 − (1 − 2ν)x2 ∂2A ∂A = 0, = (2.9.16) ∂y ∂x2 2π(1 − ν) (h2 + x2 )2 on y = 0. This is now precisely the half-space problem we have already analysed in Section 2.6.8, and may be solved by substituting the right-hand side of (2.9.16) into (2.6.80) to give −2hxy f ˜ − (1 − 2ν)x log x2 + (y + h)2 A= 2 2 4π(1 − ν) x + (y + h) −1 y + h . (2.9.17) + 4h(1 − ν) tan x This example shows, once again, how the vectorial nature of the Navier equation complicates well-known techniques like the method of images from ˜ it is potential theory. Since we still had to solve a non-trivial problem for A, debatable whether the problem was significantly simplified by introducing the image. A more direct attack using the Love function leads to (1 − ν)∇4 L = −f δ(x)δ(y − h) in y > 0, with ∂ ∂2L − ν∇2 L = 2 ∂y ∂y
∂2L 2 − ν∇ L = 0 ∂y 2
on y = 0.
(2.9.18a)
(2.9.18b)
2.9 Singular solutions in elastostatics
87
This may be solved by subtracting off the full-space solution (2.9.11), that is, writing L=−
f ˜ R2 (log R − 1) + L, 8π(1 − ν)
R2 = x2 + (y − h)2 ,
(2.9.19)
and then taking a Fourier transform in x. We can also quite quickly find the response to a point force at the boundary of a half-space by using the Papkovich–Neuber representation (2.8.51). Let us consider the axisymmetric version of the half-space problem of Section 2.6.8 in cylindrical polar coordinates (r, z). The half-space is z > 0 and we suppose the tractions on z = 0 consist purely of a normal point force P at the origin, so that τrz = 0 and τzz = −P δ(x)δ(y). Because these conditions are imposed on z = 0, in (2.8.51) we take T Ψ = 0, 0, ψ(r, z) ,
φ = φ(r, z),
(2.9.20)
where φ, ψ are harmonic functions. Hence 2µur = −
∂φ 1 ∂ψ − z , ∂r 2 ∂r
2µuz = 2(1 − ν)ψ −
∂φ 1 ∂(zψ) − . ∂z 2 ∂z
(2.9.21)
From the formulae of Section 1.11.2, the vanishing of the shear stress requires that ∂ur ∂uz + =0 on z = 0, (2.9.22) ∂z ∂r so that 2
∂ψ ∂2φ − (1 − 2ν) = 0. ∂r∂z ∂r
(2.9.23)
Hence, without loss of generality, we can choose 2
∂φ − (1 − 2ν)ψ = 0 ∂z
(2.9.24)
on z = 0 and, since the left-hand side is a harmonic function that also vanishes at infinity, it is identically zero. The normal traction is thus ∂ψ ∂2φ λ ∂ ∂uz (rur ) + (λ + 2µ) = 2(1 − ν) −2 2 r ∂r ∂z ∂z ∂z ∂ψ . = ∂z
τzz =
(2.9.25)
88
Linear elastostatics
Our problem has been reduced to finding a harmonic function ψ whose z-derivative is equal to −P δ(x)δ(y) on z = 0. It can readily be verified that the solution is P , (2.9.26) ψ= √ 2π r2 + z 2 and uz , which is proportional to ψ on z = 0, does not display the nonmonotonicity of Figure 2.13. 2.9.3 The Green’s tensor The solutions we have presented above concern the response of an elastic body to a body force concentrated at a point. To model a distributed body force, for example gravity, we must consider the response of the Navier equations (λ + µ) grad div u + µ∇2 u = −f (x)
(2.9.27)
to an arbitrary forcing function f . The standard mathematical approach to linear differential equations like (2.9.27) is to use a Green’s function. For a scalar equation of the form Lu = −f (x),
(2.9.28)
where L is an autonomous linear differential operator, i.e. one in which x does not appear explicitly, we would define the Green’s function G(x) to be the solution of LG = −δ(x),
(2.9.29)
subject to suitable boundary conditions. We can then use the key property (2.9.5) of the delta-function and formal differentiation under the integral to deduce that u(x) = R3
G(x − ξ)f (ξ) dξ
(2.9.30)
is a solution of the inhomogeneous equation (2.9.28). To adapt the above procedure to the vector equation (2.9.27), one needs to define a Green’s tensor G(x) such that (λ + µ) grad div G + µ∇2 G = −δ(x)I,
(2.9.31)
where I = (δij ) is the identity matrix. Equation (2.9.31) is shorthand for the scalar equations (λ + µ)
∂ 2 Gij ∂ 2 Gki +µ = −δij δ(x), ∂xj ∂xk ∂xk ∂xk
(2.9.32)
2.9 Singular solutions in elastostatics
89
in which the summation convention is invoked, and it is easy to see that G should be symmetric, that is Gij ≡ Gji . Assuming that there are no boundaries and that the stress decays sufficiently rapidly at large distances, it is intuitively reasonable to generalise (2.9.30) to G(x − ξ)f (ξ) dξ. (2.9.33) u(x) = R3
From a practical viewpoint, Gij may be interpreted physically as the displacement in the j-direction at x in response to a unit point force in the i-direction at ξ. In other words, (2.9.33) shows that the response to an arbitrary body force f (x) may be written as a superposition of point force responses like those constructed above in Section 2.9.2. In the case where the elastic medium occupies the whole space, with bounded stress at infinity, we can infer the Green’s tensor directly from the point force solutions found in Section 2.9.2. In plane strain, the displacement caused by a unit point force in the x-direction is given by (2.9.12) with f = 1: 2 x − y2 1 G11 = − (3 − 4ν) log r , (2.9.34a) 8πµ(1 − ν) 2r2 xy 1 , (2.9.34b) G12 = 8πµ(1 − ν) r2 and, by symmetry, we deduce that the Green’s tensor is given by 2 xy x − y2 1 2r2 − (3 − 4ν) log r r2 G(x, y) = . xy y 2 − x2 8πµ(1 − ν) − (3 − 4ν) log r r2 2r2 (2.9.35) The corresponding three-dimensional result is derived in Exercise 2.18. Finding the Green’s tensor explicitly in a body with finite boundaries is usually impossible unless there is sufficient symmetry to allow some trick to be employed. In general, we must now solve (2.9.31) along with boundary conditions for G corresponding to those that are imposed on u (so that (2.9.33) satisfies the required boundary conditions). Since the problem is not translation invariant, we are not at liberty to move the delta-function to the origin, as we did in (2.9.31). Hence we can no longer assume that G is a function only of x − ξ, and we must rewrite (2.9.29) as LG(x, ξ) = −δ(x − ξ).
(2.9.36)
90
Linear elastostatics
We note that the full-space Green’s tensor, which is (2.9.35) in plane strain, can be used to reduce the Navier equation on an arbitrary domain D to an integral equation satisfied on the boundary of D. This reduction in dimension can facilitate an efficient numerical solution, and forms the basis of the boundary element method. To illustrate the basic ideas behind this method, we begin by recalling the identities ∂u ∂v 2 2 −v· u · ∇ v − v · ∇ u dx = u· dS (2.9.37) ∂n ∂n D ∂D and D
{u · (grad div v) − v · (grad div u)} dx {(div v) u · n − (div u) v · n} dS, (2.9.38) = ∂D
for any pair of vector fields u and v. Now, reluctantly reverting to suffix notation, we know that (λ + µ) grad div Gij + µ∇2 Gij = −δ(x − ξ) δij , ∂τjk = 0, (λ + µ) (grad div u)j + µ∇2 uj = ∂xk
(2.9.39) (2.9.40)
where we have neglected the body force for simplicity. Hence, multiplying (2.9.39) by ui , (2.9.40) by Gij , then subtracting and integrating, we find that ui (ξ) = G i (x − ξ) · (τ n (x)) − u(x) · τ i n(x − ξ) dS, (2.9.41) ∂D
where G i = (Gi1 , Gi2 , Gi3 )T and τ i is the stress field associated with the displacement G i . Hence, given the traction and displacement on the boundary ∂D, we have an explicit representation of u everywhere in D. However, we do not expect both u and τ n to be given simultaneously on the boundary, so let us assume for example that the surface traction τ n is prescribed. In this case, (2.9.41) becomes an integral equation for u(ξ) as ξ tends to the boundary of the elastic solid. To solve this integral equation rather than the Navier equation numerically is the basic idea behind the boundary element method. This approach may prove advantageous compared to the more commonly used finite element method, since only the boundary of the solid needs to be discretised, rather than the whole body. On the other hand, it also brings its own share of difficulties. For example, the matrices resulting from the discretisation are usually full, and care must be taken with the singularities that occur in G i as ξ approaches ∂D.
2.9 Singular solutions in elastostatics
91
y
f f
a
f x
f
Fig. 2.16 Four point forces.
2.9.4 Point incompatibility We have shown above how a point force may be described mathematically by incorporating a delta-function into the Navier equation. We then found that the singular solutions so produced are very useful, since they may be superimposed to describe the response to an arbitrary body force. Two further avenues for investigation now suggest themselves. We could use physical motivations other than point forces to suggest useful new singular solutions, or we could ask ourselves whether the introduction of delta-functions elsewhere in the formulation of linear elasticity might have interesting physical interpretations. As an example of the former, suppose we consider the stress field in plane strain when a cavity of small radius a is maintained by a pressure P in an otherwise traction-free material. This is a limiting case of the gun barrel problem solved in Section 2.6.5 and, when we let b → ∞ and a → 0 in (2.6.41), we find that the radial displacement is given by ur =
P a2 . 2µr
(2.9.42)
The same displacement field may also be produced by superimposing four point forces, as indicated in Figure 2.16, and letting the distance between them tend to zero (Exercise 2.26). However, it is more illuminating to consider the incompatibility of the displacement field (2.9.42). Since the vanishing of ∇4 A is the condition for compatibility, we begin by trying to compute this quantity for (2.9.42). It is
92
Exercises
easy to see that A = −a2 P log r and hence, using (2.9.7), that ∇2 A = −2πa2 P δ(x)δ(y).
(2.9.43)
Thus the incompatibility associated with the displacement field (2.9.42) is given by (2.9.44) ∇4 A = −2πa2 P δ (x)δ(y) + δ(x)δ (y) , where, by analogy with (2.9.3), the derivative of a delta-function can be defined by ∞ δ (x − ξ)ψ(ξ) dξ = ψ (x) (2.9.45) −∞
for any suitably smooth test function ψ. Hence (2.9.42) satisfies the compatibility relations everywhere except at the origin, where the localised source of incompatibility is known as a nucleus of strain (Love, 1944, Article 132). Note that no traction need be applied away from the origin to maintain the stress field associated with (2.9.42), and the material is therefore said to be in a state of self-stress. More generally, in Exercise 2.21 it is shown that the compatibility conditions (2.7.5) are the six components of the symmetric tensor equation ηij = ikl jmn
∂ 2 emk ≡ 0, ∂xn ∂xl
(2.9.46)
where ijk is the alternating symbol and we sum over k, l, m and n. We therefore define ηij as the incompatibility tensor. In plane strain, for example, the zz-component of (2.9.46) is ∂ 2 eyy ∂ 2 exy 1−ν 4 ∂ 2 exx + ∇ A = 0, − 2 = 2 2 ∂y ∂x∂y ∂x 2µ
(2.9.47)
which reproduces (2.7.5a) and shows explicitly how ∇4 A is related to compatibility. Thus the right-hand side of (2.9.44) can be thought of as a point singularity in the incompatibility tensor, and this prompts us to wonder what the physical significance might be of introducing other point singularities on the right-hand side of (2.9.46). For example, the physical interpretation of solutions of ∂ 2 eyy ∂ 2 exy ∂ 2 exx + − 2 = δ(x)δ (y) (2.9.48) ∂y 2 ∂x∂y ∂x2 has fundamental implications for the theory of metal plasticity, to which we will return in Chapter 8.
2.10 Concluding remark
93
2.10 Concluding remark All the solutions in this chapter were derived for purely static situations but, in fact, they also apply to unsteady problems that evolve on a sufficiently long time-scale. For example, the analysis of a statically loaded torsion bar carried out in Section 2.4 applies equally well when the applied twist Ω is a slowly varying function of t. In such quasi-static situations, time appears in the solution only as a parameter. This approach fails, however, to describe elastic waves, in which the displacement varies rapidly with time, and the temporal and spatial dependence of the solution are coupled, as we will see in the following chapter.
Exercises 2.1
2.2
2.3
Use strips of stiff paper and sticky tape to construct the model shown in Figure 2.3(a). Now when you pull it in the direction shown, it expands in the transverse direction, as indicated by Figure 2.3(b). It therefore has negative Poisson’s ratio. An elastic membrane is stretched to an isotropic tension T such that its height is given by z = w(x, y). Assuming that the membrane is nearly horizontal (so that |∇w| 1), show that T must be spatially uniform and that w must satisfy Laplace’s equation. A uniform cylindrical bar is held with its axis along the z-axis and its boundary pinned. If the gravitational acceleration g acts in the −z direction, show that the vertical displacement w(x, y) satisfies ∇2 w =
2.4
ρg µ
in the cross-section D of the bar, with w = 0 on ∂D. If D is the ellipse x2 /a2 + y 2 /b2 < 1, show that the solution of (2.4.12), (2.4.13) is x2 y2 a2 b2 1− 2 − 2 . φ= 2 (a + b2 ) a b Hence show that the torsional rigidity of a bar with uniform elliptical cross-section is πµa3 b3 T = 2 . a + b2 Deduce that a circular bar has a higher rigidity than an elliptical bar with the same cross-sectional area.
94
2.5
2.6
Linear elastostatics
Derive the expression (2.5.2) for the torsional rigidity of a tubular bar. By contour deformation show that, if (2.5.3) holds when C is ∂Di , then it holds for all simple closed paths C contained in D. By separating the variables in polar coordinates, show that the problem (2.5.14) for a cut tubular bar has the solution 2 b − a2 log (r/b) b2 − r 2 + φ= 2 2 log (b/a) ∞ # $ # $ + Cn cosh kn (θ − π) sin kn log (b/r) , n=1
where nπ kn = , log (b/a)
# $ 4 b2 − (−1)n a2 log2 (b/a) # $. Cn = − nπ cosh(kn π) n2 π 2 + 4 log2 (b/a)
Use (2.4.15) to determine the torsional rigidity $ πµ b2 − a2 # 2 R= a + b2 log (b/a) − b2 − a2 2 log (b/a) $ $ # ∞ # 16µ log4 (b/a) b2 − (−1)n a2 tanh nπ 2 / log (b/a) − . $ # 2 π 2 + 4 log2 (b/a) 2 π n n=1 Now suppose that the tube is thin, so that b/a = 1 + ε, where ε 1. By expanding the above expression for small ε, show that 1 93ζ(5) 2π 4 3 µa ε 1 − + ε + ··· , R= 3 2 π6
2.7
where ζ is the Riemann zeta function (Abramowitz & Stegun, 1972, Section 23.2). If z = x + iy and z¯ = x − iy are regarded as independent variables, show that ∂2ψ ∇2 ψ = 4 . ∂z∂ z¯ Deduce that the general solution of Laplace’s equation may be written in the form 1 ψ = {f (z) + h(¯ z )}, 2 where f and h are arbitrary analytic functions. If ψ takes only real values, show that h(¯ z ) = f (z) and hence that ψ = Re f (z) .
Exercises
95
Now solve the biharmonic equation by writing ∇2 A = ψ in the form 4
2.8
2.9
∂2A 1 = F (z) + F¯ (¯ z) ∂z∂ z¯ 2
and integrating with respect to z and z¯ to obtain (2.6.12). Show that, for radially symmetric problems in two dimensions, A is generally a constant plus a combination of log r, r2 , and r2 log r. Show how the same conclusion may be reached from the Goursat representation (2.6.12). Now find all separable solutions of the biharmonic equation in polar coordinates of the form A = f (r) cos(mθ), with m = 0, 1, 2, 3, or A = f (r)θ cos θ. In each case, find the restrictions on f (r) for the stress field to vanish at infinity. Suppose that in some basis the stress tensor is diagonal: τ = diag (τk ). Show that the stress in the direction of the unit vector m on a sur& face with unit normal n is i τi mi ni . Hence show that the maximum shear stress S satisfies the constrained optimisation problem max S =
3
τi mi ni ,
i=1
subject to
3 i=1
m2i = 1,
3
n2i = 1,
i=1
3
mi ni = 0.
i=1
Assuming that the principal stresses τi are distinct, use the method of Lagrange multipliers to show that the extreme values occur when m3 = n3 = 0, or m1 = n1 = 0, or m2 = n3 = 0, 2.10
1 m21 = m22 = n21 = n22 = , 2 1 m22 = m23 = n22 = n23 = , 2 1 m23 = m21 = n23 = n21 = , 2
τ1 − τ2 , 2 τ2 − τ3 S=± , 2 τ3 − τ1 S=± . 2 S=±
Prove the identity u∇4 v − v∇4 u ≡ div u∇ ∇2 v − v∇ ∇2 u + ∇2 u∇v − ∇2 v∇u . If the functions Ai (x) and constants λi (i = 1, 2, . . .) satisfy ∇4 Ai = λi Ai
96
Linear elastostatics
in some bounded region V , show that ∂Aj ∂Ai ∇2 Aj − ∇2 Ai Ai Aj dx = (λi − λj ) ∂n ∂n V ∂V ∂ 2 ∂ 2 dS. + Aj ∇ Ai − Ai ∇ Aj ∂n ∂n Deduce that the biharmonic operator has real eigenvalues and orthogonal eigenfunctions when the boundary conditions are ∂A = 0, or (ii) A = ∇2 A = 0, ∂n ∂ 2 ∂A ∂ 2 = or (iii) ∇ A , or (iv) ∇2 A = ∇ A = 0. ∂n ∂n ∂n (a) Assuming y > 0, show that the inverse Fourier transforms of e−|k|y and i sign(k)e−y|k| are given by ∞ 1 y f1 (x, y) = , e−ikx e−|k|y dk = 2 2π −∞ π (x + y 2 ) (i)
2.11
A=
and i f2 (x, y) = 2π
∞
e−ikx sign(k)e−|k|y dk =
−∞
x , + y2 )
π (x2
respectively. (b) Hence show that (2.6.79) may be written as ∂ ! f!1 (k, y), τ!xx = −P (k) 1 + y ∂y ∂f1 (k, y), τ!xy = P!(k)y ∂x ∂ f!1 (k, y). τ!yy = −P!(k) 1 − y ∂y Using the fact that the inverse Fourier transform of a product f!(k)! g (k) is the convolution of f and g, that is ∞ f (x − s)g(s) ds, (f ∗ g)(x) = −∞
deduce (2.6.80). (c) Show from (2.6.82) that ∂f ∂v 1 = P!(k) y (k) − 2(1 − ν)f!2 (k) , 2µ ∂x ∂x and hence deduce (2.6.83).
Exercises
2.12
97
By making a suitable substitution, write the second term in the integral (2.6.83) as 2 − ν ∞ P (x − yt)t dt (2 − ν)y 2 ∞ P (x − s)s ds . − 2 =− π π (1 + t2 )2 −∞ (s2 + y 2 ) −∞ Deduce that, provided P (x) is bounded, this term tends to zero as y → 0. Show further that the first term in (2.6.83) may be written as −ε ε ∞ P (s)(x − s)3 ds 1−ν + + . − π ((x − s)2 + y 2 )2 −∞ −ε ε Show that the middle integral is approximately equal to (1 − ν)P (x) ε/y t3 dt − 2, π −ε/y (1 + t2 ) and explain why this integral tends to zero as y tends to zero with y ε 1. Finally deduce that, as y → 0, (2.6.83) tends to (2.6.85), where the Hilbert transform is defined by −ε ∞ 1 P (s) ds 1 ∞ P (s) ds = lim . + H[P ](x) = − π −∞ s − x π ε↓0 s−x −∞ ε
2.13
Show that, if ∇2 φ = 0 in the half-space y > 0 with φ(x, 0) = f (x), ∂φ/∂y(x, 0) = g(x) and φ → 0 at infinity, then ∞ ' ( 1 g(s) log (s − x)2 + y 2 ds. φ= 2π −∞ Deduce that f (x) = ∂φ/∂x(x, 0) = −H[g]. Show further that ∂ 2 φ/∂y 2 (x, 0) = −f (x), so that ∞ ' ( 1 ∂φ =− f (s) log (s − x)2 + y 2 ds. ∂y 2π −∞
2.14
Hence deduce that g(x) = H[f ]. Reconsider the torsion problem of Section 2.4 and the stress function φ defined by (2.4.10). Using two of the compatibility relations (2.7.5), deduce successively that ∇2 φ = f (y), that ∇2 φ = g(x), and hence that ∇2 φ = const.. [This illustrates that two compatibility conditions that are not independent may nevertheless both be necessary to determine the stress.]
98
2.15
Linear elastostatics
(a) Derive the expression (2.6.97) for the modified Airy stress function outside a circular underground tunnel. (b) Prove the identity ∂eθθ ∂erθ ∂ 2 ur + rerr + 2r + ur = −r2 2 ∂θ ∂r ∂θ
(E2.1)
relating the strain components to the radial displacement ur in plane polar coordinates (r, θ). Deduce that the coefficients of sin θ and cos θ on the right-hand side must be zero if ur is to be a 2π-periodic function of θ. (c) With the stress components given by (2.6.92), show that the right-hand side of (E2.1) is −ρgh
2.16
a2 8(1 − ν)A + (1 − 2ν)r + cos θ r 1 + 2 log a 8(1 − ν)B 2 − ρg(1 − 2ν)a sin θ, + 1 + 2 log a
and hence obtain the expressions (2.6.98). Return to the tunnel example of Section 2.6.9, this time assuming a far-field stress distribution given by τxx = τxy = 0, τyy = ρg(y − H). [This might correspond to a cylindrical hole in a vertical column.] In this case, show that (2.6.92) becomes ˜ ˜ 1 ∂2A 1 ∂A , + 2 2 r ∂θ r∂r ˜ sin 2θ ∂ 1 ∂A = ρg (r sin θ − H) − , 2 ∂r r ∂θ
τrr = ρg sin2 θ (r sin θ − H) + τrθ
τθθ = ρg cos2 θ (r sin θ − H) +
˜ ∂2A , ∂r2
and that the boundary conditions on r = a are H a ρga2 ˜ H + aθ cos θ + cos 2θ − sin 3θ A(a, θ) = 2 2 12 + A cos θ + B sin θ, ˜ ∂A ρga a (a, θ) = H + aθ cos θ + H cos 2θ − sin 3θ ∂r 2 4 A B + cos θ + sin θ, a a
Exercises
99
where A and B are arbitrary constants. Use (E2.1) and the fact that ur is single-valued to show that A = 0,
B = −νρga3 /4,
so that r a2 H 1 + log + rθ cos θ + H 1 − 2 cos 2θ a 2r 4 2 1 a2 r a a + − r(1 − 2ν) log − sin θ + sin 3θ , 2 a r 6r3 4r
2 ˜ = ρga A 2
and deduce that the hoop stress is given by 1 − 2ν sin θ + sin 3θ τθθ = −ρgH (1 + 2 cos 2θ) + ρga 2
2.17
on r = a. Note the contrast with the stress distribution (2.6.100) caused by a hydrostatic far-field stress. By comparing (2.6.9) and (2.8.22), show that z-averaged plane stress is mathematically equivalent to plane strain with new elastic constants ν and E given by ν =
2.18
ν , 1+ν
E =
1 + 2ν E. (1 + ν)2
We define the three-dimensional Fourier transform of a function f (x, y, z) by ∞ ∞ ∞ ! f= f (x, y, z)ei(kx+y+mz) dxdydz −∞ −∞ −∞ f (x)ei(k·x) dx, = R3
where k = (k, , m). Show that the Fourier transform of the Green’s tensor in three dimensions is given by G! = G!ij =
1 λ + µ kkT I − , µ|k|2 µ (λ + 2µ) |k|4
and, by inverting the transform, deduce that xi xj λ+µ 1 λ + 3µ . δij + Gij = 8πµ (λ + 2µ) |x| λ + µ |x|2
(E2.2)
100
2.19
Linear elastostatics
Show that the axisymmetric Love stress function corresponding to a unit vertical point force at the origin is given by L=
|x| . 8π (1 − ν)
Hence, show that the corresponding displacement is xz yz 1 z2 , (G31 , G32 , G33 ) = , , 3 − 4ν + 16πµ |x| (1 − ν) |x|2 |x|2 |x|2 2.20
and deduce (E2.2) by symmetry. Show that the two-dimensional Papkovich–Neuber potentials φ = φ(x, y), Ψ = (ψ1 (x, y), ψ2 (x, y), 0)T generate the stress field ∂ψ2 ∂ 2 φ x ∂ 2 ψ1 ∂ψ1 y ∂ 2 ψ2 +ν − − − , ∂x ∂y ∂x2 2 ∂x2 2 ∂x2 ∂ψ1 ∂ 2 φ x ∂ 2 ψ1 ∂ψ2 y ∂ 2 ψ2 +ν − 2 − = (1 − ν) − , ∂y ∂x ∂y 2 ∂y 2 2 ∂y 2 ∂ψ2 ∂2φ x ∂ 2 ψ1 y ∂ 2 ψ2 ∂ψ1 1 −ν + − − − . = 2 ∂y ∂x ∂x∂y 2 ∂x∂y 2 ∂x∂y
τxx = (1 − ν) τyy τxy 2.21
Prove the identity mjk
∂ 2 ui ≡0 ∂xk ∂xj
for all i and m, where mjk is the usual alternating symbol, and show that this is equivalent to ∇×(∇ui ) ≡ 0. Deduce that mjk nil
2.22
∂ 2 eij ≡0 ∂xl ∂xk
for all m and n, where eij is the linearised strain tensor. Hence obtain the compatibility conditions (2.7.5) and show that they are equivalent to (2.7.6). Show that the compatibility conditions (2.7.5) can be written in terms of the stress components as 2 ∂ 2 τyy ∂ 2 τxy ∂ ν ∂2 ∂ 2 τxx + −2 = + 2 Tr (τ ), ∂y 2 ∂x∂y ∂x2 1 + ν ∂x2 ∂y 2 ∂τxy ∂τyz ∂ τxx ∂ ∂τxz ν ∂2 = + − + Tr (τ ), ∂y∂z ∂x ∂y ∂z ∂x 1 + ν ∂y∂z the other relations being obtained by permuting x, y and z.
Exercises
2.23
Verify (2.9.7a) by writing |x| = limε→0 x2 + ε2 and noting that ε2 d2 2 2 = x + ε , dx2 (x2 + ε2 )3/2 and
∞
ε2 dx
∞
+
ε2 )3/2
=
ds
= 2. (1 + s2 )3/2 Repeat this procedure with log x2 + y 2 + ε2 to derive (2.9.7b) and find a similar derivation of (2.9.7c). Show that 2 $ ∂ 2 # 2 ∂ x + y 2 log x2 + y 2 = 8 + 4 log x2 + y 2 + 2 2 ∂x ∂y and deduce that, if A = (1/8π) x2 + y 2 log x2 + y 2 , then A satisfies −∞ (x2
2.24
101
√
−∞
∇4 A = δ(x)δ(y). 2.25
The stress components due to a point force f in the x-direction satisfy ∂τxy ∂τxx + = −f δ(x)δ(y), ∂x ∂y
∂τxy ∂τyy + =0 ∂x ∂y
plus the compatibility condition ∂ 2 τyy ∂ 2 τxy ∂ 2 τxx + −2 − ν∇2 (τxx + τyy ) = 0. 2 ∂y ∂x∂y ∂x2 Take a two-dimensional Fourier transform (defined as in Exercise 2.18) to show that k! τxx + ! τxy = −if,
k! τxy + ! τyy = 0, 2 2 τxy − k τ!yy + ν k + (! − τ!xx + 2k! τxx + τ!yy ) = 0. 2
2
Hence obtain τ!xx
ikf = 1−ν
τ!xy =
if 1−ν
τ!yy =
−ikf 1−ν
ν k 2 + 22 , − k 2 + 2 (k 2 + 2 )2 ν 2 , − k 2 + 2 (k 2 + 2 )2 2 ν , − k 2 + 2 (k 2 + 2 )2
the inverse Fourier transform of which is (2.9.13).
102
2.26
Linear elastostatics
Write down the displacement field for the four point forces depicted in Figure 2.16. Let a → 0 and show that the displacement tends to u=
1 − 2ν af er , 1 − ν 2πµ r
which agrees with (2.9.42) if f = πa(1 − ν)/(1 − 2ν).
3 Linear elastodynamics
3.1 Introduction This chapter concerns simple unsteady problems in linear elasticity. As noted in Section 1.10, the unsteady Navier equation (1.7.8) bears some similarity to the familiar scalar wave equation governing small transverse displacements of an elastic string or membrane. We therefore start by reviewing the main properties of this equation and some useful solution techniques. This allows us to introduce, in a simple context, important concepts such as normal modes, plane waves and characteristics that underpin most problems in linear elastodynamics. In contrast with the classical scalar wave equation, the Navier equation is a vector wave equation, and this introduces many interesting new properties. The first that we will encounter is that the Navier equation in an infinite medium supports two distinct kinds of plane waves which propagate at two different speeds. These are known as P -waves and S -waves, and correspond to compressional and shearing oscillations of the medium respectively. Considered individually, both P - and S -waves behave very much like waves as modelled by the scalar wave equation (1.10.9). In practice, though, they very rarely exist in isolation since any boundaries present inevitably convert P -waves into S -waves and vice versa. We will illustrate this phenomenon of mode conversion in Section 3.2.5 by considering the reflection of waves at a plane boundary. In two-dimensional and axisymmetric problems, we found in Chapter 2 that the steady Navier equation may be transformed into a single biharmonic equation by introducing a suitable stress function. In Sections 3.3 and 3.4 we will find that the same approach often works even for unsteady problems, and pays dividends when we come to analyse normal modes in cylinders and spheres. 103
104
Linear elastodynamics
In Section 3.5, we consider some initial-value problems for elastic wave propagation using the ideas of characteristics and fundamental solutions. Finally, we will discuss the interesting phenomena that can occur when elastic waves are generated by moving sources. Before we begin, let us briefly recall some familiar wave propagation models for elastic strings and membranes. The simplest such model describes small oscillations of an elastic string of line density under a tension T . It is well known that the transverse displacement w (x, t) satisfies the partial differential equation ∂2w ∂2w (3.1.1) 2 =T 2, ∂t ∂x known as the one-dimensional wave equation. The derivation and validity of this equation will be discussed in Chapter 4, where we will show that it also describes longitudinal waves in an elastic bar. If we instead consider an elastic membrane with surface density ς stretched across the (x, y)-plane under a uniform tension T , then the appropriate generalisation of (3.1.1) is ς
∂2w = T ∇2 w, ∂t2
(3.1.2)
where ∇2 = ∂ 2 /∂x2 + ∂ 2 /∂y 2 is the two-dimensional Laplacian. The threedimensional version of (3.1.2) governs many familiar wave propagation problems including acoustic waves and light waves. There are two ways in which we can approach (3.1.1) and (3.1.2) mathematically. One possibility is to try to construct a general solution that will apply whatever mechanism is driving the waves. However, this strategy is only useful in practice when the general solution can be found explicitly and also takes a sufficiently simple form for realistic boundary conditions to be imposed. Alternatively, we can attempt to describe the solution as a linear combination of elementary solutions, as in the method of normal modes in classical mechanics. This second approach can always be applied in principle and ties in with the first when we view the general solution as a superposition of elementary solutions. We therefore begin the next section by discussing some elementary solutions of (3.1.1) and (3.1.2). 3.2 Normal modes and plane waves 3.2.1 Normal modes A normal mode of a dynamical system is a motion in which the whole system oscillates at a single frequency ω. We can seek normal modes of an elastic
3.2 Normal modes and plane waves
105
string by trying solutions of (3.1.1) in the form w(x, t) = f1 (x) cos(ωt) + f2 (x) sin(ωt),
(3.2.1a)
which is often written in the compact form # $ w(x, t) = Re f (x)e−iωt ,
(3.2.1b)
where f (x) = f1 (x) + if2 (x). Solutions of the form (3.2.1) are called waves in the frequency domain. Substitution of (3.2.1) into (3.1.1) reveals that f (x) must satisfy the ordinary differential equation ω 2 d2 f f = 0, + dx2 T
(3.2.2)
whose general solution is
)
f (x) = A cos(kx) + B sin(kx),
where
k=ω
. T
(3.2.3)
Thus (3.2.1b), with f (x) given by (3.2.3), is a solution of the wave equation for any value of the frequency ω. Particular values of ω may be selected by applying suitable boundary conditions. As a simple example, consider a string fixed at its two ends x = 0 and x = a, so we require w to satisfy w(0, t) = w(a, t) = 0. Clearly f must likewise satisfy f (0) = f (a) = 0,
(3.2.4)
and by applying these to (3.2.3) we discover that nonzero solutions for f exist only if ω takes specific values, namely * nπ T , (3.2.5) ωn = a where n is any integer. These are known as the natural frequencies of the system; they represent the frequencies at which the string will oscillate in the absence of any external forcing. The corresponding displacements nπx (3.2.6) e−iωn t wn (x, t) = Re Bn sin a are called the normal modes, and we can see that there is a countably infinite number of them. For waves on a string these modes are manifested as the harmonics that are familiar to anyone who plays a stringed musical instrument; many people will also recognise the properties predicted by
106
Linear elastodynamics
(3.2.5), namely that the frequency increases as the tension increases and as the density decreases. Now suppose we are additionally given the initial displacement and velocity of the string, say w(x, 0) = w0 (x),
∂w (x, 0) = v(x). ∂t
(3.2.7)
These may be satisfied by trying a linear combination of normal modes, that is ∞ nπx {An cos(ωn t) + Bn sin(ωn t)} , sin (3.2.8a) w(x, t) = a n=1
where the coefficients are found by Fourier analysis of the initial data: a nπx nπx 2 a 2 dx, Bn = dx. w0 (x) sin v(x) sin An = a 0 a ωn a 0 a (3.2.8b) This analysis, although very straightforward, illustrates the following important points that will be useful in analysing more complex models later in this chapter. (i) We will always be able to look for time-harmonic solutions of the form (3.2.1b) whenever the problem we are solving is both linear and autonomous in t: in other words, when there is no explicit dependence on t. (ii) When looking for normal modes, we might as well have ignored the “Re” in (3.2.1b), performed all the calculations, and then taken the real part right at the end. This approach works because all the usual linear operations, such as differentiation with respect to x or t or multiplication by a real constant, commute with taking the real part. Henceforth, in this chapter, we will therefore for simplicity follow the convention of assuming the real part. We note, though, that this would be a very dangerous procedure were we to be considering a nonlinear model! (iii) Although normal modes may at first glance appear to be rather special solutions of the wave equation (3.1.2), it can be shown that the general solution, subject to simple homogeneous boundary conditions, may be written uniquely as a superposition of normal modes. (iv) When a → ∞, it may be shown that (3.2.8) generalises to the half-range Fourier transform representation ∞ sin (kx) {A(k) cos(kct) + B(k) sin(kct)} dk, (3.2.9a) w(x, t) = 0
3.2 Normal modes and plane waves
where c2 = T / and 2 ∞ w0 (x) sin(kx) dx, A(k) = π 0
B(k) =
2 πkc
107
∞
v(x) sin(kx) dx. 0
(3.2.9b) We can extend these ideas to the two-dimensional wave equation (3.1.2) by seeking solutions of the form w(x, y, t) = A(x, y)e−iωt ,
(3.2.10)
and we find that A must satisfy the Helmholtz equation
∇2 A + k 2 A = 0,
(3.2.11)
where k = ω ς/T . For example, to find the normal modes and frequencies of a drum whose skin occupies a region D in the (x, y)-plane, we must solve (3.2.11) in D subject to A = 0 on the boundary ∂D. This is another eigenvalue problem: A ≡ 0 is always a possible solution and special values of k must be sought such that A may be nonzero. For many simple shapes, these can be found by separating the variables. For example, we can see at a glance that the normal modes and natural frequencies of the rectangular membrane {0 < x < a, 0 < y < b} are mπx nπy (3.2.12a) sin e−iωm , n t , wm,n (x, y, t) = sin a b π 2 T m2 n2 2 ωm,n = + , (3.2.12b) ς a2 b2 where m and n are arbitrary integers. Thus there is a doubly infinite set of normal modes in this case. In general, there is one infinite set of frequencies for each spatial dimension in the problem. Next we consider radially-symmetric vibrations of a circular drum, so that A is a function of the plane polar distance r and (3.2.11) reads d2 A 1 dA + k 2 A = 0, + dr2 r dr
(3.2.13a)
to be solved subject to A(a) = 0. If we set ξ = kr, then the problem for A becomes d2 A 1 dA +A=0 + dξ 2 ξ dξ
with A(ka) = 0.
(3.2.13b)
This is Bessel’s equation of order zero, and it is easy to see that A(ξ) oscillates for large ξ, because the first and last terms in (3.2.13) will be approximately in balance. Moreover, for small ξ, we can spot that the first and
108
Linear elastodynamics
Jn (ξ) 1
0.6
n=0 1
0.4
2
0.8
0.2
5
10
15
20
25
30 ξ
15
20
25
30 ξ
-0.2
-0.4
Yn (ξ)
n=0 1 2
0.4
0.2
5
10
-0.2
-0.4
-0.6
-0.8
Fig. 3.1 Plots of the first three Bessel functions Jn (ξ) and Yn (ξ) for n = 0 (solid), n = 1 (dashed), n = 2 (dot-dashed).
second terms in (3.2.13) both balance and dominate the third term when A = log ξ. This suggests that the solution is either well-behaved or logarithmically singular as ξ → 0, and this conclusion may easily be confirmed using Frobenius’ method. The bounded solution with A(0) = 1 is denoted by J0 (ξ) while the singular solution with A ∼ (2/π) log ξ is called Y0 (ξ), and these important functions are plotted in Figure 3.1. Here, we require the amplitude A to be bounded at the centre of the drum r = 0 and must therefore choose A = const. J0 (ξ). The condition at r = a is then satisfied if ka = ξ0,i
(i = 1, 2, . . .),
(3.2.14a)
where ξ0,1 < ξ0,2 < · · · are the zeros of J0 (ξ). As indicated in Figure 3.1, there are an infinite number of these zeros and ξ0,n → ∞ as n → ∞. The natural frequencies of the drum for radially-symmetric modes are thus given
3.2 Normal modes and plane waves
by ξ0,i ωi = a
)
T ς
(n = 1, 2, . . .).
109
(3.2.14b)
Unlike the modes on a string, the natural frequencies here are irrational multiples of each other. In musical terms, the harmonics are out of tune with each other, and this gives rise to the characteristic sound of a drum, which is quite different from that of a piano or a violin, for example. If we drop the assumption of radial symmetry, then the Helmholtz equation becomes 1 ∂2A ∂ 2 A 1 ∂A + + + k 2 A = 0, (3.2.15) ∂r2 r ∂r r2 ∂θ2 in plane polar coordinates (r, θ). Again we impose A = 0 on r = a, and now we insist also that A must be a 2π-periodic function of θ. This restricts us to seeking separable solutions of the form (3.2.16) A(r, θ) = f (r) C1 cos(nθ) + C2 sin(nθ) , where n is an integer, and it follows that f satisfies r2
df 2 2 d2 f +r + k r − n2 f = 0 2 dr dr
with f (a) = 0.
(3.2.17a)
Setting ξ = kr as before, we find that (3.2.17a) becomes ξ2
df 2 d2 f + ξ − n2 f = 0 +ξ 2 dξ dξ
with f (ka) = 0.
(3.2.17b)
This is Bessel’s equation of order n, whose two linearly dependent solutions are denoted Jn (ξ) and Yn (ξ); the cases n = 0, 1, 2 are plotted in Figure 3.1. For any integer n, Yn (ξ) is singular as ξ → 0, so we must choose f = const. Jn (ξ). The condition at r = a is then satisfied if ka = ξn,i
(i = 1, 2, . . .),
(3.2.18)
where ξn,1 < ξn,2 < · · · are the zeros of Jn (ξ). There are an infinite number of these zeros and ξn,i → ∞ as i → ∞. The natural frequencies of the drum are thus given by 2 ωn,i =
2 T ξn,i , a2 ς
(3.2.19)
where n and i are arbitrary integers, so there is a doubly-infinite family of normal modes that depend on the two spatial coordinates (r, θ).
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Linear elastodynamics
3.2.2 Plane waves As suggested by (3.2.9), when looking for solutions of (3.1.1) on an infinite domain, it is appropriate to seek travelling waves of the form w(x, t) = A exp i(kx − ωt) , (3.2.20) rather than seeking a discrete set of normal modes. The real constants |A|, k and ω represent the amplitude, wave-number and frequency, respectively, of the wave (3.2.20). The wave-number is related to the wave-length λ by k = 2π/λ, so large values of k correspond to short waves and vice versa. We can alternatively write (3.2.20) in the form ω (3.2.21) w(x, t) = A exp ik(x − ct) , where c = ; k the quantity c is known as the phase velocity. From (3.2.21) we can easily see that c represents the speed at which wave crests propagate. We can also see that the minus sign included by convention in (3.2.20) ensures that the wave propagates in the positive x-direction when ω and k are both positive. We can generalise this approach to the two-dimensional wave equation (3.1.2) by looking for a plane wave solution of the form w(x, y, t) = A exp i(k1 x + k2 y − ωt) = A exp i k · x − ωt , (3.2.22) where we define the wave-vector k = (k1 , k2 )T . By writing (3.2.22) in the form k·x w = A exp i |k|X − ωt , where X = , (3.2.23) |k| we observe that it represents a harmonic wave travelling in the direction of k at speed ω/|k|. The phase velocity, at which the wave crests propagate, is thus given by ωk . (3.2.24) c= |k|2 When we substitute (3.2.20) into (3.1.1), we find that the amplitude can be nonzero only if ω 2 = k 2 T / .
(3.2.25a)
This dispersion relation tells us how the frequency of any given wave depends on its wave-length. We can also view (3.2.25a) as an equation for the phase velocity, namely (3.2.25b) c = ± T / ,
3.2 Normal modes and plane waves
111
which tells us that all waves move at the same speed, irrespective of their wave-length. Waves with this property are called non-dispersive, to distinguish them from dispersive waves in which c varies with k. Similarly, substitution of (3.2.22) into the two-dimensional wave equation (3.1.2) leads to the dispersion relation ω 2 = |k|2 T /ς. The phase speed |c| = c =
T /ς
(3.2.26)
(3.2.27)
is still independent of the wave-vector k, so these two-dimensional waves are also non-dispersive. As in (3.2.9), the general solution of the wave equation on an infinite domain may be written as a linear superposition of harmonic waves, travelling in both directions, in the form of a Fourier integral. In other words, we can write ∞ ∞ A(k1 , k2 ) exp i (k1 x + k2 y − ω(k1 , k2 )t) w(x, y, t) = −∞ −∞ + B(k1 , k2 ) exp i (k1 x + k2 y + ω(k1 , k2 )t) dk1 dk2 , (3.2.28a) or
w(x, t) = R2
A(k) exp i (k · x − ω(k)t) + B(k) exp i (k · x + ω(k)t) dk, (3.2.28b)
where ω(k) is given by the dispersion relation (3.2.26) and the amplitude functions A(k) and B(k) can be found from the Fourier transform of the initial conditions. By writing the displacement in the form (3.2.28b), we indicate that this and all the other results in this section apply also to the wave equation in three space dimensions.
3.2.3 Scattering Scattering refers generally to the problem of irradiating a target with a known incoming wave-field and trying to determine the resultant scattered field that is the result of the presence of the target. This idea is important, for example, in tomography, seismology and ultrasonic testing, where we try to infer, non-invasively, the properties of some inhomogeneities in a bulk elastic medium by measuring the scattered wave-fields that they produce.
112
Linear elastodynamics
The basic idea is illustrated by the problem of an elastic string, modelled by (3.1.1), stretched along the x-axis with a point mass m attached at the origin. The equation of motion for the mass leads to the boundary conditions w(0−, t) = w(0+, t),
∂w ∂w m ∂2w (0+, t) − (0−, t) = ∂x ∂x T ∂t2
(3.2.29)
at x = 0, where T is the tension in the string. Now suppose we send in a known incident wave of the form w = ei(kx−ωt) from x = −∞, where we assume that ω > 0 and k > 0 so that the wave is travelling in the positive x-direction. We can work in the frequency domain to write the resulting displacement field in the form w(x, t) = A(x)e−iωt , where eikx + cR e−ikx x < 0, A(x) = (3.2.30) x > 0. cT eikx Thus, apart from the prescribed incoming wave, the scattered wave-field is outgoing from the target, with reflection and transmission coefficients cR and cT that can be determined from the boundary conditions (3.2.29), as shown in Exercise 3.1. As a very simple example of a tomography problem we could, for instance, work out the size of the mass by measuring the amplitude |cR | of the reflected waves. The extension to higher-dimensional problems present us with a serious mathematical challenge. Indeed, even the solution of Helmholtz’ equation (3.2.11) to model plane wave incidence at a scatterer on which A = 0, say, is beyond the scope of this book. The two principal difficulties are the following. (i) Assuming an incident wave eikx , as in (3.2.30), we have to solve the Helmholtz equation for the scattered wave A˜ = A − eikx , subject to A˜ = eikx on the scatterer. This means that there is no simple solution by separation of variables, even when the scatterer is a circle. (ii) In the far field, it is not good enough simply to say that A˜ → 0 as we did in many of the elastostatic problems of Chapter 2. We now need to capture the physical requirement that A˜ be outgoing from the scatterer, again as in (3.2.30). It can be shown (see Exercise 3.3 and Bleistein, 1984, Section 6.4) that, as the radial coordinate r tends to infinity, all possible solutions of (3.2.11) take the form A˜ → A˜± (θ)r−1/2 e±ikr and, since A˜ must be multiplied by e−iωt to find the scattered wave, only the positive sign is appropriate to describe outward-travelling waves. This is equivalent to saying that A˜ satisfies the Sommerfeld radiation condition ∂ A˜ 1/2 ˜ − ik A → 0 as r → ∞. (3.2.31) r ∂r
3.2 Normal modes and plane waves
113
Then the canonical tomography problem for (3.2.11) is to reconstruct the shape of the scatterer given the directivity function A˜+ (θ). We note that, in the absence of any incident field, a circular boundary can radiate waves in which, from (3.2.16), A depends only on r and is a linear combination of J0 (kr) and Y0 (kr). Using the fact that ) 2 ±i(kr−(π/4)) e as r → ∞, (3.2.32) J0 (kr) ± i Y0 (kr) → πkr we see that, to describe outward-propagating waves, A must tend to a mul(1) tiple of the Hankel function H0 (kr) = J0 (kr) + i Y0 (kr) as r → ∞. 3.2.4 P-waves and S-waves Now we examine how the ideas developed above for scalar wave equations may be applied to the unsteady Navier equation (1.7.8). We begin by seeking travelling-wave solutions in the form u = a exp i (k · x − ωt) , (3.2.33) where the complex amplitude a, the wave-vector k and frequency ω are all constant. It is very helpful to use a little hindsight, or Exercise 3.4, to notice that, for any vector a and nonzero k, there is a unique vector B and a scalar A satisfying a = Ak + B×k,
k · B = 0.
(3.2.34)
Using this decomposition, we find that
∇2 u = − |k|2 (Ak + B×k) exp i (k · x − ωt) , grad div u = −A |k|2 k exp i (k · x − ωt) , ∂2u 2 = −ω (Ak + B×k) exp i (k · x − ωt) . ∂t2 Hence the Navier equation (1.7.8) reduces to 2 ρω − µ|k|2 (B×k) + ρω 2 − (λ + 2µ)|k|2 Ak = 0,
(3.2.35a) (3.2.35b) (3.2.35c)
(3.2.36)
which we can only satisfy for nonzero k if either B=0
and
ρω 2 = (λ + 2µ) |k|2
(3.2.37a)
A=0
and
ρω 2 = µ |k|2 .
(3.2.37b)
or
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Linear elastodynamics
The vectorial nature of the Navier equation has thus led to the existence of two dispersion relations, corresponding to two distinct types of waves. (i) P-waves, also known as Primary or Pressure waves, take the form u = Ak exp i (k · x − ωt) , (3.2.38a) where ω 2 = (λ+2µ)|k|2 /ρ. We recall from Section 1.9 that µ and λ+2µ/3 are both positive, so ω is real. The phase speed is thus given by * λ + 2µ (3.2.38b) cp = ρ and, since cp is independent of k, the waves are non-dispersive. The phase velocity cp k (3.2.38c) c= |k| is parallel to the displacement u, so P -waves are said to be longitudinal. They are also sometimes described as irrotational since they satisfy curl u = 0, as is readily verified by direct differentiation of (3.2.38a). (ii) S -waves, also known as Secondary or Shear waves, take the form u = (B×k) exp i (k · x − ωt) , (3.2.39a) where ω 2 = µ|k|2 /ρ. S -waves are also non-dispersive, with constant phase speed ) µ . (3.2.39b) cs = ρ This time, though, the phase velocity is perpendicular to the displacement, so S -waves are said to be transverse. Since (3.2.39a) satisfies div u = 0, we deduce that S -waves conserve volume, and they may thus be referred to as equivoluminal. Evidently cp > cs , so that P -waves always propagate faster than S -waves. This fact is familiar to seismologists: following an earthquake, two distinct initial signals can usually be observed, corresponding to the arrival of the P -waves followed by the S -waves, with propagation speeds in rock given approximately by cp ≈ 5 km s−1 and cs ≈ 3 km s−1 respectively. P - and S -waves are prototypical examples of polarised waves, which are defined to be solutions to general wave equations in which u = u0 f (k · x − ωt) .
(3.2.40)
3.2 Normal modes and plane waves
115
When u0 is not parallel to k, this is called a plane polarised wave, with u0 and k defining the plane of polarisation. As in the expression (3.2.28) for the general solution of the scalar wave equation, the general solution of the Navier equation may also be expressed as a linear superposition of harmonic waves. In this case, the displacement field reads u(x, t) = kA1 (k) exp i (k · x − |k|cp t) R3 + kA2 (k) exp i (k · x + |k|cp t) + k×B 1 (k) exp i (k · x − |k|cs t) (3.2.41) + k×B 2 (k) exp i (k · x + |k|cs t) dk, which represents an arbitrary combination of P - and S -waves travelling in all possible directions. Again the amplitude functions Ai (k) and B i (k) can in principle be determined from the Fourier transform of the initial data, although carrying this out in practice when boundary conditions are imposed is far from easy.
3.2.5 Mode conversion in plane strain The explicit solution (3.2.41) suggests that the response of an elastic medium to arbitrary initial conditions will nearly always involve coupled P - and S waves. This coupling lies at the heart of elastic wave propagation in more than one space dimension. An indication of the unexpected phenomena that can result comes when we reconsider the familiar rules of reflection and refraction of plane waves of the form (3.2.33) at a planar interface. Here we will initially consider the plane strain problem of reflection of a P -wave that is incident from x < 0 on a rigid barrier at x = 0, so that u = 0 there. We recall that P -waves are longitudinal and so, by choosing the coordinate axes appropriately, we may write the incident wave in the form of a plane strain displacement, # $ cos α exp i kp (x cos α + y sin α) − ωt , (3.2.42) u = ui n c = sin α where kp = ω/cp and α is the angle between the incoming wave and the x-axis. Our task now is to find a reflected wave field ur e f such that the net displacement u = ui n c +ur e f is zero on the boundary x = 0. We soon realise that
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Linear elastodynamics y P S
α β α
P
0110 Rigid 1010 boundary 1010 x 1010 1010 1010
Fig. 3.2 A P -wave reflecting from a rigid boundary.
this is impossible unless we allow for two reflected waves: one P -wave and one S -wave. Otherwise, there are not enough degrees of freedom to make both displacement components zero on x = 0. We therefore seek a reflected wave field of the form # $ − cos γ exp i kp (−x cos γ + y sin γ) − ωt u r e f = rp sin γ # $ sin β + rs exp i ks (−x cos β + y sin β) − ωt , (3.2.43) cos β where ks = ω/cs . Recall that S -waves are transverse so the amplitude is orthogonal to the wave-vector. From the condition u = 0 on x = 0, we find that the P -wave reflection is specular, meaning that the angle of reflection γ is equal to the angle of incidence α. However, the S -wave reflection angle satisfies sin β =
cs sin α cp
(3.2.44)
and, since cp > cs , it follows that β < α, as illustrated in Figure 3.2. The reflection coefficients are given by rp =
cos(α + β) , cos(α − β)
rs = −
sin(2α) . cos(α − β)
(3.2.45)
This is our first encounter with the phenomenon of mode conversion. A boundary will usually turn a pure P -wave (or a pure S -wave) into a combination of P - and S -waves. As shown in Exercise 3.6, the same happens in
3.2 Normal modes and plane waves
117
y
“rock”
µ2 ,
ρ2
µ1 ,
ρ1
h “coal”
x
“rock”
−h
µ2 ,
ρ2
Fig. 3.3 A layered elastic medium.
the case of refracted waves, and the phenomenon of total internal reflection becomes correspondingly more complicated. We now describe an example that illustrates how P - and S -waves can interact in a practical situation. 3.2.6 Love waves Let us consider the dynamic version of antiplane strain, the static case of which was introduced T in Section 2.3. If the displacement field takes the form u = 0, 0, w(x, y, t) , then w satisfies 2 ∂2w ∂ w ∂2w 2 = ρ + , (3.2.46) µ∇ w = µ ∂x2 ∂y 2 ∂t2 which is just the familiar two-dimensional scalar wave equation (3.1.2), with wave speed cs . This is to be expected, since antiplane strain is volumepreserving, with the displacement depending only on the transverse variables. The solution strategies presented above for two-dimensional waves on a membrane are all directly applicable to the solution of (3.2.46). Here we will illustrate them by describing Love waves, which are antiplane strain waves guided through a particular type of layered medium. As illustrated in Figure 3.3, the geometry is that of a uniform layer of one material, with constant thickness 2h, encased inside an infinite expanse of a second material. This set-up might model, for example, a coal seam in a rock stratum, with the displacement in the horizontal z-direction. This is in contrast with
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Linear elastodynamics
the situation depicted in Figure 3.2 where, if we identify the rigid boundary with a horizontal rock stratum, the displacement is in the vertical direction. For this reason, the S -waves considered in Section 3.2.5 are referred to as SV -waves, while the antiplane S -waves described by (3.2.46) are referred to as SH -waves. The density and shear modulus of the “coal” are denoted by ρ1 and µ1 respectively, while those of the “rock” are labelled ρ2 and µ2 . The transverse displacement wi (x, y, t) in either medium satisfies 2 ∂ wi ∂ 2 wi ∂ 2 wi 2 = cs i + (i = 1, 2), (3.2.47) ∂x2 ∂y 2 ∂t2 where csi = µi /ρi (i = 1, 2) are the S -wave speeds. On the boundaries of the seam, the displacements and tractions must be continuous, as shown in Section 1.10, so that w1 = w 2 ,
µ1
∂w1 ∂w2 = µ2 , ∂y ∂y
on y = ±h.
(3.2.48)
We seek travelling-wave solutions propagating in the x-direction in which the displacements take the form (3.2.49) wi = fi (y) exp i (kx − ωt) . Substituting (3.2.49) into (3.2.47), we find that the functions fi (y) satisfy 2 ω 2 − k fi = 0 (3.2.50) fi + c2si and, hence, are either exponential or sinusoidal. We suppose that the amplitude of the waves decays at infinity so that f2 = A2 e−y
in y > h,
f2 = B2 ey
in y < −h,
(3.2.51)
where is real and positive. In such modes, the seam acts as a wave-guide, propagating waves in the x-direction without any energy radiating or “leaking out” to y → ±∞ as discussed in Section 3.2.3. Substitution of (3.2.51) into (3.2.50) reveals that k and ω must be such that c2s2 k 2 − ω 2 = c2s2 2 > 0.
(3.2.52)
In the coal seam, we try a solution f1 = A1 cos(my) + B1 sin(my)
(3.2.53)
which may be sinusoidal if m is real or exponential if m is pure imaginary. Now (3.2.50) leads to ω 2 = c2s1 k 2 + c2s1 m2 ,
(3.2.54)
3.2 Normal modes and plane waves
so the Love waves propagate at a speed cL given by m2 ω2 2 2 cL = 2 = cs1 1 + 2 . k k
119
(3.2.55)
Let us first consider symmetric modes in which B1 = 0 and B2 = A2 , so the boundary conditions (3.2.48) reduce to A2 e−h = A1 cos(mh),
µ2 lA2 e−h = µ1 mA1 sin(mh).
(3.2.56)
We can view this as a system of simultaneous equations for A1 and A2 , whose solution is in general A1 = A2 = 0. A nonzero solution can only exist if the determinant of the system is zero, and this gives us the condition µ1 m tan mh = µ2 .
(3.2.57)
For antisymmetric waves, with A1 = 0 and B2 = −A2 , the analogous calculation in Exercise 3.7 leads to µ1 m cot mh = −µ2 .
(3.2.58)
It remains to determine m from either of the transcendental equations (3.2.57) or (3.2.58). These are easiest to analyse in the extreme case where the rock is rigid so that µ2 /µ1 → ∞, and we will focus on this limit henceforth, leaving the general case to Exercise 3.7. We then see that there are two infinite families of solutions, with mh = (2n + 1)π/2 for symmetric waves or mh = nπ for antisymmetric waves, where n is an integer. From (3.2.52) and (3.2.55), we deduce the inequalities ω 2 < c2s2 , (3.2.59) c2s1 < k which show that the waves can only exist if cs1 < cs2 , that is if the wave speed in the coal is slower than that in the rock, which is typically true in practice. The phase speed of the waves is then bounded between cs1 and cs2 and the resulting wave-fields in the rock decay exponentially as we move away from the seam. For each fixed allowable value of m, (3.2.55) shows that the wave-speed cL varies with wavenumber, with long waves travelling faster than short ones. This is our first encounter with dispersive waves, and it seems to be at odds with our knowledge that S -waves are non-dispersive. However, the dispersion relations (3.2.37) were obtained only for plane P - or S -waves in an infinite medium, and (3.2.55) illustrates how the presence of boundaries can often give rise to dispersion.
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Linear elastodynamics
ω
ω = cs2 k
k
ω = cs1 k
Fig. 3.4 Dispersion relation between frequency ω and wavenumber k for symmetric (solid) and antisymmetric (dotted) Love waves. The phase speed ω/k is bounded between cs1 and cs2 .
We see that the lowest-frequency mode is a symmetric wave with mh = π/2 and therefore 2
ω =
c2s1
π2 2 +k . 4h2
(3.2.60)
Hence, real values of k can only exist if ω exceeds a critical cut-off frequency πcs1 /2h. The existence of a cut-off frequency below which waves cannot propagate without attenuation is a characteristic of all waveguides. If we do not take the limit µ2 /µ1 → ∞, then the dispersion relation between ω and k must be obtained by eliminating , m between (3.2.52), (3.2.54) and either (3.2.57) or (3.2.58), as shown in Exercise 3.7. Crucially, the values of m satisfying (3.2.57) or (3.2.58) with > 0 are all real, so the inequalities (3.2.59) continue to hold and there is still a cut-off frequency. As shown in Figure 3.4, there is an infinite family of waves, both symmetric and antisymmetric, and, in each case, the phase speed ω/k is bounded between cs1 and cs2 .
3.2.7 Rayleigh waves Rayleigh discovered perhaps the most famous of all elastic waves, which can propagate close to a planar free boundary, decaying exponentially away from the boundary but suffering no decay at all in the direction of propagation. We can model these waves using plane strain in y < 0 below a stress-free
3.3 Dynamic stress functions
121
boundary at y = 0, where the zero-traction condition is ∂v ∂u ∂v ∂u ∂v + = 2µ +λ + =0 at y = 0. µ ∂y ∂x ∂y ∂x ∂y Now we seek frequency-domain solutions of the form u = (up eκp y + us eκs y ) exp i (kx − ωt) ,
(3.2.61)
(3.2.62)
where the dispersion relations (3.2.37) for P - and S -waves tell us that κ2p = k 2 −
ω2 , c2p
κ2s = k 2 −
ω2 . c2s
(3.2.63)
We assume as usual that k and ω are real and positive, and that Re(κp ) > 0 and Re(κs ) > 0, so that the waves propagate without attenuation in the x-direction while decaying exponentially as y → −∞. Evidently such waves can only exist if the wavenumber k in the x-direction is greater than both ω/cs and ω/cp . The propagation speed c = ω/k must therefore satisfy c < cs < cp ,
(3.2.64)
so that Rayleigh waves inevitably travel more slowly than either P -waves or S -waves. After the rather tortuous manipulations of Exercise 3.8, we find an equation for c in the form 2 1/2 1/2 c2 c2 c2 1− 2 =4 1− 2 . (3.2.65) 2− 2 cs cp cs It can be shown that this leads to a sextic equation for c but that only one positive real value for c2 exists and satisfies (3.2.64). Rayleigh waves are therefore non-dispersive, with a constant propagation speed c. These results led Rayleigh to suggest that, if a P - or S -wave originated at some source, for example an earthquake, in y < 0, mode conversion would cause such a wave to propagate indefinitely in the x-direction near y = 0. This hypothesis is born out by seismological observation: the radius of the earth is large enough for (3.2.61) to be a good approximation and many earthquake records reveal the arrival of a large Rayleigh wave after first the P - and then the S -waves have been detected. 3.3 Dynamic stress functions We now describe some of the ways in which elastic wave propagation can be reduced to the study of scalar wave equations by the use of stress functions. By taking the divergence and the curl of the dynamic Navier equation
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Linear elastodynamics
(1.7.8), we obtain 2 ∂ 2 2 − cp ∇ (div u) = 0 ∂t2
and
∂2 2 2 − cs ∇ (curl u) = 0 ∂t2
(3.3.1)
respectively. This reminds us that irrotational waves (with curl u = 0) propagate at speed cp while equivoluminal waves (with div u = 0) move at speed cs . It also provides a route for finding solutions of the Navier equation that often proves handy. We can first solve the scalar wave equation (3.3.1a) for div u and then the inhomogeneous wave equation 2 ∂ 2 2 − cs ∇ u = c2p − c2s ∇ (div u) (3.3.2) 2 ∂t for the displacement u. Moreover, by cross-differentiating (3.3.1), we obtain 2 2 ∂ ∂ 2 2 2 2 (3.3.3) − cp ∇ − cs ∇ u = 0, ∂t2 ∂t2 which we can interpret as a factorisation of the the Navier wave operator into two scalar operators corresponding to P -waves and S -waves respectively. This generalises the result that each component of the displacement u satisfies the biharmonic equation under static conditions. We recall that in Chapter 2 we showed that, when there is two-dimensional or cylindrical symmetry, the problem can be reduced to a single scalar biharmonic equation by using a suitable stress function. Now we show briefly how the same idea may be applied to dynamic problems. First we consider plane strain, in which the second component of the Navier equation (1.7.8), namely 2 ∂ u ∂2v ∂2v + µ∇2 v, (3.3.4) + ρ 2 = (λ + µ) ∂t ∂x∂y ∂y 2 can be rewritten as
∂2u ∂2v 1 ∂2v 2 + (1 − 2ν) ∇ v − 2 2 + 2 = 0. ∂x∂y cs ∂t ∂y
This is satisfied identically if we set 1 ∂2L 1 ∂2L 2 u= , (1 − 2ν) ∇ L − 2 2 + 2µ cs ∂t ∂y 2
v=−
1 ∂2L , 2µ ∂x∂y
(3.3.5)
(3.3.6)
for some function L(x, y, t), which is called the dynamic Love function by analogy with the static Love stress function introduced in Section 2.8.2. It
3.3 Dynamic stress functions
123
is then readily verified that the first Navier equation is satisfied if and only if L satisfies the scalar wave equation 2 2 ∂ ∂ 2 2 2 2 (3.3.7) − cp ∇ − cs ∇ L = 0. ∂t2 ∂t2 As in the static case, we could have started from the x- rather than the y-component of the momentum equation, or indeed any linear combination of the two. Thus one can define a one-parameter family of stress functions analogous to L. With u and v given by (3.3.6), the stress components may be evaluated from L using ∂ ∂2L 1 ∂2L 2 + (1 − ν) ∇ L − 2 2 , (3.3.8a) τxx = ∂x ∂y 2 cs ∂t 2 1 ∂2L ∂ ∂ L 1 ∂2L 2 − , (3.3.8b) − ν ∇ L − τxy = ∂y ∂y 2 c2s ∂t2 2c2s ∂t2 ∂ ∂2L 1 ∂2L 2 τyy = − . (3.3.8c) −ν ∇ L− 2 2 ∂x ∂y 2 cs ∂t For radially symmetric problems, in which the displacement takes the form u = ur er + uz ez and is dependent only on the cylindrical polar coordinates (r, z) and t, it is again possible to define a Love function L(r, z, t) such that 1 ∂ ∂L 1 ∂2L 1 1 ∂2L 2 , uz = (1 − 2ν) ∇ L − 2 2 + r , ur = − 2µ ∂r∂z 2µ cs ∂t r ∂r ∂r (3.3.9) and again L satisfies (3.3.7). In this case, the stress components by ∂ ∂2L 1 ∂2L 2 , τrr = − −ν ∇ L− 2 2 ∂z ∂r2 cs ∂t 1 ∂2L ∂ 1 ∂ 1 ∂2L ∂L 2 τrz = r −ν ∇ L− 2 2 − 2 2 , ∂r r ∂r ∂r c ∂t 2cs ∂t s 2 ∂ 1 ∂ 1 ∂ L ∂L τzz = , r + (1 − ν) ∇2 L − 2 2 ∂z r ∂r ∂r cs ∂t 1 ∂L ∂ 1 ∂2L 2 τθθ = . − +ν ∇ L− 2 2 ∂z r ∂r cs ∂t
are given
(3.3.10a) (3.3.10b) (3.3.10c) (3.3.10d)
We will now use the ideas of Sections 3.2–3.3 to enumerate some of the rare configurations for which explicit solutions of the multidimensional elastic wave equations can be written down.
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Linear elastodynamics
3.4 Waves in cylinders and spheres 3.4.1 Waves in a circular cylinder The simplest cylindrically symmetric waves are torsional waves in which ur = uz = 0 and uθ is independent of θ. In this case, we do not need any stress function representation because the cylindrical Navier equation (1.11.8) simplifies to ∂ 2 uθ uθ 1 ∂uθ ∂ 2 uθ 1 ∂ 2 uθ − + + = . ∂r2 r ∂r r2 ∂z 2 c2s ∂t2
(3.4.1)
This scalar equation supports S -waves, as expected for a displacement field satisfying ∇ · u = 0. We seek waves travelling in the z-direction with wavenumber k and frequency ω by separation of variables: uθ = f (r) ei(kz−ωt) . Substituting (3.4.2) into (3.4.1), we find that f (r) satisfies 1 1 2 f + f + m − 2 f = 0, r r
(3.4.2)
(3.4.3)
where m2 =
ω2 − k2 , c2s
(3.4.4)
and we will only consider cases in which m is real. The general solution of (3.4.3) is f (r) = A J1 (mr) + B Y1 (mr) ,
(3.4.5)
where J1 and Y1 again denote Bessel functions, while A and B are arbitrary constants. To describe waves in a circular cylinder 0 r < a, we must set B = 0 to eliminate the solution Y1 which is unbounded as r → 0. If the curved boundary of the cylinder, r = a, is free of traction, we require uθ ∂uθ − =0 (3.4.6) τrθ = µ ∂r r on r = a, which implies that m d 1 J1 (mr) = − J2 (ma) = 0, dr r a r=a
(3.4.7)
the latter equality following from known properties of Bessel functions (Gradshteyn & Ryzhik, 1994, Section 8.4). We deduce that ma must equal one of
3.4 Waves in cylinders and spheres
125
the zeros ξ2,n of J2 as defined in Section 3.2.1. There is thus one family of waves corresponding to each integer value of n. The dispersion relation cs + 2 ξ2,n + k 2 a2 (3.4.8) ω= a tells us that the bar acts as a wave-guide, in which the frequency must exceed the cut-off value ξ2,1 cs /a, while the phase velocity ω/k is not constant, but is bounded below by cs . Torsional waves are therefore dispersive, and always travel faster than S -waves. Also, for a cylinder that is finite in the z-direction, we can use (3.4.8) to find the normal frequencies. For cylindrically symmetric longitudinal waves, in which uθ = 0 and ur and uz are independent of θ, the Love stress function L introduced in Section 3.3 is especially useful. We look for harmonic waves propagating in the z-direction by setting L(r, z, t) = f (r)ei(kz−ωt) .
(3.4.9)
The partial differential equation (3.3.7) satisfied by L leads to the ordinary differential equation 2 2 d d 1 d 1 d 2 2 (3.4.10) + mp + ms f (r) = 0, + + dr2 r dr dr2 r dr for f , where now we define m2p =
ω2 − k2 , c2p
m2s =
ω2 − k2 , c2s
(3.4.11)
as shorthand. The general solution of (3.4.10) is f (r) = A J0 (mp r) + B J0 (ms r) + C Y0 (mp r) + D Y0 (ms r) ,
(3.4.12)
where A, B, C and D are arbitrary constants. To describe waves in the solid cylinder r < a, we must choose C = D = 0 so that f (r) is well-defined as r → 0. If the boundary is stress-free, then τrr and τrz are zero on r = a, and this leads to the two boundary conditions f ω2 d 2 (3.4.13a) (1 − ν) f + + νk + (2 − ν) 2 f = 0, dr r 2cs f (3.4.13b) (1 − ν)f − ν − νm2s f = 0 r on r = a. These give us a homogeneous linear system for the two remaining
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Linear elastodynamics
constants A and B, namely (1 − ν)m2p − (1 − 2ν)m2s − k 2 mp J1 (mp a) A + m2s − k 2 ms J1 (ms a) B = 0, (3.4.14a) mp J1 (mp a) − νm2s + (1 − ν)m2p a J0 (mp a) A + ms (J1 (ms a) − ms a J0 (ms a)) B = 0. (3.4.14b) These admit nonzero solutions for A and B only if the determinant of the system is zero, and this gives us a complicated dispersion relation between ω and k. Notice that the wave-field inevitably involves a combination of P waves and S -waves, illustrating the intimate coupling between these waves in practical situations. An even more complicated wave motion is that of flexural waves, where all three displacement components are nonzero. There is no Love stress function available in this case, but we can try a particularly simple θ-dependence of the displacement field, namely u(r, θ, z, t) = Ur (r) cos θer + Uθ (r) sin θeθ + Uz (r) cos θez ei(kz−ωt) . (3.4.15) It follows that div u takes the form div u = f (r) cos θei(kz−ωt) ,
where
f (r) =
1 d Uθ (rUr ) + ikUz + . r dr r (3.4.16)
Hence, when we recall from (3.3.1) that 2 ∂ 2 2 − cp ∇ (div u) = 0, ∂t2 we find that f (r) again satisfies Bessel’s equation 1 1 f + f + m2p − 2 f = 0. r r
(3.4.17)
(3.4.18)
Assuming that f (r) is bounded as r → 0, we must therefore take f (r) = A J1 (mp r).
(3.4.19)
Having found div u, we can use (3.3.2) to determine the displacement components. To calculate ∇2 u in polar coordinates, we have to use (1.7.11) and
3.4 Waves in cylinders and spheres
127
the polar coordinate formulae for div, grad and curl given in Appendix A7.1 to obtain 2 Ur 2Uθ 2 2 − Ur + + k Ur − 2 cos θer ∇ u= r r2 r Uθ 2 2Ur 2 − + Uθ + + k Uθ − 2 sin θeθ r r2 r Uz 1 2 + Uz + + k Uz cos θez ei(kz−ωt) . (3.4.20) − r r2 Similarly, by taking the grad of (3.4.16) in polar coordinates, we find that f (r) sin θeθ + ikf (r) cos θez ei(kx−ωt) . grad div u = f (r) cos θer − r (3.4.21) Just considering the ez -component of (3.3.2), we find that Uz must satisfy c2p 1 1 2 (3.4.22) Uz + Uz + ms − 2 Uz = 1 − 2 ikf, r r cs with f given by (3.4.19). The bounded solution of this inhomogeneous Bessel equation is ikA Uz = − 2 J1 (mp r) + B J1 (ms r), (3.4.23) k + m2p where B is an arbitrary constant. Next we can use (3.4.16) and (3.4.23) to determine Uθ as Uθ =
m2p A r J1 (mp r) − ikBr J1 (ms r) − rUr − Ur . k 2 + m2p
Finally, the er -component of (3.3.2) implies that c2p 2 2 2 r2 f . rUθ + Uθ + ikr Uz + 1 − ms r Ur = c2s
(3.4.24)
(3.4.25)
By substituting for Uθ , Uz and f into this expression, we obtain a single differential equation for Ur , namely 3 J1 (ms r) Ur + Ur + m2s Ur = −2ikB r r A 2 2 2 2 J1 (mp r) . (3.4.26) mp (mp − ms ) J0 (mp r) + (mp + ms ) + 2 k + m2p r
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z
t=0
2π/5ω
4π/5ω
6π/5ω
8π/5ω
Fig. 3.5 Illustration of flexural waves.
Since the general bounded solution of (3.4.26) is Ur =
ikB J0 (ms r) − J2 (ms r) 2ms mp A J1 (ms r) − J , (3.4.27) (m r) − J (m r) +C 0 p 2 p 2(k 2 + m2p ) r
where C is a further arbitrary constant, we can finally obtain Uθ from (3.4.24) as J1 (mp r) ikB J1 (ms r) J1 (ms r) A − 2 +C − ms J0 (ms r) . Uθ = 2 k + m2p r ms r r (3.4.28) Now we can look for waves in a traction-free cylinder r < a by setting τrr = τrθ = τrz = 0 on r = a. This leads to a system of three homogeneous linear equations for the three constants A, B and C. For nontrivial solutions to exist, the determinant of the system must be zero as usual and this condition leads to the dispersion relation for flexural waves. We illustrate a typical displacement in Figure 3.5 which shows typical waves corresponding to bending, or flexing, of the cylinder propagating in the z-direction.
3.4.2 Waves in a sphere The simplest waves in a sphere are spherically symmetric with a purely radial displacement, that is u = ur (r, t)er .
(3.4.29)
3.4 Waves in cylinders and spheres
129
The Navier equation (1.11.17) in spherical polar coordinates thus reduces to the scalar equation ur 1 ∂ 2 ur ∂ 2 ur 2 ∂ur −2 2. = + 2 2 2 cp ∂t ∂r r ∂r r
(3.4.30)
One can easily check that the displacement field (3.4.29) satisfies ∇×u = 0, which is why (3.4.30) describes only P -waves. This in turn implies that we can write u = ∇φ for some potential function φ(r, t), that is ur =
∂φ . ∂r
If we do so, then (3.4.30) takes the form ∂ 1 ∂ 2 φ ∂ 2 φ 2 ∂φ = 0, − 2 − ∂r c2p ∂t2 ∂r r ∂r
(3.4.31)
(3.4.32)
and integration with respect to r leads to 1 ∂ 2 φ ∂ 2 φ 2 ∂φ = F (t), − 2 − c2p ∂t2 ∂r r ∂r
(3.4.33)
for some function F (t). However, since an arbitrary function of t may be added to φ without affecting the displacement field, we deduce that F may be set to zero without any loss of generality. Then a simple rearrangement of (3.4.33) yields 2 ∂2 2 ∂ (rφ) − c (rφ) = 0. p ∂t2 ∂r2
(3.4.34)
Thus the combination (rφ) satisfies the standard one-dimensional wave equation, with wave-speed cp . If we seek normal modes in which φ(r, t) = f (r)e−iωt , then (3.4.34) becomes 2 ω d2 (rf ) = 0, (3.4.35) (rf ) + dr2 c2p whose general solution is f=
A sin(ωr/cp ) + B cos(ωr/cp ) , r
where A and B are two arbitrary constants.
(3.4.36)
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To describe normal modes in a sphere r < a, the boundedness of φ at r = 0 implies that B = 0. If the surface r = a is traction-free, then τrr must be zero there. Using the formula given in Section 1.11.3, we obtain
2 − 2c2 ) 2(c ur ∂ur p s + 2λ = ρe−iωt c2p f + f (3.4.37) τrr = (λ + 2µ) ∂r r r and, with f (r) given by (3.4.36), we find that the zero-stress condition on r = a reduces to −1 tan(ωa/cp ) ω 2 a2 = 1− . (3.4.38) ωa/cp 4c2s By plotting the left- and right-hand sides versus ω, one can easily deduce that this transcendental equation admits a countably infinite set of real solutions for ω, corresponding to the natural frequencies for radial oscillations of the sphere. More complicated formulae for solutions that are not radially symmetric may be found in Love (1944, Chapter 12). These involve so-called spherical harmonics, which inevitably arise when one attempts to separate the variables in spherical polar coordinates. We will only discuss torsional waves, in which the displacement consists of just a rotation about the z-axis, so that u = uφ eφ . Using (1.11.17), one can easily show that this is only possible if uφ is independent of φ, and it follows that div u is identically zero and we have pure S -waves. The Navier equation (1.11.17) reduces to ∂uφ uφ 1 ∂ 1 ∂ 2 uφ 1 ∂ 2 ∂uφ r + 2 sin θ − 2 2 , (3.4.39) = 2 c2s ∂t2 r ∂r ∂r r sin θ ∂θ ∂θ r sin θ and we seek a separable normal mode in which uφ (r, θ, t) = f (r)g(θ)e−iωt .
(3.4.40)
By separating the variables in the usual way, we find that the functions f and g must satisfy 2 2 ω r 2 r f + 2rf + − κ f = 0, (3.4.41a) c2s (3.4.41b) g + cot θg + κ − cosec2 θ g = 0, where κ is an arbitrary separation constant. Crucially, we require uφ to be a 2π-periodic function of θ and to be wellbehaved at θ = 0, π. We can now use a well-known result from quantum mechanics to assert that this is possible only if κ = n(n + 1), where n is a
3.4 Waves in cylinders and spheres
131
positive integer.† In this case, the relevant solution of (3.4.41b) is d g(θ) = A Pn (cos θ) , (3.4.42) dθ where A is an arbitrary constant and Pn is the Legendre polynomial of degree n (Gradshteyn & Ryzhik, 1994, Section 8.91). These polynomials are defined by 1 dn 2 n (z , (3.4.43) − 1) Pn (z) = n 2 n! dz n and the first few cases are P1 (z) = z,
P2 (z) =
3z 2 − 1 , 2
P3 (z) =
5z 3 − 3z . 2
(3.4.44)
With κ = n(n + 1), the general solution of (3.4.41a) that is bounded as r → 0 is B Jn+1/2 (ωr/cs ) √ f (r) = , (3.4.45) r where B is an arbitrary constant. Fortunately, the Bessel function Jn+1/2 takes a relatively simple form when n is an integer, namely ) 2 n+1/2 1 d n sin z n Jn+1/2 (z) = (−1) z , (3.4.46) π z dz z and the first few cases are ) 2 sin z − cos z , J3/2 (z) = πz z ) 2 (3 − z 2 ) sin z 3 cos z , − J5/2 (z) = πz z2 z ) 2 3(5 − 2z 2 ) sin z (z 2 − 15) cos z . + J7/2 (z) = πz z3 z2
(3.4.47a) (3.4.47b) (3.4.47c)
Now, for a stress-free spherical boundary at r = a, the appropriate boundary condition is ∂uφ uφ τrφ = µ − = 0, (3.4.48) ∂r r and the corresponding condition for f is f (a) − †
f (a) = 0. a
(3.4.49)
This may be established by writing g(θ) as a power series in cos θ and then requiring the series to converge as cos θ → ±1.
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By substituting for f from (3.4.45), with C = 0, and simplifying, we arrive at the equation (n − 1) Jn+1/2 (ωa/c) = (ωa/c) Jn+3/2 (ωa/c)
(3.4.50)
for the natural frequencies ω. For each integer value of n, (3.4.50) has a countably infinite family of solutions, say ωn,m (m = 1, 2, . . . ) (see Exercise 3.11). Thus there is a doubly infinite set of natural frequencies corresponding to all possible values of m and n, as we would expect for a problem in two spatial dimensions (r, θ).
3.5 Initial-value problems 3.5.1 Solutions in the time domain Thus far in this chapter, we have focused on normal modes and monochromatic waves, both of which correspond to frequency-domain solutions that are harmonic in time with a single frequency ω. However, if we wish to model situations like the plucking of a string or the initiation of elastic waves by an earthquake, we have to solve an initial-value problem in the time domain, in which all frequencies will be excited. Typically this will comprise a given initial displacement and velocity and our task will be to determine how the medium subsequently evolves. To keep the discussion as simple as possible, we will ignore the effects of boundaries in the medium. The simplest example is the one-dimensional wave equation (3.1.1), whose general solution is w(x, t) = F (x − ct) + G(x + ct), (3.5.1) where F and G are arbitrary functions, and c = T / is again the constant wave-speed. By this we mean that any solution of (3.1.1) may be expressed in the form (3.5.1), and this is readily verified for all the simple solutions given in Section 3.2. If, for example, we are given the initial conditions w = f (x),
∂w = g(x) ∂t
at
t = 0,
(3.5.2)
then, as in Exercise 3.12, we can easily evaluate the corresponding F and G to obtain the d’Alembert solution 1 x+ct 1 f (x − ct) + f (x + ct) + g(s) ds. (3.5.3) w(x, t) = 2 2c x−ct
3.5 Initial-value problems
133
In more than one space dimension, there is usually no general solution akin to (3.5.1) and initial-value problems are consequently much more difficult to solve. There are two main approaches, the first of which is to try and superimpose normal modes or harmonic waves in such a way as to satisfy the initial conditions. We have already seen examples of this approach in Section 3.2. However, given the scarcity of elastic wave problems that can be solved explicitly in the frequency domain, even fewer explicit solutions can be found in the time domain using this approach. The second possibility is to use singular solutions of the wave equation, analogous to the Green’s functions introduced in Section 2.9, which in principle allow us to write down the solutions of initial-value problems. Although there are very few geometries for which these fundamental solutions can be constructed explicitly, we will see that they demonstrate the key role played by dimensionality in wave propagation. 3.5.2 Fundamental solutions Suppose we were to force the one-dimensional wave equation (3.1.1) with an impulse at time t = 0 that is localised at x = 0. In such a situation, w satisfies 2 ∂2w 2∂ w − c = δ(x)δ(t), (3.5.4) ∂t2 ∂x2 where δ is the Dirac delta-function defined in Section 2.9 and w is assumed to be zero for t < 0. The right-hand side of (3.5.4) indicates that there is a jump in ∂w/∂t at t = 0, and we can therefore restate (3.5.4) as the initial-value problem 2 ∂2w 2∂ w − c = 0, in t > 0, (3.5.5a) ∂t2 ∂x2 ∂w = δ(x) at t = 0. (3.5.5b) w = 0, ∂t Substitution of (3.5.5) into the d’Alembert solution (3.5.3) leads to the fundamental solution 1 −ct < x < ct, (3.5.6a) w = R(x, t) = 2c 0 otherwise,
which is also known as the Riemann function for the one-dimensional wave equation. It may conveniently be recast as 1 R(x, t) = H(x + ct) − H(x − ct) , (3.5.6b) 2c
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Linear elastodynamics
R(x, t)
t
x
Fig. 3.6 The one-dimensional fundamental solution R(x, t).
which is explicitly in the form of (3.5.1), where 0 s < 0, H(s) = 1 s > 0,
(3.5.7)
is the so-called Heaviside function or step function. On the other hand, if w starts from rest with the initial displacement a localised singularity of the form w(x, 0) = δ(x),
∂w (x, 0) = 0, ∂t
(3.5.8)
then we easily find that w=
1 δ(x + ct) + δ(x − ct) . 2
(3.5.9)
This solution might represent the behaviour of a string that is plucked at a single point, while the fundamental solution R(x, t) models a string being struck at a point. Since formal differentiation† gives H (s) = δ(s), it follows that w = ∂R/∂t, and we can thus write the general d’Alembert solution (3.5.3) as a superposition of fundamental solutions, namely ∞ ∞ ∂ f (s)R(x − s, t) ds + g(s)R(x − s, t) ds. (3.5.10) w(x, t) = ∂t ∞ −∞ The Riemann function thus plays an analogous rˆ ole to that performed by the Green’s function in elastostatic problems. We plot the fundamental solution R(x, t) in Figure 3.6. Notice that the initial disturbance is felt everywhere inside the region |x| < ct, but nowhere †
for example noting that d(|s|)/ds = H(s) + 1 and using Exercise 2.23
3.5 Initial-value problems
135
R(r, t)
r
t
Fig. 3.7 The two-dimensional fundamental solution R(x, y, t) versus radial distance r = x2 + y 2 .
outside, and that ∂w/∂t is zero everywhere except on the the lines x = ±ct. Using (3.5.3), it is straightforward to generalise this observation to arbitrary localised initial data: if f (x) and g(x) are zero outside some interval, say a < x < b, then for all time ∂w/∂t is zero except on the two intervals a − ct < x < b − ct and a + ct < x < b + ct. Now let us consider two-dimensional elastic waves in a membrane or in antiplane strain, when there is no general solution like (3.5.1) to guide us. Nevertheless, the wave equation (3.1.2) can still be solved subject to singular initial data analogous to (3.5.5), for example by seeking a solution in plane polar coordinates, as in Exercise 3.13. This reveals that the solution of (3.1.2) with ∂w = δ(x)δ(y) at t = 0, (3.5.11) w = 0, ∂t is H (ct − r) √ , (3.5.12) w = R(x, y, t) = 2πc c2 t2 − r2 where r2 = x2 +y 2 and H again denotes the Heaviside function. The function R(r, t) defined by (3.5.12) is plotted in Figure 3.7. We see that, like the onedimensional fundamental solution, R(r, t) is zero outside the cone r2 = c2 t2 . In this case, although the the leading edge of the disturbance at r = ct is sharp, the retreating edge or “tail” is not, and ∂R/∂t is nonzero everywhere inside the cone. As in the one-dimensional case, we can write the general solution of the two-dimensional wave equation, subject to the initial conditions, w = f (x, y),
∂w = g(x, y) ∂t
at t = 0,
(3.5.13)
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as a linear superposition of fundamental solutions, namely
∞
w(x, y, t) = −∞
∞
g(ξ, η)R(x − ξ, y − η, t) dξdη ∞ ∞ ∂ f (ξ, η)R(x − ξ, y − η, t) dξdη. (3.5.14) + ∂t −∞ −∞
−∞
From this, one can infer that the properties of R noted above also apply to arbitrary localised disturbances. If the initial data f and g are zero outside some region, say r < a, then for all time w is zero outside the cone r = a+ct. However, the smooth tail of R implies that the disturbance persists inside the cone for all time. In three dimensions, as typified by (3.4.33), the radially-symmetric wave equation takes the form ∂ 2 w 2 ∂w 1 ∂2w , = ∇2 w = + 2 2 c ∂t ∂r2 r ∂r
(3.5.15)
where now r2 = x2 + y 2 + z 2 , and the transformation in (3.4.34) leads to the general solution w(r, t) =
F (r − ct) + G(r + ct) , r
(3.5.16)
where F and G are two arbitrary scalar functions. This illustrates that, as in one-dimensional waves, a localised radially-symmetric disturbance propagates outwards with a sharp leading edge and a sharp tail. Huygens’ principle states that this happens for radially-symmetric waves in any odd number of space dimensions, but not the two-dimensional case considered above. We can use the general radially-symmetric solution (3.5.16) to construct the three-dimensional Riemann function R(x, y, z, t) =
δ(r − ct) . 4πcr
(3.5.17)
This enables us to write the general solution to the three-dimensional initialvalue problem in a form analogous to (3.5.14), known as the retarded potential solution (Ockendon et al., 2003, p. 121). Remarkably, a retarded potential solution can also be written down for the full three-dimensional Navier equation, as shown in Love (1944, Section 211). However, we emphasise that these solutions only apply in an infinite medium, and the presence of any boundaries usually makes it impossible to construct a Riemann function.
3.5 Initial-value problems
137
3.5.3 Characteristics The concept of characteristics for hyperbolic partial differential equations gives fundamental insight into wave propagation. There are several ways of thinking about characteristics mathematically but, for our purposes, it is most convenient to generalise (3.5.8), (3.5.9) and base our definition on the solution of the equations that is zero for t < t0 and driven by a localised forcing at x = x0 , t = t0 . As in (3.2.28b), such a forcing will excite a superposition of plane waves of the form u = aei(k·x−ω(k)t) , where k · x − ωt = k · x0 − ωt0 .
(3.5.18)
As k varies, this is a family of planes in (x, t)-space through x = x0 , t = t0 , and geometric intuition suggests that they will envelop a cone whose vertex is at this point (see Exercise 3.14 for an analytical explanation of this fact). For different values of x0 , t0 , these cones are called the characteristic cones of the system of partial differential equations. The intersections of the characteristic cone through (x0 , t0 ) with the planes t = T , T > t0 are called the wave-fronts of the disturbance originating at (x0 , t0 ). For example, for the one-dimensional wave equation (3.1.1), the planes (3.5.18) are simply x ± ct = x0 ± ct0 , and they coincide with the characteristics. For higher-dimensional scalar wave equations for which ω(k) = ±ck,
(3.5.19)
|x − x0 |2 = c2 (t − t0 )2
(3.5.20)
we can notice that the cone
has normal (k, ω) in (x, t)-space and is hence the envelope of (3.5.18) as k varies. This is illustrated in two dimensions in Figure 3.8 and Exercise 3.14 gives a derivation of this result. The wave-fronts are circles or spheres in two or three dimensions respectively. For the unsteady Navier equation, Section 3.2.4 shows that (3.5.19) generalises to ω 2 − c2s |k|2 ω 2 − c2p |k|2 = 0 and hence the characteristic surface through x = y = z = t = 0 is a two-sheeted cone 2 (3.5.21) x + y 2 + z 2 − c2p t2 x2 + y 2 + z 2 − c2s t2 = 0, as illustrated in Figure 3.9 for just two spatial dimensions. This is in stark contrast with, for example, the three-dimensional scalar wave equation or with electromagnetic waves in isotropic media, where Maxwell’s equations, although also vectorial, admit only one wave-speed, namely the speed of light.
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Linear elastodynamics 2
2
2 2
x +y =c t
k1 x + k2 y = ωt
t
y
x
Fig. 3.8 The cone x2 + y 2 = c2 t2 tangent to the plane k1 x + k2 y = ωt.
t
x2 + y 2 = c2s t2
x2 + y 2 = c2p t2 y
x
Fig. 3.9 The two-sheeted characteristic cone for the Navier equation.
3.6 Moving singularities We end this chapter by considering the interesting class of problems in which elastic waves are initiated by a moving source. This can happen, for example, in an overhead cable above the pantograph on an electric train or in an ice sheet underneath a moving vehicle. In such situations, we might anticipate
3.6 Moving singularities
w
139
w
(a)
(b)
increasing t x w
(c)
x (d)
w
x
x
Fig. 3.10 The response of a string to a point force moving at speed V : (a) V = 0, (b) 0 < V < c, (c) V = c, (d) V > c.
a dramatic change in behaviour when the source velocity passes through one of the speeds of sound in the material. As a first illustration, consider the one-dimensional problem of an elastic string on which a point force of magnitude P is imposed at the moving point x = V t. This situation is modelled by the equation
∂2w ∂2w − T = P δ(x − V t), ∂t2 ∂x2
(3.6.1a)
where, as usual, δ is the Dirac delta-function. Assuming that the string starts from rest with zero displacement, we impose the initial conditions w=
∂w =0 ∂t
at
t = 0.
(3.6.1b)
This problem may be solved, for example, by changing dependent variables to ξ = x − ct and η = x + ct, where the speed of sound is c = T / , to obtain, as in Exercise 3.15, w=
Pc (c + V )|x − ct| + (c − V )|x + ct| − 2c|x − V t| , (3.6.2) 4T (c2 − V 2 )
which is a single-valued function of x when c > V . As illustrated in Figure 3.10, the gradient ∂w/∂x ahead of the force increases as the propagation speed V increases, becoming infinite as V approaches the speed of sound c. The assumption of small slope that underpins the model (3.6.1a) clearly breaks down when V is close to c and, for V > c, the only continuous solution w ceases to be single-valued, as shown in Exercise 3.15 and Figure 3.10(d). In addition, we note that, no matter
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how long we wait, the solution never settles down to a travelling wave in which w is just a function of x − V t. In two or three space dimensions, it is more difficult to obtain solutions to initial-value problems analogous to (3.6.1), but it is now sometimes possible to find travelling wave solutions. For example, an elastic membrane subject to a moving point force is modelled by the equation ς
∂2w − T ∇2 w = P δ(x − V t)δ(y). ∂t2
(3.6.3)
If we suppose that w is a function only of ξ = x − V t and y, we find that it must satisfy ∂2w ∂2w P (3.6.4) + = − δ(ξ)δ(y), 1 − M2 2 2 ∂ξ ∂y T where c = T /ς and the Mach number is defined by M=
V . c
(3.6.5)
When M < 1, so the force is moving subsonically, (3.6.4) is an elliptic partial differential equation, and w is thus just a multiple of the √ Green’s function, as in Section 2.9. By changing variables again to X = ξ/ 1 − M 2 and y, so that (3.6.4) is transformed to Poisson’s equation (see Exercise 3.16), the solution is easily found to be P (x − V t)2 2 w=− √ (3.6.6) log + y + const.. 1 − M2 2T 1 − M 2 Notice that the displacement is singular (as expected) as the point force (V t, 0) is approached, and that the entire membrane is disturbed by the force. Indeed the displacement grows in amplitude as (x, y) approaches infinity, a feature typical of two-dimensional elliptic problems. Had we tried to solve an initial-value problem, we would have found that the influence of the point force spreads out at speed c, eventually invading the whole membrane, as shown schematically in Figure 3.11(a). If M > 1, so the force is moving supersonically, then (3.6.4) is a hyperbolic partial differential equation. In fact, it is analogous to the one-dimensional wave equation (3.5.4), and we can infer the solution directly from (3.5.6) as ξ ξ √P H y−√ −H y+ √ , ξ < 0, M2 − 1 M2 − 1 w = 2T M 2 − 1 0, ξ > 0. (3.6.7)
3.6 Moving singularities
(a)
y
141
increasing t x
(b)
y x
Fig. 3.11 Wave-fronts generated by a moving force on an elastic membrane with (a) M < 1, (b) M > 1.
Notice that we have made the “causality” assumption that w = 0 ahead of the point force. In terms of physical variables, (3.6.7) may be written as √ P , w = T M2 − 1 0,
x−Vt Vt−x √
(3.6.8)
and the influence the force is thus confined to a Mach cone, whose apex of √ −1 2 angle is tan 1/ M − 1 ≡ sin−1 (1/M ). This may again be visualised by plotting wave-fronts caused by the moving force, as in Figure 3.11(b). Since the force moves supersonically, it overtakes the wave-fronts generated by itself. A similar wave pattern occurs behind a supersonic aircraft and is responsible for the notorious “sonic boom”. As was the case with (3.6.2), the subsonic (3.6.6) and supersonic (3.6.8) solutions both grow without bound as the Mach number approaches unity. This clearly violates the assumption of small displacements under which the model (3.6.3) for an elastic membrane is valid. To describe the behaviour as M passes through unity it is therefore necessary to incorporate nonlinear effects into (3.6.3).
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(a)
Linear elastodynamics
y
(b)
(c)
x
Fig. 3.12 P -wave- (dashed) and S -wave- (solid) fronts generated by a point force moving at speed V in plane strain with (a) 0 < V < cs , (b) cs < V < cp , (c) V > cp .
Now let us apply the same ideas to plane strain driven by a moving point force in the x-direction, which is described by the equations 2 2 ∂ u ∂2u ∂ u ∂2v ∂2u −µ + + 2 = P δ(x − V t)δ(y), ρ 2 − (λ + µ) ∂t ∂x2 ∂x∂y ∂x2 ∂y (3.6.9a) ∂2v ∂2v ∂2u ∂2v ∂2v = 0. (3.6.9b) + 2 −µ + ρ 2 − (λ + µ) ∂t ∂x∂y ∂y ∂x2 ∂y 2 These may be conveniently cast in terms of the Love stress function L defined by (3.3.6), which must now satisfy P 1 ∂2 1 ∂2 2 2 ∇ − 2 2 ∇ − 2 2 L=− δ(x − V t)δ(y). (3.6.10) cp ∂t cs ∂t 1−ν We again seek a travelling wave solution in which L is a function of ξ = x − V t and y, in which case L must satisfy 2 2 P ∂2 ∂2 2 ∂ 2 ∂ δ(ξ)δ(y), (1 − Ms ) 2 + 2 L = − (1 − Mp ) 2 + 2 ∂ξ ∂y ∂ξ ∂y 1−ν (3.6.11) where we now define two Mach numbers Mp =
V , cp
Ms =
V . cs
(3.6.12)
Although the solution of (3.6.11) is quite complicated mathematically, the qualitative behaviour may be understood by considering the wave-fronts generated by the moving force, by analogy with Figure 3.11.
Exercises
143
If Mp < Ms < 1, then the motion is subsonic with respect to both P and S -waves, and (3.6.11) is an elliptic equation similar to the biharmonic equation. In this case, as shown in Figure 3.12(a), all waves propagate out to infinity. If Mp < 1 < Ms , then the motion is subsonic with respect to P -waves, which therefore propagate to infinity, but supersonic with respect to S waves, which are thus confined to a Mach cone, as illustrated in Figure 3.12(b). In this transonic case, (3.6.11) is of mixed hyperbolic-elliptic type. If Ms > Mp > 1, then the motion is entirely supersonic, so both P -waves and S -waves are confined to Mach cones. Notice the analogy with the twosheeted characteristic cone shown in Figure 3.9. 3.7 Concluding remarks The ideas expounded in this chapter describe the fundamentals of many models that are regularly used to simulate elastic waves in situations ranging from tomography to oil exploration. In particular, non-destructive testing of solid structures is frequently carried out by examining elastic wave reflection, refraction and diffraction. In these studies, it is often the parameters λ and µ (which will usually be functions of position) that have to be determined from the response of a material to elastic waves, and hence they are called inverse problems. A classic example is the question, first posed by Kac (1966), can one hear the shape of a drum? ; in other words, if we know all the natural frequencies of a membrane, can we determine its boundary?† The main complication that arises when considering the Navier equation as opposed to the scalar wave equation is the existence of two distinct wavespeeds cp and cs . Many of the problems analysed in this chapter are simplified significantly if we consider incompressible materials (cf Section 1.8), in which cp → ∞ and div u = 0, so that A = 0 in (3.2.34) and only S -waves propagate at finite speed. There are many other fascinating and practically important problems in the theory of elastic waves that fall beyond the scope of this chapter. These include finite-amplitude waves, to be discussed in Chapter 5, and wave propagation through inhomogeneous media, to which we will return briefly in Chapter 9. Exercises 3.1 †
Let a mass m be attached to a string with line density and tension T . Using the boundary conditions (3.2.29) at this point, show
The answer is now known to be no.
144
Linear elastodynamics
that the reflection and transmission coefficients for an incoming wave ei(kx−ωt) are cR = 3.2
3.3
imk/2 , 1 − imk/2
cT =
1 . 1 − imk/2
Consider a wave with unit amplitude travelling in the positive xdirection on a string under tension T , whose density changes from − to + at x = 0. From continuity of the displacement and the force at x = 0, show that jump in density transmits a wave with am this plitude cT = 2/ 1 + − / + and reflects a wave with amplitude cR = cT − 1. The Helmholtz equation in plane polar coordinates is 1 ∂2A ∂ 2 A 1 ∂A + 2 2 + k 2 A = 0. + 2 ∂r r ∂r r ∂θ To study the far field scattered from a localised obstacle, write r = R/ε, where 0 < ε 1, and use the ansatz A ∼ A0 eiku(R)/ε , where A0 and u are independent of ε. Show that A0 du 2 ∂A0 + = 0, = 1, and 2 dR ∂R R and deduce that outward-propagating waves take the form A ∼ A+ (θ)r−1/2 eikr
3.4
3.5
as
r → ∞.
Show that, for any vector a and nonzero vector k, there exists a unique vector B and scalar A such that a = Ak+B×k and k·B = 0. [Hint: calculate a · k and a×k.] Suppose that an elastic medium occupies the half-space x < 0 and that the face x = 0 is held fixed. A plane S-wave is incident from x → −∞ with sin β uinc = exp{iks (x cos β + y sin β) − iωt}, − cos β where ks = ω/cs . Show that the reflected wave takes the form sin β exp{iks (−x cos β + y sin β) − iωt} uref = rs cos β − cos α exp{ikp (−x cos α + y sin α) − iωt}, +rp sin α
Exercises
145
where kp = ω/cp and the reflection angle α of the P -wave satisfies sin β sin α = . cp cs Show also that the reflection coefficients are given by rs =
3.6
cos(β + α) , cos(β − α)
rp =
sin(2β) . cos(β − α)
What happens when β > sin−1 (cs /cp )? Suppose that the face x = 0 separates elastic media characterised by Lam´e constants λ− , µ− in x < 0 and λ+ , µ+ in x > 0. Derive the jump conditions ∂u ∂v + ∂u ∂u ∂v + µ = 2µ =0 + +λ + ∂y ∂x − ∂x ∂x ∂y − to be satisfied across x = 0. If an incident S -wave as in Exercise 3.5, with wave-vector (cos β− , sin β− ), generates reflected and transmitted S - and P -waves with wave-vectors (− cos β− , sin β− ), (− cos α− , sin α− ) and (cos β+ , sin β+ ), (cos α+ , sin α+ ) respectively, show that sin α− sin β− sin α+ sin β+ = = = . cp− cs− cp+ cs+
3.7
How does the number of transmitted waves vary as β− increases from zero? (a) Show from (3.2.52), (3.2.55) and (3.2.57) that the dispersion relation for symmetric Love waves is given implicitly by * * * 2 ω2 ω2 ω 2 tan h 2 2− k − k − k . = µ µ1 2 c2s1 c2s1 c2s2 Write s = h ω 2 /c2s1 − k 2 , α = cs1 /cs2 , β = µ1 /µ2 to obtain the parametric representation α s α2 + β 2 tan2 s hω √ =√ s 1 + β 2 tan2 s, kh = , cs2 1 − α2 1 − α2 (E3.1) where nπ s < (n + 1/2)π and n is an integer. (b) Show that antisymmetric Love waves satisfy the condition (3.2.58) and deduce that their dispersion relation is given parametrically by (E3.1) with tan s replaced by cot s and (n − 1/2)π s < nπ.
146
Linear elastodynamics
cs2
cg
cs1 k Fig. 3.13 Group velocity cg = dω/dk versus wave-number k for symmetric (solid) and antisymmetric (dotted) modes of Love waves.
(c) Hence reproduce the dispersion graphs shown in Figure 3.4. (d) The group velocity cg of linear waves with dispersion relation ω = ω(k) is defined by dω . dk Use (E3.1) to find cg as a function of s for Love waves, and hence plot cg versus k. Deduce that, as shown in Figure 3.13, the group velocity is bounded above by cs2 but attains a local minimum before tending to cs1 as k → ∞. [This minimum in the group velocity allows an obstruction in a coal seam to be detected by studying the travel times of reflected waves (see Tayler, 2002, Chapter 2).] Show that up = ap (k, −iκp )T and us = as (κs , −ik)T for plane P waves and S-waves of the form (3.2.62), where the amplitudes ap,s are unknown. Show also that the boundary conditions (3.2.61) lead to 2kκp ap + (k 2 + κ2s )as = 0, 2 2 cp (κp − k 2 ) + 2c2s k 2 ap + 2c2s kκs as = 0, cg (k) =
3.8
and deduce that nonzero amplitudes exist only if the determinant k 4 (c2p − 2c2s ) + k 2 2c2s (2κp − κs )κs + c2p (κ2s − κ2p ) − c2p κ2p κ2s vanishes. Using the definitions of κp,s , derive the dispersion relation (3.2.65) for Rayleigh waves. Show graphically that there is only one real solution to this equation for the propagation speed c.
Exercises
3.9
147
In dynamic plane strain, suppose that the stress components are given by τxx =
1 ∂2φ ∂2U 1 ∂2U ∂2U + − , τ = − , xy ∂y 2 2c2s ∂t2 ∂x∂y 2c2s ∂t2 ∂2U 1 ∂2U τyy = − , ∂x2 2c2s ∂t2
for two functions U(x, y, t) and φ(x, y, t). Deduce from the twodimensional Navier equation and constitutive relations that U and φ may be chosen to satisfy 2 2 2 ∂ ∂ ∂ 2 2 2 2 2 2 − cs ∇ φ = − cp ∇ − cs ∇ U = 0. ∂t2 ∂t2 ∂t2 3.10
Show that the general solution of the scalar wave equation 2 2 2 2 ∂ ∂ 2 ∂ 2 ∂ U=0 − c − c p s ∂t2 ∂x2 ∂t2 ∂x2 is U = Fp (x − cp t) + Gp (x + cp t) + Fs (x − cs t) + Gs (x + cs t) ,
3.11
where Fp , Gp , Fs , Gs are arbitrary scalar functions. Show that the dispersion relation (3.4.50) for torsional waves in a sphere reduces to tan η 3 = η 3 − η2 tan η 12 − η 2 = η 12 − 5η 2 tan η 75 − 8η 2 = η 75 − 33η 2 + η 4
when n = 1, when n = 2, when n = 3,
where η = ωa/cs . By sketching the left- and right-hand sides as functions of η, show that there is a countably infinite set of solutions ηn,m in each case. By letting η → ∞, deduce that the highest modes are given approximately by 3 + ··· , mπ 5 + ··· , ∼ (m + 1/2)π − mπ 8 + ··· , ∼ mπ − mπ
η1,m ∼ mπ − η2,m η3,m as m → ∞.
148
3.12
3.13
Linear elastodynamics
Show that, after a suitable change of independent variables, the onedimensional wave equation (3.1.1) can be written as ∂2w = 0. ∂η∂ξ Hence obtain the d’Alembert solution (3.5.1). (a) Show that the axially symmetric wave equation 1 ∂2w ∂ 2 w 1 ∂w 2 = ∇ w = + c2 ∂t2 ∂r2 r ∂r admits similarity solutions of the form 1 r w(r, t) = f , t t where f (η) satisfies 2 d 2 df 2 η c −η − η f = 0. dη dη
(E3.2)
(b) Assuming that f is well-defined as η → 0, show that A f (η) = , c2 − η 2
0 η < c,
where A is an arbitrary constant. (c) Show that ct r dr √ = ct 2 c t2 − r 2 0 and deduce that 1 √ , 0 r < ct, 2 w(r, t) = 2πc c t2 − r2 0, r > ct, satisfies (E3.2) subject to ∂w = δ(x)δ(y) at t = 0. ∂t The characteristic surface through the origin for the two-dimensional wave equation (3.1.2) is defined to be the envelope of the planes (3.5.18) subject to the dispersion relation (3.5.19). Show that it is equivalent to the envelope of the planes w = 0,
3.14
(x − x0 ) cos θ + (y − y0 ) sin θ = c(t − t0 ) over all values of θ, and deduce that this is the characteristic cone (x − x0 )2 + (y − y0 )2 = c2 (t − t0 )2 . [The envelope of a one-parameter family of surfaces F (x, y, t; θ) may be found from the simultaneous equations F = ∂F/∂θ = 0.]
Exercises
149
In higher dimensions, show that xi − x0i =
3.15
cki (t − t0 ) |k|
on the envelope of (3.5.18), and deduce (3.5.20). Show that, in terms of the variables ξ = x − ct and η = x + ct, the one-dimensional wave equation (3.6.1a) subject to a moving point source is transformed to Pc c−V ∂2w = δ ξ+ η . (E3.3) ∂ξ∂η 2T (c + V ) c+V Using the fact that, from (2.9.7a), d2 |z| = 2δ(z), dz 2 deduce that the general solution of (E3.3) is Pc (c + V )ξ + (c − V )η + F (ξ) + G(η), w= 2 2 4T (c − V ) where F and G are arbitrary functions. Transform back to (x, t) and apply the initial conditions to obtain the solution (3.6.2) when c>V. When V > c, write x − V t = X and show that (3.6.1a) becomes
3.16
V 2 − c2
∂2w ∂2w ∂2w P c2 + δ(X). − 2V = ∂X 2 ∂X∂t ∂t2 T
Deduce that ∂w/∂X suffers a jump of P c2 /T (V 2 − c2 ) across x = V t and hence obtain (3.6.2). Prove the identity 1 δ(x), δ(ax) ≡ |a| where δ√is the Dirac delta-function. Hence show that, in terms of X = ξ/ 1 − M 2 and y, (3.6.4) reads ∂2w ∂2w P + =− √ δ(X)δ(y) 2 2 ∂X ∂y T 1 − M2 and deduce that
P log X 2 + y 2 √ + const.. w=− 2T 1 − M 2
4 Approximate theories
4.1 Introduction So far in this book we have been considering linear elasticity only for very simple geometries such as cylinders, spheres and half-spaces. In this chapter, we will consider more general solids under the restriction that they are thin and the equations of elasticity can consequently be simplified. A familiar example that we have already encountered is the wave equation governing the transverse displacements of a thin elastic string, and we will revisit this model below in Section 4.3. A string is characterised by its inability to withstand any appreciable shear stress, so its only internal force is a tension acting in the tangential direction. Similarly, a membrane is a thin, nearly two-dimensional structure, such as the skin of a drum, which supports only in-plane tensions. A bar, on the other hand, is a nearly one-dimensional solid that can be subject to either tension or compression. However, many thin elastic bodies also have an appreciable bending stiffness and therefore admit internal shear stress as well as tension. A familiar example is a flexible ruler, which clearly resists bending while deforming transversely in two dimensions, and is known as a beam. A thin, nearly one-dimensional object which can bend in both transverse directions, such as a curtain rod or a strand of hair, will be referred to as a rod. On the other hand, a nearly planar elastic structure with significant bending stiffness, for example a pane of glass or a stiff piece of paper, is called a plate. Finally, a shell is a thin, nearly two-dimensional elastic body which is not initially planar, for example a ping-pong ball or the curved panel of a car. In this chapter, we will show how models for all these structures can be derived using net force and moment balances combined with plausible constitutive relations. We will soon find, however, that it is difficult to enunciate 150
4.2 Longitudinal displacement of a bar
151
δx T (x, t)
T (x + δx, t)
x Fig. 4.1 The forces acting on a small length δx of a uniform bar.
all the physical assumptions that are needed. To do this requires a more systematic asymptotic analysis, and it will be deferred to Chapter 6. Here we will focus initially on small displacements and hence obtain linear governing equations. However, we will find that the physically-based approach also allows us to look at the effect of geometric nonlinearity, when the displacements are large but the strain is small. The nonlinear models that result exhibit interesting non-uniqueness properties that help us to understand important physical phenomena such as buckling.
4.2 Longitudinal displacement of a bar As a first illustrative example, let us consider longitudinal waves propagating along a thin bar with uniform cross-section area A. We consider a short segment of the bar between some arbitrary point x and x+δx, where x measures longitudinal distance along the bar; we can think of x as an Eulerian or Lagrangian coordinate since, as explained in Section 1.7, they are indistinguishable in linear elasticity. The mass of this segment is ρAδx, where ρ is the volume density of the bar, and the dominant force it experiences consists of the tensions T exerted on each of its faces by the sections of the bar on either side, as illustrated in Figure 4.1. Denoting the longitudinal displacement by u(x, t), we thus obtain Newton’s second law in the form ∂2u (4.2.1) T (x + δx, t) − T (x, t) = ρAδx 2 (x, t). ∂t In the limit δx → 0, this reduces to the partial differential equation ∂2u ∂T = ρA 2 . ∂x ∂t
(4.2.2)
To close the problem, we now need a constitutive relation between T and u. On physical grounds, we might expect T to be proportional to the stretch
152
Approximate theories
∂u/∂x, by analogy with Hooke’s law. Motivated by the exact static solution obtained in Section 2.2.3, we postulate the constitutive relation ∂u , (4.2.3) ∂x where E again denotes Young’s modulus. By substituting (4.2.3) into (4.2.2), we find that u(x, t) satisfies the wave equation T = EA
E
∂2u ∂2u = ρ , ∂x2 ∂t2
(4.2.4) which says that longitudinal waves in the bar travel with speed E/ρ. Since E < λ + 2µ, these waves travel slower than the longitudinal P-waves of Section 3.2.4. Typical boundary conditions are that u or the axial force EA∂u/∂x should be prescribed at each end of the bar and, of course, u and ∂u/∂t need to be given at t = 0. We should point out that various implicit assumptions underly the derivation given above. We have assumed, for example, that the longitudinal displacement u is uniform in each cross-section of the bar, and that the constitutive relation (4.2.3) holds, although its derivation in Section 2.2.3 was performed only under static conditions. Neither of these assumptions is exactly true in practice, reflecting the fact that solutions of (4.2.4) are not exact solutions of the Navier equations. Intuitively, we expect (4.2.4) to be a good approximate model√ when the bar is thin and the displacement is small, specifically if |u| A L, where L is the length of the bar. However, this simple example illustrates the difficulty of assessing the validity of such an ad hoc model. We will show in Chapter 6 how such models can be derived from the underlying continuum equations in a more rigorous manner that allows the accuracy to be carefully estimated. 4.3 Transverse displacements of a string Before deriving a model for the transverse displacements of a beam, let us remind ourselves briefly of the corresponding derivation for an elastic string, which is characterised by the fact that the only internal force that it can support is a tension T acting in the tangential direction. Assuming that gravity g acts transversely to the string, as illustrated in Figure 4.2, the net force experienced by a small segment of undisturbed length δx is x+δx 0 cos θ δx, + T − g sin θ x where denotes the line density.
4.4 Transverse displacements of a beam
153
T (x + δx, t) θ g
T (x, t) w
x δx Fig. 4.2 The forces acting on a small length δx of an elastic string.
Under the assumption that the transverse displacement w(x, t) is small compared to the length of the string, we can approximate the angle θ between the string and the x-axis by θ ∼ ∂w/∂x 1 and hence use the leading-order approximations ∂w , cos θ ∼ 1. (4.3.1) sin θ ∼ ∂x At the same time, we suppose that there is no longitudinal displacement so that the acceleration is just ∂ 2 w/∂t2 in the vertical direction. By applying Newton’s second law to the segment and letting δx → 0, we thus obtain the equations ∂2w ∂2w ∂T = 0, T 2 − g = 2 . (4.3.2) ∂x ∂x ∂t Hence we find again that the displacement satisfies the wave equation and that the tension T must be spatially uniform. Usually T is assumed to be a known constant although, in principle, it may be a function of time, for example while a guitar string is being tuned. Common experience suggests that a string is unable to withstand a compressive longitudinal force and hence that T should be positive. We can make the same observation on mathematical grounds by noting that (4.3.2b) would change type from hyperbolic to elliptic if T were negative, and hence cease to be well-posed as an initial-value problem (Ockendon et al., 2003, p. 41). 4.4 Transverse displacements of a beam 4.4.1 Derivation of the beam equation Now let us consider how to extend the model derived above to describe an elastic beam. In contrast with a string, a beam can support an appreciable transverse shear force N as well as the tension T , as illustrated in Figure 4.3;
154
Approximate theories N (x + δx, t) T (x + δx, t) M (x, t)
g M (x + δx, t)
T (x, t) N (x, t)
Fig. 4.3 The forces and moments acting on a small segment of an elastic beam.
for convenience N is defined to act perpendicular to the x-axis. Again considering small, purely transverse displacements, we obtain the equations ∂ 2 w ∂N ∂2w ∂T = 0, T 2 + − g = 2 . (4.4.1) ∂x ∂x ∂x ∂t Now our task is to relate N to w, and we start by performing a moment balance on the segment shown in Figure 4.3. When doing so, we recall the suggestion from Section 2.6.7 that each section of the beam exerts on its neighbours a bending moment M about the y-axis, as well as the tangential and normal force components T and N . Conservation of angular momentum about the point x leads to the equation −M (x + δx, t) + M (x, t) + δxN (x + δx, t) = g
δx2 ∂2θ + Iˆ 2 , 2 ∂t
(4.4.2)
where θ ≈ ∂w/∂x is once again the small slope of the beam and the moment of inertia of the segment about its end is given by Iˆ = (δx)3 /3. When we let δx → 0, the right-hand side of (4.4.2) is thus negligible and we are left with ∂M + N = 0. (4.4.3) ∂x Finally, we need a constitutive relation for M . It is a practical experience, for example when bending a flexible ruler, that applying an increasing moment to a beam results in an increasing curvature. For small displacements, this suggests a constitutive relation of the form −
M = −B
∂2w , ∂x2
(4.4.4)
where B is a constant known as the bending stiffness. We note that (4.4.3) and (4.4.4) are consistent with the semi-infinite strip results (2.6.70) and (2.6.73) respectively.
4.4 Transverse displacements of a beam
(a)
(b)
155
(c)
x
x
x
Fig. 4.4 The end of a beam under (a) clamped, (b) simply supported and (c) free conditions.
As in (4.2.3), we can use a simple exact solution of the Navier equations from Chapter 2 to derive an equation for B. In this case we consider the plane stress solution (2.8.30) in which the displacement field and the only nonzero stress component are −2xz u κ , (4.4.5) u = v = τxx = −κEz. 2νyz 2 2 2 2 x − νy + νz w We identify the transverse displacement of the beam with κx2 /2, neglecting the small νy 2 and νz 2 on account of the slenderness of the beam. The net moment generated by this stress field on the cross-section A is given by zτxx dydz = −Eκ z 2 dydz, (4.4.6) M= A
A
which corresponds to (4.4.4) with B = EI,
where
z 2 dydz
I=
(4.4.7)
A
is the moment of inertia of the cross-section A about the y-axis. Postulating that the constitutive relation (4.4.4) still holds under dynamic conditions, we combine (4.4.1)–(4.4.7), to obtain the beam equation −EI
∂2w ∂2w ∂4w + T 2 − g = 2 . 4 ∂x ∂x ∂t
(4.4.8)
Evidently, (4.4.8) reduces to (4.3.2) as the bending stiffness EI tends to zero. Unlike the wave equation, though, (4.4.8) is not immediately classifiable as elliptic or hyperbolic.† †
It is interesting to note that the real and imaginary parts of the solution ψ of the Schr¨ odinger equation ∂2 ψ ∂ψ =− ∂t 2m ∂x2 satisfy (4.4.8) with T = g = 0, /2m = EI/ . i
156
Approximate theories
4.4.2 Boundary conditions On physical grounds we expect to need to specify w and ∂w/∂t at t = 0, as for a string. However, since (4.4.8) has four x-derivatives rather than two, we might anticipate that it requires two boundary conditions at each end of the beam, in contrast with a string. If, for example, a beam is clamped as shown in Figure 4.4(a), then both w and ∂w/∂x would be prescribed at the clamp; in the case illustrated ∂w w= = 0. (4.4.9) ∂x Alternatively, we could envisage a simply supported beam end, as shown in Figure 4.4(b), where the displacement is fixed without applying any moment, so that w = M = 0 and thus ∂2w = 0. (4.4.10) w= ∂x2 In the final example shown in Figure 4.4(c), the end of the beam is free. It therefore experiences no shear force or bending moment, and from (4.4.3) and (4.4.4) we deduce the boundary conditions ∂3w ∂2w = = 0, (4.4.11) ∂x2 ∂x3 and in this case we must also have T ≡ 0. If we specify distributed tractions on the end of a beam, then the only information about them required for our model is the net force and moment that they exert. Specifically, if the longitudinal and tangential stress components applied to the section x = 0 are σx (y, z) and σz (y, z) respectively, then the boundary conditions to be imposed on the beam equation are σx (y, z) dydz, N= σz (y, z) dydz, T = A A zσx (y, z) dydz. (4.4.12) M= A
Here we are effectively invoking Saint-Venant’s principle: all details of the edge tractions apart from the three numbers T , N and M are lost outside a neighbourhood of the edge where they are applied. We showed in Section 2.6.7 that this is true in plane strain, and here we assume that it applies more generally. 4.4.3 Compression of a beam One of the most dramatic new features of (4.4.8) compared with (4.3.2) is that we can now consider situations in which T < 0. We illustrate an
4.4 Transverse displacements of a beam n=1
w
n=2
w
1
1
1
0.5
0.5
0.2
0.4
0.6
0.8
1
x
0.2
0.4
0.6
n=3
w
0.5
1
0.8
x
0.2
-0.5
-0.5
-0.5
-1
-1
-1
157
0.4
0.6
0.8
1
x
Fig. 4.5 The first three buckling modes of a clamped elastic beam (with a = 1 and L = 1).
unexpected new possibility that arises in such cases by considering steady displacements of a beam of length L subject to negligible gravity. We suppose that the ends are clamped and subject to a compressive force P = −T and zero transverse force. In this case (4.4.8) reduces to the ordinary differential equation EI
d4 w d2 w + P = 0, dx4 dx2
(4.4.13a)
subject to the boundary conditions d3 w dw = =0 dx dx3
at
x = 0, L.
(4.4.13b)
We can consider (4.4.13) as an eigenvalue problem. One possibility is always that the beam remains straight with w ≡ const. but, if the applied force takes one of the discrete values n2 π 2 P = , EI L2
(4.4.14)
where n is an integer, then (4.4.13) admits the eigenfunction solution w = A cos
nπx L
,
(4.4.15)
where A is a constant. The first three such eigenfunctions are shown in Figure 4.5; these are the shapes that a beam can adopt as it buckles under a sufficiently large compressive force. The amplitude A appears to be indeterminate, although we might expect it to be a smoothly increasing function of the applied force. This is a deficiency of the model that will be addressed in Section 4.9.
158
Approximate theories
4.4.4 Waves on a beam Concerning the dynamic equation (4.4.8) with g = 0 and adopting the philosophy of Section 3.2.2, we can seek travelling-wave solutions of the form u = A exp i(kx − ωt) , (4.4.16) where the real part is assumed as usual, and hence obtain the dispersion relation ω 2 = EIk 4 + T k 2 .
(4.4.17)
Elastic waves on a beam are therefore dispersive, unlike P -waves, S -waves or waves on a string. This should not come as too much of a surprise, since we have already discovered in Chapter 3 that elastic waves are usually dispersive in bounded domains. For a beam under positive tension T > 0, waves with frequency ω can thus propagate with wave-length 2π/k provided * 1/2 EIk 2 T ω = 1+ . (4.4.18) k T Evidently this reduces to the dispersion relation for a string if the waves are long, with k T /EI. However, the bending stiffness becomes increasingly important, and the waves become increasingly dispersive, as the wave-length decreases. This observation can be used to explain, for example, why the harmonics of a piano string with small but nonzero bending stiffness are slightly sharp compared with the fundamental (see Exercise 4.1). For a beam under compression, with P = −T > 0, wave-like solutions of (4.4.8) exist only if k 2 > P/EI. For smaller values of k, (4.4.17) leads to complex values of ω, corresponding to solutions that grow exponentially in time. It follows that the beam is unstable to waves with wave-length greater than 2π EI/P , and we will investigate this further in Section 4.9.3.
4.5 Linear rod theory We next consider the motion of a nearly straight uniform elastic rod that can bend in two transverse T directions, so that the displacement is w(x, t) = v(x, t), w(x, t) . Now, in addition to the tension T , there are two shear force components Ny and Nz in the y- and z-directions respectively, as illustrated in Figure 4.6. By applying Newton’s second law and assuming small displacements as above, we again find that T is spatially
4.5 Linear rod theory
z
159
Nz
y
Ny T x
Fig. 4.6 The internal force components T , Ny and Nz in a thin elastic rod.
z
y Mz My
Mx
x
Fig. 4.7 Cross-section through a rod showing the bending moment components.
uniform and obtain the following generalisation of (4.4.8): T
∂2w ∂ 2 w ∂N + , + f = ∂x2 ∂x ∂t2
(4.5.1)
T where N = Ny , Nz and f is the body force per unit length. In general we must now allow for three components of the bending moment M = (Mx , My , Mz )T . As shown in Figure 4.7, My is the moment about the y-axis previously referred to simply as M in Section 4.4, while Mz represents bending in the (x, y)-plane. We will begin by neglecting the first component Mx , which corresponds to twisting of the rod about its axis. A balance of moments in the y- and z-directions analogous to (4.4.3) then leads to ∂My − Nz = 0, ∂x
∂Mz + Ny = 0. ∂x
(4.5.2)
Finally, we need to generalise the constitutive relation (4.4.4), and we will again use the plane stress solution (4.4.5) as a guide. By combining (4.4.5) with an analogous expression representing bending in the y-direction, we
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Approximate theories
obtain the following exact solution of the Navier equations: −2xz −2xy κ κz + y x2 + νy 2 − νz 2 , u= 2νyz 2 2 2νyz x2 − νy 2 + νz 2 τxx = −κz Ez − κy Ey.
(4.5.3a) (4.5.3b)
The two constants κy and κz represent bending in the (x, y)-plane and the (x, z)-plane respectively. The moments about the y- and z-axes generated over the cross-section A by this stress field are given by zτxx dydz, Mz = − yτxx dydz. (4.5.4) My = A
A
By substituting (4.5.3) into (4.5.4) we obtain the relations ∂2w Mz = EI 2 , −My ∂x where the “inertia tensor” Iyy I= Iyz
Iyz Izz
= A
y 2 yz yz z 2
(4.5.5)
dydz
(4.5.6)
characterises the bending stiffness in each direction. Hence the generalisation of (4.4.8) is the coupled system ∂4w ∂2w ∂2w − EI + f = . (4.5.7) ∂x2 ∂x4 ∂t2 Note that we can choose the y- and z-axes such that the symmetric positive definite matrix I is diagonal; these correspond to the directions in which the resistance to bending is maximised and minimised. It follows that the y- and z-components of (4.5.7) are simply two decoupled beam equations for v and w; note, though, that this decoupling does not occur if the rod cross-section is non-uniform in x. By analogy with (4.4.8), we therefore expect to have to impose initial conditions on w and ∂w/∂t as well as two boundary conditions each on v and w at either end of the rod. The conditions corresponding to clamped, simply supported and free ends are obvious generalisations of (4.4.9), (4.4.10) and (4.4.11). Examples of values of Iyy and Izz for various cross-section shapes with respect to principal axes are given in Figure 4.8. These are crucial pieces of information to bear in mind when designing beams or rods in practice. By considering (4.5.4), we observe that Iyy measures resistance to bending about the z-axis, while Izz represents resistance to bending about the y-axis. For example, if one considers the bending of a long strip of paper with T
4.5 Linear rod theory
161
(b) (a)
a
Izz = a3 b/12
b
a Iyy = ab3 /12
b (c)
Iyy = Izz = πab(a2 + 4b2 )/4 Izz Iyy < Izz
Fig. 4.8 Examples of cross-sections in the (y, z)-plane and their bending stiffnesses.
transverse dimensions a and b in the z- and y-directions respectively, where b a, it is then easy to see as in Figure 4.8(a) that Izz Iyy . This explains why it is so much easier to bend such a strip about the y-axis than about the z-axis. On the other hand, if we roll the same paper strip into a long cylinder, it will become become much stiffer in all bending directions as illustrated in Figure 4.8(b). This situation can be seen as a limiting case of a cylindrical shell, and it gives us a hint as to why curved shells are generally much stiffer than flat rods or plates. Meanwhile, the “I-beam” in Figure 4.8(c) strongly resists bending about the y-axis. Proceeding along the same lines as for longitudinal waves, we now consider torsion, i.e. twisting a rod about its longitudinal axis. As illustrated in Figure 4.7, we denote by Mx the moment about the x-axis exerted on each cross-section through the rod. By balancing the net torque with the rate of change of angular momentum of a small segment of length δx and then letting δx tend to zero, we obtain ∂Mx ∂2θ = (Iyy + Izz ) 2 , ∂x ∂t
(4.5.8)
where θ(x, t) denotes the angle of twist about the x-axis. Now we refer to the exact steady solution of Section 2.4 to motivate the constitutive relation ∂θ (4.5.9) Mx = R ∂x
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Approximate theories
between the torque and the twisting gradient, where R again denotes the † torsional rigidity. We thus find that θ satisfies the wave equation, with wave speed R/ρ (Iyy + Izz ). For the simple case of a circular cross-section, it is easy to show that πa4 µ πa4 , R= (4.5.10) 2 2 and hence that the wave speed is equal to cs . This reproduces the wave speed of the first family of torsional waves found in Section 3.4.1; that is, (3.4.8) with n = 0 and ξ2,0 = 0: the theory presented here assumes each section deforms uniformly and thus fails to discern the higher modes. Iyy + Izz =
4.6 Linear plate theory 4.6.1 Derivation of the plate equation Now we derive the equation governing the small transverse displacement w(x, y, t) of an elastic plate that is bent out of the plane z = 0. We describe the in-plane forces using a two-dimensional stress tensor Txx Txy , (4.6.1) T = Tyx Tyy where Tij is the i-component of the force per unit length on a section of the plate with outward normal in the j-direction. We also denote the transverse shear force on a section with normal in the j-direction by Nj . The forces acting on a small rectangular section of the plate are illustrated in Figure 4.9. By balancing moments around the z-axis, as in Section 1.5, we discover that Tyx ≡ Txy , so that T is symmetric. If we assume that there is no acceleration in the x- and y-directions and that the only body force is gravity acting in the negative z-direction, then Newton’s second law gives ∂Txy ∂Txx + = 0, ∂x ∂y and ∂ ∂x
∂Txy ∂Tyy + =0 ∂x ∂y
(4.6.2)
∂w ∂w Nx + Txx + Txy ∂x ∂y ∂ ∂2w ∂w ∂w + Ny + Txy + Tyy − ςg = ς 2 , (4.6.3) ∂y ∂x ∂y ∂t
where ς is now the mass of the plate per unit area. †
For consistency with the notation of this chapter, x should be substituted for z in the results of Section 2.4.
4.6 Linear plate theory
163
Ny Tyy Txy Txx δy Tyx
Nx Tyx
Nx
δx
z
Txx y Txy x
Tyy Ny
Fig. 4.9 The forces acting on a small section of an elastic plate.
Considering the bending moments, we use an analogous notation Mij (i, j = x, y) to denote the i-component of the moment per unit length acting on a section with outward normal in the j-direction, as illustrated schematically in Figure 4.10. We note that Mij is not in general symmetric, although it is a two-dimensional tensor, as will shortly become apparent. By balancing moments on the segment shown in Figure 4.10, we obtain the relations ∂Mxy ∂Mxx + + Ny = 0, ∂x ∂y
∂Myy ∂Myx + − Nx = 0. ∂x ∂y
(4.6.4)
Next we seek constitutive equations for the bending moments which, by analogy with Section 4.4, we expect to be linear functions of the second derivatives of w. Again we can use exact plane stress solutions to evaluate the appropriate coefficients. In this case, by choosing χ0 = φ = 0 and χ1 a suitable quadratic function of x and y in (2.8.28), we can construct a solution with displacement field 1 u= 2
−2(ax + by)z −2(bx + cy)z 2 2 2 ax + 2bxy + cy + ν(a + c)z /(1 − ν)
(4.6.5)
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Approximate theories
z Mxy Myx
y Myy Mxx x
Fig. 4.10 The bending moments acting on a section of an elastic plate.
and nonzero stress components τxx = −
E(a + νc)z , 1 − ν2
τxy = −
Ebz , 1+ν
τyy = −
E(νa + c)z . 1 − ν2
(4.6.6)
Now by considering the moments exerted on surfaces x = const. and y = const. respectively, we obtain the expressions h/2 h/2 zτxy dz, Myx = zτxx dz, (4.6.7a) Mxx = − −h/2
Mxy = −
−h/2
h/2
−h/2
zτyy dz,
Myy =
h/2
−h/2
zτxy dz,
(4.6.7b)
where h is the plate thickness. Hence, Mij are the components of the tensor h/2 0 −1 τxx τxy z dz. 1 0 −h/2 τxy τyy By substituting (4.6.5) and (4.6.6) into (4.6.7) we obtain the relations ∂2w Eh3 , 12(1 + ν) ∂x∂y 2 ∂ w Eh3 ∂2w =− +ν 2 , 12 (1 − ν 2 ) ∂x2 ∂y ∂2w ∂2w Eh3 . ν = + 12 (1 − ν 2 ) ∂x2 ∂y 2
Mxx = −Myy = Myx Mxy
(4.6.8a) (4.6.8b) (4.6.8c)
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165
It is reassuring that, in the notation of this section, the plane strain result (2.6.73) implies that Myx = −
µh3 ∂ 2 w , 6(1 − ν) ∂x2
(4.6.9)
which is consistent with (4.6.8b) when w = w(x). On the other hand, if we were to bend a plate about the y-axis while applying no moment about the x-axis, then we would have Mxy = 0 and therefore ∂2w ∂2w = −ν . ∂y 2 ∂x2
(4.6.10)
Thus, without the imposition of a transverse bending moment, the plate will automatically bend upwards in the y-direction when we attempt to bend it downwards in the x-direction. Unfortunately, it is difficult to observe this effect using a piece of paper because Poisson’s ratio is close to zero. By substituting (4.6.10) into (4.6.8b), we find in this case that Myx =
Eh3 ∂ 2 w , 12 ∂x2
(4.6.11)
which is consistent with (4.4.4) and (4.4.7), since h3 /12 is the moment of inertia per unit length in the y-direction. Hence we see that the constant of proportionality between curvature and bending moment in one dimension depends on whether the transverse curvature or the transverse moment are set to zero. This is analogous to the biaxial strain examples considered in Section 2.2.4, where the effective one-dimensional elastic modulus depends on whether zero stress or zero strain is imposed in the transverse direction. When we use the constitutive relations (4.6.8) in (4.6.3), we are left with the plate equation Txx
∂2w ∂2w ∂2w ∂2w 4 + T + 2T − D∇ w − ςg = ς , xy yy ∂x2 ∂x∂y ∂y 2 ∂t2
(4.6.12)
where ∇2 = ∂ 2 /∂x2 + ∂ 2 /∂y 2 and D=
Eh3 12 (1 − ν 2 )
(4.6.13)
is the bending stiffness of the plate. A membrane is a plate with negligible bending stiffness, and is described by (4.6.12) with D = 0. Unfortunately, the problem is still under-determined since (4.6.2) gives us only two equations in the three stress components. To close the problem, we also need constitutive relations for Txx , Txy and Tyy in terms of the in-plane displacements of the plate. We leave this calculation to Section 4.6.5, here
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Approximate theories
concentrating on the simple case where the plate is subjected to a known isotropic tension T . This corresponds to the trivial exact solution of (4.6.2) in which Txx = Tyy = T and Txy = 0, and reduces (4.6.12) to T ∇2 w − D∇4 w − ςg = ς
∂2w . ∂t2
(4.6.14)
Comparison with (4.4.8) reveals the difference in bending stiffness between a beam undergoing planar displacements and a plate deforming in two dimensions.
4.6.2 Boundary conditions As initial conditions for (4.6.14), we should specify w and ∂w/∂t. For a clamped plate, the boundary conditions are analogous to those for a beam, namely ∂w = 0, (4.6.15) w= ∂n where ∂/∂n is the normal derivative. For a simply supported plate, we require the displacement and the bending moment about an axis tangential to the boundary to be zero. The latter may be written in the form (−ny , nx ) Mxx Mxy nx = 0, (4.6.16) Msn = Myx Myy ny where n = (nx , ny )T is the outward-pointing unit normal to the boundary. By substituting for the moments from (4.6.8) and using the fact that w is zero on the boundary, we can reduce (4.6.16) to w=
∂w ∂2w = 0, + νκ 2 ∂n ∂n
(4.6.17)
where κ is the curvature of the boundary (see Exercise 4.8). Only for a straight boundary, then, can we apply the obvious generalisation of (4.4.10) in which w and its second normal derivative are zero. Finally we consider the boundary conditions to be imposed at a free edge, where a horizontal force balance evidently requires that T = 0. If, for the sake of argument, the boundary is at x = 0, then, for there to be zero applied stress, we are apparently led to the conditions Nx = Mxx = Myx = 0. However, it is to impossible to impose three boundary conditions on the biharmonic problem (4.6.14)! This conceptual difficulty caused great consternation to the pioneers of plate theory (see Love, 1944, Article 297), and
4.6 Linear plate theory
167
a version of Saint-Venant’s principle is commonly invoked to reduce the number of boundary conditions to two. However, a systematic resolution of the difficulty requires us to acknowledge that there is a narrow region near the free edge where the assumptions that gave rise to the plate equation fail. The careful analysis of this layer carried out in Section 6.4 shows that the correct conditions at a free edge x = 0 are Myx = 0,
∂Myx ∂Mxx −2 =0 ∂x ∂y
(4.6.18)
∂3w ∂3w + (2 − ν) = 0. ∂x3 ∂x∂y 2
(4.6.19)
or, in terms of the displacement, ∂2w ∂2w + ν = 0, ∂x2 ∂y 2
By using (4.6.4) and (4.6.8), we may also rewrite the second of (4.6.18) as Nx =
∂Mxx , ∂y
(4.6.20)
which shows that the shear stress Nx as calculated from plate theory does not in general vanish at a free edge! Note also that a discontinuity in the bending moment at a corner in the boundary results in a delta-function in the shear stress, corresponding to a point force in the transverse direction (see Timoshenko & Woinowsky-Krieger, 1959). This suggests the existence of a three-dimensional “Saint-Venant” region in the vicinity of the corner. It is also possible to obtain (4.6.18) as the natural boundary conditions associated with minimising the strain energy in the plate. Although it is beyond the scope of this chapter to derive this systematically, we note that, in the exact solution (4.6.5) where tension is neglected, the nonzero stress components are given by (4.6.6) and the corresponding strain components by exx = −az,
exy = −bz,
eyy = −cz.
(4.6.21)
Recalling the definition (1.9.5) of the strain energy density W, we find that the stored energy per unit plate area is h/2 h/2 1 τij ij dz W dz = −h/2 −h/2 2 D 2 a + 2νac + c2 + 2(1 − ν)b2 = 2 D (4.6.22) = (a + c)2 + 2(1 − ν) b2 − ac . 2
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Approximate theories
This suggests that, more generally, the net strain energy due to bending will take the form 2 2
2 2 ∂2w ∂2w ∂ w D dxdy, − U= ∇ w − 2(1 − ν) 2 2 2 ∂x ∂y ∂x∂y Ω (4.6.23) where the integral is taken over the region Ω in the (x, y)-plane occupied by the plate. The integrand in (4.6.23) shows that the total energy depends on a combination of the mean curvature ∇2 w = κ1 + κ2 and the Gaussian curvature ∂2w ∂2w − ∂x2 ∂y 2
∂2w ∂x∂y
(4.6.24)
2 = κ1 κ2 ,
(4.6.25)
where κ1 and κ2 are the principal curvatures of the surface z = w(x, y). We will soon discover that these geometric quantities are fundamental to all theories of plates and shells. Exercise 4.10 demonstrates that, if we minimise (4.6.23) using the calculus of variations, then w must satisfy the biharmonic equation, which agrees with the steady version of (4.6.14), when tension and gravity are neglected. In addition, Exercise 4.10 shows that (4.6.19) are the natural boundary conditions for the minimisation. 4.6.3 Simple solutions of the plate equation Let us start by considering steady solutions of (4.6.14) with T = 0, that is ςg (4.6.26) ∇4 w = − . D Solutions of (4.6.26) describe the sagging of a plate under gravity. We will consider both clamped and simply supported boundary conditions; it is impossible to solve (4.6.26) with entirely free boundaries since some boundary tractions are needed to balance gravity. For example, to describe the sagging of an elastic disc r < a, we can easily solve (4.6.26) in cylindrical polar coordinates. With clamped boundary conditions w = dw/dr = 0 at r = a, we find that 2 ςg 2 w=− (4.6.27) a − r2 . 64D Alternatively, the simply supported boundary conditions (4.6.17) at r = a lead to the solution 5+ν 2 ςg 2 2 2 a −r . (4.6.28) a −r w=− 64D 1+ν
4.6 Linear plate theory
0 -0.0002 -0.0004 w -0.0006 0.5 0.4 0.3 0.2 0.1 y
0 0.2 0.4
x 0.6
169
0.8
10
Fig. 4.11 The displacement (4.6.29) of a simply supported rectangular plate sagging under gravity, with a = 1, b = 1/2, ςg/D = 1.
Note in particular that the reduced rigidity afforded by the simple support compared with the clamped plate means that (4.6.28) gives a larger displacement at the centre of the disc by a factor of (5 + ν)/(1 + ν) compared with (4.6.27). Next let us consider the sag of a rectangle 0 < x < a, 0 < y < b. For clamped boundary conditions, we encounter exactly the same difficulty as in Section 2.6.6. The non-orthogonality of the functions encountered in separating the variables in the biharmonic equation with boundary conditions on w and ∂w/∂n makes any analytical solution impractical. However, the simply supported boundary conditions w = ∂ 2 w/∂n2 = 0 are now physically realistic and it is straightforward to separate the variables and obtain the solution as a sum of mutually orthogonal trigonometric functions, namely −16ςg sin (mπx/a) sin (nπy/b) w= 6 . (4.6.29) π D mn (m2 /a2 + n2 /b2 )2 m,n odd
A typical solution is shown in Figure 4.11.
4.6.4 An inverse plate problem Here we describe a novel version of the plate equation that is relevant to the manufacture of curved windscreens by heating horizontal glass plates simply supported on a frame. The heating decreases the bending stiffness D and hence enhances the sag of the glass under gravity and, by suitably distributing the heating, any desired sag can be achieved in principle. If D is temperature- and hence position-dependent, and the in-plane tension is
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Approximate theories
negligible, then the displacement satisfies 2 ∂2w ∂ w ∂2 ∂2w ∂2 D D + 2(1 − ν) + ν ∂x2 ∂x2 ∂y 2 ∂x∂y ∂x∂y 2 2 2 ∂ w ∂ w ∂ + ςg = 0. (4.6.30) +ν 2 + 2 D ∂y ∂y 2 ∂x Given D(x, y), (4.6.30) is a simple generalisation of the biharmonic equation which is straightforward in principle to solve for w(x, y), at least numerically. The corresponding inverse problem is, given a desired sag profile w(x, y), to determine the required distribution of the bending stiffness D(x, y). When viewed as a problem for D, (4.6.30) is a second-order linear partial differential equation, and two immediate questions arise: “what boundary conditions should be imposed?” and “will D be positive?”. Since the terms involving the highest derivatives of D in (4.6.30) are 2 2 ∂ w ∂2w ∂2D ∂2w ∂2D ∂2w ∂2D ∂ w + +ν 2 + 2(1 − ν) +ν 2 , ∂x2 ∂y ∂x2 ∂x∂y ∂x∂y ∂y 2 ∂x ∂y 2 we can read off the discriminant 2 2 2 2 ∂ w ∂ w ∂ w ∂2w ∂2w 2 − +ν 2 +ν 2 , ∆ = (1 − ν) ∂x∂y ∂x2 ∂y ∂y 2 ∂x
(4.6.31a)
and simple rearrangements of the right-hand side yield M 2 + Mxy Myx (4.6.31b) ∆ = xx D2 2 2 2 2 ∂ w ∂2w ∂2w ∂ w ∂2w − + . (4.6.31c) − ν = −(1 − ν)2 ∂x2 ∂y 2 ∂x∂y ∂x2 ∂y 2 Now, if there is a simply supported edge at x = 0, then we must have Myx = 0 there and we deduce from (4.6.31b) that ∆ > 0 and (4.6.30) is therefore hyperbolic. On the other hand, the right-hand side of (4.6.31c) shows that ∆ < 0 wherever the Gaussian curvature is positive, which we expect to be the case nearly everywhere in a typical windscreen. It follows that (4.6.30) must change type somewhere between the simply supported boundary and the interior, and it is an interesting open question as to whether smooth solutions to this mixed type partial differential equation exist (see Salazar & Westbrook, 2004). 4.6.5 More general in-plane stresses If we do not make the simplifying assumption that the in-plane stress is isotropic and known, then we need to obtain constitutive relations for the
4.6 Linear plate theory
171
components Txx , Txy and Tyy . We appeal to the exact biaxial strain solution (2.2.19) to pose the constitutive relations Eh (exx + νeyy ) , 1 − ν2 Eh exy , = 1+ν Eh = (νexx + eyy ) , 1 − ν2
Txx = Txy = Tyx Tyy
(4.6.32a) (4.6.32b) (4.6.32c)
where the linearised strain components are related to in-plane displacements by ∂u 1 ∂u ∂v ∂v , exy = + , eyy = . (4.6.33) exx = ∂x 2 ∂y ∂x ∂y We therefore have a plane strain problem to solve for the two-dimensional displacement field (u, v)T . From (4.6.2) we infer the existence of an Airy stress function A such that Txx =
∂2A , ∂y 2
Txy = −
∂2A , ∂x∂y
Tyy =
∂2A . ∂x2
(4.6.34)
Then elimination of u and v from (4.6.32) reveals that A satisfies the twodimensional biharmonic equation ∇4 A = 0.
(4.6.35)
The transverse displacement of the plate is therefore governed by ∂2A ∂2w ∂2A ∂2w ∂2w ∂2A ∂2w 4 + − 2 − D∇ w − ςg = ς , ∂y 2 ∂x2 ∂x∂y ∂x∂y ∂x2 ∂y 2 ∂t2
(4.6.36)
where A satisfies (4.6.35). The uniform tension T assumed in (4.6.14) corre sponds to the particular solution of (4.6.35) in which A = T x2 + y 2 /2. Equally, an anisotropically stretched membrane corresponds to D = 0, A = T1 x2 + T2 y 2 /2, where T1 and T2 are constant. In general, however, in addition to the displacement and/or bending conditions (4.6.15), (4.6.17) needed to determine w given A, we would need to specify two further boundary conditions around the edge of the plate to determine A. These would typically consist of specified in-plane displacements or tractions, that is u Txx Txy n = σ(x, y), (4.6.37) = ub (x, y) or Txy Tyy v where n is the unit normal to the edge of the plate.
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Approximate theories
4.7 Von K´ arm´ an plate theory 4.7.1 Assumptions underlying the theory There is an interesting geometrically nonlinear generalisation of plate theory which can be derived plausibly using the ideas of Section 4.6, although we will have to wait until Chapter 6 for a systematic exposition on the range of applicability of the theory. We follow the derivations used in the previous section to obtain the governing equations ∂Txy ∂Txx + = 0, ∂x ∂y
∂Txy ∂Tyy + =0 ∂x ∂y
(4.7.1)
∂2w ∂2w ∂2w ∂2w 4 + T + 2T − D∇ w − ςg = ς xy yy ∂x2 ∂x∂y ∂y 2 ∂t2
(4.7.2)
for the in-plane tensions and Txx
for the transverse displacement. Any small segment of the plate will be locally approximately planar, so we also assume that the constitutive relations (4.6.32) still hold. Our focus, then, is on obtaining improved approximations for the strain components eij . We note with concern that in (4.6.32) we are including the in-plane displacement, although we derived (4.7.1) by neglecting the in-plane acceleration. A systematic justification of this step requires us to render the equations dimensionless and take a careful asymptotic limit, as we will demonstrate in Chapter 6. Nevertheless, it is apparent that our model (4.6.12) requires both the in-plane displacements (u, v) and the transverse displacement w to be sufficiently small. The von K´ arm´an theory emerges when we make a specific choice about exactly how small they must be, and it will transpire that the in-plane displacements must be an order of magnitude smaller than the transverse displacement. This choice means that all the displacement components contribute to the leading-order strain of the plate, as we will discover below, yet it also allows us to retain the linear constitutive relations (4.6.32).
4.7.2 The strain components A point that starts on the centre-surface of the plate with Lagrangian position vector X will be displaced to a new Eulerian position x, where X X + u(X, Y ) X = Y , x(X) = Y + v(X, Y ) . (4.7.3) 0 w(X, Y )
4.7 Von K´ arm´ an plate theory
173
A nearby point with initial position (X + δX, Y + δY, 0)T will arrive at X + δX + u(X + δX, Y + δY ) x(X + δX) = Y + δY + v(X + δX, Y + δY ) w(X + δX, Y + δY ) 1 + ∂u/∂X ∂u/∂Y (4.7.4) = x(X) + δX ∂v/∂X + δY 1 + ∂v/∂Y + O |δX|2 ∂w/∂X ∂w/∂Y after the deformation. Now, when calculating the change in length of the small line element δX, we retain only the leading terms in u, v and w to obtain . ∂w 2 ∂u 2 2 2 |δx| − |δX| = δX 2 + ∂X ∂X . ∂v ∂w ∂w ∂w 2 ∂v ∂u 2 + + + δY 2 + . (4.7.5) + 2δXδY ∂Y ∂X ∂X ∂Y ∂Y ∂Y Our assumption that w, although small, greatly exceeds u and v, means that the terms on the right-hand side of (4.7.5) are all of the same order. It also means that the Lagrangian and Eulerian coordinates are identical to leading order, so we can replace (X, Y ) with (x, y) without incurring any additional errors. We therefore take the in-plane strain components to be ∂u 1 ∂w 2 + exx = , (4.7.6a) ∂x 2 ∂x 1 ∂u ∂v ∂w ∂w + + , (4.7.6b) exy = 2 ∂y ∂x ∂x ∂y ∂v 1 ∂w 2 + eyy = . (4.7.6c) ∂y 2 ∂y Then (4.7.5) gives us the lowest-order change in length of a line element in the form |δx|2 − |δX|2 = 2exx δX 2 + 4exy δXδY + 2eyy δY 2 .
(4.7.7)
Notice that (4.7.6) may also be obtained from (1.4.5) by assuming that w is an order of magnitude larger than u and v. By including the nonlinear terms in (4.7.6) we are abandoning one of the principal assumptions of linear elasticity, namely that the strain may be approximated as a linear function of the displacement gradients. However, we still plan to use the linear constitutive relations (4.6.32) between stress and strain. The von K´ arm´an theory is our first example of a theory that is
174
Approximate theories
mechanically linear but geometrically nonlinear, a distinction that we will discuss in more detail in Chapter 5. Before proceeding to incorporate (4.7.6) into the governing equations for the plate, let us pause to contrast them with the corresponding plane strain components (4.6.33) where w ≡ 0. First, we recall that in plane strain (4.6.33) are only soluble for u and v if the compatibility condition (2.7.5a) is satisfied. Here, (4.7.6) gives us three equations in the three displacements, so there is no compatibility condition, but (4.7.6) does give us the interesting result that 2 2 ∂ 2 exy ∂ 2 eyy ∂2w ∂2w ∂ w ∂ 2 exx + 2 = − . (4.7.8) − − ∂y 2 ∂x∂y ∂x2 ∂x2 ∂y 2 ∂x∂y Second, let us pose the question: “which displacement fields give rise to zero in-plane strain?” We see from (4.7.7) that such deformations will preserve the lengths of all line elements in the plate: |δx| and |δX| will be equal for all δX and δY . Such length-preserving transformations are known as isometries, and, in plane strain, the only isometries are rigid-body motions. When we allow the additional freedom of transverse as well as in-plane displacements, there is another class of isometries, corresponding to bending of the plate. It is, for example, easy to bend this page without significantly changing the lengths of any lines printed upon it. When we have zero in-plane strain, the equations exx = exy = eyy = 0 form three coupled partial differential equations for u, v and w. The elimination of u and v that led to (4.7.8) reduces the system to a single equation for w, namely 2 2 ∂2w ∂2w ∂ w − = 0. (4.7.9) 2 2 ∂x ∂y ∂x∂y Thus a surface z = w(x, y) can be isometrically deformed from a plane if and only if w satisfies (4.7.9), which is a version of the Monge–Amp`ere equation (Ockendon et al., 2003, p. 380). A surface possessing this property is known as developable. Roughly speaking, a developable surface is any shape into which a piece of paper may be bent without creasing or tearing, and familiar examples include cylinders and cones (see, for example, Kreyszig, 1959, Section 58). Equation (4.7.9) also states that the plate has zero Gaussian curvature. We recall from Section 4.6.2 that the Gaussian curvature is defined to be K = κ1 κ2 ,
(4.7.10)
where κ1 and κ2 are the principal curvatures of the surface z = w(x, y). A developable surface therefore has either κ1 = 0 or κ2 = 0 everywhere,
4.7 Von K´ arm´ an plate theory
175
(a)
(b)
(c)
(d)
Fig. 4.12 (a) A cylinder, (b) a cone, (c) another developable surface, (d) a hyperboloid, which is ruled but not developable.
so at each point there is one principal direction in which the surface has zero curvature. These directions define a family of straight lines, known as generators, embedded in the surface. Indeed, we can say that the surface is generated by moving a straight line through a given trajectory. Simple examples of developable surfaces include cylinders (not necessarily circular) and cones, as illustrated in Figure 4.12(a) and (b), where the generators are shown as black lines. However, there are many less familiar cases, such as that shown in Figure 4.12(c). We also caution that there are also nondevelopable ruled surfaces, that is, surfaces containing a straight line through any point. For example, the hyperboloid shown in Figure 4.12(d) contains two families of straight lines, although its Gaussian curvature is negative everywhere. To be clear: every developable surface is ruled but most ruled surfaces are not developable.
4.7.3 The von K´ arm´ an equations Now we just have to assemble the ingredients collected above to derive the governing equations for the plate. It is convenient to use (4.7.1) to introduce
176
Approximate theories
an Airy stress function A, defined in the usual way, so that (4.7.2) becomes ∂2A ∂2w ∂2w ∂2A ∂2w ∂2A ∂2w 4 − 2 − D∇ w − ςg = ς . + ∂y 2 ∂x2 ∂x∂y ∂x∂y ∂x2 ∂y 2 ∂t2
(4.7.11)
Next, we use (4.6.32) and (4.7.8) to eliminate the strain components and hence obtain 2 2
2w ∂2w ∂ ∂ w . (4.7.12) − ∇4 A = −Eh 2 2 ∂x ∂y ∂x∂y The coupled partial differential equations (4.7.11) and (4.7.12) for w and A comprise the von K´ arm´an model. Evidently (4.7.11) reproduces the linear plate equation (4.6.36), so the improved approximation for the strain has led to the introduction of just one new term: the right-hand side of (4.7.12). We recognise the expression in braces as the Gaussian curvature, which is zero only if the deformed plate is developable. Hence, any transverse displacement that does not consist of a pure bending of the plate inevitably causes in-plane stress, in contrast with linear plate theory, where in-plane and transverse deformations are decoupled. It is the nonlinear coupling provided by the right-hand side of (4.7.12) that makes the von K´ arm´an equations so much more difficult to solve than the linear plate equations. In the same way that we were led to the strain energy (4.6.22) for linear bending of a plate, we may use (4.6.23), generalised to include linear stretching, to suggest that the energy per unit area in a von K´ arm´an plate is D 2
2 2
∂2w ∂2w ∂ w − ∂x2 ∂y 2 ∂x∂y 1 2 + , (Txx + Tyy )2 − 2(1 + ν) Txx Tyy − Txy 2Eh
2 2 ∇ w − 2(1 − ν)
where the integrated stress components are given by (4.6.32) and the strain components are again defined by (4.7.6). A lengthy exercise in the calculus of variations shows that when we consider virtual displacements (u, v, w) that minimise the net strain energy in the plate, we do retrieve (4.7.11), (4.7.12). Concerning boundary conditions, we have to impose two conditions on w, as described in Section 4.6.2, and two conditions on A, analogous to those described in Section 2.6.3 for plane strain problems.
4.8 Weakly curved shell theory
177
4.8 Weakly curved shell theory 4.8.1 Strain in a weakly curved shell It is relatively straightforward to generalise the von K´ arm´an model to describe the deformation of a pre-cast elastic shell whose curvature is small. Suppose that the centre-surface of the shell is given in the initial unstressed state by Z = W (X, Y ). We follow the same procedure as in Section 4.7.2, considering the displacement of a point on the centre-surface from
X X= Y W (X, Y )
to
X + u(X, Y ) . x(X) = Y + v(X, Y ) W (X, Y ) + w(X, Y )
(4.8.1)
Now a nearby point on the centre-surface with initial position
X + δX X + δX = Y + δY W (X + δX, Y + δY ) 1 0 + δY 1 + O |δX|2 = X + δX 0 ∂W/∂X ∂W/∂Y
(4.8.2)
is deformed to x + δx, where ∂u/∂Y 1 + ∂u/∂X + δY 1 + ∂v/∂Y + O |δX|2 . (4.8.3) δx = δX ∂v/∂X ∂(W + w)/∂Y ∂(W + w)/∂X
Now when we calculate the change in the square of the length of the small line element δX, we find to leading order that 2
2
|δx| − |δX| = δX 2 + 2δXδY
∂u ∂W ∂w 2 +2 + ∂X ∂X ∂X
∂w ∂X
∂v ∂W ∂w ∂W ∂u + + + ∂Y ∂X ∂X ∂Y ∂y ∂v ∂W +2 + δY 2 2 ∂Y ∂Y
2 . ∂w ∂w ∂w + ∂X ∂X ∂Y . ∂w ∂w 2 , (4.8.4) + ∂Y ∂Y
178
Approximate theories
which leads us to define the strain components as ∂u ∂W ∂w 1 ∂w 2 + + , exx = ∂x ∂x ∂x 2 ∂x ∂W ∂w ∂W ∂w ∂w ∂w 1 ∂u ∂v + + + + , exy = 2 ∂y ∂x ∂x ∂y ∂y ∂x ∂x ∂y ∂v ∂W ∂w 1 ∂w 2 eyy = + + . ∂y ∂y ∂y 2 ∂y
(4.8.5a) (4.8.5b) (4.8.5c)
Again following Section 4.7.2, we can eliminate the horizontal displacement (u, v) from (4.8.5) to obtain 2 2 ∂ 2 eyy ∂ 2 exy ∂2w ∂2w ∂ w ∂ 2 exx − +2 = − − ∂y 2 ∂x∂y ∂x2 ∂x2 ∂y 2 ∂x∂y ∂2W ∂2w ∂2W ∂2w ∂2W ∂2w . (4.8.6) + + − 2 ∂x2 ∂y 2 ∂y 2 ∂x2 ∂x∂y ∂x∂y Notice that the right-hand side of (4.8.6) may be written as 2 2 2
2 2 ∂ 2 (W + w) ∂ 2 (W + w) ∂ W ∂2W ∂ (W + w) ∂ W − , − − ∂X 2 ∂Y 2 ∂X∂Y ∂X 2 ∂Y 2 ∂X∂Y which is the change in the Gaussian curvature compared to that of the initial shape of the plate. The isometries of our initially curved shell are therefore those deformations that preserve the Gaussian curvature. This evidently generalises the deformation of a flat plate, which can be bent without stretching only into a surface with zero Gaussian curvature. If we denote the current shape of the shell by z = f (x, y) = W (x, y) + w(x, y)
(4.8.7)
and the initial Gaussian curvature by K0 (x, y), then, for the strain to be zero, f must satisfy the inhomogeneous Monge–Amp`ere equation 2 2 ∂ f ∂2f ∂2f − = K0 (X, Y ). (4.8.8) 2 2 ∂X ∂Y ∂X∂Y This famous nonlinear partial differential equation has the unusual property that its type is determined by the right-hand side, as shown in Exercise 4.12. If K0 = 0 then the initial shell shape is developable, so at each point it resembles a cylinder, as illustrated in Figure 4.13(a), and we recover (4.7.9), derived previously for an initially flat plate. In this case, (4.8.8) is parabolic, with one repeated set of real characteristics corresponding to the generators of the initial developable surface. This reflects the fact that the shell can be arbitrarily bent about the generators without causing any in-plane stress.
4.8 Weakly curved shell theory (a)
(b)
179 (c)
Fig. 4.13 Typical surface shapes with (a) zero, (b) negative and (c) positive Gaussian curvature.
If K0 < 0 then the initial shell shape is anticlastic, like the saddle point shown in Figure 4.13(b), and (4.8.8) is hyperbolic. Hence there are two distinct families of real characteristics and, for there to be no in-plane strain, any localised bending of the shell will cause non-local displacements in the region of influence spanned by these characteristics. Such a shell is therefore somewhat stronger than a developable surface. Finally, if K0 > 0 then the initial shell shape is synclastic, as in Figure 4.13(c), and (4.8.8) is elliptic. Such a shell will be stronger still because any local bending causes deformations throughout the entire shell.
4.8.2 Linearised equations for a weakly curved shell Having obtained expressions for the in-plane strains, let us generalise the force balances (4.6.2) and (4.6.3). As shown in Exercise 4.11, we find that the transverse displacement satisfies ∂2A ∂2f ∂2A ∂2f ∂2A ∂2f ∂2w 4 + − 2 − D∇ w − ςg = ς , ∂y 2 ∂x2 ∂x∂y ∂x∂y ∂x2 ∂y 2 ∂t2
(4.8.9)
where f is again used as shorthand for W + w. The Airy stress function is defined as usual by Eh ∂2A = Txx = (exx + νeyy ) , 2 ∂y 1 − ν2 Eh ∂2A = Txy = exy , − ∂x∂y 1+ν ∂2A Eh = Tyy = (νexx + eyy ) , 2 ∂x 1 − ν2
(4.8.10a) (4.8.10b) (4.8.10c)
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Approximate theories
with the strain components now given by (4.8.5). By eliminating the in-plane displacement (u, v) between these, we find that A now satisfies 2 2 2 2
∂2W ∂2W ∂ W ∂2f ∂2f ∂ f 4 . (4.8.11) − − + ∇ A = Eh 2 2 2 2 ∂x ∂y ∂x∂y ∂x ∂y ∂x∂y In (4.8.9) and (4.8.11) we have two equations for A and w, generalising the von K´ arm´an equations, which may be recovered by setting W ≡ 0, f ≡ w. To make the model more tractable, let us now suppose that the transverse displacement is much smaller than the initial deflection of the centre-surface, so that w W . Then, if we keep only the lowest order terms in w, (4.8.9) and (4.8.11) reduce to ∂2W ∂y 2 ∂2W ∂y 2
∂2W ∂2A ∂2W ∂2A ∂2A + − 2 = D∇4 w, ∂x2 ∂x∂y ∂x∂y ∂x2 ∂y 2 ∂2W ∂2w ∂2W ∂2w ∂2w + − 2 = −(Eh)−1 ∇4 A, ∂x2 ∂x∂y ∂x∂y ∂x2 ∂y 2
(4.8.12) (4.8.13)
where, for additional simplicity, we have also neglected the body force and time dependence. Given the initial shell profile W (x, y), we therefore have a coupled system of linear partial differential equations governing the small transverse displacement w and the Airy stress function A.
4.8.3 Solutions for a thin shell Let us consider a shell whose initial shape W (x, y) is of order W0 . We first try making the variables dimensionless in (4.8.12), (4.8.13) as follows: x = Lx ,
y = Ly ,
W = W0 W ,
w = w0 w ,
A=
Dw0 A, W0
(4.8.14)
where L is a typical lateral dimension, and w0 a typical boundary displacement. We obtain, after suppressing primes, ∂2W ∂y 2 ∂2W ∂y 2
∂2W ∂2A ∂2A ∂2W ∂2A + − 2 = ∇4 w, ∂x2 ∂x∂y ∂x∂y ∂x2 ∂y 2 ∂2W ∂2w ∂2W ∂2w ∂2w + − 2 = −δ∇4 A, ∂x2 ∂x∂y ∂x∂y ∂x2 ∂y 2
(4.8.15) (4.8.16)
where δ=
h2 . 12(1 − ν 2 )W02
(4.8.17)
4.8 Weakly curved shell theory
181
For a sufficiently thin shell, we may therefore neglect the right-hand side of (4.8.16) so that the equations decouple: given suitable boundary conditions, our strategy would be to solve ∂2W ∂2w ∂2W ∂2w ∂2W ∂2w + − 2 =0 ∂y 2 ∂x2 ∂x∂y ∂x∂y ∂x2 ∂y 2
(4.8.18)
for w and then substitute the result into (4.8.15) to obtain an equation for A. We therefore have to solve two linear second-order partial differential equations in succession, each involving the differential operator on the lefthand side of (4.8.18). It is easy to verify that the discriminant ∆ which determines the type of (4.8.18) is equal to the initial Gaussian curvature of the shell, that is 2 2 ∂2W ∂2W ∂ W − . (4.8.19) ∆ = K0 (x, y) = 2 2 ∂x ∂y ∂x∂y The problem is therefore parabolic, hyperbolic or elliptic, according to whether the shell is developable, anticlastic or synclastic. This immediately casts doubt on the model (4.8.18) for, suppose we wished to prescribe w around the perimeter of an anticlastic shell. Then (4.8.18) would present us with an ill-posed Dirichlet problem for a hyperbolic partial differential equation, and there would probably be no solution at all. On the other hand, to apply clamped boundary conditions on a synclastic shell, we would apparently need to impose both w and ∂w/∂n on a second-order elliptic equation, which again leads to an ill-posed problem. Fortunately we can understand the deficiencies in (4.8.18) when we realise from (4.8.6) that, when w is small enough for quadratic terms to be neglected, (4.8.18) is a necessary condition for there to be no in-plane stretching, i.e. only bending is allowed. Hence, if the stresses applied to the shell are violent enough to produce in-plane stretching, then we must reconsider our use of (4.8.14) to render the problem dimensionless. One possibility is to rescale A such that ˜ = δA = O (1), A
(4.8.20)
which models deformations other than pure bending which increase the inplane stress by an order of magnitude. Substituting (4.8.20) into (4.8.15) and (4.8.16) before neglecting δ, we find that the equations again decouple, ˜ now determined by with A ˜ ˜ ˜ ∂2W ∂2A ∂2W ∂2A ∂2W ∂2A + − 2 =0 ∂y 2 ∂x2 ∂x∂y ∂x∂y ∂x2 ∂y 2
(4.8.21)
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Approximate theories
and w then found from ∂2W ∂2w ∂2W ∂2w ∂2W ∂2w ˜ + − 2 = −∇4 A. ∂y 2 ∂x2 ∂x∂y ∂x∂y ∂x2 ∂y 2
(4.8.22)
Hence we again find a reduction from fourth to second order, and the types of the equations (4.8.21) and (4.8.22) are again determined by (4.8.19). Therefore, although the rescaling (4.8.20) allows us to describe in-plane stretching, it does not alter the limitations on the boundary conditions that we may be able to impose. However, any incompatibilities that may arise with the imposed boundary conditions will be resolved over narrow boundary layers, in which both stretching and bending are important. To explore the behaviour in such regions, one possibility is to rescale (x, y) as well as A, setting ˆ A = δ −1/2 A,
(x, y) = δ 1/4 (ξ, η).
(4.8.23)
Recalling that W is a prescribed function of x and y, we see that this transforms (4.8.15) and (4.8.16) into ∂2W ∂2A ∂2W ∂2A ∂2W ∂2A ˆ 4 w, + − 2 =∇ (4.8.24) ∂y 2 ∂ξ 2 ∂x∂y ∂ξ∂η ∂x2 ∂η 2 ∂2W ∂2w ∂2W ∂2w ∂2W ∂2w ˆ 4 A, + − 2 = −∇ (4.8.25) ∂y 2 ∂ξ 2 ∂x∂y ∂ξ∂η ∂x2 ∂η 2 ˆ 2 = ∂ 2 /∂ξ 2 + ∂ 2 /∂η 2 . This is effectively the full problem for w, A, where ∇ except that the coefficients are constant to lowest order on the (ξ, η)-scale. We have therefore identified the following three alternative classes of deformation that a thin shell may suffer. (i) If relatively small stresses are applied at the boundaries, then the deformation described by (4.8.18) is an isometry, and the in-plane stress that it produces may be determined a posteriori from (4.8.15). (ii) When large in-plane stresses are applied, then the bending stiffness of ˜ satisfies the decouthe shell becomes negligible in comparison, so that A pled equation (4.8.21). The in-plane stretching caused by these stresses then drives the equation (4.8.22) for the transverse displacement. (iii) Both effects of bending stiffness and in-plane stretching can balance in narrow regions of width O δ 1/4 . These regions may be close to the boundary of the shell, or they may take the form of creases that are remote from the boundary. In cases (i) or (ii), the reduction of order means that it will in general be impossible to find solutions that are everywhere compatible with any
4.8 Weakly curved shell theory
183
boundary conditions imposed on w and A. However, the full system (4.8.15), (4.8.16) is well posed given any physically reasonable boundary conditions. The full solution of the problem as δ → 0 will thus comprise regions described by (i) or (ii), patched together across narrow layers described by (iii). These creases in the shell, and the construction described above, may be visualised by simply crumpling a piece of paper: the resultant shape will consist of developable regions, which have undergone pure bending, joined together by thin creases. Some beautiful experiments illustrating the corresponding behaviour of synclastic, cylindrical and anticlastic shells are described in Vaziri & Mahadevan (2008). We will now illustrate these scenarios with some simple examples. To avoid the complication of solving a boundary-value problem each time, we will simply ask ourselves what kinds of displacements w will be possible for any prescribed shell shape W . Let us first consider deformations of the initially cylindrical shell αy 2 , 2 for which (4.8.15) and (4.8.16) become
(4.8.26)
W =
∂2w ∂2A = ∇4 w, α 2 = −δ∇4 A. (4.8.27) 2 ∂x ∂x Now, letting δ → 0, we see that w can only be a combination of two forms: α
w(x, y) = a(y)
and w(x, y) = xb(y),
(4.8.28)
where a and b are arbitrary functions. These displacement fields correspond, respectively, to the bending of the shell about its generators and to the rotation of the generators, as shown schematically in Figure 4.14(b) and (c). One can easily verify using a section cut from a cardboard tube that such deformations require very small stresses, while bending about an axis perpendicular to the generators, as in Figure 4.14(d), is much more difficult. Indeed, a uniform bending βx2 w= , (4.8.29) 2 inevitably causes a large in-plane stress, with αβy 4 + O (1), (4.8.30) 24δ corresponding to the stress field, made dimensionless with Dw0 /W0 L2 , A=−
Txx = −
αβy 2 , 2δ
Txy = 0,
Tyy = 0.
(4.8.31)
184
Approximate theories (a)
(b)
z y x (c)
(d)
Fig. 4.14 Deformations of a cylindrical shell; (a) original shape, (b) bending about the generators, (c) rotating the generators, (d) bending along the generators.
We can associate this stress in the x-direction with compression of the generators. Next, let us consider the anticlastic shell W = αxy,
(4.8.32)
depicted in Figure 4.15(a), which contains two families of straight lines x = const. and y = const. This time the governing equations (4.8.15) and (4.8.16) take the form −2α
∂2A = ∇4 w, ∂x∂y
2α
∂2w = δ∇4 A. ∂x∂y
(4.8.33)
When δ is negligible, the displacement field must be a linear combination of w(x, y) = a(x)
and w(x, y) = b(y),
(4.8.34)
where a and b are again arbitrary functions. As illustrated in Figure 4.15, these displacements correspond to bending along either of the characteristic lines x = const. or y = const., and one can try these in practice using a section cut from the neck of a plastic bottle. Large stresses result from any
4.8 Weakly curved shell theory (a)
185
(b)
z y x (c)
(d)
Fig. 4.15 Deformations of an anticlastic shell; (a) original shape, (b) bending along the lines x = const., (c) bending along the lines y = const., (d) bending along the lines x − y = const.
other transverse displacement. For example, w=
β(x + y)2 , 2
(4.8.35)
which represents bending at an angle of π/4 to the coordinate axes, as shown in Figure 4.15(d), leads to a stress function A=
αβ 4 x + y 4 + O (1). 24δ
(4.8.36)
The corresponding dimensionless stress field Txx =
αβy 2 , 2δ
Txy = 0,
Tyy =
αβx2 2δ
(4.8.37)
shows that both the normal stresses increase quadratically. due to stretching of the straight lines x = const. and y = const. respectively. Finally, let us consider the synclastic shell α x2 + y 2 W = . (4.8.38) 2
186
Approximate theories (a)
(b)
z y x (c)
(d)
Fig. 4.16 Deformations of a synclastic shell; (a) original shape, (b) and (c) two possible deformations, (d) one-dimensional bending.
As may be seen in Figure 4.16(a), there are no straight lines embedded in this surface. The governing equations (4.8.15) and (4.8.13) read α∇2 A = ∇4 w,
α∇2 w = −δ∇4 A,
(4.8.39)
so that, when δ is small, only harmonic displacement fields are possible. Some examples are 2 β x4 − 6x2 y 2 + y 4 2 , (4.8.40) w(x, y) = β x − y and w(x, y) = − 4 which are illustrated in Figure 4.16(b) and (c) respectively. In the first, the shell is bent upwards in the x-direction and downwards in the y-direction; in the second, the corners are bent upwards and the edges downwards. These can easily be realised using a segment from a ping-pong ball. On the other hand, if we perform the rescaling (4.8.20) before letting δ → 0, we find that ˜ satisfies Laplace’s equation and thus A ˜ = 0. α∇2 w = −∇4 A
(4.8.41)
Hence, any non-harmonic displacement field, for example the one-dimensional bending w = βx2 illustrated in Figure 4.16, does not just give rise to large in-plane stress but is actually impossible. If we tried to impose boundary
4.9 Nonlinear beam theory
187
conditions that force such a one-dimensional bending response, we would inevitably cause a crease to be formed. Although the above theory only applies to very small transverse displacements of shells whose built-in curvature is already small, it illustrates many of the key differences between the elastic responses of shells and plates. Any theory for more general shells demands more differential geometry than we can conveniently introduce in this chapter, and we will return to this topic in Chapter 6. We can, however, consider nearly one-dimensional elastic bodies with arbitrary curvature, and this we do in the next section.
4.9 Nonlinear beam theory 4.9.1 Derivation of the model We now return to the beam configuration considered in Section 4.4, now generalising the model to make it applicable to commonly observed phenomena such as the deflection of a diving board. Diving boards undergo large displacement without any of the damaging effects that are associated with large strains. This is possible because a thin elastic beam can be bent without significantly stretching its centre-line, as illustrated in Figure 4.17(a,b). The internal displacement field in such a beam is shown schematically in Figure 4.17(c): the net effect is to stretch the outer surface of the beam and compress the inner surface, while the length of the centre-line is virtually unchanged. It is an elementary exercise in trigonometry to show that the (a) h
(b) (c)
R
Fig. 4.17 A beam (a) before and (b) after bending; (c) a close-up of the displacement field.
188
Approximate theories
N0 (a)
(b) N (s + δs) T0
T (s + δs) T0
M (s) θ
M (s + δs) N0
T (s) N (s)
Fig. 4.18 (a) The forces and moments acting on a small segment of a beam. (b) The sign convention for the forces at the ends of the beam.
strain associated with such a displacement is of order h/R, where h is the thickness of the beam and R the radius of curvature through which it is bent. Provided the beam is sufficiently thin, it can therefore suffer large displacements while the internal strain remains small. As noted above in Section 4.8, a developable shell has the same property when bent about its generators. If the strain is small, then we can still assume that the stress is a linear function of the strain. However, when the displacement is large, linear elasticity is no longer valid: the Eulerian and Lagrangian coordinates are far from interchangeable, and it is not legitimate to linearise the relationship between strain and displacement. We therefore seek a geometrically nonlinear but mechanically linear theory, in a similar vein to the von K´ arm´an plate theory from Section 4.7. In equilibrium, it is surprisingly easy to generalise our derivation of linear beam theory in Section 4.4 to model large two-dimensional transverse displacements. We describe the deformation of the beam using arc-length s along the centre-line and the angle θ(s) between the centre-line and the x-axis. As discussed above, we assume the centre-line to be inextensible to leading order, so that arc-length is conserved by the deformation and we can thus view s as a Lagrangian coordinate that is fixed in the deforming beam. The transverse displacement is given parametrically by x = x(s), w = w(s), where dx dw = cos θ, = sin θ. (4.9.1) ds ds Now we balance forces and moments on a small segment of the beam as shown in Figure 4.18(a). We neglect inertia and body forces for the moment
4.9 Nonlinear beam theory
189
and note that N is now defined to be the normal, rather than transverse, force; since θ is no longer assumed to be small this is a significant distinction. We thus obtain the equations d (T cos θ − N sin θ) = 0, ds
d (N cos θ + T sin θ) = 0, ds
dM − N = 0, ds (4.9.2)
the first two of which simply show that the internal forces in the x- and zdirections are conserved. If a force (T0 , N0 ) is applied at the right-hand end, with an equal and opposite force at the left-hand end, as in Figure 4.18(b), it follows that T = T0 cos θ + N0 sin θ,
N = N0 cos θ − T0 sin θ.
(4.9.3)
As a constitutive relation we expect, as in Section 4.4, the bending moment to be proportional to the curvature which, for a nonlinear deflection, is given by dθ/ds. Since we are considering small strains, we assume that the constant of proportionality is the same as in the linear case, that is M = −EI
dθ . ds
(4.9.4)
By collecting (4.9.2c), (4.9.3) and (4.9.4), we obtain the Euler–Bernoulli beam equation EI
d2 θ + N0 cos θ − T0 sin θ = 0. ds2
(4.9.5)
If we are given the applied force components T0 and N0 , then we expect to impose two further boundary conditions (one at each end) on the secondorder differential equation (4.9.5). Typical examples are clamped conditions, where we specify the angle θ, or simple support, where there is zero bending moment and hence dθ/ds = 0. Suppose, instead, that we are told the positions of the ends of the beam. Without loss of generality, we can take the end s = 0 to be fixed at the origin, and denote by (X, Z) the position of the other end s = L, where L is the length of the beam. We then deduce from (4.9.1) the conditions L L cos θ(s) ds, Z= sin θ(s) ds, (4.9.6) X= 0
0
from which we can in principle recover T0 and N0 . It is reassuring to confirm that the theory above reduces to the linear beam theory derived in Section 4.4 for cases where the deflection is small.
190
Approximate theories
For small θ, we can simplify the geometric relations (4.9.1) to lowest order to give x = s,
dw = θ, dx
(4.9.7)
and (4.9.5) thus becomes d3 w dw = 0. (4.9.8) + N 0 − T0 3 dx dx One further x-derivative reproduces the linear beam equation (4.4.8) in the absence of inertia and gravity. EI
4.9.2 Example: deflection of a diving board Under a shift in the origin of θ, (4.9.5) is equivalent to theequation for a pendulum whose small-amplitude frequency of oscillation is T02 + N02 /EI. However, in (4.9.5), s is far from being a time-like variable, and the typical boundary conditions discussed above are quite different from the sort of initial conditions we would expect to apply to a pendulum. However, we can use techniques that are familiar from the study of pendulums to construct solutions of (4.9.5). Let us first consider the example, alluded to previously, of the steady deformation of a diving board, with gravity neglected for simplicity. If the board is clamped horizontally at s = 0 and a downward load F is applied to the other end, which is otherwise free, then we have T0 = 0, N0 = −F and (4.9.5) becomes d2 θ (4.9.9) EI 2 = F cos θ, ds subject to dθ (L) = 0. (4.9.10) ds Multiplying (4.9.9) through by dθ/ds and integrating once with respect to s, we obtain 2 dθ 2F (sin θ − sin α) , (4.9.11) = ds EI θ(0) = 0,
where α is shorthand for −θ(L). When taking the square root, we note that we expect dθ/ds to be negative and thus obtain the solution in parametric form as ) −θ dφ 2F √ =s . (4.9.12) EI sin α − sin φ 0
L 1
2
4.9 Nonlinear beam theory
191 x
2F/EI
3
4
5
0.2
6
0.4
0.6
0.8
1
-0.1
-0.25
1
-0.2
-0.5
-0.3
−α -0.75
w
-0.4
-0.5
-1
-0.6
-1.25
-0.7
-1.5
-0.8
L
3
2
2F/EI = 4
Fig. 4.19 (a) Final angle −α of a diving board versus applied force parameter L 2F/EI. (b) Deflection of a diving board for various values of the force parameter; the dashed lines show the linearised solution when L 2F/EI = 1 and 2.
It just remains to determine the angle α from the transcendental equation ) α dφ 2F √ =L , (4.9.13) EI sin α − sin φ 0 which can be written in terms of elliptic integrals. Given the applied force F , we have to solve (4.9.13) for α (numerically), and the deflection may then be reconstructed using (4.9.12) and (4.9.1); see Exercise 4.15. In Figure 4.19(a), we plot the final angle −α as a function of the force parameter L 2F/EI. As the applied force increases, the angle decreases, tending towards −π/2. In Figure 4.19(b), we show the diving board profile corresponding to different applied forces, and we can see clearly how the force causes the deflection to increase. For small applied forces, we would expect the linear equation (4.9.8) to be applicable. The linear model that describes our diving board is dw d3 w (0) = 0, = F, w(0) = 3 dx dx and the solution is readily found to be EI
d2 w (L) = 0, dx2
(4.9.14)
F 2 x (3L − x). (4.9.15) 6EI In Figure 4.19(b), (4.9.15) is plotted as dashed curves, and we see that there is excellent agreement with the full nonlinear model provided the deflections are reasonably small. w=−
4.9.3 Weakly nonlinear theory and buckling Now let us return to the compression of an elastic beam, which we discussed previously in the linear case in Section 4.4. We focus on the model problem of a beam of length L, clamped at both ends, subject to a compressive force
192
Approximate theories
P = −T0 and zero transverse force. We therefore have to solve the Euler strut equation P d2 θ sin θ = 0, + 2 ds EI
(4.9.16a)
subject to the boundary conditions θ (0) = θ (L) = 0.
(4.9.16b)
This is a nonlinear eigenvalue problem: θ ≡ 0 is always a possibility, and we are seeking values of the applied force P for which (4.9.16) admits nonzero solutions. Such solutions, if they exist, correspond to buckling of the beam. If θ is small, it is easy to show that (4.9.16) reduces to the linear eigenvalue problem (4.4.13) studied previously, and we can read off from (4.4.15) the solution nπs L2 P = n2 , , A sin (4.9.17) θ= L π 2 EI 0, otherwise, where n is any integer. Thus the amplitude A of the solution is zero, unless P takes one of a discrete set of critical values, in which case it is arbitrary. Hence buckling can only occur when P = n2 π 2
EI . L2
(4.9.18)
We can try to visualise this behaviour by plotting a response diagram of the magnitude of the solution θ = max |θ| = |A| 0<s
(4.9.19)
versus the control parameter λ=
L2 P . π 2 EI
(4.9.20)
The response diagram corresponding to (4.9.17) is shown in Figure 4.20(a); exactly the same diagram would have resulted had we used any other sensible norm θ instead of (4.9.19). There are several problems with the solution (4.9.17). When λ = n2 , where n is an integer, the solution is not unique, since its amplitude is indeterminate. Also, if the applied force slightly exceeds one of the critical values, we would expect on physical grounds that the buckling would continue, while
4.9 Nonlinear beam theory
(a)
|A|
193
(b)
|A| 1.4
1.2
1
0.8
0.6
0.4
0.2
5
10
15
20
2.5
λ
5
7.5
10 12.5 15 17.5 20
λ
Fig. 4.20 (a) Response diagram of the amplitude θ of the linearised solution (4.9.17) for a buckling beam versus the force parameter λ. (b) Corresponding response of the weakly nonlinear solution; the exact nonlinear solution is shown using dashed lines.
Figure 4.20(a) indicates that the solution instantly reverts to θ ≡ 0. These criticisms can be answered by noting that, if we follow one of the branches λ = n2 , then θ will eventually increase to the point where the linearisation of (4.9.16) is no longer valid. We therefore need to reintroduce the nonlinearity to resolve the behaviour when λ is close to n2 . To do this systematically requires the use of asymptotic analysis, and we must first non-dimensionalise the model. The angle θ is already dimensionless, but it is convenient to define θ = δΘ,
(4.9.21)
where Θ is order unity and δ is a small positive parameter that characterises the smallness of θ. We also set s = Lξ and thus obtain the non-dimensional model d2 Θ sin(δΘ) = 0, + π2 λ 2 dξ δ
θ (0) = θ (1) = 0,
(4.9.22)
where λ is again the dimensionless parameter defined by (4.9.20). We focus on a neighbourhood of λ = n2 by writing λ = n2 + ελ1 ,
(4.9.23)
where ε is a fixed small positive number and λ1 is a control parameter which parametrises the difference between λ and n2 . We thus have two small parameters in the problem: the amplitude δ of the solution and the deviation ε of λ from its critical value. The vital step is to find a relation between these two parameters which yields a balance
194
Approximate theories
between the compressive loading, characterised by ε, and the nonlinearity, characterised by δ, and the correct choice leads to a so-called weakly nonlinear theory. If we use the assumed smallness of δ to expand the sine in (4.9.22), we obtain the Duffing equation 3 2 d2 Θ 2 2Θ Θ − δ + · · · = 0, (4.9.24) + π + ελ n 1 dξ 2 6 and we clearly see that the required balance is obtained by choosing √ δ = ε. (4.9.25) Before doing any further calculation, we can already infer from this that the amplitude of the solution will vary as the square root of the excess loading. After making the choice (4.9.25), we write Θ as an asymptotic expansion of the form† Θ ∼ Θ0 (ξ) + εΘ1 (ξ) + · · · . (4.9.26) By substituting (4.9.26) into (4.9.24) and equating successive powers of ε, we find that d2 Θ0 + n2 π 2 Θ0 = 0, Θ0 (0) = Θ0 (1) = 0, (4.9.27a) dξ 2 3 d2 Θ1 2 2 2 2 2 Θ0 , Θ1 (0) = Θ1 (1) = 0. (4.9.27b) + n π Θ = −π λ Θ + n π 1 1 0 dξ 2 6 The general solution of (4.9.27a) is Θ0 = A0 sin (nπξ) ,
(4.9.28)
and we seem to have made very little progress from (4.9.17). However, when we examine the problem for Θ1 , we find that (4.9.27b) has no solutions unless the right-hand side satisfies a solvability condition, namely 1 3 2 Θ0 sin (nπξ) dξ = 0. (4.9.29) λ1 Θ0 − n 6 0 By substituting for Θ0 from (4.9.28), we obtain the following equation for the leading-order amplitude: 8λ1 (4.9.30) A0 A20 − 2 = 0. n When λ1 is negative, the only real solution of (4.9.30) is A0 = 0 but, for √ positive values of λ1 , there are three such solutions: A0 = 0, ±(2/n) 2λ1 . †
see Hinch (1991), for example, for the definition of an asymptotic expansion; for the purposes of this chapter, we can interpret ∼ as meaning approximates increasingly well as ε → 0
4.10 Nonlinear rod theory
(a)
(b)
A0
195
A0
stable stable
unstable
λ1
λ1
stable Fig. 4.21 (a) Pitchfork bifurcation diagram of leading-order amplitude A0 versus forcing parameter λ1 . (b) The corresponding diagram when asymmetry is introduced.
This behaviour of A0 as a function of λ1 , depicted in Figure 4.21(a), is characteristic of a so-called pitchfork bifurcation. Working backwards, we can easily turn (4.9.30) into an equation for the amplitude of θ; that is, λ 2 −1 = 0, (4.9.31) |A| |A| − 8 n2 and this weakly nonlinear response is plotted in Figure 4.20(b). This gives the physically expected result that the amplitude of each buckled solution increases with the excess applied force. We can also see how Figure 4.20(a) approximates this response for very small |A|. For comparison, we also show the response of the full nonlinear solution of (4.9.16); see Exercise 4.18. We can use the argument after (4.4.18) to show that the solution θ = 0 is stable for λ1 < 0 but loses stability to the nonzero solution as λ1 crosses zero. This justifies the labelling in Figure 4.21(a) and can also be explained on the basis of an energy argument, as in Exercise 4.14. Another key ingredient of bifurcation pictures like Figure 4.21(a) is the symmetry that we have assumed in our strut model. Any imperfection or asymmetry in the model would deform the response diagram into something like Figure 4.21(b), in which there is a smooth dependence of the solution on the control parameter. This is exemplified by the re-introduction of gravity in the model as in Exercise 4.16. 4.10 Nonlinear rod theory We are now in a position to generalise and combine the linear rod theory of Section 4.5 with the nonlinear beam theory of Section 4.9 to derive a model for the equilibrium of a rod that can both twist about its tangent vector
196
Approximate theories
and bend in two perpendicular directions. We let F and M denote the force and moment exerted on any cross-section s = const. of the rod, s being arc-length along the centre-line. As in Section 4.9, we will assume that the rod is inextensible so that s is effectively a Lagrangian variable. Neglecting body forces for simplicity, a force balance gives dF = 0, ds
so that
F = F 0 = const..
(4.10.1)
This equation generalises the first two equations of (4.9.2). Also, if r(s) parametrises the centre-line of the rod, then a moment balance analogous to the final equation of (4.9.2) gives dr dM + ×F = 0, so that M + r×F 0 = M 0 = const.. (4.10.2) ds ds The equations (4.10.1), (4.10.2) for the vectors F , M and r now need to be closed by a constitutive law for M , and this is what poses the most interesting modelling challenge. Instead of adopting the usual differential geometry definition of curvature, we consider what happens to a Lagrangian orthonormal system ei (s) (i = 1, 2, 3) as the rod deforms. This system is fixed in the rod and we choose e1 (s) =
dr , ds
(4.10.3)
with e2 and e3 defining the normal plane. At different s-stations, this system will have rotated by different amounts, and we infer that there exists a vector Ω(s) such that dei = Ω(s)×ei (s). ds
(4.10.4)
Thinking of s as time for the moment, the vector Ω = (Ω1 , Ω2 , Ω3 )T represents the “angular velocity” of the orthonormal system {e1 , e2 , e3 }, with Ω1 corresponding to twisting of the rod about its axis and Ω2 , Ω3 to bending. This leads us to propose a linear constitutive relation between M and Ω, so that M = BΩ
(4.10.5)
for some 3 × 3 matrix B, whose elements we will choose to ensure that (4.10.5) agrees with (4.5.5), (4.5.9) and (4.9.4) in the appropriate limits. T In linear rod theory, we write r = x, v(x), w(x) , where x = s to lowest order. When we neglect quadratic terms, the orthonormal vectors ei may be
4.10 Nonlinear rod theory
written in the form dv dw T , , e1 = 1, dx dx
e2 =
−
dv , 1, θ dx
197
T ,
e3 =
T dw , −θ, 1 − , dx (4.10.6)
where θ measures the twist of the rod about the x-axis. It is easy to check that these are consistent with (4.10.4) and correspond to T dθ d2 w d2 v Ω= ,− 2 , 2 . (4.10.7) dx dx dx Now we see that we can reproduce (4.5.5) and (4.5.9) by choosing R 0 0 B = 0 EIyy −EIyz , (4.10.8) 0 −EIyz EIzz in the notation of Section 4.5. T To retrieve nonlinear beam theory, we write r = x(s), 0, w(s) , so that cos θ 0 − sin θ e1 = 0 , e2 = 1 , e1 = 0 , (4.10.9) sin θ 0 cos θ and we easily find that
T dθ . Ω = 0, , 0 ds
(4.10.10)
Provided the beam is symmetric so that Iyz = 0, (4.10.5) with B given by (4.10.8) thus reduces to the constitutive relation (4.9.4) for a nonlinear beam. The relations (4.10.1)–(4.10.5) comprise a formidable system of 15 equations for F , M , r, ei and Ω. Fortunately, there is a wonderful analogy that relieves us of the task of discussing the behaviour of this system. Consider a rigid body rotating about a fixed origin 0 such that one principal axis e1 at 0 passes through the centre of gravity which is a distance h from 0. The equations of motion for such a body are dei dH H = Iω, (4.10.11) = ω×ei , = he1 ×W , dt dt where ω is the angular velocity, e2 , e3 are the other principal axes, H is the angular momentum, W is the weight and I the inertia tensor. When we identify ω with Ω, H with M , hW with F and, crucially, s with t, these equations are simply (4.10.4), (4.10.2) and (4.10.5). Hence our knowledge
198
Approximate theories
about spinning tops, gyroscopes and “inertia coupling” in classical mechanics can be used to explain the often infuriating coupling between torsion and bending that is only too familiar to those who have to wind cables and garden hoses. This Kirchhoff analogy disappears when we consider the dynamics of a rod subject to a body force g, the model for which is precisely as above with d/ds replaced by ∂/∂s and (4.10.1) replaced by ρ
∂F ∂2r . = ρg + 2 ∂t ∂s
(4.10.12)
4.11 Geometrically nonlinear wave propagation When we include nonlinear effects in models for elastic wave propagation, we will rarely be able to find explicit solutions. Hence, in this section, we will simply describe a few nonlinear models that are relatively easy to derive and posess interesting exact solutions. 4.11.1 Gravity-torsional waves Our first example of nonlinear wave propagation is a generalisation to include gravity in the model (4.5.8) for torsional waves in a rod. In particular, we will try to model the waves that can propagate when a series of rigid pendulums is attached to a rod which is stiff but has negligible mass. In practice, such a configuration can be realised by attaching paper clips to a taut segment of a rubber band, as shown in Figure 4.22, where the paper clips are drawn as pendulums.† To model this situation, we suppose that each pendulum is acted upon by a moment δM at its point of support. A net moment balance, as illustrated in Figure 4.22(b), leads to ∂2θ , (4.11.1) ∂t2 where θ(x, t) is the angle between the pendulum and the downward vertical while m and are the mass and length of the pendulum respectively. Now we identify the moment δM with b∂M/∂x, where b is the spacing between the pendulums and ∂M/∂x is given by the constitutive relation (4.5.9). We therefore find that θ satisfies ∂2θ ∂2θ (4.11.2) bR 2 = mg sin θ + m2 2 , ∂x ∂t δM = mg sin θ + m2
†
We are grateful to the late Prof. T. Brooke Benjamin for drawing this experiment to our attention.
4.11 Geometrically nonlinear wave propagation
199
(a) b
(b) z δM
z
y y
θ
x mg Fig. 4.22 (a) A system of pendulums attached to a twisting rubber band. (b) Transverse view defining the angle θ(x, t).
which can easily be rescaled to the sine–Gordon equation ∂2θ ∂2θ − + sin θ = 0. (4.11.3) ∂t2 ∂x2 This is one of the most famous completely integrable nonlinear partial differential equations.This means that it can be solved explicitly for any given initial data on −∞ < x < ∞ by using inverse scattering theory; see for instance Drazin & Johnson (1989). Moreover, localised travelling waves exist that exhibit strong stability properties; even though their speed depends on their amplitude, they can pass through each other virtually unscathed. Such localised waves are called solitons and, for (4.11.3), we can find them by setting θ to be a function only of η = x − vt, where the wave speed v is constant. Then (4.11.3) is reduced to the nonlinear ordinary differential equation d2 θ 2 + sin θ = 0. (4.11.4) v −1 dη 2 If we seek an isolated soliton solution, in which θ → const. as η → ±∞, then the only possible solutions of (4.11.4) are η − η0 −1 √ when |v| > 1 (4.11.5) tanh θ = 4 tan 2 v2 − 1 or η0 − η when |v| < 1. (4.11.6) θ = 4 tan−1 exp √ 1 − v2 Since (4.11.5) approaches the unstable solutions θ = ±π, in which the paper clips are upright, as η → ±∞, it is not physically realisable and only
200
Approximate theories
t=0 z
t=1
t=2
x y
Fig. 4.23 A kink propagating along a series of pendulums attached to a rod.
the subsonic waves (4.11.6) can be observed in practice. In these so-called kink solutions, the rod undergoes one complete twist, with θ = 0 ahead of the wave (η → +∞) and θ = 2π behind (η → −∞), as shown in Figure 4.23. They can easily be realised in the system illustrated in Figure 4.22 by holding the rubber band tight and horizontal, with all the paper clips dangling vertically, and then quickly twisting one end through 2π. 4.11.2 Travelling waves on a beam Our second example concerns the unsteady generalisation of the geometrically nonlinear beam theory derived in Section 4.9. The displacement of the beam is now given parametrically by x = x(s, t), w = w(x, t), where, as in (4.9.1), ∂w ∂x = cos θ, = sin θ, (4.11.7) ∂s ∂s and θ(s, t) is the angle made by the beam with the x-axis. When we include acceleration, the force balances (4.9.2) become ∂ ∂2x (T cos θ − N sin θ) = 2 , ∂s ∂t
∂2w ∂ (N cos θ + T sin θ) = 2 , (4.11.8) ∂s ∂t
where N = −EI
∂2θ . ∂s2
(4.11.9)
Although this is a more complicated model than (4.11.3), we can still seek a travelling wave solution in which x, w, T , N and θ are functions only of η = s − vt. We also postulate the boundary conditions T → T∞ ,
N → 0,
θ → 0,
x ∼ s,
w→0
as
s → ∞, (4.11.10)
which would apply, for example, to a long taut rope that had been shaken briefly at one end. As in Section 4.11.1, by looking for a travelling wave, we reduce (4.11.8) to nonlinear ordinary differential equations, which may be
4.11 Geometrically nonlinear wave propagation
w -2
-1
1
2
201
x
-0.5
-1
-1.5
-2
v Fig. 4.24 Travelling wave solution of the nonlinear beam equations (with k = 1).
integrated to obtain T cos θ − N sin θ = v 2 (cos θ − 1) + T∞ ,
T sin θ + N cos θ = v 2 sin θ. (4.11.11)
Hence the tension and shear force are given by N = v 2 − T∞ sin θ, T = v 2 + T∞ − v 2 cos θ,
(4.11.12)
and (4.11.9) therefore becomes EI d2 θ 2 + M − 1 sin θ = 0, 2 T∞ dη
(4.11.13)
where M = |v| /T∞ . We recall from Chapter 3 that T∞ / is the phase velocity of small-amplitude transverse waves on a string, and M is the Mach number of the wave. By analogy with (4.11.4), we see that, as long as M < 1, there is a solution connecting θ → 0 as η → +∞ to θ → 2π as η → −∞, namely ) T∞ −1 k(η 0 −η) (1 − M 2 ), θ = 4 tan (4.11.14) e , where k = EI where the constant η0 represents an arbitrary translation. With θ given by (4.11.14), we can integrate (4.11.7) to obtain the parametric description 1 ξ − 2 tanh ξ x = (4.11.15) w −2 sech ξ k for the shape of the rope, where ξ = k(η − η0 ). As shown in Figure 4.24, this represents a single loop, in which the rope turns through 2π, propagating at speed v which depends, through (4.11.14), on the amplitude. The multivaluedness of w(x) is only physically realistic if the rope is allowed to deform slightly out of the (x, z)-plane.
202
Approximate theories
4.11.3 Weakly nonlinear waves on a beam If we wish to analyse general unsteady deformations of a beam, we appear to be confronted with the full system (4.11.7)–(4.11.9) of nonlinear equations for x, w, T , N and θ. However, we will now show that, when the solution is close to a travelling wave, we can obtain a single partial differential equation incorporating all the ingredients of unsteadiness, dispersion and nonlinearity. Moreover, it will transpire that this equation is closely related to one of the most famous of all soliton equations. We observe that (4.11.13) is degenerate when EI = 0 and M 2 = 1: when the beam has zero bending stiffness, θ can be an arbitrary function of s − ct. This motivates us to seek a “distinguished limit” in which the bending stiffness is small but nonzero and the wave is approximately moving at speed c = T∞ / , where T∞ is the tension applied at infinity as before. To analyse this limit, our first step is to express the equations in a moving reference frame, by transforming from (s, t) to (ζ, t), where ζ = s − ct, so that (4.11.7)–(4.11.9) become ∂2θ , ∂ζ 2 2 ∂ ∂ x ∂2x , − 2c (T − T∞ ) cos θ − N sin θ = ∂ζ ∂t2 ∂ζ∂t 2 ∂ ∂ w ∂2w . − 2c N cos θ + (T − T∞ ) sin θ = ∂ζ ∂t2 ∂ζ∂t ∂x = cos θ, ∂ζ
∂w = sin θ, ∂ζ
N = −EI
(4.11.16) (4.11.17) (4.11.18)
Now we have to non-dimensionalise the equations before we can take a systematic asymptotic limit. We denote by a typical amplitude of the wave and obtain a suitable scaling for N from (4.11.16). The relevant time-scale is then found by balancing the final term in (4.11.17) with the normal stress on the left-hand side. We thus define the dimensionless variables as x X w = W , ζ ξ
T = T∞ T ,
N=
EI 2
N,
t=
2c 3 EI
τ,
(4.11.19) so that (4.11.16)–(4.11.18) become ∂X = cos θ, ∂ξ
∂W = sin θ, ∂ξ
(4.11.20)
4.11 Geometrically nonlinear wave propagation
N =−
∂2θ
, ∂ξ 2 ε2 ∂ 2 X ∂ ∂2X , − ε (T − 1) cos θ − εN sin θ = ∂ξ 4 ∂τ 2 ∂ξ∂τ ε2 ∂ 2 W ∂ ∂2W εN cos θ + (T − 1) sin θ = , − ε ∂ξ 4 ∂τ 2 ∂ξ∂τ
203
(4.11.21) (4.11.22) (4.11.23)
where the only remaining dimensionless parameter in the problem is ε=
EI . T∞ 2
(4.11.24)
We suppose, as in Section 4.11.2, that the beam is held straight and horizontal, under a uniform tension at infinity, so that T → 1,
N → 0,
θ → 0,
X ∼ ξ,
W →0
as
ξ → ∞. (4.11.25)
Now we take the limit ε → 0, which corresponds to the bending stiffness of the beam being small. When ε = 0, (4.11.22) and (4.11.23) are satisfied identically by T = 1, and this motivates the ansatz T ∼ 1 + εT1 + · · · .
(4.11.26)
When we substitute (4.11.26) into (4.11.22) and (4.11.23) and let ε → 0, we find that the leading-order equations may be integrated once with respect to ξ, using the boundary conditions (4.11.25), to obtain T1 cos θ − N sin θ +
∂X = 0, ∂τ
T1 sin θ + N cos θ +
∂W = 0. ∂τ
(4.11.27)
We solve these simultaneously for T1 and N and substitute into (4.11.21) to obtain ∂W ∂ 2 θ ∂X sin θ − cos θ = 0, + 2 ∂ξ ∂τ ∂τ
(4.11.28)
which is to be solved along with (4.11.20) for θ(ξ, τ ), X(ξ, τ ) and W (ξ, τ ). A remarkable first integration is now possible which allows us to eliminate X and W to obtain a single equation for θ. When we multiply (4.11.28) by ∂θ/∂ξ we discover by virtue of (4.11.20) that it may be integrated with respect to ξ, leading, from (4.11.25), to ∂W 1 ∂X cos θ + sin θ = ∂τ ∂τ 2
∂θ ∂ξ
2 .
(4.11.29)
204
Approximate theories
On the other hand, if we instead differentiate (4.11.28) with respect to ξ, again using (4.11.20), we find that ∂W ∂θ ∂ 3 θ ∂θ ∂X (4.11.30) cos θ + sin θ = − 3. ∂ξ ∂τ ∂τ ∂τ ∂ξ Finally, comparing (4.11.29) and (4.11.30), we obtain ∂θ 1 ∂θ 3 ∂ 3 θ − − 3 = 0. (4.11.31) ∂τ 2 ∂ξ ∂ξ If we differentiate (4.11.31) with respect to ξ, we find that the equation satisfied by ∂θ/∂ξ is a version of the modified KdV equation, which can itself be transformed into the celebrated KdV equation (see Exercise 4.20). The KdV equation was originally used to model large-amplitude water waves, and its study provided a key stimulus for the theory of solitons. By reversing the scalings (4.11.19), we obtain the dimensional version of (4.11.31), namely 1 ∂θ 3 ∂ 3 θ 2T∞ 1 ∂θ ∂θ + − − 3 = 0. (4.11.32) EI c ∂t ∂s 2 ∂s ∂s Now if we seek a travelling wave, in which θ is again a function only of η = s − V t, then we obtain the ordinary differential equation dθ d3 θ 1 dθ 3 2T∞ (1 − M ) = 0, (4.11.33) + − 3 dη 2 dη EI dη where M = V /c again. As shown in Exercise 4.21, the solution of this equation satisfying θ → 0 as η → +∞ and θ → 2π as η → −∞ is ) 2T∞ (1 − M ) −1 κ(η 0 −η) . (4.11.34) e , where κ = θ = 4 tan EI We thus reproduce the travelling wave solution (4.11.14) found previously, noting that κ is the leading-order approximation to k as M → 1. 4.12 Concluding remarks In this chapter, we have emphasised phenomena that can occur when there is some strong geometric constraint of “thinness”, and hence the possibility of geometric nonlinearity. However, what is more remarkable than the phenomena themselves is the mathematical challenge posed by passing from a fully three-dimensional model to simpler models for nearly one- or twodimensional solids. This challenge is exemplified by the fact that, although (4.3.2) is an apparently “physically obvious” paradigm for linear wave propagation, we will see in Chapter 6 that it can only be derived systematically
Exercises
205
from the equations of nonlinear three-dimensional elasticity. Similarly, our model (4.9.2) for beams relied on the “physically obvious” assumption that the centre line was inextensible, which it clearly could not be were Young’s modulus sufficiently small; equally (4.3.2) implicitly relied on the string being extensible, yet no mention was made of Young’s modulus. Geometric nonlinearity and inextensibility are both concepts that can be properly understood only by a more thorough mathematical approach, which we will present in Chapters 5 and 6. Finally, we note that there is another class of problems where the geometry suggests that a mathematical simplification may be possible. This is when the elastic body contains a thin void, rather than itself being thin. We will discuss such geometries in Chapter 7 and use them to model cracks and contact problems between elastic bodies that are pressed together.
Exercises 4.1
Show that the natural frequencies of a piano string of length L, simply supported at either end, with line density , tension T and sufficiently small bending stiffness EI are, approximately, * n3 π 3 EI nπ T + 3√ . ωn ∼ L L T
4.2
A beam of length L is simply supported at its two ends x = 0 and x = L and subject to zero tensile force. Show that its displacement as it sags under gravity is given by g x(L − x) L2 + Lx − x2 w=− 24EI
4.3
and deduce that the maximum transverse deflection is 5 g/384EI. Justify the following model for the lateral displacement w(x) of a strut of length L, clamped at its two ends and compressed by a force P : P dw d3 w = 0, + dx3 EI dx
4.4
w(0) =
dw (0) = 0, dx
w(L) =
dw (L) = 0. dx
Find the minimum force P required for w to be nonzero. Why is this value different from that found in Section 4.10? Consider a beam of length L, clamped at a distance < L from the edge of a horizontal table, with a weight F hung from the other end, as shown in Figure 4.25. Assuming that the weight of the beam itself
206
Approximate theories
z
R
111111111 000000000 000000000 111111111 000000000 111111111 000000000 111111111
x
F Fig. 4.25 A beam clamped near the edge of a table.
is negligible compared with F and that the transverse displacement w(x) is small, justify the following model: d4 w R δ(x − ), = dx4 EI d2 w (L) = 0, dx2
dw (0) = 0, dx d3 w F (L) = , dx3 EI
w(0) =
where δ is the Dirac delta-function and the reaction force R is to be determined from the contact condition w() = 0. Show that the reaction force is given by R = (3L − )F/2 and that the displacement is x < , 6(L − )x2 ( − x), F w(x) = # $ 2 24EI ( − x) 3(L − )(3L − )−(2x − 3L + ) , x > .
4.5
Find the maximum magnitude of the slope |dw/dx| and deduce that these results are valid provided F L(L − )/EI 1. Consider a beam of length L that is simply supported at two points and allowed to sag under its own weight, as shown in Figure 4.26. The supports are assumed to be a distance < L apart and to be symmetric about the middle of the beam. Derive the following dimensionless model for the vertical displacement w(x) of the beam: d4 w = Rδ(x − β), dx4 d3 w dw d2 w d3 w (0) = (0) = (1/2) = (1/2) = w(β/2) = 0, dx dx3 dx2 dx3 where β = /L and δ is the Dirac delta-function. Show that the dimensionless reaction force R is equal to 1/2 and
Exercises
g
207
z x L
Fig. 4.26 A beam supported at two points.
4.6
explain this result physically. Solve for w(x) and plot the solution as β is varied. Show that, if β is small, then the beam sags down at its ends and goes up in the middle while, if β is close to 1, then it sags down in the middle and its ends move upwards. Explore how the behaviour varies between these two limits. Longitudinal waves in a bar of section A, Young’s modulus E and length L are modelled by (4.2.4). The bar is initially unstressed and at rest. The ends x = 0 and x = L are stress-free except for an impulsive compressive force J applied at x = 0 for 0 < t < T , where T < L/c. Show that 1, x − ct < −cT, u ct − x = , −cT < x − ct < 0, U cT 0, 0 < x − ct, for 0 < t < L/c, where the maximum displacement at x = 0 is given by U = JcT /EA. Show that an incident wave u = f (x − ct) impinging on the stressfree boundary at x = L gives rise to a reflected wave f (2L − x − ct). Deduce that, as T → 0 with U kept fixed, the resulting displacement after the first reflection from x = L is u = U H(ct − x) + H(x + ct − 2L) ,
4.7
where H is the Heaviside function defined in (3.5.7). Hence show that the compressive incident wave reflects as a tensile wave. [This is the basis of the Hopkinson bar test; the fracture strength of a metal bar is determined by the impulse that must be applied for a piece to be ejected from x = L.] An elastic beam of bending stiffness EI and line density is subject to a large compressive force P . Using the approach of Section 4.4.4,
208
4.8
Approximate theories
show that the most unstable waves have wave-length 2π 2EI/P √ and grow over a time-scale t ∼ EI/P . Suppose a strand of uncooked spaghetti is held vertically while a 1 kg weight is placed on the upper end. Explain why it will shatter into fragments roughly 1 cm long. [Typical parameter values for spaghetti are ≈ 2 × 10−3 kg m−1 , EI ≈ 1.5 × 10−4 N m2 .] Writing (nx , ny ) = (sin θ, − cos θ), show that Msn , as given by (4.6.16) and (4.6.8), may be written as ∂2w Eh3 2(1 − ν) sin θ cos θ Msn = 12 (1 − ν 2 ) ∂x∂y 2 2 2 ∂ w ∂ w ∂2w ∂ w 2 2 cos θ . + ν 2 sin θ − ν 2 + − ∂x2 ∂y ∂x ∂y 2 Now use the chain rules cos θ ∂ ∂ ∂ = + sin θ , ∂x 1 + κn ∂s ∂n
∂ sin θ ∂ ∂ = − cos θ , ∂y 1 + κn ∂s ∂n
where the curvature of the boundary is κ = dθ/ds, to show that 2 ∂2w ∂ w Eh3 ∂w Msn = − +ν 2 . + νκ 12 (1 − ν 2 ) ∂n2 ∂n ∂s
4.9
Hence obtain the conditions (4.6.17) that apply on a simply supported boundary. Show that the steady sag of a cylindrically symmetric plate with non-uniform bending stiffness D(r) is governed by the equation 2 d w d d2 w 1 dw ςgr2 dw dD r 2 +ν + Dr = − . (E4.1) + dr dr dr dr dr2 r dr 2 For the special case in which we wish w to be given by
2 7+ν 2 2 12a4 2 2 r − a , + w =− a −r 1+ν (1 + ν)2 show that the only solution D(r) of (E4.1) that is bounded as r → a is D=
(1 + ν)ςg . 24(7 − ν) (5 + ν)a2 − (1 + ν)r2
Exercises
4.10
209
Show that, when w is changed to w + η, where |η| |w|, the change in the net strain energy given by (4.6.23) is
∇2 w ∇2 η Ω 2 ∂2w ∂2η ∂ w ∂2η ∂2w ∂2η + − 2 dxdy, − (1 − ν) ∂x2 ∂y 2 ∂y 2 ∂x2 ∂x∂y ∂x∂y
δU = D
and show this can be written as δU = D η∇4 w + div ∇2 w∇η − η∇(∇2 w) Ω
∂ 2 w ∂η ∂ 2 w ∂η ∂ 2 w ∂η ∂ 2 w ∂η − (1 − ν) div − , − ∂y 2 ∂x ∂x∂y ∂y ∂x2 ∂y ∂x∂y ∂x
T
dxdy.
Deduce that ∇4 w = 0 when U is minimised with respect to variations in w. Show that, when Ω is the half-space x > 0 and all variables are assumed to decay at infinity, 3 ∞ ∂η ∂ 2 w ∂ w ∂2w ∂3w dy = 0. +ν 2 −η + (2 − ν) ∂x2 ∂y ∂x3 ∂x∂y 2 −∞ ∂x
4.11
Deduce that (4.6.19) are the natural boundary conditions for the minimisation. Suppose the centre-surface of a weakly-curved shell, initially given by z = W (x, y), undergoes a transverse displacement w(x, y), so that it is deformed to z = f (x, y) = W (x, y) + w(x, y). Following the approach adopted in Section 4.6.1, show that the transverse displacement and in-plane stress resultants satisfy Txx
4.12
∂2w ∂2f ∂2f ∂2f 4 + T + 2T − D∇ w − ςg = ς , xy yy ∂x2 ∂x∂y ∂y 2 ∂t2 ∂Txy ∂Txy ∂Tyy ∂Txx + = + = 0, ∂x ∂y ∂x ∂y
where the surface density ς is assumed to be constant. By differentiating (4.8.8) successively with respect to x and y, show that it can be transformed into the quasi-linear system ∂ p −2s 0 ∂ p ∂K0 /∂x q p + = , q p ∂y q ∂K0 /∂y 0 −2s ∂x q
210
Approximate theories
where p = ∂ 2 f /∂x2 , q = ∂ 2 f /∂y 2 and s = ∂ 2 f /∂x∂y. Hence show that the characteristics are given by −s ± s2 − pq dy = , dx q 4.13
and deduce that the system is hyperbolic if and only if K0 is negative. Consider a thin two-dimensional elastic beam, with bending stiffness EI, subject to a body force − gk per unit length. Suppose the centre-line of the beam makes an angle θ(s) with the x-axis, where s is arc-length. Derive the following equations for θ, the tension T and the shear force N in the beam: d (T cos θ − N sin θ) = 0, ds EI
d (T sin θ + N cos θ) = g, ds d2 θ = N. ds2
Consider the special case of a string of length L with zero bending stiffness, sagging under gravity and pinned at (x, w) = (0, 0) and (x, w) = (d, 0). Show that 2s , tan θ(s) = tan θ0 1 − L where θ0 is the angle made by the string with the horizontal line at s = 0. Show further that 2x − d tan θ0 = sinh−1 (tan θ) , L and deduce an equation for tan θ0 . Finally, show that the string is a catenary, given by L 2x − d d w= tan θ0 − cosh tan θ0 cosh . 2 tan θ0 L L 4.14
Use the calculus of variations to show that minimisation of the functional
L EI dθ 2 − (1 − cos θ)P ds, U [θ] = 2 ds 0 subject to the boundary conditions θ(0) = θ(L) = 0, leads to the Euler strut equation (4.9.16a). Give physical interpretations of the terms in the integrand.
Exercises
211
Show that the value of U [θ] corresponding to the solution (4.9.17) is approximately U [θ] ≈
4.15
π 2 EIA2 2 n −λ , 4L
where λ = L2 P/π 2 EI. Deduce that θ = 0 is a local minimiser of U , and hence stable, only if λ < 1. Derive the following model for the deflection θ(s) of a diving board clamped horizontally at one end while a downward force F is applied on the other: d2 θ dθ F cos θ, θ(0) = 0, (L) = 0. = 2 ds EI ds Non-dimensionalise the problem and show that it depends on a single dimensionless parameter ε = F L2 /EI. Show that, when ε is small, the solution may be approximated asymptotically by 2 ξ θ ∼ − ξ + ε2 Θ1 + O ε4 , ε 2 where ξ = s/L, and Θ1 (ξ) is to be found. Hence find and plot the leading-order shape of the board. If ε is not assumed to be small, show that θ is related to ξ by −θ √ dφ √ = ξ 2ε, sin α − sin φ 0 where α is to be determined from α √ dφ √ = 2ε. sin α − sin φ 0 Deduce that the dimensionless shape of the board is given parametrically by x = x(θ), y = y(θ), where ) √ 2 √ sin α − sin α + sin θ , x(θ) = ε −θ 1 sin φ dφ √ , y(θ) = − √ sin α − sin φ 2ε 0
4.16
and θ varies between −α and 0. Hence plot the shape of the board for various values of ε. Compare these exact solutions with the small-ε approximation. Consider a beam of length L and mass per unit length, clamped horizontally at each end and sagging under gravity. If a horizontal
212
Approximate theories
compressive force P and equal vertical forces are applied at either end, derive the boundary conditions gL , θ(0) = θ(L) = 0, T (0) = T (L) = −P, −N (0) = N (L) = 2 and deduce that the Euler strut equation (4.9.16) becomes, d2 θ L EI 2 + P sin θ + g s − cos θ = 0. ds 2
4.17
By following the non-dimensionalisation of Section 4.9.3 and assuming that gL3 β= = O ε3/2 , EI show that the orthogonality condition (4.9.30) becomes nπ 16β 8λ1 2 . A0 A0 − 2 = − 3/2 2 2 cos2 n 2 ε n π For n = 2, draw the resulting response diagram and compare it with the case β = 0. Show that the beam can buckle upwards only if λ 4 + 3β 3/2 /2π 2 . A beam of length L and line density is clamped vertically upwards at one end (s = 0) and free at the other (s = L). Show that the shear force in the beam is N = g(s − L) cos θ and hence obtain the model dθ d2 θ EI (s − L) cos θ = 0, θ(0) = π/2, (L) = 0. + 2 ds g ds Now suppose the beam is only slightly perturbed from the vertical, so that θ = π/2 + φ, where |φ| 1. Defining g 1/3 g 1/3 , β=L , ξ = (s − L) EI EI show that φ satisfies Airy’s equation d2 φ − ξφ = 0. dξ 2 The solutions of Airy’s equation with zero slope at ξ = 0 are √ φ=a 3 Ai(ξ) + Bi(ξ) , where Ai and Bi are Airy functions (Abramowitz & Stegun, 1972, Section 10.4) and a is an arbitrary constant. Deduce that, for nontrivial solutions, β must satisfy √ 3 Ai(−β) + Bi(−β) = 0,
Exercises
2
z 1
213
3
n=1
0.8
0.6
0.4
0.2
0.05 0.1 0.15 0.2 0.25 0.3
x
Fig. 4.27 The first three buckling modes of a vertically clamped beam.
4.18
and show (numerically) that the minimum value of β satisfying this condition is βc ≈ 1.986. Thus find the maximum height of a column (or a rebellious hair) before it buckles under its own weight. [See Figure 4.27 for a plot of the first three buckling modes.] Show that the exact solution of the buckling problem (4.9.16) satisfies −1/2 θ ˆ √ sin2 (θ/2) 2πs 1− dθˆ = λ sin( θ /2) 2 L sin ( θ /2) 0 and deduce that the nth branch of the response diagram is given implicitly by λ=
4.19
2 4n2 2 K sin ( θ /2) , 2 π
where K denotes an elliptic integral (Gradshteyn & Ryzhik, 1994, Section 8.1). An infinite beam initially lying at rest along the x-axis is subject to a transverse point force F (t) acting at the origin. Derive the model ∂2w ∂4w + F (t)δ(x) = , ∂x4 ∂t2 ∂w (x, 0) = 0, w(x, 0) = ∂t
−EI
w→0
as
x → ±∞
and, for example by taking a Fourier transform in x, show that the
214
Approximate theories
displacement of the origin is related to the applied force by t √ 1 F (τ ) t − τ dτ. w(0, t) = √ 2π (EI 3 )1/4 0 If the origin is forced to move at speed V , so w(0, t) = V t, show that the required force is ) 2 3 1/4 . F (t) = 2V EI πt
4.20
[This is a simple model for the action of a lawn-mower blade on a grass stalk, or of a razor blade on a bristle.] Start from the equation (4.11.31) for weakly nonlinear waves on a beam. If ∂θ/∂ξ = 2u(z, τ ), where z = −ξ, show that u satisfies the modified KdV (mKdV) equation ∂u ∂ 3 u ∂u + 6u2 + 3 = 0. ∂τ ∂z ∂z Show that the Miura transform ∂u ∂z converts the mKdV equation into the Korteweg–de Vries (KdV) equation ∂v ∂ 3 v ∂v + 6v + = 0. ∂τ ∂z ∂z 3 v(ζ, τ ) = u2 − i
4.21
By multiplying (4.11.33) by d2 θ/dη 2 , obtain the first integral 2 2 2 dθ 1 dθ 4 d θ 2 + −κ = 0, 2 dη 4 dη dη where
) κ=
2T∞ (1 − M ) . EI
By using the substitution dθ = ±2κ sech φ(η) , dη or otherwise, obtain the general solution θ = const. ± 4 tan−1 eκ(η0 −η) .
5 Nonlinear elasticity
5.1 Introduction In Chapters 2 and 3, we have analysed solutions of the steady and unsteady Navier equations, which were derived in Chapter 1 under the two assumptions that underpin linear elasticity. First, we assumed that we could discard the nonlinear terms in the relation (1.4.5) between strain and displacement. Geometrically nonlinear elasticity concerns large deformations in which these terms are not negligible, so the strain is a nonlinear function of the displacement gradients. This inevitably leads to the further complication that the Lagrangian and Eulerian variables may no longer be approximated as equal. The second assumption behind linear elasticity is that the stress is a linear function of the strain. This is a reasonable approximation for small strains, but it does not work well for materials such as rubber, which can suffer large strain and still remain elastic (see Treloar, 2005). Models for such materials require mechanically nonlinear elasticity, in which the stress is a nonlinear function of the strain. As indicated in Section 1.6, the fundamental difficulty to be confronted is that the balance of stresses is performed in the deformed state, while the constitutive relation must be imposed relative to the reference configuration. As a first step in addressing this difficulty, we will revisit the concepts of stress and strain. We will show how they may both be expressed in a Lagrangian frame of reference, allowing a self-consistent constitutive law to be imposed between them. For mechanically nonlinear materials, such laws are far less easy to specify than (1.7.6), and we will see that great care has to be taken to avoid models that allow unphysical behaviour. Finally we will show how the nonlinear theory, be it mechanical or geometric or both, can be greatly simplified for hyperelastic materials for which the stress is related to 215
216
Nonlinear elasticity
the strain via the partial derivatives of an appropriate strain energy density, thereby generalising (1.9.4).
5.2 Stress and strain revisited 5.2.1 Deformation and strain We begin by recalling the analysis of strain from Section 1.4, using the same notation that a particle at position X in the undeformed reference state is displaced to a new position x(X) in the deformed state. Recall that X and x are referred to as Lagrangian and Eulerian variables respectively. An infinitesimal line element dX is transformed to dx under the deformation, and these are related by the chain rule dxi = Fij dXj ,
(5.2.1)
where the deformation gradient tensor is defined by F = (Fij ) = (∂xi /∂Xj ) .
(5.2.2)
The change in the length of the small element dX is thus given by |dx|2 = dX T C dX,
(5.2.3)
C = F T F,
(5.2.4)
where and C, which will shortly be shown to be a tensor, is called the Green deformation tensor. Now suppose that a rigid-body motion is superimposed, so that each point x is further displaced to x = c + P x,
(5.2.5)
where the vector c and orthogonal matrix P are constant. It is a straightforward matter to substitute for x into (5.2.2) and thus obtain the new deformation gradient as Fij =
∂xi = Pik Fkj ∂Xj
(5.2.6)
or, in matrix notation, F = P F. From the orthogonality of P , it therefore follows that T C = F F = F T F = C,
(5.2.7)
(5.2.8)
5.2 Stress and strain revisited
217
so that C, unlike F , is invariant under any superimposed rigid-body motion of the material. On the other hand, suppose we perform a rigid-body motion on the material before applying the deformation. In other words we consider the transformation X → x(X ),
where
X = c + QX,
(5.2.9)
where the vector c and orthogonal matrix Q are constant. Now the chain rule gives ∂xi (5.2.10) = F QT F = ∂Xj and the corresponding Green deformation tensor is thus T C = F F = QCQT .
(5.2.11)
This demonstrates that C transforms as a tensor under transformations of the reference configuration. To connect with Chapter 1, let us note that if the displacement from X to x is a rigid-body motion, then F is orthogonal and, hence, C is equal to the identity matrix I. We are therefore led to define the strain tensor E = (Eij ), where 1 1 T E = (C − I) = (5.2.12) F F −I . 2 2 By construction, E is a symmetric tensor which is objective, by which we mean that it has the same definition after arbitrary rotation of the axes, and is zero for a rigid-body displacement. Also (5.2.3), written in the form (1.4.4), namely |dx|2 − |dX|2 = 2dX T E dX,
(5.2.13)
shows how the stretch of line elements in the continuum depends on E. We do not want the reader to drown under a deluge of new notations in this introduction. Nonetheless, we note for future reference that another deformation tensor can also be used, namely B = F F T.
(5.2.14)
This is called the left Green deformation tensor or, more commonly, the Finger tensor. We will find that B is more natural than C as a measure of deformation for an observer using Eulerian coordinates x.
218
Nonlinear elasticity dX
dx
N n
da
dA
Fig. 5.1 The deformation of a small scalene cylinder.
5.2.2 The Piola–Kirchhoff stress tensors The elastic force exerted on a surface element da = n da in the deformed medium, with area da and normal n, is given by df = τ n da,
(5.2.15)
where τ = (τij ) is the Cauchy stress tensor, as defined in Chapter 1. As in Section 1.7, we will need to impose a constitutive relation between the stress and the strain tensor E, and this requires us to express τ relative to a Lagrangian frame. As a first step, let us find how the surface element da is related to the area dA that it occupied in the reference state. One way to do this is to consider a small scalene cylinder in the reference state, with base dA and axis dX. As shown in Figure 5.1, this will be deformed to a new cylinder, with base da and axis dx, which is related to dX by (5.2.1). The volumes of the two cylinders are given by dV = dX · dA and dv = dx · da respectively and, since the Jacobian J = det (()F ) measures the local volume change at any point, these must be related by dv = J dV . We therefore obtain dx · da = dX · F T da = JdX · dA, (5.2.16) in which the vector element dX is arbitrary, so the area elements are related by −1 dA. (5.2.17) da = det (F ) F T When we apply this result to the expression (5.2.15) for the force on a small area element, we obtain −1 dA. (5.2.18) df = det (F ) τ F T
5.2 Stress and strain revisited
219
This gives the stress in the deformed configuration on an area element which, in the reference configuration, was given by dA. The quantity in braces, −1 , (5.2.19) T = det (F )τ F T is a second-rank tensor called the first Piola–Kirchhoff stress tensor. As shown in Section 1.4, the Cauchy stress tensor τ is symmetric, but T in general is not. We can, though, use the symmetry of τ to deduce the following identity satisfied by T : T F T = F T T.
(5.2.20)
This motivates the introduction of the second Piola–Kirchhoff stress tensor S, defined by −1 S = F −1 T = det (F ) F −1 τ F T , (5.2.21) so that S is symmetric.
5.2.3 The momentum equation In Section 1.6 we derived Cauchy’s momentum equation ρ
∂τij ∂ 2 xi = ρgi + , 2 ∂t ∂xj
(5.2.22)
which must apply to any continuum for which a Cauchy stress tensor (τij ) can be defined. In (5.2.22), gi are the components of the applied body force and ρ is the density of the material, related to the initial density ρ0 by ρ0 = J = det (F ). (5.2.23) ρ Now let us derive the Lagrangian equivalent of (5.2.22). We start, as in Section 1.6, by applying Newton’s second law to a material volume V (t) whose boundary ∂V (t) has outward unit normal denoted by n = (ni ): ∂xi d ρ dx = gi ρ dx + τij nj da. (5.2.24) dt V (t) ∂t V (t) ∂V (t) Now we change the integration variables to Lagrangian coordinates X, using (5.2.17) to convert the final surface integral: d ∂xi −1 ρJ dX = Jτik Fjk Nj dA. gi ρJ dX + dt ∂t V (0) V (0) ∂V (0) (5.2.25)
220
Nonlinear elasticity
With respect to Lagrangian variables, the integration domain V (0) is timeindependent, so we may differentiate through the first integral, using the fact that ρJ = ρ0 (X) is independent of t. In the final integral, we recognise the term in braces as the first Piola–Kirchhoff tensor Tij and apply the divergence theorem to obtain ∂Tij ∂ 2 xi ρ dX = gi ρ0 dX + dX. (5.2.26) 2 0 ∂t ∂X j V (0) V (0) V (0) Since this must hold for all reference volumes V (0) we deduce, assuming that the integrand is continuous, the following Lagrangian form of Cauchy’s equation: ∂Tij ∂ 2 xi . (5.2.27) ρ0 2 = ρ0 gi + ∂t ∂Xj Although it is not immediately obvious, (5.2.27) may also be obtained directly by using (5.2.19) to replace τ with T in (5.2.22) and applying the chain rule (Exercise 5.2). 5.2.4 Example: one-dimensional nonlinear elasticity The simplest example that illustrates both mechanical and geometric nonlinearity is a unidirectional displacement u(X, t) in the X-direction. In this very special situation, S and E just involve scalars Sxx and Exx and the most general constitutive law is simply a functional relationship between them, that is Sxx = φ (Exx ). From (5.2.13), we obtain the one-dimensional strain 1 ∂u 2 ∂u + (5.2.28) Exx = ∂X 2 ∂X and hence Txx = (F S)xx
∂x = φ ∂X
∂u 1 + ∂X 2
∂u ∂X
2 .
(5.2.29)
In equilibrium under a constant stress Txx , the displacement is such that ∂u 1 ∂u 2 ∂u φ + = Txx . (5.2.30) 1+ ∂X ∂X 2 ∂X If we suppose that the material is mechanically linear, so that φ is the linear function φ (Exx ) = (λ + 2µ) Exx ,
(5.2.31)
then (5.2.30) is a cubic equation for ∂u/∂X with only one real root.
5.3 The constitutive relation
221
More exciting possibilities occur when we examine longitudinal waves propagating in the X-direction. Again assuming the linear constitutive relation (5.2.31), we find that the momentum equation (5.2.27) in one spatial dimension reads ∂2u ∂u 1 ∂u ∂u 2 ∂ 1+ 1+ , (5.2.32) = cp ∂t2 ∂X ∂X 2 ∂X ∂X where c2p = (λ + 2µ)/ρ0 . This is a nonlinear generalisation of the P -wave equation that we encountered in Chapter 3. We recall that one-dimensional linear P -waves propagate information along the two families of characteristics X ± cp t = const. in the (X, t)-plane. However, for (5.2.32), the characteristics are given by the equation dX = ± cp dt
3 ∂u + 1+3 ∂X 2
∂u ∂X
2 1/2 ,
(5.2.33)
and they are generally not straight lines. Even more importantly, they depend on the solution ∂u/∂X itself, and it can be shown that characteristics of the same family will almost always eventually cross. When this happens, the pieces of information carried by each of these two characteristics are usually incompatible, so that u becomes multi-valued. This results in the formation of a shock, which is a curve in the (X, t)-plane across which the first derivatives of u are discontinuous (Bland, 1988, Section 10.1).
5.3 The constitutive relation 5.3.1 Polar decomposition The polar decomposition theorem (Strang, 1988) tells us that any nonsingular matrix F may be written as the product of an orthogonal matrix M T and a positive definite symmetric matrix U : F = M T U.
(5.3.1)
Hence, if the real, positive eigenvalues of U are denoted λ1 , λ2 and λ3 , there exists an orthogonal matrix R such that λ1 0 0 Λ = 0 λ2 0 . 0 0 λ3
U = RT ΛR,
where
(5.3.2)
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Nonlinear elasticity
The rows of R are the eigenvectors of U , that is T e1 , R = eT where U ei = λi ei , ei · ej = δij . 2 T e3
(5.3.3)
Since F is a function of X, it follows that M , U , R and Λ likewise vary with X. Substitution of (5.3.1) and (5.3.2) into (5.2.1) leads to the relation dx = M T RT ΛR dX
(5.3.4)
between line elements dX and dx in the reference and deformed configurations respectively. Using (5.3.3), we can decompose dX into its components along each of the eigenvectors ei : λi ei (ei · dX) . (5.3.5) dx = M T i
The effect of the transformation may thus be understood as a stretch, by a positive factor λi , along each of the eigenvectors ei , followed by a rotation via the orthogonal matrix M . We therefore define the eigenvalues λi to be the principal stretches and corresponding eigenvectors ei to be the principal directions corresponding to the deformation; both will, in general, vary with position. By substituting (5.3.1) into (5.2.4), we see that U is related to C by C = U 2 = RT Λ2 R.
(5.3.6)
It follows that C shares the same eigenvectors ei as U , while the eigenvalues of C are λ21 , λ22 and λ23 . Moreover, since C is related to the strain tensor E by (5.2.12), the principal strains Ei , introduced in Section 2.2.5, are related to λi by (5.3.7) λi = 1 + 2Ei . 5.3.2 Strain invariants We may expand out the characteristic polynomial of C as det (ζI − C) = ζ − λ21 ζ − λ22 ζ − λ23 = ζ 3 − I1 (C)ζ 2 + I2 (C)ζ − I3 (C), (5.3.8) where Ij (C) are the isotropic invariants of C, given by I1 (C) = λ21 + λ22 + λ23 ,
I2 (C) = λ21 λ22 + λ22 λ23 + λ23 λ21 ,
I3 (C) = λ21 λ22 λ23 . (5.3.9)
5.3 The constitutive relation
223
If C is diagonal (with entries λ21 , λ22 , λ23 ), then it is clear that the three invariants may be written as I1 (C) = Tr (C),
I2 (C) =
1 Tr (C)2 − Tr C 2 , 2
I3 (C) = det (C). (5.3.10)
It is also clear that I1 (C), I2 (C) and I3 (C), like the eigenvalues and characteristic polynomial of C, are invariant under orthogonal transformations of the axes. Hence the equations given in (5.3.10) are identities, whether or not C is diagonal. Henceforth we will suppress the argument of Ik to avoid cluttering the equations. Now suppose a scalar function φ(C) of the Green deformation tensor is known to be invariant under rigid-body motions of the reference state. As shown in Section 5.2.1, transformation of the axes by an orthogonal matrix Q converts C to C = QCQT , so the invariance required of φ may be stated as φ QCQT ≡ φ (C) (5.3.11) for all orthogonal matrices Q. In particular, (5.3.11) must hold if Q is equal to R, the orthogonal matrix that diagonalises C, so φ (C) ≡ φ Λ2 ,
(5.3.12)
and φ can therefore depend only on λ21 , λ22 and λ23 . Moreover, additional rotations of the axes can further permute the diagonal elements of Λ2 and, hence, φ must be invariant under permutation of the λi . It follows that φ must be a function of the strain invariants Ij , that is φ = φ (I1 , I2 , I3 ) ,
(5.3.13)
which represents a considerable restriction of all possible functions of the six independent components of the symmetric tensor C. Note that B in (5.2.14) also has eigenvalues λ2i and invariants Ii , although generally not the same eigenvectors as C. We also recall from the Cayley– Hamilton theorem that C satisfies its own characteristic polynomial, namely C 3 − I1 C 2 + I2 C − I3 I = 0.
(5.3.14)
This can be used to express any power of C in terms of just I, C and C 2 , and similarly for B.
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Nonlinear elasticity
5.3.3 Frame indifference and isotropy Now we are at last in a position to relate stress and strain in the Lagrangian reference frame. A material is called elastic if the second Piola–Kirchhoff stress is a function only of the deformation gradient; that is, S = S(F );
(5.3.15)
S could also depend on X if the elastic properties were spatially nonuniform, but we will ignore this possibility here. The key requirement is that the relation (5.3.15) be invariant under rigidbody motions; in other words, the way a material responds to stress should not depend on the frame in which it is observed. As demonstrated in Section 5.2.1, rotation of the Eulerian coordinate axes through an orthogonal matrix P transforms F to F = P F , so this frame indifference leads to the restriction S (F ) ≡ S (P F )
(5.3.16)
for all orthogonal matrices P . Since the Green deformation tensor C is invariant under rigid-body motions, (5.3.16) is certainly satisfied if the constitutive relation takes the form S = S(C),
(5.3.17)
and it may be shown, as in Exercise 5.3, that this condition is necessary as well as sufficient. Notice that (5.3.17) is more specific than (5.3.15) since C has only six distinct elements, while F has nine. Further simplification may be achieved by assuming that the material is isotropic, meaning it has no preferred directions. Suppose we take the undeformed material and rotate it about an arbitrary origin X 0 via an orthogonal matrix Q such that X = X 0 + Q (X − X 0 ) .
(5.3.18)
Then, if we take the rotated material and apply exactly the same deformation as before, the net deformation is given by (5.3.19) X → x(X ) = x X 0 + Q (X − X 0 ) . As shown in Section 5.2.1, the Green deformation tensor corresponding to (5.3.19) is C = QCQT , and the corresponding stress tensor at the point X 0 is therefore S (C) = S QCQT . (5.3.20)
5.3 The constitutive relation
225
If the material is isotropic, then this should be identical to the stress which we would have obtained without the original rotation, albeit related to the new coordinates X rather than to X. By applying the usual rule for the rotation of a tensor, we deduce that S (C) = QS(C)QT ,
(5.3.21)
which must apply identically for any fixed point X 0 and any rotation matrix Q. The constitutive relation (5.3.17) between S and C must therefore satisfy the symmetry condition S(QCQT ) ≡ QS(C)QT
(5.3.22)
for all orthogonal matrices Q, at any point X at which the material is isotropic. It may be shown (Exercise 5.4) that S has the symmetry property (5.3.22) if and only if it can be written in the form S(C) = φ0 (I1 , I2 , I3 ) I + φ1 (I1 , I2 , I3 ) C + φ2 (I1 , I2 , I3 ) C 2 ,
(5.3.23)
where φ0 , φ1 and φ2 are functions of the three invariants of C. An isotropic constitutive relation thus amounts to a specification of these three scalar functions. We note that, in the limit of small strain, when Cij → δij + 2eij in the notation of Chapter 1, the only relevant strain invariant is the trace ekk . Hence the right-hand side of (5.3.23) reduces to a linear combination of ekk δij from the first term and eij from the second and third terms, thereby retrieving (1.7.6). We will return to the small displacement limit in Section 5.3.6. We may directly infer from (5.3.23) that in an isotropic material, S has the same eigenvectors as C. On the other hand, using (5.2.19), equation (5.3.23) gives, for the Cauchy stress, $ −1/2 # φ0 B + φ1 B 2 + φ2 B 3 , (5.3.24) τ = I3 so that the principal axes of τ coincide with those of B. Furthermore, using (5.3.14), one can eliminate B 3 and obtain $ −1/2 # τ = I3 I3 φ2 I + (φ0 − I2 φ2 ) B + (φ1 + I1 φ2 ) B 2 . (5.3.25) This demonstrates how the Cauchy stress is more elegantly expressed in terms of B, while C is more natural for the Piola–Kirchhoff stress. If the material is not pre-stressed, then S should be zero in the reference configuration, that is S(I) = 0, which leads to the condition φ0 (3, 3, 1) + φ1 (3, 3, 1) + φ2 (3, 3, 1) = 0.
(5.3.26)
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Nonlinear elasticity
However, we will see in the next section that the requirement (5.3.26) is far from sufficient for the constitutive relation (5.3.23) to lead to a physically acceptable theory of mechanically nonlinear elasticity. 5.3.4 The energy equation In Chapter 1, we found that the work done on any region of a linear elastic solid is balanced by the change in both the kinetic energy and the strain energy stored by the material as it deforms. Now let us try to repeat this analysis for a nonlinear elastic material. We start by multiplying the momentum equation (5.2.27) by the velocity ∂xi /∂t and integrating over a control material volume V0 : ∂xi ∂ 2 xi ∂xi ∂xi ∂Tij dX + ρ0 dX = ρ0 gi dX. (5.3.27) 2 ∂t ∂t ∂t V0 V0 V 0 ∂t ∂Xj The time derivative may be taken outside the first integral, while the final integral can be manipulated using the divergence theorem to obtain d dt
V0
ρ0 2
∂xi ∂t
2
∂Fij dX + Tij dX ∂t V0 ∂xi ∂xi dX + Tij Nj dA. (5.3.28) ρ0 gi = ∂t V0 ∂V 0 ∂t
Recalling that ρ0 dX ≡ ρ dx, we see that the first term on the left-hand side of (5.3.28) is the rate of change of kinetic energy, while the first term on the right-hand side is the rate at which work is done by the body force. Finally, the boundary integral is the rate at which work is done by stress on ∂V . We can therefore interpret the second term on the left-hand side of (5.3.28) as the rate at which elastic energy is stored by the medium. Unfortunately, this implies that apparently legitimate nonlinear constitutive relations may allow a net extraction of energy from an elastic material under periodic loading cycles. Let us consider, for example, a material with the isotropic constitutive relation S = λ21 λ22 λ23 − 1 I. (5.3.29) subject to a deformation in which 0 0 λ1 (t) F = 0 λ2 (t) 0 , 0 0 1
(5.3.30)
5.3 The constitutive relation
227
where λ1 , λ2 are periodic functions of t. We use (5.2.21) to calculate the first Piola–Kirchhoff stress as 0 0 2 2 λ1 (t) T = F S = λ 1 λ2 − 1 0 (5.3.31) λ2 (t) 0 0 0 1 and hence find that 2 2 ∂Fij dλ1 dλ2 dX = V0 λ1 λ2 − 1 λ1 + λ2 Tij , ∂t dt dt V0
(5.3.32)
which is a function whose time integral over a period may be positive or negative. When λ1 = 1 + a cos(ωt), λ2 = 1 + bsin(ωt), for example, the integral of (5.3.32) over a period 2π/ω is 3πab b2 − a2 /2. Hence, if an elastic material were to exist that satisfied (5.3.29), then it could be used as a limitless energy source! This behaviour is clearly unacceptable and a sufficient condition to preclude it is the existence of a strain energy density W (Fij ) such that Tij =
∂W , ∂Fij
(5.3.33a)
or, introducing the convenient notation for differentiation by a tensor, T = If so, then we can write Tij V0
∂W . ∂F
∂Fij d dX ≡ ∂t dt
(5.3.33b) W dX,
(5.3.34)
V0
and interpret the right-hand side as the strain energy stored in the medium; the change in this energy automatically integrates to zero over a periodic loading cycle. We will now explore this happy circumstance in more detail. 5.3.5 Hyperelasticity A material is called hyperelastic if there is a strain energy density W (Fij ) satisfying (5.3.33). The theory of hyperelasticity has proved to be by far the most commonly-used and convenient way to construct constitutive relations for materials like rubber. By posing a functional form for W, and inferring from (5.3.33) the corresponding stress–strain relation, one automatically avoids thermodynamically unfeasible situations like that described above. However, the mere existence of W is not sufficient to guarantee wellposedness of the resulting elastic model. At the moment all we can say is
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Nonlinear elasticity
that our experience with linear elasticity in Chapter 1 suggests that W (Fij ) should have a minimum (taken to be zero without loss of generality) at Fij = δij . As in Section 5.3.3, we must insist that the constitutive relation be invariant under rigid-body motions of the reference state. In the hyperelastic framework, this implies that W can depend only on the six components of C, and the second Piola–Kirchhoff stress is then given by S=2
∂W , ∂C
(5.3.35)
as shown in Exercise 5.8. Henceforth we limit our attention to isotropic materials, for which W is invariant under rigid-body rotation of the reference state, and we can follow Section 5.3.2 to assert that W = W (I1 , I2 , I3 ) .
(5.3.36)
The second Piola–Kirchhoff stress tensor is therefore given by S=2
∂W ∂Ik . ∂Ik ∂C
(5.3.37)
k
To find the circumstances under which such a strain energy function can exist, we note from Exercise 5.9 that ∂I1 = I, ∂C
∂I2 = I1 I − C, ∂C
∂I3 = I3 C −1 , ∂C
(5.3.38)
where I is the identity. Hence, after a bit of algebra (see Exercise 5.11), we find that ∂W 2 I− C+ C , S=2 ∂I3 (5.3.39) which gives us explicit forms for the functions φi in (5.3.23). Since the φi satisfy
φ2 = 2
∂W ∂W ∂W + I1 + I2 ∂I1 ∂I2 ∂I3
∂W ∂W + I1 ∂I2 ∂I3
∂W ∂W ∂W , φ1 + I1 φ2 = −2 , φ0 + I1 (φ1 + I1 φ2 ) − I2 φ2 = 2 , ∂I3 ∂I2 ∂I1 (5.3.40)
5.3 The constitutive relation
229
cross-differentiation reveals that
∂φ0 ∂I3 ∂φ1 ∂φ0 + I1 ∂I2 ∂I2
∂φ1 ∂φ2 ∂φ2 + + I1 = 0, ∂I3 ∂I2 ∂I3 ∂φ2 ∂φ2 ∂φ1 2 + I1 + I1 − I2 − = 0, ∂I3 ∂I3 ∂I1 ∂φ2 ∂φ1 2 ∂φ2 + + I1 − I2 + I1 = 0. ∂I1 ∂I2 ∂I1
(5.3.41a) (5.3.41b) (5.3.41c)
Any choice of the functions φi that does not satisfy (5.3.41) will lead to behaviour such as that exhibited in (5.3.32); indeed it was these integrability conditions that suggested the counter-example (5.3.29). We note from (5.2.21) that the Cauchy stress is given in terms of W as −1/2 ∂W
τ = I3
∂F
FT
(5.3.42)
and, as shown in Exercise 5.7, this leads to the useful expression −1/2
τi = I3
λi
∂W ∂λi
(5.3.43)
(no summation) for the Cauchy principal stresses. As well as clarifying the characterisation of elastic materials, hyperelasticity also often simplifies the mathematical and numerical analysis of nonlinear elastic problems. The net elastic energy stored in a material volume V0 is given by W dX. (5.3.44) U= V0
By virtue of (5.3.33), a calculation analogous to Exercise 1.8 implies that the steady version of the gravity-free momentum equation (5.2.27) is a necessary condition for U to be minimised with respect to the displacement, assuming of course that W is sufficiently smooth. Crucially, the minimisation of a functional like (5.3.44) is generally easier computationally than solving the nonlinear partial differential equation (5.2.27). In particular, minimisation problems of this type are naturally suited to the finite element method (see Fung & Tong, 2001, Chapter 18). However, for a nonlinear material, finding the uniqueness and smoothness of a minimum of (5.3.44) now poses a typically difficult challenge in the calculus of variations. It transpires that not only do we require W to be strictly positive except at F = I, but also that it should be quasi-convex, which demands that the level surfaces of W are convex in a suitable function space. It is also difficult to compare this result with the condition that, in
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Nonlinear elasticity
equilibrium, (5.2.27) should comprise, with suitable boundary conditions, a well-posed system for xi .
5.3.6 Linear elasticity Now we briefly verify that the hyperelastic formulation of elasticity outlined above reduces to the linear elastic constitutive relation introduced in Chapter 1 when the strains are small. We recall from (5.3.7) that the principal strains are related to the principal stretches by (5.3.45) λi = 1 + 2Ei ∼ 1 + Ei when |Ei | 1. Also we recall that W is a function of the principal stretches {λ1 , λ2 , λ3 } with a unique global minimum at λj ≡ 1. Moreover, for isotropic materials, W is invariant under permutations of {λ1 , λ2 , λ3 }. Hence, as λ1 , λ2 , λ3 → 1, the local behaviour of W near its minimum must take the form W∼µ
3 i=1
(λi − 1)2 +
3 λ (λi − 1) (λj − 1) , 2
(5.3.46)
i,j=1
where the scalar constants λ and µ, which we will shortly identify with the Lam´e constants of Chapter 1, must satisfy µ > 0 and 3λ+2µ > 0 for (5.3.46) to be positive definite. Since, in principal axes, W = W(λi ) and C = diag λ2i , (5.3.35) implies that 1 ∂W . (5.3.47) Si = λi ∂λi Substitution from (5.3.45) and (5.3.46) thus leads to Si ∼ λ (λ1 + λ2 + λ3 − 3) + 2µ (λi − 1) ∼ λ (E1 + E2 + E3 ) + 2µEi (5.3.48) as the strain tends to zero. The stress and strain tensors are thus related by S ∼ λ Tr (E) I + 2µE,
(5.3.49)
and, since the left- and right-hand sides both transform as tensors, (5.3.49) holds with respect to any chosen axes. If the displacement is small, relative to any other length-scale, then the deformation gradient F is approximately equal to the identity and hence, from (5.2.19) and (5.3.48), both the Piola–Kirchhoff stress tensors and the Cauchy stress tensor are all approximately equal. In addition, the quadratic
5.3 The constitutive relation
231
terms in the strain tensor may be neglected to leading order, and (5.3.49) thus reproduces the linear elastic constitutive relation (1.7.6). However, (5.3.49) holds just as long as the strain is small, so the displacement need not be small provided it is close to a rigid-body motion. In such situations, we can thus justify the use of the mechanically linear constitutive equation (5.3.49), while retaining the geometrically nonlinear relation between x and X. Indeed we have already done this several times in Chapter 4.
5.3.7 Incompressibility Many rubber-like materials are observed to be almost incompressible, and it is common to employ constitutive relations that impose this. From (1.3.6), which holds for nonlinear deformations, the condition of incompressibility is J = ρ0 /ρ = 1 or, in terms of the strain invariants, I3 ≡ 1.
(5.3.50)
As we found in Section 1.8, the imposition of this constraint on the problem can be achieved at the expense of introducing an additional unknown scalar function p which can be interpreted as an isotropic pressure. Now we will consider how to introduce p into nonlinear elasticity in a self-consistent way, and there are two ways to go about this. The approach followed in Section 1.8 was to characterise the compressibility by a small but nonzero parameter ε and then carefully take the limit ε → 0. Alternatively, we could have examined the variational formulation of the problem in terms of the strain energy density W and then identified p as a Lagrange multiplier associated with the constraint (5.3.50), as in Exercise 1.8. We can follow the first strategy by constructing a strain energy density that heavily penalises departures of I3 from unity, for example W (I1 , I2 , I3 ) =
µ (I3 − 1)2 ˜ (I1 , I2 ) , +W 2ε
(5.3.51)
where ε 1. The actual functional form of W is unimportant provided it has a very strong minimum at I3 = 1, but the particular example (5.3.51) will help to fix ideas. We anticipate that this strain energy function will force I3 to remain close to unity, and therefore set I3 = 1 −
2ε p, µ
(5.3.52)
where the scalar function p is to be determined. Substituting (5.3.51) into
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Nonlinear elasticity
(5.3.39) and using (5.3.14), we find that our desired constitutive relation becomes ∂W ∂W ∂W I −2 + I1 C − pC −1 . (5.3.53) S=2 ∂I1 ∂I2 ∂I2 The status of p as a hydrostatic pressure is clearer in the corresponding expression for the Cauchy stress, namely ∂W ∂W 2 ∂W τ = −pI + 2 B−2 + I1 B . (5.3.54) ∂I1 ∂I2 ∂I2 To arrive at the same conclusion from a purely variational viewpoint, we note that incompressibility is satisfied in a small virtual displacement by adding to Fij an increment δFij such that ∂ (det F ) δFij = 0. ∂Fij
(5.3.55)
In Exercise 5.6, we show that this is equivalent to Fji−1 δFij = 0.
(5.3.56)
We also note from (5.3.28) that no additional work is done by the increment provided Tij δFij = 0.
(5.3.57)
Hence, considering only virtual deformations satisfying the constraint (5.3.56), we deduce that T is only determined up to an unknown scalar −1 . An arbitrary scalar multiple of C −1 may be thus added multiple of F T to S, and (5.3.53) follows immediately. 5.3.8 Examples of constitutive relations Some commonly used examples of constitutive relations for the strain energy density are µ (5.3.58a) neo-Hookean: W = (I1 − 3) , 2 (5.3.58b) Mooney–Rivlin: W = c1 (I1 − 3) + c2 (I2 − 3) , W = 2µ (λ1 + λ2 + λ3 − 3) , (5.3.58c) α α α λ + λ2 + λ3 − 3 , (5.3.58d) Ogden: W = 2µ 1 α where µ, c1 , c2 and α are positive constants. In each case, the material is also assumed to be incompressible, so the constitutive relation is supplemented by the constraint I3 ≡ 1. Varga:
5.4 Examples
F
(a)
F
λ1 F
(b)
233
F
λ1
(d)
F
λ1
(c)
λ1
(e)
F
(f)
λ1
λ1
Fig. 5.2 Typical force–strain graphs for uniaxial tests on various materials: (a) neoHookean, (b) Mooney–Rivlin, (c) Varga, (d) Ogden (α < 1), (e) Ogden (1 < α < 2), (f) Ogden (α > 2).
In Figure 5.2, we show typical force-versus-strain response curves for uniaxial stress tests on materials described by each of the above constitutive relations (see Exercise 5.10). The neo-Hookean and Mooney–Rivlin materials are characterised by an initial linear response, followed by transition to a less stiff linear behaviour. Varga materials fail at a finite value of the applied force. For Ogden materials, the behaviour depends on α: when α < 1, the force reaches a maximum before decaying towards zero at large strain; thus once again only a finite force is needed for the material to fail completely. For α between 1 and 2, the response is qualitatively similar to that for a Mooney–Rivlin material, while for α > 2 the stiffness always increases with increasing strain.
5.4 Examples 5.4.1 Principal stresses and strains We conclude with some simple examples which have sufficient symmetry for analytical progress to be made. In all cases, we will assume incompressibility of the medium, which leads to the relations I3 = λ21 λ22 λ23 = 1,
I1 = λ21 + λ22 + λ23 ,
−2 −2 I2 = λ−2 1 + λ2 + λ3 ,
(5.4.1)
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Nonlinear elasticity
F h
F Fig. 5.3 A square membrane subject to an isotropic tensile force F .
for the strain invariants. In all the examples considered below, the stress and strain tensors are diagonal, and the principal stresses are found from (5.3.54) to be τi = λi
∂W − p. ∂λi
(5.4.2)
Here, the λi are treated as independent variables while performing the derivatives. We focus on the Mooney–Rivlin constitutive relation (5.3.58b), for which (5.4.2) reads τi = 2c1 λ2i −
2c2 − p, λ2i
(5.4.3)
where we have made use of the incompressibility condition λ21 λ22 λ23 ≡ 1. 5.4.2 Biaxial loading of a square membrane In this example, we consider a thin square membrane of initial thickness h and side length loaded on its edges by a tensile force F , as shown in Figure 5.3. This leads to the uniform displacement field xi = λi Xi , in which case the stresses are also uniform and given by (5.4.2). By relating these to the applied force F , we obtain the equations λ1
F ∂W , −p= ∂λ1 λ2 λ3 h
λ2
F ∂W , −p= ∂λ2 λ1 λ3 h
λ3
∂W − p = 0, ∂λ3
(5.4.4)
and elimination of p leads to ∂W λ3 ∂W ∂W λ3 ∂W F = − = − . h ∂λ1 λ1 ∂λ3 ∂λ2 λ2 ∂λ3
(5.4.5)
To proceed further, we now have to choose a constitutive relation. Using the Mooney–Rivlin model (5.4.3), we find that the stretch ratios satisfy $ # (5.4.6) (λ1 − λ2 ) c1 1 + λ31 λ32 + c2 λ21 + λ1 λ2 + λ22 − λ41 λ42 = 0.
5.4 Examples
(a)
λ2
(b)
W
5
235
(c)
F
30 15 25
4
12.5 20 3
10 15 7.5
2
λc 1
10
5
5
2.5
1 1
2
3
λ1
4
5
1
2
3
4
2
3
4
5
5
λ1
λ1
Fig. 5.4 Response diagrams for a biaxially-loaded incompressible sheet of Mooney– Rivlin material with c2 /c1 = 0.5. (a) Locus of compatible stretches with a symmetric square loading. (b) Strain energy density as a function of one of the stretches. (c) Applied force as a function of one of the stretches. The thin lines represent a symmetric elastic response, the thick lines an asymmetric one, and the arrows indicate the evolution of the stable solution as F increases.
This always has the solution λ1 = λ2 but, whenever c2 = 0, (5.4.6) also admits asymmetric solutions in which λ1 = λ2 . As shown in Figure 5.4(a), there is a critical value λc of the stretches at which symmetric response bifurcates to an asymmetric one (see Exercise 5.12 for the details). We also show in Figure 5.4(b) that, when λ1 > λc , the strain energy is reduced by breaking the symmetry, so the asymmetric solution becomes energetically favourable. Finally, in Figure 5.4(c), we show how the applied force varies with the stretch. We see that as λ crosses λc , the stiffness of the sheet suddenly reduces as it switches to an asymmetric response. This example illustrates one of the most dramatic consequences of mechanical nonlinearity: the strain response to a given load is generally not unique. We have already encountered non-uniqueness as the result of geometrical nonlinearity in Chapter 4 for the Euler strut, and we note that in both cases the symmetry is broken in the bifurcation.
5.4.3 Blowing up a balloon It is a common experience that blowing up a balloon is more difficult in the early stages than it is later on. This phenomenon can be understood by considering a thin, spherical, incompressible rubber membrane of initial radius R and thickness h R. Assuming the spherical symmetry is preserved as the balloon inflates, the two tangential stretches λθ and λφ (where θ and φ are the usual spherical polar coordinates) will be equal and related
236
Nonlinear elasticity
P
c = 0.3
6
0.2
5
4
0.1
3
2
1
0 2
4
3
5
6
λθ Fig. 5.5 Scaled pressure inside a balloon as a function of the stretch λθ = R/r for various values of the Mooney–Rivlin parameter c = c2 /c1 .
to the stretched radius r by λθ = λφ =
r , R
(5.4.7)
and the normal stretch λr is determined by incompressibility. Since the balloon is assumed to be thin, we can use the biaxial result above to calculate the tension, ∂W ∂W , (5.4.8) − λr T = Tθ = Tφ = hλr τθ = hλr λθ ∂λθ ∂λr noting that the thickness of the balloon is hλr following the deformation. The final observation is that a normal force balance relates the tension to the internal pressure P and the curvature of the membrane via P =
2T . r
(5.4.9)
It is now a simple matter to assemble these ingredients and thus relate the inflation pressure to the radius of the balloon. Again using the Mooney– Rivlin model (5.4.3), for example, we find 4 1 + c λ2θ λ6θ − 1 RP = P (say) = , (5.4.10) hc1 λ7θ where c is the dimensionless ratio c2 /c1 . With c = 0, we see in Figure 5.5 that the pressure required to inflate the balloon initially increases before decreasing when the radius is sufficiently large, successfully reproducing the familiar behaviour described above. For small positive values of c , however, the behaviour is more complicated, with
5.4 Examples
237
the pressure reaching a maximum, decreasing, then finally increasing again for very large strains. In an experiment where a controlled pressure is imposed (not generally possible using one’s lungs!), the radius would jump as indicated by the arrow when the pressure reaches its maximum value. Increasing c corresponds to making the material stiffer at large strains, reflecting the fact that polymer molecules can only withstand a finite extension without breaking. If c exceeds a critical value 2/3 √ 11 11 − 34 ≈ 0.21446, 25 this increased stiffness removes the maximum in the pressure completely and the behaviour becomes monotonic.
5.4.4 Cavitation Suppose a spherical cavity embedded in a rubber continuum expands as a result of an increasing internal pressure P . Such a situation could be achieved by dissolving a gas in a rubber matrix, for example. Now we use spherical polar coordinates (R, θ, φ) in the rest state and again assume the displacement is purely radial, so that θ and φ are preserved while each radial position R expands to a new radius r(R). We can hence write down the principal stretches λR =
dr , dR
λφ = λ θ =
r , R
(5.4.11)
and the incompressibility condition λR λθ λφ = 1 gives us a differential equation for r(R), namely dr R2 = 2. dR r
(5.4.12)
Denoting by a the initial radius of the sphere, we write the solution of (5.4.12) as 1/3 , (5.4.13) r = R3 + λ30 a3 − a3 where λ0 = λθ (0) =
r(a) a
(5.4.14)
is the expansion ratio of the cavity. A displacement of the form (5.4.13) is the only incompressible purely radial deformation. We can read off from
238
Nonlinear elasticity P/c1
0.2
10
0.1
8
6
c = 0
4
2
2
3
4
5
7
6
8
9
λ0
Fig. 5.6 Gas pressure inside a cavity as a function of inflation coefficient for various values of the Mooney–Rivlin parameter c = c2 /c1 .
(5.4.11) the principal stretches λR =
R2 R3 + λ30 a3 − a3
2/3 ,
R3 + λ30 a3 − a3 λφ = λ θ = R
1/3 .
(5.4.15)
We next turn to the familiar radial momentum equation from (1.11.16): 2τrr − τθθ − τφφ dτrr + = 0. dr r
(5.4.16)
We can use (5.4.13) to transform to Lagrangian coordinates and substitute for the stress components from (5.4.2), thus obtaining R3 + a3 λ20 − 1 dτrr ∂W ∂W = 2λθ − 2λR . (5.4.17) R2 dR ∂λθ ∂λR Now solving the first-order differential equation (5.4.17) subject to the two boundary conditions τrr (a) = −P,
τrr → 0
as
R → ∞,
(5.4.18)
yields an expression for the internal pressure P in terms of the inflation coefficient λ0 . For Mooney–Rivlin materials, for example, this gives rise to the relation 4 1 1 (5.4.19) − 4 − 2c2 1 − 2λ0 + 2 , P = c1 5 − λ0 λ0 λ0 which we plot in Figure 5.6 for various values of the ratio c2 /c1 . When c2 = 0, the material is neo-Hookean, and we see that only a finite pressure P = 5c1 is needed to inflate the cavity to infinity. This unlikely behaviour reflects the failure of the neo-Hookean model to capture the inability of materials
Exercises
239
to withstand unbounded strains, and the situation is remedied whenever c2 is positive.
5.5 Concluding remarks This chapter has provided an introduction to what is probably the most mathematically challenging branch of elasticity theory. In principle, our basic task is to solve for xi from (5.2.27), bearing in mind that the stress is now a much more complicated function of the strain than it was for mechanically linear elasticity. Concerning the constitutive law, it is convenient to work with the second Piola–Kirchhoff tensor S, but there are now many more physically acceptable relations between S and F than there were for linear elasticity. Nonetheless, any selection of this relation must ultimately lead to a well-posed system of partial differential equations for xi before we can have confidence that we have a good model for the nonlinear evolution of an elastic solid. If we confine ourselves to statics, then it is conceptually appealing to work with hyperelastic materials for which we have the apparently much simpler task of minimising the net strain energy (5.3.44). However, even here we have to select from a wide range of functions relating the strain energy density to the strain invariants, and, when we have done this, we still have to confront the daunting problem of the well-posedness of the relevant minimisation problem in the calculus of variations. Having at last faced up to the theoretical challenges of nonlinear elasticity, we are now in a position to discuss the implications for some of the practically important geometric configurations that we encountered in Chapter 4.
Exercises 5.1
5.2
Show that the displacement corresponding to a rigid-body motion is given by X(x, t) = a(t) + P (t)x, where the vector a and orthogonal matrix P are spatially uniform. Show that the strain E defined by (5.2.12) is identically zero for this displacement field, but that the linearised strain (1.7.1) is not. (a) Prove the identity ∂xj 1 ∂J ∂ , (E5.1) ≡ ∂xj ∂Xk J ∂Xk (assuming the summation convention). [Hint: integrate both
240
Nonlinear elasticity
sides over an arbitrary material volume V (t) and use the divergence theorem.] (b) Substitute the Piola–Kirchhoff stress tensor for the Cauchy stress tensor in the momentum equation (5.2.22) and use the chain rule to obtain −1 ∂ 2 xi −1 ∂ J Til Fjl . (E5.2) ρ0 2 = ρ0 gi + JFkj ∂t ∂Xk
5.3
(c) Expand out the right-hand side of (E5.2) and apply the identity (E5.1) to obtain the Lagrangian momentum equation (5.2.27). Suppose the scalar function f of the two-dimensional matrix F is invariant under the transformation F → P F , where P is any orthogonal matrix. Let f (F ) = g(A, B, α, β), where F is written in the form A cos α B cos β F11 F12 = . F = F21 F22 A sin α B sin β By expressing P as the rotation matrix cos θ sin θ P = , − sin θ cos θ show that g must satisfy g(A, B, α, β) ≡ g(A, B, α − θ, β − θ)
5.4
for all θ. Explain why g(A, B, α, β) ≡ h(A, B, α − β) for some function h of three independent variables. Deduce that f = f (C), where C = F TF . [A conceptually equivalent argument works in three dimensions; see, for example, Noll (1958); Spencer (1970).] (a) Suppose that two 2 × 2 symmetric matrices S and C satisfy a functional relation S = S(C) which enjoys the symmetry (5.3.22) for all orthogonal matrices Q. By considering 1 0 Q= , 0 −1 or otherwise, show that S must be diagonal whenever C is. (b) With respect to coordinates in which C (and hence also S) is diagonal, deduce that S must take the form 0 s1 (λ21 , λ22 ) , S= 0 s2 (λ21 , λ22 )
Exercises
241
where s1 and s2 are arbitrary functions of the eigenvalues λ21 and λ22 of C. Show that this expression may be manipulated to S = φ0 (I1 , I2 )I + φ1 (I1 , I2 )C,
5.5
(E5.3)
where φ0 and φ1 are two arbitrary functions of the invariants I1 and I2 of C (note that there are only two such invariants in two dimensions). (c) Show that (E5.3) is invariant with respect to orthogonal transformations and, hence, is true whether or not C is diagonal. (d) Generalise the above argument to three dimensions. Considering only two-dimensional spatially linear displacements, with (x1 , x2 ) = (λ1 (t)X1 , λ2 (t)X2 ) so that F and S are both diagonal, show that energy is consumed at a rate dλ1 dλ2 + λ2 S22 dt dt per unit volume. Deduce that the medium conserves energy if and only if the stress components satisfy q = λ1 S11
λ1
∂S11 ∂S22 ≡ λ2 . ∂λ2 ∂λ1
For the anisotropic constitutive relation (S11 , S22 ) = µ λ21 + λ22 (1, α) , where α is a constant, show that, over a periodic cycle in which λ1 = 1 + ε cos(ωt),
λ2 = 1 + ε sin(ωt),
the net energy consumption per unit volume is 2π/ω q dt = 2πε2 (α − 1)µ. 0
5.6
Show that ∂det (F ) = det (F )Fji−1 . ∂Fij
5.7
[Hint: recall the inversion formula Fij−1 = cofactor (Fji ) / det(F ).] Recall from Section 5.3.1 the existence of two orthogonal matrices R and M such that F = M T RT ΛR, where Λ = diag (λi ). Use the chain rule to show that ∂W ∂W = M T RT R. T = ∂F ∂Λ
242
Nonlinear elasticity
Now use the relationship (5.2.19) between the Cauchy and Piola– Kirchhoff stresses to show that −1/2 ∂W
RM τ M T RT = I3
5.8
∂Λ
Λ−1 .
Since Λ is diagonal, deduce that the principal Cauchy stresses are given by (5.3.43). If the strain energy density W is a function only of the symmetric Green deformation tensor Cij , show that ∂W ∂W = Fik , ∂Fij ∂Ckj and deduce that the second Piola–Kirchhoff stress tensor is given by S=2
5.9
Use Exercise 5.6 to prove the identities (a)
5.10
∂W . ∂C
∂I1 = δij , ∂Cij
(b)
∂I2 = I1 δij − Cij , ∂Cij
(c)
∂I3 −1 = I3 Cij . ∂Cij
Consider uniaxial stretching, in which a bar of initial cross-sectional area A is subject to an axial force F . Show that F is related to the axial stretch λ1 by F λ2 ∂W ∂W − , = A ∂λ1 λ1 ∂λ2 −1/2
5.11
5.12
where λ2 = λ3 = λ1 . Hence justify the response diagrams shown in Figure 5.2. Use the results from Exercise 5.9 to write out equation (5.3.37) as ∂W ∂W ∂W −1 ∂W S=2 + I1 C + I3 C I− . (E5.4) ∂I1 ∂I2 ∂I2 ∂I3 Using (5.3.14), deduce (5.3.39). Assuming the Mooney–Rivlin form for the strain energy in (5.4.4), deduce (5.4.6). Show that the critical stretch λc , at which bifurcation from symmetric to asymmetric stretching occurs, is given implicitly by 1 + λ6 c2 = c = 2 6 c , c1 λc (λc − 3)
Exercises
243
where λc > 31/6 . By introducing Θ = λ1 λ2 , show that the asymmetric solution satisfies λ1 = λ± , where λ2± = 5.13
−P (Θ) ±
λ2 =
+ P (Θ) + 4c 2 Θ2 2c
Θ , λ±
, P (Θ) = 1 + Θ3 + c Θ − Θ4 .
Consider a thin cylindrical tube, of initial radius R and thickness h R, inflated by an internal air pressure P . (a) Assuming the Mooney–Rivlin model and following the same methodology as in Section 5.4.3, show that the internal pressure P and the axial tension Tz are related to the tangential stretches by 2 1 + c λ2z λ4θ λ2z − 1 RP = , P = hc1 λ4θ λ3z 2 1 + c λ2θ λ2θ λ4z − 1 Tz = , hc1 λ3θ λ3z where c = c2 /c1 . (b) If the tube is constrained in the z-direction so that λz = 1, show that only a finite pressure P = 2 (1 + c ) is needed to inflate the tube to infinity. Show also that the axial tension needed to maintain zero displacement in the z-direction tends to infinity as λθ does. (c) Now, instead suppose that the tube is free to contract in the z-direction, so that Tz = 0. Show that in this case P → ∞ as λθ → ∞, although the behaviour is non-monotonic if c >
5.14
√ 2/3 34 + 11 11 ≈ 4.663. 7
(a) By changing independent variables to λθ , show that the differential equation (5.4.17) for the stress outside a spherical cavity may be written in the form dτrr ∂W ∂W = 2λθ − 2λR −λθ λ3θ − 1 dλθ ∂λθ ∂λR
244
Nonlinear elasticity
and, for the Mooney–Rivlin model, derive the equation 4 c1 + c2 λ2θ λ3 + 1 dτrr =− . dλθ λ5θ (b) For a spherical cavity in an infinite medium, show that the appropriate boundary conditions are τrr = −P
at λθ = λ0 ,
τrr → 0 as λθ → 1,
and hence obtain the relation (5.4.19) between the internal pressure P and the inflation parameter λ0 . (c) For a sphere with initial internal radius a and finite thickness h, show that 4 1 4 1 1 1 + 4 − − 4 −2c2 2λ − 2 − 2λ0 + 2 , P = c1 λ λ λ0 λ λ0 λ0 where
λ =
1+
1/3 3 λ0 − 1 a3 (a + h)3
.
Hence recover the balloon result (5.4.10) in the limit h/a → 0.
6 Asymptotic analysis
6.1 Introduction In Chapter 4, we derived various approximate models for thin or slender elastic configurations such as rods and plates. These models were obtained using net force and moment balances combined with ad hoc constitutive relations, for example between the bending moments and the curvatures. In this chapter, we show how such models may be derived systematically from the underlying continuum equations and boundary conditions. We concentrate on a few canonical models for plates, beams, rods and shells. Each of these models is important in its own right, and their derivation illustrates the tools that are widely useful for analysing more general thin structures. The basic idea is to exploit the slenderness of the geometry so as to simplify the equations of elasticity asymptotically. This process is made systematic by first non-dimensionalising the equations, so that all the variables are dimensionless and of order one. This highlights the small slenderness parameter ε = h/L, where h is a typical thickness and L a typical length of the elastic body. A simplified system of equations is then obtained by carefully taking the limit ε → 0. Typically, the solution is sought as an asymptotic expansion in powers of the small parameter ε, and the techniques demonstrated here fall within the general theories of asymptotic expansions and perturbation methods. Kevorkian & Cole (1981), Hinch (1991) and Bender & Orszag (1978) provide very good general expositions of these methods. In fact we have already encountered an example of this approach when discussing the torsion of a thin-walled tube in Section 2.5, and an even simpler paradigm is the dimensionless model for antiplane strain of a thin plate. We will use this example in Section 6.2 to introduce the asymptotic arguments that form the basis of this chapter. Their systematic nature offers 245
246
Asymptotic analysis
many advantages compared to the less rigorous derivations of Chapter 4. For example, in principle the process allows further corrections to be calculated, resulting in increasingly accurate models. Furthermore, it makes explicit the assumptions behind a simplified model, thus allowing us to estimate the error incurred in making an approximation and to determine when that approximation may become invalid. In this regard, we recall that the beam and plate theories developed in Chapter 4 are unable to resolve the details of the tractions applied to the edges. A boundary layer analysis in the neighbourhood of these edges will allow us to explain how such tractions can effectively be replaced by an equivalent point force/moment system, without having to assume Saint-Venant’s principle. Finally, since we start from the general continuum equations of elasticity, our asymptotic approach will lead to explicit formulae for practically useful parameters, such as the bending stiffness, in terms of the underlying elastic parameters, such as the Lam´e constants. In Section 6.3 we re-derive the linear plate equation. As it describes infinitesimal transverse displacements of a plate, we can obtain it starting from linear elasticity. In Section 6.4, we analyse a boundary layer near an edge of the plate and re-establish the correct boundary conditions for this model. Next, in Section 6.5, we re-derive the improved von K´ arm´an plate equations, incorporating geometrically nonlinear terms. This requires us to start from the equations of nonlinear elasticity, although the asymptotic approach is otherwise analogous to that used in Section 6.3. In Section 6.6, we extend the analysis to describe large two-dimensional deflections of a plate and thus derive the Euler strut equation. Finally, in Sections 6.7–6.8, we illustrate the geometrical generalisations needed to obtain the equations governing infinitesimal displacements of rods and shells. 6.2 Antiplane strain in a thin plate We first introduce our asymptotic methodology by modelling small antiplane displacements in a thin plate such that the region D in Figure 2.5 is the rectangle 0 < y < h, 0 < x < L. The slenderness parameter in this case is h . (6.2.1) L Suppose the lateral boundaries of this plate are traction-free and that w is prescribed on the ends x = 0, L. The first step towards an asymptotic analysis is to non-dimensionalise the spatial coordinates and w by writing ε=
x = Lx ,
y = hy ,
w = W w ,
(6.2.2)
6.2 Antiplane strain in a thin plate
247
where W is a typical displacement at the boundary. From (2.3.2) and (2.3.3) we find that the dimensionless displacement w satisfies ε2
∂ 2 w ∂ 2 w + =0 ∂x 2 ∂y 2
with
∂w = 0 on y = 0, 1, ∂y
(6.2.3)
along with w = f (y ) at x = 0 and w = g(y ) at x = 1, where both f and g are prescribed functions. To avoid clutter in the equations, we drop the primes henceforth. Away from the ends of the plate, we expand w in an asymptotic expansion in which w ∼ w0 + ε2 w2 + · · · as ε → 0. This gives, to lowest order in ε, ∂ 2 w0 =0 ∂y 2
with
∂w0 = 0 on y = 0, 1. ∂y
(6.2.4)
Hence w0 = w0 (x), but this function is not determined at this stage and we must proceed further in the asymptotic expansion. Collecting all O ε2 terms, we find that d2 w0 ∂ 2 w2 = − ∂y 2 dx2
with
∂w2 = 0 on y = 0, 1. ∂y
The solution w2 can only satisfy both boundary conditions if 1 2 ∂w2 1 ∂ w2 dy = . ∂y 2 ∂y 0 0
(6.2.5)
(6.2.6)
This solvability condition for w2 gives rise to the “thin sheet” equation d2 w0 =0 dx2
(6.2.7)
for w0 . To complete the model, we need to derive boundary conditions for (6.2.7). We do this by subjecting the ends of the plate to a mathematical magnifying glass. We first focus on the end x = 0 by setting x = εˆ x and letting the displacement in this boundary layer near the edge be given by the function w(x, y) = w(ˆ ˆ x, y).
(6.2.8)
This gives the semi-infinite strip model ˆ ∂2w ˆ ∂2w + =0 2 2 ∂x ˆ ∂y
with
∂w ˆ = 0 on y = 0, 1 ∂y
(6.2.9)
and w ˆ = f (y) prescribed on x ˆ = 0. Letting now w ˆ∼w ˆ 0 + εw ˆ1 + · · · , using
248
Asymptotic analysis
separation of variables and making the assumption that w ˆ0 does not grow as x ˆ → ∞, we find ∞
a0 + an e−nπ xˆ cos nπy, w ˆ0 = 2
(6.2.10)
n=1
where the ai are the Fourier cosine coefficients of f (y). Finally, we require that the functions w ˆ0 and w0 match, in the sense that, ˆ0 when the latter is evaluated for large x ˆ. as x → 0, w0 joins smoothly with w More specifically, we require that ˆ0 , lim w0 = lim w x ˆ →∞
x→0
and we thus obtain
(6.2.11)
1
w0 (0) =
f (y) dy,
(6.2.12)
g(y) dy.
(6.2.13)
0
and similarly
w0 (1) =
1
0
These are the crucial boundary conditions for the thin sheet model (6.2.7): the only information that w0 has about f and g is their average values. Now we undertake the more challenging task of extending this asymptotic argument to the bending of elastic plates.
6.3 The linear plate equation 6.3.1 Non-dimensionalisation and scaling We now turn to small displacements in a horizontal elastic plate subject to a transverse gravitational acceleration g. As for the antiplane strain problem just analysed, we assume that the displacements are small enough for linear elasticity to apply, so we can use the momentum equation given in component form by (1.11.3), and the components of the Cauchy stress tensor are given by (1.11.1). If the plate has uniform thickness h and its centre-surface initially occupies the plane z = 0, then its free surfaces are at z = ±h/2, and we impose the stress-free boundary conditions τxz = τyz = τzz = 0
on z = ±h/2.
(6.3.1)
In linear elasticity we do not distinguish between Eulerian and Lagrangian coordinates, so the boundaries of the plate effectively remain fixed at
6.3 The linear plate equation
249
z = ±h/2. The treatment of larger transverse displacements, comparable to h, say, will be deferred to Section 6.5. Denoting by L a typical dimension in the x- and y-directions, the slenderness parameter is again ε = h/L, and we will now construct an approximate theory for the deformations of the plate based on the assumption that ε is small. To exploit this fact, we again non-dimensionalise the equations before taking the asymptotic limit ε → 0, making the important assumption that λ and µ are held fixed. The spatial coordinates are again scaled with their typical values as x = Lx ,
y = Ly ,
z = hz .
(6.3.2)
As always happens in asymptotic simplifications, choosing the right scalings for the dependent variables is a matter of trial-and-error guided by experience. Here, simple geometry implies that a transverse displacement of magnitude O (W ) is associated with in-plane displacements of O (εW ). Moreover, from (6.3.1), we know that, on the free surface, ∂u/∂z = −∂w/∂x. Now, we have the order-of-magnitude estimates ∂u/∂z ∼ u/h and ∂w/∂x ∼ w/L, and balancing the two yields the non-dimensionalisation u = εW u ,
v = εW v ,
w = W w .
(6.3.3)
The appropriate non-dimensionalisation for the stress components is slightly less clear. Our best strategy is to seek a scaling that balances as many terms as possible in the Navier equations (1.11.3), and we give ourselves the freedom to do this by writing , , τxy , τyy (τxx , τxy , τyy ) = τ τxx (τxz , τyz ) = ετ τxz , τyz ,
(6.3.4b)
, τzz = ε2 τ τzz
(6.3.4c)
(6.3.4a)
where τ is to be determined. A suitable choice may then be obtained by balancing the in-plane stresses and strains in the constitutive relation (1.11.1), which leads to τ =
ε2 EW , h
(6.3.5)
where E is Young’s modulus. Finally, by looking for a balance in the
250
Asymptotic analysis
transverse Navier equation (1.11.3c), we infer a suitable time-scale, namely ) h ρ t . t= (6.3.6) 2 ε E To summarise, the geometry of the plate has driven our non-dimensionalisation (6.3.2) of the spatial variables. Our scalings (6.3.3) of the displacements amount to assumptions about how big the transverse and in-plane deflections are; thereafter, stress components are rescaled so as to balance as many terms as possible in the momentum equations. We will now derive the leading-order model that results from these scalings.
6.3.2 Dimensionless equations Substituting (6.3.2) and (6.3.4) into (1.11.3) and neglecting terms of order ε2 we obtain the dimensionless momentum equations ∂τxy ∂τxx ∂τxz + + , ∂x ∂y ∂z ∂τyy ∂τyz ∂τxy + + , 0= ∂x ∂y ∂z ∂τyz ∂2w ∂τzz ∂τxz + + − G, = ∂t2 ∂x ∂y ∂z 0=
(6.3.7a) (6.3.7b) (6.3.7c)
where G=
ρgh2 ε4 EW
(6.3.8)
is a dimensionless constant measuring the importance of gravity. Here, and henceforth, we drop the primes to avoid cluttering the equations. The stressfree conditions (6.3.1) on the upper and lower surfaces simply become τxz = τyz = τzz = 0
on z = ±1/2.
(6.3.9)
It is helpful to average the momentum equations by integrating (6.3.7) with respect to z and applying (6.3.9). This yields 0=
∂Txy ∂Txx + , ∂x ∂y
0=
∂Txy ∂Tyy + ∂x ∂y
(6.3.10a)
and ∂Ny ∂2w ∂Nx + − G, = 2 ∂t ∂x ∂y
(6.3.10b)
6.3 The linear plate equation
251
where w denotes the average of w across the plate, and the net in-plane and transverse stresses are defined as in Section 4.6 by 1/2 1/2 Tij = τij dz, Nj = τjz dz. (6.3.11) −1/2
−1/2
Similarly, multiplication through by z before integrating leads to the moment balance equations 0=
∂Myy ∂Myx + − Nx , ∂x ∂y
∂Mxy ∂Mxx + + Ny , ∂x ∂y
0=
where the bending moments are defined as in Section 4.6 by 1/2 1/2 Myx = zτxx dz, Mxy = − zτyy dz, −1/2
Myy = −Mxx =
(6.3.12)
(6.3.13a)
−1/2
1/2
−1/2
zτxy dz.
(6.3.13b)
We may now use (6.3.12) to eliminate Nx and Ny from (6.3.10b) to give ∂ 2 Myx ∂ 2 Mxy ∂2w ∂2 (M = + − M ) − − G. yy xx ∂t2 ∂x2 ∂x∂y ∂y 2
(6.3.14)
Hence the deformation of the plate is governed by the averaged equations (6.3.10a) and (6.3.14). We must now relate the averaged stresses and moments to the displacements by using the dimensionless constitutive equations. These take the form ε2 τxx = τxy = ε2 τyy = ε2 τxz = ε2 τyz = ε4 τzz =
ε2 (1 − ν)ux + ε2 νvy + νwz , (1 + ν)(1 − 2ν) u y + vx , 2(1 + ν) ε2 νux + ε2 (1 − ν)vy + νwz , (1 + ν)(1 − 2ν) u z + wx , 2(1 + ν) vz + w y , 2(1 + ν) ε2 νux + ε2 νvy + (1 − ν)wz , (1 + ν)(1 − 2ν)
(6.3.15a) (6.3.15b) (6.3.15c) (6.3.15d) (6.3.15e) (6.3.15f)
where ν is Poisson’s ratio and, in this chapter only, we will occasionally use subscripts as shorthand for partial derivatives of the displacements. When we take the limit ε → 0 in (6.3.15), we treat all the other parameters as
252
Asymptotic analysis
being O (1). In particular, we assume that ν is not too close to either −1 or 1/2, so that we preclude situations such as that described in Section 1.8.
6.3.3 Leading-order equations If we immediately set ε = 0 in (6.3.15), we get the same equation wz = 0 three times. It is therefore expedient first to eliminate wz between the equations to obtain τxx −
ux + νvy ε2 ν τzz = , 1−ν 1 − ν2
τyy −
νux + vy ε2 ν τzz = . 1−ν 1 − ν2
(6.3.16)
This allows us simply to let ε tend to zero in the above equations without having to write the dependent variables as explicit asymptotic expansions. With w independent of z (to leading order), we may integrate (6.3.15d) and (6.3.15e) to obtain u(x, y, z, t) = u(x, y, t) − zwx (x, y, t),
(6.3.17a)
v(x, y, z, t) = v(x, y, t) − zwy (x, y, t)
(6.3.17b)
as ε → 0. The first terms on the right-hand sides give purely in-plane displacements, while the terms proportional to z correspond to bending of the plate. By substituting (6.3.17) back into (6.3.15) and integrating, we find that the averaged stresses and moments satisfy Txx =
ux + νv y , 1 − ν2
Myx = −
Txy =
uy + v x , 2(1 + ν)
wxx + νwyy , 12(1 − ν 2 ) Myy = −Mxx
Tyy =
νux + v y , 1 − ν2
νwxx + wyy , 12(1 − ν 2 ) wxy . =− 12(1 + ν)
Mxy =
(6.3.18)
(6.3.19a) (6.3.19b)
We are reassured by the fact that the expressions (6.3.18) for the in-plane tensions agree with the exact biaxial straining solutions (2.2.19). Equally, the relations between the bending moments and the second derivatives of w reproduce those found in (4.6.8) by ad hoc comparison with exact plane stress solutions. Recalling that Txx , Txy and Tyy satisfy (6.3.10a), we see that the in-plane displacements satisfy a plane strain problem. As explained in Section 2.6, one approach to this problem is to introduce an Airy stress function A(x, y)
6.4 Boundary conditions and Saint-Venant’s principle
253
such that Txx =
∂2A , ∂y 2
Txy = −
∂2A , ∂x∂y
Tyy =
∂2A , ∂x2
(6.3.20)
and elimination of u and v shows that A satisfies the biharmonic equation ∇4 A = 0.
(6.3.21)
Also, by substituting (6.3.19) into (6.3.14), we find that the transverse displacement w satisfies the linear plate equation wtt = −
∇4 w − G. 12(1 − ν 2 )
(6.3.22)
Notice that the equation (6.3.22) for w can be solved independently of u and v. In other words, transverse bending completely decouples from inplane deformation of the plate. In summary, our model consists of the linear partial differential equation (6.3.22) for w and a decoupled biharmonic equation for A. We have derived these equations systematically, without invoking any other assumptions than the scalings in Section 6.3.1. Our derivation is constructive and yields explicit formulae for the other quantities of interest, that is the displacements and stress components. Equation (6.3.22) does not contain the “membrane” term T ∇2 w obtained from a momentum balance argument in Section 4.6. Since the tension T is proportional to the plane strain components ux , vy , etc., this product of T with ∇2 w is nonlinear in the displacements. As hinted at in Section 4.6, it is impossible, starting from the linear Navier equations (1.11.3) and constitutive relations (1.11.1), to obtain any such nonlinear terms. We will show below in Section 6.5 how they arise from a geometrically nonlinear model.
6.4 Boundary conditions and Saint-Venant’s principle 6.4.1 Boundary layer scalings We are now poised to resolve systematically the difficulties encountered in Section 4.6.2 concerning the boundary conditions for plate models. In the light of Section 6.2, it will come as no surprise that we must proceed by addressing a boundary layer region near the edge of the plate. In this boundary layer we will find a model that is fully three-dimensional, but fortunately we will not need to solve it in detail to obtain the sought-after boundary conditions.
254
Asymptotic analysis
z y
x
σx σy σz
Fig. 6.1 The edge of a plate subject to tractions.
For simplicity, we consider only a straight edge x = 0 which is subject to a given traction, so we impose the boundary conditions τxx = σx ,
τxy = σy ,
τxz = σz
at
x = 0,
(6.4.1)
on the dimensionless stress components; see Figure 6.1 for the sign convention. The tractions σx , σy and σz may in general be any functions of y and z. In the plate solutions constructed in Section 6.3, the in-plane stress components are linear functions of z of the form τxx = Txx + 12zMyx ,
τxy = Txy − 12zMxx ,
τyy = Tyy − 12zMxy , (6.4.2a)
and the transverse shear stresses are found from (6.3.7) to be 1 1 2 2 −z , −z , τyz = 6Ny τxz = 6Nx 4 4 τzz = −2
∂2w 1 2 −z . +G z ∂t2 4
(6.4.2b)
(6.4.2c)
Hence, unless the applied tractions have exactly the same dependence on z, it will be impossible to apply the boundary conditions (6.4.1) directly. Moreover, even if the boundary tractions do by chance have a z-dependence consistent with (6.4.2), we can see that there is still a boundary layer to be negotiated before the conditions (6.4.1) can be imposed. To illustrate the
6.4 Boundary conditions and Saint-Venant’s principle
255
difficulty, consider a traction-free edge, so that σx = σy = σz = 0. By naively applying (6.4.1) to (6.4.2), we apparently obtain five conditions, namely Txx = Txy = Myx = Mxx = Nx = 0.
(6.4.3)
However, only four boundary conditions can be imposed on our model for the plate, so at least one of these must be neglected. To address this issue, as in Section 6.2 we now focus our attention on a thin boundary layer in which x = εˆ x, where x ˆ is O (1). To get a nontrivial balance in the Navier equations (6.3.7), we also find it necessary to rescale some of the stress components as follows: τxz =
τˆxz , ε
τyz =
τˆyz , ε
τzz =
τˆzz . ε2
(6.4.4)
In view of (6.3.4), all stress components are now of the same order of magnitude. In particular, the transverse stress is two orders of magnitude larger near the edge of the plate than it is in the interior. This gives us a strong clue that the boundary layer may have an unexpected influence on the rest of the plate.
6.4.2 Equations and boundary conditions After we apply the rescaling (6.4.4) and neglect terms of order ε2 , the Navier equations become ∂ τˆxy ∂ τˆxz ∂ τˆxx +ε + , ∂x ˆ ∂y ∂z ∂ τˆyy ∂ τˆyz ∂ τˆxy +ε + , 0= ∂x ˆ ∂y ∂z ∂ τˆyz ∂ τˆxz ∂ τˆzz 0= +ε + . ∂x ˆ ∂y ∂z
0=
(6.4.5a) (6.4.5b) (6.4.5c)
Here we have used hats to distinguish dependent variables (even unscaled ones) evaluated in the boundary layer from those in the interior. As ε → 0, (6.4.5) effectively reduces to a set of partial differential equations with only x ˆ and z as dependent variables, y being simply a parameter. The boundary conditions on the edge and the upper and lower surfaces read τˆxz = τˆyz = τˆzz = 0 τˆxx = σx , τˆxy = σy , τˆxz = εσz
on z = ±1/2,
(6.4.6a)
on x ˆ = 0.
(6.4.6b)
256
Asymptotic analysis
The rescaled constitutive relations (6.3.15) take the form ∂w ˆ ∂u ˆ ∂ˆ v + ε2 ν +ν , ∂x ˆ ∂y ∂z v ∂u ˆ ∂ˆ 2ε(1 + ν)ˆ τxy = ε + , ∂y ∂x ˆ ∂w ˆ ∂u ˆ ∂ˆ v ε2 (1 + ν)(1 − 2ν)ˆ + ε2 (1 − ν) +ν , τyy = εν ∂x ˆ ∂y ∂z ˆ ∂u ˆ ∂w 2ε2 (1 + ν)ˆ + , τxz = ε ∂z ∂x ˆ ˆ ∂ˆ v ∂w 2ε(1 + ν)ˆ τyz = + , ∂z ∂y ∂w ˆ ∂u ˆ ∂ˆ v ε2 (1 + ν)(1 − 2ν)ˆ + ε2 ν + (1 − ν) . τzz = εν ∂x ˆ ∂y ∂z
ε2 (1 + ν)(1 − 2ν)ˆ τxx = ε(1 − ν)
(6.4.7a) (6.4.7b) (6.4.7c) (6.4.7d) (6.4.7e) (6.4.7f)
As in the antiplane strain example of Section 6.2, we must match the two solutions: the asymptotic behaviour of the inner solution as x ˆ → ∞ must be the same as that of the outer solution as x → 0. In other words, we impose that
∂2w ∂u (0, y) − z 2 (0, y) + · · · , (6.4.8a) ∂x ∂x ∂2w ∂v ∂w (0, y) + εˆ x (0, y) − z (0, y) + · · · , (6.4.8b) vˆ ∼ v(0, y) − z ∂y ∂x ∂x∂y
∂w (0, y) + εˆ x u ˆ ∼ u(0, y) − z ∂x
∂w (0, y) + · · · , ∂x ∼ Txx (0, y) + 12zMyx (0, y) + · · · ,
w ˆ ∼ w(0, y) + εˆ x τˆxx
τˆxy ∼ Txy (0, y) − 12zMxx (0, y) + · · · , 1 2 − z + ··· , τˆxz ∼ 6εNx (0, y) 4 1 2 τˆyz ∼ 6εNy (0, y) − z + ··· , 4 τˆzz ∼ O ε2 as x ˆ → ∞.
(6.4.8c) (6.4.8d) (6.4.8e) (6.4.8f) (6.4.8g) (6.4.8h)
6.4 Boundary conditions and Saint-Venant’s principle
257
6.4.3 Asymptotic expansions Unlike the situation encountered in Section 6.3.3, there is now no way to avoid writing the dependent variables in asymptotic expansions in powers of ε, for example (0) (1) (2) + εˆ τxx + ε2 τˆxx + ··· . τˆxx ∼ τˆxx
(6.4.9)
To leading order in ε, (6.4.5) becomes (0)
(0)
(0)
(0)
(0)
(0)
∂ τˆxx ∂ τˆxz ∂ τˆxy ∂ τˆyz ∂ τˆxz ∂ τˆzz + , 0= + , 0= + , ∂x ˆ ∂z ∂x ˆ ∂z ∂x ˆ ∂z and the integrated versions of these equations are, simply, 1/2 1/2 1/2 ∂ ∂ ∂ (0) (0) τˆ dz = τˆ dz = τˆ(0) dz. 0= ∂x ˆ −1/2 xx ∂x ˆ −1/2 xy ∂x ˆ −1/2 xz 0=
(6.4.10)
(6.4.11)
Hence the average leading-order stresses are constant over the entire boundary layer and, in view of (6.4.6), (6.4.8d), and (6.4.8e), we immediately deduce that the two boundary conditions to be applied to (6.3.21) are 1/2 σx (y, z) dz, (6.4.12a) Txx (0, y) = Txy (0, y) =
−1/2 1/2 −1/2
σy (y, z) dz.
(6.4.12b)
In the same way, multiplying (6.4.10a) by z and averaging over the thickness of the plate, we obtain 1/2 ∂ zˆ τ (0) dz (6.4.13) 0= ∂x ˆ −1/2 xx and therefore, combining (6.4.6) with (6.4.8d), 1/2 zσx (y, z) dz. Myx (0, y) =
(6.4.14)
−1/2
Equations (6.4.12) and (6.4.14) show that the net in-plane tractions and their moment along the edges are balanced by the corresponding stresses on the other side of the boundary layer, as we might have expected physically. Equation (6.4.14), together with (6.3.19a), provides one boundary condition for the outer plate equation (6.3.22). One further boundary condition is needed, and to obtain it we must proceed to the next order in ε, where (6.4.5c) yields (1)
0=
(0)
(1)
∂ τˆyz ∂ τˆzz ∂ τˆxz + + . ∂x ˆ ∂y ∂z
(6.4.15)
258
Asymptotic analysis
Integrating with respect to z, we now find that ∂ 0= ∂x ˆ
1/2
−1/2
(1) τˆxz
1/2
dz + −1/2
(0)
∂ τˆyz dz, ∂y
(6.4.16)
but all we can say thus far, using (6.4.6) and (6.4.8f), is that Nx (0, y) −
1/2 −1/2
σz (y, z) dz = −
1/2
−1/2
∞
0
(0)
∂ τˆyz dˆ xdz. ∂y
(6.4.17)
Hence we cannot entirely escape from resolving the details of the displacements and stresses in the boundary layer if we wish to establish this last boundary condition for the model in the interior of the plate. Expanding u ˆ, vˆ and w ˆ as in (6.4.9), we find from the constitutive relations (6.4.7) that the leading-order displacements are all independent of x ˆ. The matching conditions (6.4.8) then give ¯(0, y) − z u ˆ(0) = u
∂w ∂w (0, y), vˆ(0) = v¯(0, y) − z (0, y), w ˆ (0) = w(0, y). ∂x ∂y (6.4.18)
We further deduce from (6.4.8f) and (6.4.8e) that ∂w ˆ (1) = 0, ∂z
∂u ˆ(0) ∂w ˆ (1) + = 0, ∂z ∂x ˆ
(6.4.19)
from which it follows that ˆ w ˆ (1) = x
∂w (0, y). ∂x
(6.4.20)
Now, from the second Navier equation (6.4.5b), we obtain the antiplane strain problem (0)
(0)
∂ τˆyz ∂ τˆxy + = 0, ∂x ∂z
(6.4.21)
where, from (6.4.7), (0) = 2(1 + ν)ˆ τxy
∂ˆ v (1) ∂u ˆ(0) + , ∂y ∂x ˆ
(0) 2(1 + ν)ˆ τyz =
∂w ˆ (1) ∂ˆ v (1) + . ∂z ∂y
(6.4.22)
Hence vˆ(1) satisfies the two-dimensional Laplace equation 2 (1) 2 (1) ˆ 2 vˆ(1) = ∂ vˆ + ∂ vˆ = 0, ∇ ∂x ˆ2 ∂z 2
(6.4.23)
6.4 Boundary conditions and Saint-Venant’s principle
259
subject to the boundary conditions ∂u ˆ(0) ∂ˆ v (1) = 2(1 + ν)σy − ∂x ∂y (1) (1) ∂w ˆ ∂ˆ v =− ∂z ∂y
at x ˆ = 0,
(6.4.24a)
1 at z = ± . 2
(6.4.24b)
The matching condition (6.4.8b) leads to ∂2w ∂ˆ v (1) ∼ −ˆ x (0, y), ∂z ∂x∂y
(6.4.25)
as x ˆ → ∞, while combining (6.4.8a) and (6.4.8e) yields ∂u ∂2w ∂ˆ v (1) ∼ − (0, y) + z (0, y) + 2(1 + ν) Txy (0, y) − 12zMxx (0, y) . ∂x ˆ ∂y ∂x∂y (6.4.26) By cross-differentiation, we see that these two conditions are consistent only if ∂2w (0, y) = 12(1 + ν)Mxx (0, y), (6.4.27) ∂x∂y and this reassuringly reproduces the outer constitutive relation (6.3.19b). After using this relation, we can write vˆ(1) in the form ∂u (1) (0, y) x ˆ vˆ = 2(1 + ν)Txy (0, y) − ∂y − 12(1 + ν)Mxx (0, y)ˆ xz + 2(1 + ν)φ, (6.4.28) where φ satisfies ˆ 2 φ = 0, ∇ ∂φ = 0, ∂z ∂φ = 12Mxx (0, y)z + σy (y, z) − Txy (0, y), ∂x ˆ φ → 0,
(6.4.29a) 1 z=± , 2
(6.4.29b)
x ˆ = 0,
(6.4.29c)
x ˆ → ∞.
(6.4.29d)
The solvability of this Neumann problem for φ is ensured since 1/2 ∂φ ˆ 2 φ dˆ ds = Txy (0, y) − xdz = σy (y, z) dz, (6.4.30) 0= ∇ ∂n −1/2 where the integration region is the strip [0, ∞] × [−1/2, 1/2], and we have
260
Asymptotic analysis
already established that the right-hand side above vanishes. Hence we can solve for φ by separating the variables: ∞
φ=
an (y) cos nπ(z + 1/2) e−nπ xˆ ,
(6.4.31)
n=1
where an (y) = −
2 nπ
1/2
−1/2
Fy (y, z) cos nπ(z + 1/2) dz,
(6.4.32a)
and Fy (y, z) = 12Mxx (0, y)z + σy (y, z).
(6.4.32b)
The stress components are then given in terms of φ as (0) τˆxy = Txy (0, y) − 12Mxx (0, y)z +
∂φ , ∂x ˆ
(0) τˆyz =
∂φ , ∂z
(6.4.33)
(0)
ˆ = 0 to the giving the transition of τˆxy from the prescribed function σy on x expected linear z-dependence in the outer region. This therefore illustrates the antiplane strain version of Saint-Venant’s principle: the details of the traction applied to the edge are lost outside the narrow boundary layer. Only the net force and moment exerted by the edge traction are transmitted to the interior of the plate. At last, we are in a position to evaluate (6.4.17) as
1/2
∂ σz (y, z) dz = − Nx (0, y) − ∂y −1/2
∞
φ(ˆ x, y, 1/2) − φ(ˆ x, y, −1/2) dˆ x.
0
(6.4.34) Substituting for φ from (6.4.32), we get
∞
φ(ˆ x, y, 1/2) − φ(ˆ x, y, −1/2) dˆ x=−
0
=2
−1/2
=−
1/2
Fy (y, z)
∞ 1 − (−1)n n=1
∞ 1 − (−1)n n=1
n2 π 2
nπ
an (y)
cos nπ(z + 1/2)
dz
1/2
−1/2
Fy (y, z)z dz,
(6.4.35)
6.5 The von K´ arm´ an plate equations
261
and (6.4.34) therefore becomes 1/2 1/2 ∂ Mxx (0, y) + σz (y, z) dz = σy (y, z)z dz . Nx (0, y) − ∂y −1/2 −1/2 (6.4.36) We easily recognise in the left-hand side of (6.4.36) the difference between the vertical shear forces on either side of the boundary layer. The righthand side represents the rate of change of the net bending moment about the x-axis that is produced by the outer moment and the edge traction. All that matters for the plate model (6.3.21), (6.3.22) is that both contributions balance; this is akin to the angular momentum balance (4.4.3) that arises in linear beam theory. Both sides of (6.4.36) are statically equivalent in the interior of the plate. Neither the transverse stress nor the twisting moment is conserved across the boundary layer; instead (6.4.36) represents a playoff between the two effects. To summarise, we have obtained the four boundary conditions (6.4.12), (6.4.14) and (6.4.36) that apply at a straight edge of a plate when specified tractions are imposed. At a stress-free edge, for example, these take the form Txx = Txy = Myx = Nx −
∂Mxx = 0, ∂y
(6.4.37)
in agreement with (4.6.18). This concludes our systematic derivation of linear plate theory. It has revealed how much more complicated is the derivation of the boundary conditions compared to that of the field equations. Indeed the boundary layer near the plate edge is crucial in determining the global response of the plate and the asymptotic approach leading to (6.4.4) reveals that the normal stresses there can exceed the shear stresses by two orders of magnitude.
6.5 The von K´ arm´ an plate equations 6.5.1 Background In Section 6.3, we modelled the deformation of a plate using linear elasticity. In other words, we assumed that the strains are sufficiently small for all nonlinear terms to be neglected a priori. We then used another assumption, namely that the plate is geometrically thin, to reduce the three-dimensional Navier equations to the linear plate equation (6.3.22) and a decoupled plane strain problem (6.3.20), (6.3.21) for the horizontal displacements. In practice, however, the tractions and displacements applied at the edge may well cause coupling between in-plane stretching and transverse bending. For
262
Asymptotic analysis
example, putting a membrane under increasing tension through in-plane stretching certainly affects its response to transverse oscillations. Equally, we will see that bending a plate in two orthogonal directions can induce net in-plane stress. To generalise the theory of Section 6.3, we begin by realising that a plate, with thickness h and longitudinal dimensions of order L, undergoing a transverse displacement of order W , is characterised by two small parameters, namely the slenderness parameter ε = h/L and δ = W/L, which is the size of a typical transverse strain. In Section 6.3, by using linear elasticity we were implicitly neglecting all terms of order δ 2 , although we had to consider corrections of order ε2 during our derivation. This suggests that there is a r´egime in which the small parameters δ and ε are roughly equal, so that the transverse displacement is roughly equal to the plate thickness, and the strains, although small, are not negligible. In the language of perturbation methods, this is a distinguished limit, in which we let δ and ε tend to zero simultaneously, rather than setting δ to zero first and only subsequently using the fact that ε is small. The choice of an appropriate coupling between two small parameters will lead us to a weakly nonlinear model, which is similar in spirit to the Euler strut analysis of Section 4.9.3, where the small parameters were the excess applied force above the buckling force and the amplitude of the induced perturbation. By following this approach, we will now systematically derive the von K´ arm´an plate model, encountered previously in Section 4.7, in which there is strong coupling between bending and stretching. The crucial coupling terms are nonlinear and hence could not possibly have been obtained from linear elasticity. The analysis carried out below therefore serves as an illustration of the need for geometrically nonlinear elasticity even in situations where the strains are small. Although the details are more complicated, the asymptotic techniques involved are analogous to those used in Section 6.3, and so we omit many of the details.
6.5.2 Scalings We consider a uniform plate of thickness h whose centre-surface lies in the plane Z = 0, where now (X, Y, Z) are Lagrangian coordinates which must be distinguished from Eulerian coordinates (x, y, z). The coordinates are scaled with their typical values as follows: X = LX ,
Y = LY ,
Z = hZ .
(6.5.1)
6.5 The von K´ arm´ an plate equations
263
As suggested above, we will suppose that the transverse displacement is of the same order as the plate thickness h; in other words, we set W = h. The analysis to follow is simplified by anticipating the fact (demonstrated in Section 6.3) that the leading-order transverse displacement is uniform across the plate. We therefore non-dimensionalise the displacements as follows: u = εhu , v = εhv , w = h w (x, y, t) + ε2 w ˜ . (6.5.2) We follow (6.3.4) in non-dimensionalising the first Piola–Kirchhoff stress tensor as (6.5.3a) (T11 , T12 , T21 , T22 ) = ε2 E T11 , T12 , T21 , T22 , 3 (T13 , T23 , T31 , T32 ) = ε E T13 , T23 , T31 , T32 , (6.5.3b) T33 = ε4 ET33 ,
(6.5.3c)
and the dimensionless time is again defined by (6.3.6). Henceforth we drop the primes to avoid clutter.
6.5.3 Leading-order equations After non-dimensionalising and neglecting terms of order ε2 , we reduce the the nonlinear momentum equation (5.2.27) to ∂T11 ∂T12 ∂T13 + + , ∂X ∂Y ∂Z ∂T21 ∂T22 ∂T23 0= + + , ∂X ∂Y ∂Z ∂2w ∂T32 ∂T33 ∂T31 + + − G, = 2 ∂t ∂X ∂Y ∂Z 0=
(6.5.4a) (6.5.4b) (6.5.4c)
where now G=
ρ0 gh . ε4 E
(6.5.5)
The dimensionless boundary conditions on the stress-free surfaces of the plate are T13 = T23 = T33 = 0
on Z = ±1/2.
(6.5.6)
As in Section 6.3, it is helpful to integrate (6.5.4) with respect to Z and apply (6.5.6) to obtain the averaged stress and moment equations 0=
∂T 12 ∂T 11 + , ∂X ∂Y
0=
∂T 21 ∂T 22 + , ∂X ∂Y
(6.5.7)
264
Asymptotic analysis
∂T 31 ∂2w ∂T 32 = + − G, ∂t2 ∂X ∂Y
(6.5.8)
∂M22 ∂M12 ∂M11 ∂M21 + − T 13 , + + T 23 , 0= ∂X ∂Y ∂X ∂Y where the averaged stresses and bending moments are defined by 1/2 T ij = Tij dZ, 0=
M11 M12 = M21 M22
(6.5.9)
(6.5.10)
−1/2 1/2
−T21 −T22 Z dZ. T11 T12 −1/2
(6.5.11)
In terms of dimensionless variables, the deformation gradient tensor is given by ε2 u Y εuZ ε2 u X F =I + (6.5.12) ε2 vX ε2 vY εvZ . 3 3 2 εwX + ε w ˜X εwY + ε w ˜Y ε w ˜Z Recall from Section 5.2.2 that the first Piola–Kirchhoff stress tensor is not symmetric, but satisfies T F T = F T T.
(6.5.13)
This provides three independent scalar equations which, using (6.5.3) and (6.5.12), may be reduced to (6.5.14a) T21 = T12 + O ε2 , 2 T31 − T13 = wX T11 + wY T12 + O ε , (6.5.14b) 2 (6.5.14c) T32 − T23 = wX T21 + wY T22 + O ε . The in-plane averaged stress tensor is therefore symmetric to leading order, and, as in Section 6.3, we can deduce from (6.5.7) the existence of an Airy stress function A(X, Y ) such that T 11 =
∂2A , ∂Y 2
T 21 = T 12 = −
∂2A , ∂X∂Y
T 22 =
∂2A ∂X 2
(6.5.15)
up to order ε2 . We can also use (6.5.14b), (6.5.14c) and (6.5.9) to eliminate T 31 and T 32 from (6.5.8) and hence obtain the generalisation of (6.3.14) as ∂ 2 M11 ∂ 2 M12 ∂ 2 M21 ∂ 2 M22 ∂2w − − + G = + ∂t2 ∂X 2 ∂X∂Y ∂X∂Y ∂Y 2 2 2 2 ∂2w ∂2A ∂ w∂ A ∂ w ∂2A + + − 2 . (6.5.16) ∂Y 2 ∂X 2 ∂X∂Y ∂X∂Y ∂X 2 ∂Y 2
6.5 The von K´ arm´ an plate equations
265
To close the problem, we must now impose a constitutive relation. We note that the strain tensor, expanded in powers of ε, takes the form 0 0 u Z + wX ε 1 E= F TF − I = 0 0 vZ + wY 2 2 u Z + wX vZ + wY 0 2 u Y + vX + wX wY 0 2uX + wX ε2 + u Y + vX + wX wY 2vY + wY2 0 2 2 2 0 0 2w ˜ Z + u Z + vZ + O ε3 . (6.5.17) The smallness of ε justifies assuming that the second Piola–Kirchhoff stress tensor S is linear† and, arguing as in Section 5.3.6, we write, in dimensional variables, S = λTr (E)I + 2µE. The dimensionless form of (6.5.18) is S11 S12 εS13 1 ν Tr (E)I + E. ε2 S12 S22 εS23 = (1 + ν)(1 − 2ν) 1+ν 2 εS13 εS23 ε S33
(6.5.18)
(6.5.19)
On the other hand, by definition, T = F S, and considering first just the lowest-order expressions for T13 and T23 , namely wX + u Z wY + vZ + O ε2 , + O ε2 , ε2 T23 = (6.5.20) ε2 T13 = 2(1 + ν) 2(1 + ν) we deduce, as in (6.3.17), that u = u(X, Y, t) − ZwX ,
v = v(X, Y, t) − ZwY .
(6.5.21)
Making use of these expressions for u and v, we then find that, to lowest order, ε2 T33 =
2 + w 2 + 2ν(u + v ) + 2(1 − ν)w ˜Z wX X Y Y + O ε2 2(1 + ν)(1 − 2ν)
(6.5.22)
and, hence, w ˜Z = − †
2 + w 2 + 2ν(u + v ) wX X Y Y . 2(1 − ν)
(6.5.23)
had we used a nonlinear relation of the form (5.3.23), the smallness of ε would have led to a similar theory in which some of the coefficients in the lowest-order model were modified as in the example of Section 5.2.4; the correction to the stress-strain relation would be at most of O ε2
266
Asymptotic analysis
We can now use (6.5.21) and (6.5.23) to evaluate the remaining stress components as 2 + ν(2v + w 2 ) 2uX + wX Y Y , 2(1 − ν 2 ) u Y + vX + wX wY , = 2(1 + ν)
T11 = T21 = T12
T22 =
2 ) + 2v + w 2 ν(2uX + wX Y Y , 2(1 − ν 2 )
(6.5.24a) (6.5.24b) (6.5.24c)
up to order ε2 . We now have all the ingredients we need to construct the von K´ arm´an equations. By averaging (6.5.24), we obtain T 11 = T 12 = −
2 + ν(2v + w 2 ) 2uX + wX ∂2A Y Y = , 2 2 ∂Y 2(1 − ν )
∂2A u Y + v X + wX wY = , ∂X∂Y 2(1 + ν)
T 22 =
2 ) + 2v + w 2 ν(2uX + wX ∂2A Y Y , = ∂X 2 2(1 − ν 2 )
(6.5.25a) (6.5.25b) (6.5.25c)
and the simultaneous solution of (6.5.25a) and (6.5.25c) reveals that uX +
2 wX ∂2A ∂2A = − ν , 2 ∂Y 2 ∂X 2
vY +
wY2 ∂2A ∂2A = − ν . 2 ∂X 2 ∂Y 2
(6.5.26)
Thus u and v may be eliminated by differentiating (6.5.25b) with respect to X and Y and using (6.5.26), giving 2 2 ∂2w ∂2w ∂ w 4 − = 0. (6.5.27) ∇ A+ 2 2 ∂X ∂Y ∂X∂Y Expressions for the bending moments are found by multiplying (6.5.24) with respect to Z and then integrating: 2 ∂ w 1 ∂2w M21 = − , (6.5.28a) +ν 12(1 − ν 2 ) ∂X 2 ∂Y 2 ∂2w 1 , 12(1 + ν) ∂X∂Y 2 ∂ w 1 ∂2w . ν = + 12(1 − ν 2 ) ∂X 2 ∂Y 2
M11 = −M22 = M12
(6.5.28b) (6.5.28c)
6.6 The Euler–Bernoulli plate equations
267
Thus (6.5.16) reduces to ∇4 w ∂2w ∂2A ∂2w ∂2A ∂2w ∂2A ∂2w + G + − 2 . (6.5.29) = + ∂t2 12(1 − ν 2 ) ∂Y 2 ∂X 2 ∂X∂Y ∂X∂Y ∂X 2 ∂Y 2 With a suitable change of notation, (6.5.27) and (6.5.29), are the von K´ arm´an equations (4.7.11), (4.7.12) for transverse motions of a thin elastic plate. In principle the approach of Section 6.4 can be adapted to determine the boundary conditions to be applied to (6.5.27) and (6.5.29) when specified edge tractions are given. However, since the strain in any boundary layer region will be small, we can anticipate that the results of such an analysis would be analogous to those found in Section 6.4, with just a rigid-body translation and rotation superimposed.
6.6 The Euler–Bernoulli plate equations 6.6.1 Dimensionless equations Next we would like to give an asymptotic derivation of the Euler–Bernoulli beam model of Section 4.9. However, in the light of the analogy made at the end of Section 4.6.1, we will instead consider the simpler problem of bending a thin elastic plate whose thickness h is much smaller than its length L. This allows us to make the simplifying assumption that the deformation is purely plane strain in the (x, z)-plane. The resulting model will differ slightly from the beam theory derived in Section 4.9, where our derivation was based on plane stress. We will discover that, as in Section 4.6.1, the only practical difference between the two is a scalar factor in the bending stiffness. As usual, a two-dimensional plate is described using the Lagrangian coordinates (X, Z), where −h/2 < Z < h/2, 0 < X < L, the corresponding Eulerian coordinates (x, z) point initially at (X, Z) being such that a material occupies the position x(X, Z, t), z(X, Z, t) at any subsequent time t. We non-dimensionalise X and Z with their typical values, while allowing for large displacements as follows: X = LX ,
Z = hZ ,
x = Lx ,
z = Lz .
(6.6.1)
268
Asymptotic analysis
In contrast to (6.5.3), the first Piola–Kirchhoff stress components are nondimensionalised using (T11 , T31 ) = εE T11 , T31 , (T13 , T33 ) = ε2 E T13 , T33 , (6.6.2) and the time-scale is chosen to make t of O (1), where ) h ρ0 t. t= 2 ε E
(6.6.3)
The two-dimensional momentum equations become ∂T13 ∂T11 ∂2x + , = ∂t2 ∂X ∂Z ∂2z ∂T33 ∂T31 ε 2 = + − εG, ∂t ∂X ∂Z
ε
(6.6.4a) (6.6.4b)
where the relevant dimensionless gravity parameter is now G=
ρ0 gh = εG. ε3 E
(6.6.5)
We can relate the stress components in (6.6.4) using the symmetry property (6.5.13) which, in two dimensions, reduces to zX T11 + zZ T13 = xX T31 + xZ T33 ,
(6.6.6)
where we again use suffices to denote partial derivatives. Using the boundary conditions T13 = T33 = 0
on Z = ±1/2,
(6.6.7)
we may again obtain integrated versions of (6.6.4), namely ε
∂T 11 ∂2x , = ∂t2 ∂X
ε
∂2z ∂T 31 − εG, = ∂t2 ∂X
(6.6.8)
where over-bars denote transverse averages as in Section 6.5. A balance of moments is obtained by subtracting x×(6.6.4b) from z×(6.6.4a), that is by taking the cross product between x and the momentum equation, before integrating with respect to Z. Using the symmetry condition (6.6.6) and again applying the boundary conditions (6.6.7), we find 1/2 1/2 ∂ ∂ (zxt − xzt ) dZ = (zT11 − xT31 ) dZ + εGx, (6.6.9) ε ∂t −1/2 ∂X −1/2 which represents net conservation of angular momentum.
6.6 The Euler–Bernoulli plate equations
z
269
Z X θ x
Fig. 6.2 The geometry of a deformed two-dimensional plate.
6.6.2 Asymptotic structure of the solution Now, to impose a constitutive relation, we must calculate the deformation and strain tensors. As in Section 6.5, this is simplified by anticipating the structure of the solution and then justifying our assumptions a posteriori. Here we suppose that the displacement is, to leading order, uniform across the plate, so that x(X, Z, t) = x(0) (X, t) + εx(1) (X, Z, t) + +ε2 x(2) (X, Z, t) + O ε3 , (6.6.10a) 3 (0) (1) 2 (2) z(X, Z, t) = z (X, t) + εz (X, Z, t) + +ε z (X, Z, t) + O ε . (6.6.10b) In addition, we assume as in Chapter 4 that the plate is inextensible to leading order, so that the distance between any two material points on the centre-line Z = 0 is approximately conserved. It follows that, to leading order, X measures arc-length along the deformed plate, so we can write ∂x(0) = cos θ, ∂X
∂z (0) = sin θ, ∂X
(6.6.11)
where θ(X, t) is the angle between the centre-line of the plate and the xaxis. Finally, we suppose that each transverse section through the plate is to leading order simply rotated through the angle θ, as shown in Figure 6.2, so that x(1) = −Z sin θ,
z (1) = Z cos θ.
(6.6.12)
These physically plausible assumptions are justified in Exercise 6.4, and they ensure that the O (1) displacement (6.6.10) is consistent with the stress scalings in (6.6.2).
270
Asymptotic analysis
6.6.3 Leading-order equations The deformation gradient tensor takes the form (2) ∂xi cos θ − sin θ −ZθX cos θ xZ ∼ +ε +O ε2 , (6.6.13) F = (2) sin θ cos θ ∂Xj −ZθX sin θ zZ in which the leading-order term is simply a rotation through the angle θ. Hence, the strain tensor is given by (2) (2) ε 1 T −2ZθX xZ cos θ + zZ sin θ E= F F −I ∼ (2) (2) (2) 2 2 x(2) Z cos θ + zZ sin θ −2xZ sin θ + 2zZ cos θ + O ε2 . (6.6.14) Since the strain is small, we can again limit our attention to the mechanically linear dimensional constitutive relation S = F −1 T = λTr (E)I + 2µE.
(6.6.15)
We non-dimensionalise (6.6.15) using (6.6.2) and expand the stress components in powers of ε, writing (0) (1) (0) (1) T11 = T11 + εT11 + O ε2 , T31 = T31 + εT31 + O ε2 , (6.6.16) to obtain (0)
(0)
T11 cos θ + T31 sin θ =
(2) (2) −(1 − ν)ZθX + ν zZ cos θ − xZ sin θ (1 + ν)(1 − 2ν)
,
(6.6.17a) (2)
0=
(2)
(0) T31
cos θ −
(0) T11
(2)
xZ cos θ + zZ sin θ , 2(1 + ν)
(6.6.17b)
(2)
x cos θ + zZ sin θ , (6.6.17c) sin θ = Z 2(1 + ν) (2) (2) −νZθX + (1 − ν) zZ cos θ − xZ sin θ 0= , (1 + ν)(1 − 2ν) (6.6.17d)
from which it follows that (0)
T11 = −
ZθX cos θ , 1 − ν2
(0)
T31 = −
ZθX sin θ . 1 − ν2
(6.6.18)
6.6 The Euler–Bernoulli plate equations (0)
271
(0)
Thus T 11 = T 31 = 0, so the lowest-order averaged stresses are (1)
(1)
Tx = T 11 ,
Tz = T 31 ,
(6.6.19)
in the x- and z-directions respectively. The averaged momentum equations (6.6.8) thus give us (now dropping the superscripts) ∂Tx ∂2x , = 2 ∂t ∂X
∂2z ∂Tz − G. = 2 ∂t ∂X
(6.6.20)
Next we use (6.6.10) and (6.6.16) to expand x, z and the stress components in the angular momentum equation (6.6.9) and simplify the result to obtain ∂M + Tx sin θ − Tz cos θ = 0, ∂X where the bending moment is given by 1/2 (0) (0) M= T11 cos θ + T31 sin θ Z dZ = − −1/2
θX . 12(1 − ν 2 )
(6.6.21)
(6.6.22)
Equations (6.6.20) and (6.6.21) are equivalent to the dynamic beam model (4.11.8), when we identify the tangential and normal internal stresses with N = Tz cos θ − Tx sin θ.
T = Tx cos θ + Tz sin θ,
(6.6.23)
However, since we have modelled the bending of a plate rather than a beam, we have obtained the constitutive relation (6.6.22) between bending moment and curvature, rather than (4.11.9). One advantage of our systematic approach is that we can determine the details of the internal stresses and strains which are not predicted by the ad hoc theory of Section 4.9. As an illustration, we will now show briefly how the longitudinal stretching of the plate can be found.
6.6.4 Longitudinal stretching By substituting (6.6.18) into the momentum equations (6.6.4), we find that the other two leading-order stress components are given by (θX cos θ)X (θX sin θ)X 1 1 (0) (0) 2 2 − = − Z , T Z . (6.6.24) T13 = 33 2(1 − ν 2 ) 4 2(1 − ν 2 ) 4 (2)
(2)
We can also determine xZ and zZ from (6.6.17) and integrate to obtain x(2) = a(x, t) −
νZ 2 θX sin θ , 2(1 − ν)
z (2) = b(x, t) +
νZ 2 θX cos θ , 2(1 − ν)
(6.6.25)
272
Asymptotic analysis
where a and b are as yet arbitrary. Note that the centre-line of the plate is deformed to (0) x(X, 0, t) x (X, t) + ε2 a(X, t) + · · · , (6.6.26) ∼ xc (X, t) = z(X, 0, t) z (0) (X, t) + ε2 b(X, t) + · · · so that ∂xc ∼ ∂X
cos θ 2 aX +ε + ··· . sin θ bX
and arc-length s along the centre-line is thus related to X by ∂xc ∂s ∼ 1 + ε2 (aX cos θ + bX sin θ) + · · · . = ∂X ∂X
(6.6.27)
(6.6.28)
Arc-length is therefore conserved up to order ε2 : this is consistent with our assumption that the plate is approximately inextensible. 2 The small longitudinal stretching that does occur is described by the O ε correction on the right-hand side of (6.6.28), which may be determined by analysing the constitutive relation (6.6.15) in more detail as follows. Considering the expressions for S11 and S33 at O ε2 , we find 2 3 − 10ν + 9ν 2 − ν 3 Z 2 θX (1) (1) T11 cos θ + T31 sin θ = 2(1 − ν 2 )(1 − ν)(1 − 2ν) (1 − ν) (aX cos θ + bX sin θ) + (1 + ν)(1 − 2ν) ν (3) (3) + zZ cos θ − xZ sin θ , (1 + ν)(1 − 2ν) (6.6.29a) and
2 1 − 2ν + 4Z 2 (1 − 3ν + ν 2 ) θX 0= 8(1 − ν 2 )(1 − 2ν) ν (aX cos θ + bX sin θ) + (1 + ν)(1 − 2ν) (1 − ν) (3) (3) zZ cos θ − xZ sin θ , (6.6.29b) + (1 + ν)(1 − 2ν)
respectively. By eliminating the final terms involving the third-order strains, we find (1) (1) aX cos θ + bX sin θ = 1 − ν 2 T11 cos θ + T31 sin θ 2 ν − 12(1 − ν)Z 2 θX + (6.6.30) 8(1 − ν)
6.7 The linear rod equations
273
and integration with respect to Z over (−1/2, 1/2) leads to 2 (1 − 2ν)θX . aX cos θ + bX sin θ = 1 − ν 2 T − 8(1 − ν)
(6.6.31)
Equation (6.6.31) tells us how much the plate stretches along its centreline. Recall that T = (Tx cos θ + Tz sin θ) is the tension in the plate, so we should not be surprised that the stretch increases linearly with T . Perhaps less intuitive is the final term which is quadratic in the curvature and tells us that bending the plate inevitably causes it to shrink.
6.7 The linear rod equations 6.7.1 Dimensionless equations We now consider the deflection of a straight rod whose centre-line initially lies along the x-axis. This time, we use as slenderness parameter √ A , (6.7.1) ε= L where L is the rod length and A denotes the area of the cross-section. As with the linear plate equation, we suppose that the rod undergoes transverse displacements of order W , small enough for the linear Navier equations to be valid. The scalings that apply to the present situation are analogous to those employed in Section 6.3, namely ) L ρ t= t , (6.7.2a) ε E (x, y, z) = L(x , εy , εz ),
(6.7.2b)
(6.7.2c) (u, v, w) = W (εu , v , w ), EW , τxz , ετyy , ετyz , ετzz (τxx , τxy , τxz , τyy , τyz , τzz ) = , (6.7.2d) ετxx , τxy L so that the dimensionless Navier equations (with primes dropped) take the form ∂τxy ∂τxz ∂2u ∂τxx + + , = ε2 2 ∂t ∂x ∂y ∂z ∂τyy ∂τyz ∂τxy ∂2v + + , ε2 2 = ∂t ∂x ∂y ∂z ∂τyz ∂τzz ∂τxz ∂2w ε2 2 = + + − ε2 G, ∂t ∂x ∂y ∂z ε4
where G is defined by (6.3.8) and represents downwards gravity.
(6.7.3a) (6.7.3b) (6.7.3c)
274
Asymptotic analysis
Recall that the rod is assumed to be uniform, so its cross-section occupies a fixed two-dimensional region D in the (y, z)-plane. Our scalings for y and z imply that D has unit area in terms of dimensional variables. In addition, we define the x-axis to lie along the centre-line of the rod, that is the centroid of D. These choices lead to the conditions dydz = 1, y dydz = 0, z dydz = 0. (6.7.4) D
D
D
The unit normal n to the boundary ∂D lies entirely in the (y, z)-plane, that is n = (0, ny , nz )T . If no surface tractions are applied to the rod, we therefore have the boundary conditions ny τxy + nz τxz = ny τyy + nz τyz = ny τyz + nz τzz = 0
on ∂D.
(6.7.5)
By integrating (6.7.3) with respect to y and z, using the divergence theorem and applying the boundary conditions (6.7.5), we obtain the averaged equations ε2
∂T ∂2u , = 2 ∂t ∂x
ε2
∂Ny ∂2v , = 2 ∂t ∂x
ε2
∂Nz ∂2w − ε2 G, = 2 ∂t ∂x
where bars now denote the average over the cross-section, that is f= f dydz
(6.7.6)
(6.7.7)
D
and the tension and shear stresses are defined by T = τ xx ,
Ny = τ xy ,
Nz = τ xz .
(6.7.8)
An equation representing net conservation of angular momentum about the centre-line of the rod is found by taking y×(6.7.3c)−z×(6.7.3b) before integrating over the cross-section. Again using the divergence theorem and applying (6.7.5), we find ε2
∂2 ∂Mx , (yw − zv) = 2 ∂t ∂x
(6.7.9)
where Mx = yτxz − zτxy
(6.7.10)
is the torque about the centre-line. Finally, by multiplying (6.7.3a) by y and z before integrating over the cross-section, we deduce ε4
∂2 ∂Mz − Ny , (yu) = −ε2 2 ∂t ∂x
ε4
∂My ∂2 − Nz , (zu) = ε2 2 ∂t ∂x
(6.7.11)
6.7 The linear rod equations
275
where Mz = −yτxx
My = zτxx ,
(6.7.12)
are the bending moments about the y- and z-axes respectively. Now we use (6.7.11) to eliminate Ny and Nz from (6.7.6), neglecting terms of order ε2 , to obtain the equations ∂ 2 Mz ∂ 2 v¯ = − , ∂t2 ∂x2
∂ 2 My ¯ ∂2w = − G, ∂t2 ∂x2
(6.7.13)
governing transverse bending; these equations are equivalent to (4.5.1) and (4.5.2). Our equations of motion will be (6.7.13) combined with the axial stress balance (6.7.6a) and the axial angular momentum balance (6.7.9); 2 with O ε corrections neglected, these reduce to ∂Mx ∂T = = 0. ∂x ∂x
(6.7.14)
6.7.2 Constitutive relations We must now use constitutive equations to relate the axial tension T , the axial torque Mx and the transverse bending moments My and Mz to the deformation of the beam. After using the scalings (6.7.2), we find that the non-dimensionalised linear constitutive equations read ε2 (1 − ν)ux + νvy + νwz , (1 + ν)(1 − 2ν) ε2 νux + (1 − ν)vy + νwz , = (1 + ν)(1 − 2ν) ε2 νux + νvy + (1 − ν)wz , = (1 + ν)(1 − 2ν)
u y + vx , 2(1 + ν) u z + wx , = 2(1 + ν) vz + w y . = 2(1 + ν)
ε2 τxx =
τxy =
(6.7.15a)
ε2 τyy
τxz
(6.7.15b)
ε2 τzz
ε2 τyz
(6.7.15c)
As usual, the dependent variables are all written as asymptotic expansions in powers of the small parameter ε2 , typically u ∼ u(0) + ε2 u(1) + · · · .
(6.7.16)
At leading order, we deduce from (6.7.15) that the transverse displacements satisfy ∂w(0) ∂v (0) ∂w(0) ∂v (0) = = + =0 ∂y ∂z ∂z ∂y
(6.7.17)
276
Asymptotic analysis
and must therefore take the form v (0) (x, y, z, t) = a(x, t) − zc(x, t),
w(0) (x, y, z, t) = b(x, t) + yc(x, t), (6.7.18)
where the arbitrary functions a and b represent uniform translations in the y- and z-directions, while c corresponds to rotation of the cross-section. By substituting for τxy and τxz from (6.7.15) into (6.7.3a) and (6.7.5), we find that the leading-order axial displacement satisfies the two-dimensional Laplace equation, ∂ 2 w(0) ∂ 2 u(0) ∂ 2 v (0) ∂ 2 u(0) − = 0, + = − ∂y 2 ∂z 2 ∂x∂y ∂x∂z subject to the Neumann boundary condition ∂a ∂c ∂b ∂c ∂u(0) ∂u(0) + −z + nz + +y =0 ny ∂y ∂x ∂x ∂z ∂x ∂x
(6.7.19a)
on ∂D.
(6.7.19b) The boundary-value problem (6.7.19) may be simplified by writing u(0) in the form u(0) (x, y, z, t) = U (x, t) − y
∂b ∂c ∂a −z + ψ(y, z) , ∂x ∂x ∂x
(6.7.20)
where U is the mean axial displacement, as yet unknown, and where ψ satisfies ∂2ψ ∂2ψ + =0 ∂y 2 ∂z 2 ∂ψ ∂ψ − z + nz +y =0 ny ∂y ∂z
in D,
(6.7.21a)
on ∂D.
(6.7.21b)
The canonical boundary-value problem (6.7.21) is identical to that obtained in Section 2.4 for the axial displacement in a bar undergoing pure torsion. For a given cross-sectional shape, (6.7.21) determines ψ(y, z) uniquely up to the addition of an arbitrary constant. A simple extension of the argument in Section 2.4 now reveals that the axial torque is related to the twist c by Mx = R
∂c , ∂x
where
R=
φ (1 + ν)
(6.7.22)
is the dimensionless torsional rigidity of the rod, as in Section 2.4. More importantly, since we are considering a uniform rod and Mx has already been shown to be spatially uniform from (6.7.14), it follows that the
6.7 The linear rod equations
277
twist c must be a linear function of x, as in the exact theory of Chapter 2. Hence (0)
(0)
∂τxz ∂τxy = = 0, ∂x ∂x
(6.7.23)
so the transverse components of the Navier equation (6.7.3) reduce to (0)
(0)
(0)
∂τyz ∂τyy + = 0, ∂y ∂z
(0)
∂τyz ∂τzz + = 0. ∂y ∂z
(6.7.24)
These are just the steady plane strain equations and, subject to the zerotraction boundary conditions (6.7.5), imply that the leading-order transverse stress components are all zero: (0) (0) (0) = τyz = τzz = 0. τyy
(6.7.25)
Next we determine the axial tension T = τ xx . The constitutive relation (6.7.15) at order ε2 gives (0)
(1)
(1)
(0) = τxx
(1 − ν)ux + νvy + νwz , (1 + ν)(1 − 2ν)
(0) τyy =0=
νux + (1 − ν)vy + νwz , (1 + ν)(1 − 2ν)
(0)
(1)
(0)
(0) τzz
(1)
(6.7.26a)
(1)
(6.7.26b)
(1)
νux + νvy + (1 − ν)wz , =0= (1 + ν)(1 − 2ν)
(6.7.26c)
from which we can eliminate v (1) and w(1) to obtain (0) τxx =
∂U ∂2a ∂u(0) ∂2b = −y 2 −z 2. ∂x ∂x ∂x ∂x
(6.7.27)
By integrating over D and recalling that y and z are zero, we deduce that the tension is equal to the axial stretch, T =
∂U , ∂x
(6.7.28)
exactly as in the uniaxial stretching discussed in Section 2.2.3. Finally, we find the bending moments My and Mz by multiplying (6.7.27) through by y and z before integrating over D. This results in (0)
∂2a ∂2b − I , yz ∂x2 ∂x2 ∂2a ∂2b = −My = −Iyz 2 − Izz 2 , ∂x ∂x
yτxx = Mz = −Iyy (0)
zτxx
(6.7.29a) (6.7.29b)
278
Asymptotic analysis
where I again denotes the tensor 2 Iyy Iyz y yz I= = dydz. 2 Iyz Izz D yz z
(6.7.30)
The transverse bending equations (6.7.13) therefore reduce to ∂4a ∂4b ∂2a = −I − I , yy yz ∂t2 ∂x4 ∂x4
∂2b ∂4a ∂4b = −I − I − G, yz zz ∂t2 ∂x4 ∂x4
(6.7.31)
which, with a suitable change of notation, is the rod model (4.5.7). The ideas expounded in this section could now be combined with those of Euler–Bernoulli plate theory to construct a systematic nonlinear rod theory, and thereby validate Section 4.9. Rather than performing this by-nowroutine exercise, we will conclude this chapter with a brief discussion of linear shell theory.
6.8 Linear shell theory 6.8.1 Geometry of the shell Our final asymptotic model deals with the generalisation of Section 6.3 to cover infinitesimal deformations of a fully fledged elastic shell, as distinct from the weakly curved shell of Section 4.8. The initial centre-surface of the shell is parametrised by r = r c (ξ1 , ξ2 ),
(6.8.1)
in which ξ1 and ξ2 are two spatial parameters. Since we restrict our attention to linear elasticity, there is no need to distinguish between Lagrangian and Eulerian coordinates. We will use curvilinear coordinates (ξ1 , ξ2 , n) to describe any point in the plate whose position vector is r = r c (ξ1 , ξ2 ) + nn,
(6.8.2)
where n is the unit normal to the centre-surface oriented as described below. As described in Appendix 1, the task of writing down the Navier equations is relatively straightforward if the coordinate system (ξ1 , ξ2 , n) is orthogonal. This can be achieved by choosing coordinates ξ1 and ξ2 that parametrise lines of curvature, with respect to which the first and second fundamental forms of the centre-surface are both diagonal, that is ∂r c ∂r c · = 0, ∂ξ1 ∂ξ2
∂ 2 rc ·n=0 ∂ξ1 ∂ξ2
(6.8.3)
6.8 Linear shell theory
279
(see for example Kreyszig, 1959). This choice simplifies the derivations but does not involve any loss of generality, since we will find that the final equations may readily be expressed in any other convenient coordinate system. We set ∂r c ∂r c , , a2 (ξ1 , ξ2 ) = (6.8.4) a1 (ξ1 , ξ2 ) = ∂ξ1 ∂ξ2 and hence define an orthonormal basis {e1 , e2 , n}, where e1 =
1 ∂r c , a1 ∂ξ1
e2 =
1 ∂r c , a2 ∂ξ2
n = e1 ×e2 .
(6.8.5)
The derivatives of these basis vectors are given by 1 ∂a1 ∂e1 =− e2 + κ1 a1 n, ∂ξ1 a2 ∂ξ2 1 ∂a2 ∂e2 =− e1 + κ2 a2 n, ∂ξ2 a1 ∂ξ1 ∂n = −κ1 a1 e1 , ∂ξ1
∂e1 1 ∂a2 = e2 ∂ξ2 a1 ∂ξ1 ∂e2 1 ∂a1 = e1 , ∂ξ1 a2 ∂ξ2 ∂n = −κ2 a2 e2 , ∂ξ2
(6.8.6a) (6.8.6b) (6.8.6c)
where κ1 and κ2 are the principal curvatures of the centre-surface. Applying these identities to the parametrisation (6.8.2), we find that ∂r = a1 (1 − κ1 n)e1 , ∂ξ1
∂r = a2 (1 − κ2 n)e2 , ∂ξ2
∂r = n, ∂n
(6.8.7)
so this coordinate system is indeed orthogonal, with scaling factors h1 = a1 (1 − κ1 n),
h2 = a2 (1 − κ2 n),
h3 = 1.
(6.8.8)
6.8.2 Dimensionless equations We denote the shell thickness by h, so its surfaces (assumed stress-free) are given by n = ±h/2. As usual we assume here that h is constant, although it is straightforward to apply the same methods to a shell with non-uniform thickness. We also define L to be a typical radius of curvature, so the lengths in the problem are non-dimensionalised via 1 (κ , κ ). (6.8.9a) L 1 2 We denote the displacement field by u = u1 e1 +u2 e2 +wn. Because the shell is assumed not to be nearly flat, we must expect the in-plane and transverse displacements to be of the same order, say n = hn ,
(ξ1 , ξ2 ) = L(ξ1 , ξ2 ),
(κ1 , κ2 ) =
(u1 , u2 , w) = W (u1 , u2 , w ),
(6.8.9b)
280
Asymptotic analysis
where W is small enough for linear elasticity to apply. The Cauchy stress tensor, relative to the curvilinear coordinate system, is now scaled using (τ11 , τ12 , τ22 ) =
EW ε2 EW τ11 , τ12 , τ22 , (τ13 , τ23 , τ33 ) = τ13 , τ23 , τ33 , L L (6.8.9c)
as distinct from (6.3.4), and the appropriate time-scale is now ) ρ t. t=L E
(6.8.9d)
Gravity is assumed to act in the direction −k and is represented by its dimensionless components along each of the basis vectors, defined as g1 = −
ρgL2 (k · e1 ) , EW
g2 = −
ρgL2 (k · e2 ) , EW
g3 = −
ρgL2 (k · n) . EW (6.8.10)
To avoid clutter, we henceforth drop the primes on the dimensionless variables. 6.8.3 Leading-order equations The Navier equations and linear constitutive relations in an arbitrary orthogonal coordinate system may be found in the Appendix. As in the previous sections, we simplify the dimensionless equations by letting ε → 0 to obtain ∂ 1 ∂ ∂a1 ∂a2 ∂ 2 u1 , − g1 = (a2 τ11 ) + (a1 τ12 ) + τ12 − τ22 ∂t2 a1 a2 ∂ξ1 ∂ξ2 ∂ξ2 ∂ξ1 (6.8.11a) ∂ 1 ∂ ∂a2 ∂a1 ∂ 2 u2 , − g2 = (a2 τ12 ) + (a1 τ22 ) + τ12 − τ11 ∂t2 a1 a2 ∂ξ1 ∂ξ2 ∂ξ1 ∂ξ2 (6.8.11b) ∂2w − g3 = κ1 τ11 + κ2 τ22 , (6.8.11c) ∂t2 at leading order. Once we have used the constitutive relations to express τ11 , τ12 and τ22 in terms of the displacements, (6.8.11) will give us three equations for u1 , u2 and w. The constitutive relations imply that the displacement components are all independent of n to leading order. Furthermore, the dimensionless constitutive relation for τ33 reads νe11 + νe22 + (1 − ν)e33 = ε2 τ33 , (1 + ν)(1 − 2ν)
(6.8.12)
6.8 Linear shell theory
281
which we can use to express e33 in terms of e11 and e22 , and hence obtain τ11 =
e11 + νe22 , 1 − ν2
τ22 =
νe11 + e22 . 1 − ν2
The relevant leading-order strain components are 1 ∂u1 u2 ∂a1 − κ1 w, + e11 = a1 ∂ξ1 a2 ∂ξ2 1 ∂u2 u1 ∂a2 − κ2 w, e22 = + a2 ∂ξ2 a1 ∂ξ1 1 ∂w , e33 = ε ∂n while the leading-order in-plane shear stress reads ∂u1 ∂a1 ∂u2 ∂a2 1 τ12 = − u1 + a2 − u2 a1 . 2(1 + ν)a1 a2 ∂ξ2 ∂ξ2 ∂ξ1 ∂ξ1
(6.8.13)
(6.8.14a) (6.8.14b) (6.8.14c)
(6.8.15)
Space does not permit a detailed discussion of the system (6.8.11)–(6.8.15) for u1 , u2 and w, although some indication of the richness of its solutions may be discerned in Exercises 6.6 and 6.7. Here we will merely add a few general observations. Although we have derived our leading-order model using the specific coordinate system defined by (6.8.2), it may be cast in an invariant form that is independent of the parametrisation chosen. The momentum equations (6.8.11) may be written as ˆ ∂2u ˆ · τˆ, ˆ=∇ −g 2 ∂t
∂2w − g3 = K : τˆ, (6.8.16) ∂t2 ˆ is the surface gradient ˆ = u − wn is the in-plane displacement, ∇ where u operator, τˆ is in-plane stress and K is the curvature tensor. In the same notation, the in-plane stress satisfies the constitutive relation ν 1 ˆ E+ Tr Eˆ I, (6.8.17) τˆ = 2 1+ν 1−ν where the surface strain tensor is given by 1ˆ ˆ u)T − wK. (6.8.18) ∇ˆ u + (∇ˆ Eˆ = 2 The theory just derived describes deformations in which the in-plane tensions dominate and the bending stiffness is negligible. However, our model allows for nontrivial displacements that cause zero leading-order stress. For example, if we let the shell tend to a flat sheet so that κ1 = κ2 = 0, then the normal displacement w decouples entirely from the in-plane stresses and is arbitrary in the absence of bending stiffness. Similarly, a cylinder bent about
282
Asymptotic analysis
its generators offers no resistance to a large class of displacements, as shown in Exercise 6.6. More generally, elimination of w from (6.8.14) and (6.8.15) shows that zero stress results from in-plane displacement fields satisfying the system of partial differential equations ∂ ∂ a2 κ2 0 u1 0 −a1 κ1 u1 + 0 a2 ∂ξ1 u2 a1 0 ∂ξ2 u2 κ1 u1 ∂a2 /∂ξ1 − κ2 u2 ∂a1 /∂ξ2 . (6.8.19) = u1 ∂a1 /∂ξ2 + u2 ∂a2 /∂ξ1 It is easy to calculate that the characteristic curves for this system are given by ) a1 κ1 dξ2 =± − . (6.8.20) dξ1 a2 κ2 Hence (6.8.19) is elliptic, parabolic or hyperbolic, depending on the sign of the Gaussian curvature, exactly as in Section 4.8, and we can expect the existence of a zero-stress mode compatible with given boundary conditions to depend strongly on this type. In cases where the imposed boundary conditions are compatible with (6.8.19), the displacement field is not uniquely determined by our model. The resolution of the indeterminacy would require us to consider a geometrically nonlinear limit similar to that which led to the von K´ arm´an theory in Section 6.5. This would describe weakly nonlinear deformations of a shell, in which the in-plane stresses and bending stiffness balance, but this is beyond the scope of this book.
6.9 Concluding remarks It is comforting to see that some of the approximate models in Chapter 4, which were derived on the basis of intuition and plausibility, can be recovered by systematic perturbation procedures. The asymptotic approach outlined here, however, provides us with a much more detailed picture of the stress field than the approximate theories alone. For instance, we have been able to resolve its three-dimensional structure in the vicinity of the boundaries and elucidate the Saint-Venant principle. Additionally, we have seen the fascinating challenges posed by geometric nonlinearity. Perhaps the biggest surprise is that the familiar membrane terms in equations like (4.4.8) actually arise, and can only be derived, from geometrically nonlinear elasticity. A recurrent pattern in the asymptotic methodology has emerged: first, the geometry of the solid suggests particular scalings for the displacement
Exercises
283
field; then, the stress components are rescaled so as to balance as many terms as possible in the Navier equations; finally, these equations are analysed asymptotically, or, if we are lucky, by suitable global averaging over boundary layers. We have only been concerned with plates, shells and rods with uniform thickness or cross-section and comparable elastic moduli. If the thickness of the plate were to vary rapidly with a typical length-scale L, a quite new theory would be needed. The same would be true if µ/λ 1 (i.e. ν is close to 1/2). In such cases, we would have to state precisely what are the relative orders of magnitude of the various small parameters involved, namely ε, /L, and µ/λ. In particular, there is no reason to expect that the limits ε → 0 and µ/λ → 0 would commute.
Exercises 6.1
Reconsider the antiplane strain example of Section 6.2, this time assuming that the bottom and top of the sheet are subjected to tractions τyz = σ− (x) and τyz = σ+ (x) on y = 0 and y = h, respectively. (a) Non-dimensionalise using the same perturbation scheme as in Section 6.2 away from the edges. Rescaling the surface trac tions as σ± (x) = (µW/h) 2 σ± (x), derive the solvability condi tion σ+ − σ− = O ε . (b) Hence, letting σ+ = σ− + ε2 σ, deduce from the solvability condition at O ε2 that d2 w0 + σ = 0. dx2
6.2
Repeat the linear rod derivation from Section 6.7 using the fast timescale ) ρ t . t = εL E Show that the decompositions (6.7.18), (6.7.20) still apply, where the functions a, b, c and U satisfy the equations ∂2a = 0, ∂t2
∂2b = 0, ∂t2
(Iyy + Izz )
∂2c ∂2c = R , ∂t2 ∂x2
∂2U ∂2U = . ∂t2 ∂x2
[This shows that longitudinal and torsional waves occur over a much shorter time-scale than the flexural waves considered in Section 6.7.]
284
6.3
Asymptotic analysis
Derive the governing equations for a weakly curved shell as follows. Suppose the upper and lower surfaces of the shell are given in dimensionless variables by 1 Z = H(X, Y ) ± , 2 so that H(X, Y ) represents the undeformed centre-surface, and the stress-free boundary conditions read T13 =
∂H ∂H ∂H ∂H T11 + T12 , T21 + T22 , T23 = ∂X ∂Y ∂X ∂Y ∂H ∂H T31 + T32 , T33 = ∂X ∂Y
on Z = H ± 1/2. Use the asymptotic approach of Section 6.5 to derive the equations 2 ∂2w ∂X∂Y ∂2H ∂2w ∂2H ∂2w ∂2H ∂2w + + − 2 ∂Y 2 ∂X 2 ∂X∂Y ∂X∂Y ∂X 2 ∂Y 2
∂2w ∂2w − −∇ A= ∂X 2 ∂Y 2 4
and ∂ 2 (H + w) ∂ 2 A ∂2w ∇4 w = + G + ∂t2 12(1 − ν 2 ) ∂Y 2 ∂X 2 ∂ 2 (H + w) ∂ 2 A ∂ 2 (H + w) ∂ 2 A + −2 . ∂X∂Y ∂X∂Y ∂X 2 ∂Y 2 6.4
Show that these reduce to (4.8.9) and (4.8.11) when |w| |H|. Show that the strain tensor in Section 6.6 is given by 2 −1 1 x2X + zX ε−1 (x X xZ + zX zZ ) . E= 2 ε−1 (xX xZ + zX zZ ) ε−2 x2Z + zZ2 − 1 Hence, show that T is O ε−2 E unless (6.6.10) is assumed. Further, show that the components of S must be at most O (εE) for the scaling (6.6.2) to hold and therefore that 2 2 2 2 ∂x(0) ∂z (0) ∂x(1) ∂z (1) + = 1, + = 1, ∂X ∂X ∂Z ∂Z ∂z (0) ∂z (1) ∂x(0) ∂x(1) + = 0. ∂X ∂Z ∂X ∂Z From this, justify (6.6.11) and (6.6.12).
Exercises
6.5
285
Show that the stress–strain relations for the scalings appropriate to linear rod theory are ε2 (1 − ν)ux + νvy + νwz , (1 + ν)(1 − 2ν) ε2 νux + (1 − ν)vy + νwz = , (1 + ν)(1 − 2ν) ε2 νux + νvy + (1 − ν)wz , = (1 + ν)(1 − 2ν)
u y + vx , 2(1 + ν) u z + wx = , 2(1 + ν) vz + w y , = 2(1 + ν)
ε2 τxx =
τxy =
ε2 τyy
τxz
ε2 τzz
ε2 τyz
and deduce (6.7.18). Furthermore, eliminate v and w to show that τxx − ν (τyy + τzz ) = ux . 6.6
(a) Taking (ξ1 , ξ2 , n) = (θ, z, r) and (u1 , u2 , w) = (uθ , uz , ur ) in cylindrical polar coordinates, show that a1 = r, a2 = 1, κ1 = 1/r and κ2 = 0, in the notation of Section 6.8. (b) Hence derive the equations of motion τθθ ∂ 2 ur , − gr = ∂t2 r ∂ 2 uθ ∂τθz 1 ∂τθθ + , − gθ = ∂t2 r ∂θ ∂z ∂ 2 uz ∂τzz 1 ∂τθz + , − gz = ∂t2 r ∂θ ∂z for a circular cylindrical shell of radius r. (c) Show that displacements of the form uθ = f (θ), ur = f (θ), uz = 0 generate no strain and hence no stress in the leadingorder shell theory. (d) Show also that such a displacement exists for a cylindrical shell with any cross-section. [This shows that a cylinder can undergo deformations that are one order of magnitude larger if bent along a generator than otherwise.]
6.7
(a) Taking (ξ1 , ξ2 , n) = (θ, φ, r) and (u1 , u2 , w) = (uθ , uφ , ur ) in spherical polar coordinates, show that a1 = r, a2 = r sin θ and κ1 = κ2 = 1/r. (b) Deduce that the equations of motion for a spherical shell of
286
Asymptotic analysis
radius r are τθθ + τφφ ∂ 2 ur , − gr = 2 ∂t r ∂τθφ ∂ 2 uθ ∂ 1 (sin θτθθ ) + − τφφ cos θ , − gθ = ∂t2 r sin θ ∂θ ∂φ ∂τφφ ∂ 2 uφ 1 ∂ (sin θτθφ ) + + τθφ cos θ . − gφ = ∂t2 r sin θ ∂θ ∂φ (c) Suppose that the strain is identically identically zero. Eliminate ur and uθ (or use (6.8.19) directly) to show that uφ satisfies the equation ∂ 2 uφ ∂ uφ 2 ∂ sin θ = 0, + sin θ ∂φ2 ∂θ ∂θ sin θ while
∂ uφ ∂uθ = − sin2 θ , ∂φ ∂θ sin θ
and ur =
∂uθ . ∂θ
By seeking separable solutions that are periodic in φ, show that possible solutions for uφ are (i)
uφ = sin θ,
(ii) uφ = sin θ log tan(θ/2) , (iii) uφ = sin(kφ) sin θ tank (θ/2), and find the corresponding expressions for uθ and ur . [Hint: show that sin θ ∂/∂θ = ∂/∂ξ with ξ = log tan(θ/2).] (d) Note that (i) is simply a rigid body motion. Show that the remaining solutions are physically unacceptable if the shell is a complete sphere. Discuss solutions (ii) and (iii) for hemispherical shells. Show that (ii) gives rise to a multi-valued displacement. To which physical situation could it correspond?
7 Fracture and contact
7.1 Introduction Fracture describes the behaviour of thin cracks, like the one illustrated in Figure 7.1, in an otherwise elastic material. The crack itself is a thin void, whose faces are usually assumed to be stress-free. When a solid containing a crack is stressed, we will find that the stress is localised near the crack tip, becoming singular if the tip is sharp. We will see that the strength of the singularity can be characterised by a stress intensity factor, which depends on the size of the crack and on the applied stress. This factor determines the likelihood that a crack will grow and, therefore, that the solid will fail.† On the other hand, contact refers to the class of problems in which two elastic solid bodies are brought into contact with each other, as illustrated in Figure 7.2. When the material properties are the same in the two bodies, the geometrical configuration near the edge of the contact region is apparently similar to that of fracture, with voids now outside the contact set, that is, the set of points at which the two solids are in contact. The mathematical setup of such problems does therefore have some similarity with fracture, but, in the steady state, there is one crucial difference. Whereas much of the study of fracture concerns cracks of prescribed length, in contact problems the contact set itself is often unknown in advance. They are thus known as free boundary problems, that is problems whose geometry must be determined along with the solution. An example of such a problem is to determine how the contact area between a car tyre and the road depends on the inflation pressure. †
The reader may be reassured to know that, although several cracks emanate from many rivets in an airliner, they are carefully monitored to ensure that none of them is dangerous.
287
288
Fracture and contact crack tip
crack faces
Fig. 7.1 Definition sketch of a thin crack.
contact set
Fig. 7.2 Definition sketch for contact between two solids.
7.2 Static brittle fracture 7.2.1 Physical background In Section 2.2.5, we proposed the idea that the theory of linear elasticity may fail when some stress components in a solid reach a critical value at some point. While this statement is generally true, the way in which failure occurs can be very different for different solids, or even for the same solid under different loading conditions. This section will focus on the simplest mathematical model for one type of failure, namely brittle fracture. The adjective “fractured” is usually used to describe configurations where a continuum solid has developed cracks, which are very thin stress-free voids. These voids are characterised by being thin in only one direction so that they are nearly slits in a two-dimensional solid (see Figure 7.1). Thus a crack has two faces with a common perimeter which is called the crack tip, and the tip is just two points in the two-dimensional case. Cracks are often initiated
7.2 Static brittle fracture
289
at the surface of the material, which is usually the only place where they can be discerned by the naked eye. Brittle fracture covers that class of fractures, such as windscreen shattering, where the initiation and growth of the crack do not affect the material modelling, which is still governed by the Navier equations. Such a situation might not be true for a metal, where quite a large region near the crack tip may have to be modelled using plasticity rather than elasticity equations; then the fracture is called ductile, and we will discuss this further in Chapter 8. We can say little more here about the physical background of this vast and important subject. However, we urge the reader to think intuitively that fracturing, i.e. crack growth, is basically a local stress-relieving mechanism. As a crack grows, the strain energy in the evolving fractured configuration is less than the value it would have taken had the crack not evolved. This argument suggests that the criterion for a crack to evolve under a small increase of loading is that the release, −δW, of strain energy resulting from a small growth δA in the crack face area is such that −δW dx > δS,
(7.2.1)
V
where V denotes the region excluding the crack and δS is the surface energy of the area δA. In principle, δS could be estimated from molecular considerations but, in the theory of Griffith cracks (see, for example, Sneddon & Lowengrub, 1969, Chapter 1; Freund, 1989, Chapter 1) δS is thought of as resulting from an effective surface tension γ; in this case, δS = γδA. It is interesting to compare fracture with the more familiar failure of a liquid, which cavitates when the pressure is too low, so that the molecular bonds weaken and allow the molecules to form a vapour. This often results in the appearance of a spherical bubble, whereas a crack morphology is usually the one preferred by solids. The difference in behaviour arises because it is easier to create new interface between a liquid and a vapour than it is to create new interface between a solid and a void. Hence a crack can grow most easily by creating new surface energy just in the vicinity of the crack tip. It is also instructive to contrast fracture, which often occurs as a result of some remote loading process, with the drilling of a thin hole through the solid (for example using a shaped charge; see Section 3.6). It is an everyday observation that the energy required to drill a hole per unit surface area generated is greater than that required to cleave the material using an axe.
290
Fracture and contact (a)
(b)
τyz → σIII y
σIII −c
σIII
c τyz = 0
x
x y
τyz → σIII
Fig. 7.3 (a) A Mode III crack. (b) A cross-section in the (x, y)-plane.
7.2.2 Mode III cracks Let us now investigate the predictions of the Navier model for linear elasticity in the presence of a crack. The very simplest configuration is that of a crack in antiplane strain, which is called a Mode III crack, as illustrated in Figure 7.3. Although this configuration is not so important in practice, it is much simpler mathematically than Mode I and II cracks, which will be introduced later. We will consider a planar crack whose faces lie close to the (x, z)-plane between the crack tips x = ±c, y = 0. The physical set-up is that of a large cracked slab being sheared at infinity in the (y, z)-plane with a shear stress σIII . Assuming that the faces of the crack are stress free, we find that the mathematical model for the displacement w(x, y) in the z-direction is ∇2 w = 0
(7.2.2a)
everywhere except on y = 0, |x| < c, with ∂w → σIII ∂y ∂w =0 µ ∂y
µ
as
x2 + y 2 → ∞,
(7.2.2b)
on
y = 0, |x| < c.
(7.2.2c)
There is a fundamental difference between (7.2.2) and most of the boundary value problems we have thus far considered for elastostatics, namely that the boundary on which the Neumann data (7.2.2c) are prescribed is not smooth at the crack tip. To see the kind of difficulty that this can cause, suppose we were to shift the origin to (−c, 0) and concentrate on the region near the crack tip. Then we would need to find a displacement field in which ∇2 w = 0 everywhere except on y = 0, x > 0, with µ
∂w =0 ∂y
on y = 0, x > 0.
(7.2.3)
7.2 Static brittle fracture
291
By separating the variables in polar coordinates (r, θ), we immediately see that w can be any function of the form w = Arn/2 cos(nθ/2) = A Re z n/2 , (7.2.4) where z = reiθ , A is a constant and n is an integer. The corresponding stress components are given by τrz =
µnA n/2−1 r cos(nθ/2), 2
τθz = −
µnA n/2−1 r sin(nθ/2). 2
(7.2.5)
This plethora of solutions gives us the strong hint that we will not be able to solve (7.2.2) uniquely unless we supply some extra information about the behaviour of w near (±c, 0). We also note that, whenever n is not an even positive integer, the stress is non-analytic at the crack tip r = 0, and, if n < 2, the stress is not even bounded. From a mathematical point of view it is natural to ask whether the solution of (7.2.2) must be singular at (±c, 0) and, if so, what is the mildest singularity which we have to endure. To answer these questions, one possibility is to round off the crack, that is, to replace it with a thin but smooth boundary. A particularly convenient shape is the ellipse y2 x2 + = 1, 2 c2 cosh ε c2 sinh2 ε
(7.2.6)
which is smooth for all positive ε but approaches the slit geometry of Figure 7.3(b) in the limit ε → 0. Now we can easily solve Laplace’s equation by introducing elliptic coordinates defined by z = x + iy = c cosh ζ,
where
ζ = ξ + iη,
(7.2.7a)
so that x = c cosh ξ cos η,
y = c sinh ξ sin η.
(7.2.7b)
Since the map (7.2.7) from z to ζ is conformal except on y = 0, |x| < c, Laplace’s equation is preserved and the model (7.2.2) becomes ∂2w ∂2w + =0 ∂ξ 2 ∂η 2
in ξ > ε
(7.2.8a)
with ∂w =0 ∂ξ
on ξ = ε,
(7.2.8b)
292
Fracture and contact
Im z
z
θ2
r1
r
r2 θ
θ1 c
−c Fig. 7.4 Definition sketch for the function
Re z
√ z 2 − c2 .
and, since y ∼ (c/2)eξ sin η as ξ → ∞, w∼
cσIII ξ e sin η 2µ
as
ξ → ∞.
By separating the variables, we easily find the solution cσIII sin η eξ + e2ε−ξ . w= 2µ
(7.2.8c)
(7.2.9)
We thus have a unique displacement field for any positive value of ε and, when we let ε → 0, we obtain the solution of the crack problem as cσIII Im (sinh ζ) . (7.2.10) w= µ Using (7.2.7), this can be written as w=
σIII Im z 2 − c2 , µ
where the square root is defined to be √ z 2 − c2 ≡ r1 r2 ei(θ1 +θ2 )/2 ,
(7.2.11)
(7.2.12)
with r1 , r2 , θ1 and θ2 defined as shown in Figure 7.4. The angles are taken to lie in the ranges −π < θj < π, so that a branch cut lies along the crack between z = −c and z = c (see, for example, Priestley, 2003, Chapter 9). As shown in Figure 7.5, the displacement w is discontinuous across this branch cut.
7.2 Static brittle fracture
293
w
y x Fig. 7.5 Displacement field for a Mode III crack.
Despite its simplicity, the formula (7.2.11) lies at the very heart of the theory of brittle fracture. It reveals the famous square root singularity in which the elastic displacement varies as the square root of the distance from the crack tip.† By rounding off the crack before taking the limit ε → 0, we have managed to select one of the many possible singular solutions suggested by (7.2.4). This dependence immediately implies that the stress tensor, whose non-zero components are τxz = µ
∂w ∂x
and
τyz = µ
∂w , ∂y
(7.2.13)
diverges as the inverse square root of the distance from the tip. This physically unacceptable consequence renders the Navier model invalid sufficiently close to the tip, but there are several ways of recovering from this setback, including the following. (i) Rounding the tip This is the approach adopted above when considering the elliptical crack (7.2.6), and it is easily shown, using this example, that the stress at the crack tip is given approximately by ) c (7.2.14) τyz ∼ 2σIII r0 when r0 , the tip radius of curvature, is small (Exercise 7.1). (ii) Plastic zone Even if the tip is rounded, (7.2.14) shows that the stress may still become †
A similarly fundamental square root singularity arises in the mathematically analogous theory of aerofoils; (see, for example, Batchelor, 2000, p. 467).
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Fracture and contact
large enough for the material to yield plastically if r0 is sufficiently small. This suggests the introduction of a plastic zone near the tip, and this also has the effect of preventing the stress from growing without bound. We will discuss plasticity further in Chapter 8. (iii) Tip cohesion In (7.2.2), we assumed that the two faces of the crack exert no traction on each other. Instead we might suppose that there is an effective cohesion between the faces, so that (7.2.2c) is replaced by µ
∂w = f (x) ∂y
on y = 0, |x| < c,
(7.2.15)
where f (x) models the cohesive effect of intermolecular bonding, which will be strongest near the crack tip. As shown in Exercise 7.3, a suitable choice of f can be made to ensure that the stress remains finite everywhere. Rather than pursue any of these possibilities for “regularising” our model near the crack tip, we will show how the existence of the square root in (7.2.11) can be exploited to great practical effect. The result (7.2.11) predicts that any critical stress, no matter how large, will always be attained sufficiently close to the crack tip. Hence, let us return to the discussion of (7.2.1) and consider whether or not the crack is dangerous, that is, whether or not it will propagate. This poses the question: “is the local stress large enough for it to do sufficient work to create new surface energy at the crack tip when σIII is increased slightly?” The following answer to this question has formed the basis of the theory of fracture for many decades. We note that, in the material ahead of the crack tip (c, 0), the only nonzero stress component at the crack plane y = 0 is τyz and that √ lim τyz (x, 0) x − c = σIII c/2. (7.2.16) x↓c
Hence, no matter which of the mechanisms such as (i)–(iii) above prevents the stress from becoming infinite in practice, it will have to be triggered by a local stress intensification that is proportional to the inverse square root of distance from the tip. It turns out that the selection of the value n = 1 in (7.2.4) is generic for all Mode III cracks. Every such crack tip is characterised by the limit defined in (7.2.16) and, conventionally, this limit is written as √ KIII (7.2.17) lim τyz (x, 0) x − c = √ . x↓c 2π
7.2 Static brittle fracture
295
The stress intensity factor KIII is the parameter that characterises the propensity of the crack to propagate. For the crack modelled by (7.2.2), √ for example, we find that KIII = πcσIII . We postulate that the crack will propagate if KIII exceeds a critical value, which must be determined either from (i)–(iii) above or from experiment, and which we expect to be proportional to the surface energy γ. Under this postulate, (7.2.16) immediately reveals that a Mode III crack is more likely to grow if it is longer or subject to greater stress. We emphasise that a consequence of this postulate is that KIII is the only piece of information concerning the global stress field that is relevant for deciding whether or not the crack propagates. We will shortly find that the concept of a stress intensity factor applies to many other crack configurations, but first let us review the mathematical challenges posed by problems like (7.2.2).
7.2.3 Mathematical methodologies for crack problems Now let us quickly review some different approaches that we might have adopted to obtain (7.2.11) had we not been able to utilise elliptic coordinates and take the limit as ε → 0. Four possibilities are the following. (i) We could conformally map the region outside the cut y = 0, |x| < c onto the exterior of a circle and solve Laplace’s equation in polar coordinates. This is effectively what we have done to obtain (7.2.11), but in principle the method applies to any antiplane strain crack problem where the relevant conformal map can be found by inspection. However, it crucially relies on the fact that Laplace’s equation is invariant under conformal mapping; as we will see below, considerably more effort is required to generalise this approach to the biharmonic equation. (ii) We could represent w(x, y) as a suitable distribution of functions that are singular on the slit. This approach allows most scope for physical intuition. Noting that tan−1 (y/x) is a solution of Laplace’s equation except at the origin and on a branch cut from the origin, we can directly compute that σIII c ξ tan−1 (x − ξ)/y µw = σIII y − dξ (7.2.18) π −c c2 − ξ 2 is equivalent to (7.2.11), as shown in Exercise 7.2. Thus w can be thought of as resulting from the imposed stress together with a distribution of what are called virtual dislocations, and we will return to this idea in
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Fracture and contact
Chapter 8. This observation suggests that we could have proceeded ab initio by trying c (7.2.19) f (ξ) tan−1 (x − ξ)/y dξ, µw = σIII y + −c
and then the boundary condition (7.2.2c) would have led to a singular integral equation for the function f (ξ). (iii) Since w is an odd function of y, the problem may be formulated in the half-plane y 0 with the boundary conditions w(x, 0) = 0,
|x| > c,
∂w (x, 0) = 0, ∂y
|x| < c.
(7.2.20)
Such problems in which the boundary data switches from Dirichlet to Neumann are called mixed boundary value problems and they can easily pose serious mathematical challenges. Nonetheless, the theory of such mixed problems provides the basis for the most powerful methodology for solving crack problems. The basic idea is to take a Fourier transform in x, which is a simple matter for many planar crack problems until it comes to applying the boundary conditions. However, to take the transform of (7.2.20), we would have to introduce the transforms of both w(x, 0) and ∂w/∂y(x, 0), neither of which do we know explicitly. Nonetheless, if we were bold enough to do this, we would find that it is possible to use analytic continuation in the complex Fourier plane to find w. This is the basis of the Wiener–Hopf method, but we have no space to describe it further here; we simply remark that it is equivalent to the singular integral equation theory that emerges from (ii) above (Carrier, Krook & Pearson, 1983, Chapter 8). (iv) We can exploit the fact that the Papkovich–Neuber representation (2.8.51) may take a particularly simple form when boundary conditions are applied on y = 0. This can give us a very useful shortcut, as we will explain shortly.
7.2.4 Mode II cracks We now move on to study cracks in plane strain. This is inevitably more complicated than antiplane strain since we have to solve the biharmonic equation rather than Laplace’s equation. As pointed out above, there are several approaches to constructing solutions, and we will consider two of
7.2 Static brittle fracture
(a)
(b)
y σII
297
y σII
Ω x
x
σII
σII
∂Ω
Fig. 7.6 (a) A planar Mode II crack. (b) The regularised problem of a thin elliptical crack.
them in detail. We will start by using a conformal mapping technique, which is analogous to that employed in Section 7.2.2 for Laplace’s equation. As before, we will regularise the problem by considering an elliptical crack, with a small but finite diameter of order ε, and then letting ε → 0. Then, we will see how Papkovich–Neuber potentials provide an alternative shortcut to the solution. In a planar Mode II crack, a far-field shear stress σII (not to be confused with σ11 ) parallel to the plane of the crack is applied, as shown in Figure 7.6. We denote the two-dimensional region outside the crack by Ω and the elliptical boundary of the crack by ∂Ω. This is evidently a plane strain problem, so we employ an Airy stress function which, as usual, satisfies the biharmonic equation in Ω. If the crack is stress-free then, as shown in Section 2.6.3, we can without loss of generality impose the boundary conditions ∇A = 0
on ∂Ω.
(7.2.21)
The imposed uniform shear stress far from the crack implies that A has the asymptotic behaviour A ∼ −σII xy
as
x2 + y 2 → ∞.
(7.2.22)
We recall from Section 2.6 that the general solution of the two-dimensional biharmonic equation may be written in the form A = Re z¯f (z) + g(z) , (7.2.23) where f and g are any two analytic functions of z = x + iy. To transform the boundary conditions for A into conditions on f and g, it is helpful to write (7.2.23) in the form A=
1 z¯f (z) + g(z) + z f¯(¯ z ) + g¯(¯ z) , 2
(7.2.24)
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Fracture and contact
where f¯ is the conjugate function to f , that is f¯(¯ z ) ≡ f (z). From (7.2.21), we deduce that 1 ∂A ∂A ∂A = −i =0 (7.2.25) ∂z 2 ∂x ∂y on ∂Ω and, hence, by using (7.2.24), we obtain the condition z ) + g (z) = 0 z¯f (z) + f¯(¯
on ∂Ω.
(7.2.26)
In addition, the far-field behaviour (7.2.22) implies that f and g satisfy iσII 2 z as z → ∞. (7.2.27) 2 Amazingly, the two functions f and g can be determined using only the fact that they are both analytic in Ω and the conditions (7.2.26) and (7.2.27). However, it is not immediately obvious how to do this, and the task is greatly simplified by conformally mapping Ω onto a region that is easier to manipulate. Here we note that the region outside our elliptical crack is the image of the unit disc under the conformal mapping f (z) → 0,
g(z) ∼
b z = ω(ζ) = aζ + , ζ
(7.2.28)
where a and b are real constants with b > a > 0. The principal radii of the ellipse are (a + b) and (a − b), so that ce−ε ceε , b= , (7.2.29) 2 2 in the terminology of Section 7.2.2. We also introduce the notation F (ζ) = f ω(ζ) , G(ζ) = g ω(ζ) (7.2.30) a=
for the transformed versions of f and g. Thus F is analytic in the unit disc |ζ| 1, and G is analytic apart from a double pole at the origin, where G(ζ) ∼
iσII b2 2ζ 2
as
ζ → 0.
(7.2.31)
The boundary condition (7.2.26) is transformed to −F¯ (1/ζ) =
ω ¯ (1/ζ)F (ζ) G (ζ) + ω (ζ) ω (ζ)
at |ζ| = 1,
(7.2.32)
aζ 2 − b , ζ2
(7.2.33)
where ω ¯ (1/ζ) =
a + bζ 2 , ζ
ω (ζ) =
7.2 Static brittle fracture
299
and we use the fact that ζ¯ = 1/ζ on the unit circle. Provided b > a > 0, the map z = ω(ζ) is conformal and hence ω (ζ) is nonzero in the unit disc. The only singularity in the right-hand side of (7.2.32) therefore arises from the pole in G(ζ) at the origin, where we find that G (ζ) iσII b ∼ ω (ζ) ζ
as
ζ → 0.
(7.2.34)
Let us subtract this from both sides of (7.2.32) to remove the singularity from the right-hand side and thus obtain 2 G (ζ) + ζ a + bζ 2 F (ζ) ζ iσ iσII b b II −F¯ (1/ζ) − = − at |ζ| = 1. ζ aζ 2 − b ζ (7.2.35) Now we arrive at the crux of the argument. The left-hand side of (7.2.35) is analytic in |ζ| 1, while the right-hand side is analytic in |ζ| 1. We can therefore use (7.2.35) to analytically continue the left-hand side into |ζ| < 1 and hence obtain a function that is analytic on the entire complex plane and, because of (7.2.27), tends to zero as ζ → ∞ (see, for example, Carrier, Krook & Pearson, 1983, Section 2.8). According to Liouville’s theorem, the only function that has these properties is the zero function, and we deduce that the left- and the right-hand sides of (7.2.35) must both be identically zero. We can therefore evaluate the function F (ζ) as F (ζ) = iσII bζ
(7.2.36)
and, by using this expression in the right-hand side of (7.2.35), we obtain 1 (7.2.37) G (ζ) = −iσII b2 ζ + 3 . ζ By integrating with respect to ζ and ignoring an irrelevant constant of integration, we thus obtain iσII b2 1 2 (7.2.38) −ζ . G(ζ) = 2 ζ2 Finally, by using the inverse mapping √ z − z 2 − 4ab , ζ= 2a
(7.2.39)
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Fracture and contact
where the square root is again defined by (7.2.12), we evaluate the functions f and g in terms of the original variable z as iσII b z − z 2 − 4ab , (7.2.40a) f (z) = 2a √ iσII (7.2.40b) g(z) = 2 (a2 − b2 )(z 2 − 2ab) + (a2 + b2 )z z − 4ab . 4a When substituting these into the formula (7.2.23) for A, we simplify the resulting expression by letting the crack thickness tend to zero, so that a and b both tend to c/2, and thus obtain σII (7.2.41) Im (¯ z − z) z 2 − c2 . A= 2 By using the chain rules ∂ ∂ ∂ ∂ ∂ ∂ = + , =i − , (7.2.42) ∂x ∂z ∂ z¯ ∂y ∂z ∂ z¯ as shown in Exercise 7.4, we can recover the stress components as z f (z) − g (z) + 2f (z) τxx = Re −¯
4z 3 + c2 (¯ σII z − 5z) Im , (7.2.43a) = 2 (z 2 − c2 )3/2 τxy = Im z¯f (z) + g (z)
2z 3 + c2 (¯ z − 3z) σII Re , (7.2.43b) = 2 (z 2 − c2 )3/2 τyy = Re z¯f (z) + g (z) + 2f (z)
σII c2 z − z¯ . (7.2.43c) = Im 2 (z 2 − c2 )3/2 By approximating these in the neighbourhood of the crack tip z = c, we find that √ θ1 5θ1 σII c √ τxx ∼ − + 7 sin , (7.2.44a) sin 2 2 4 2r1 √ θ1 5θ1 σII c + 3 cos , (7.2.44b) cos τxy ∼ √ 2 2 4 2r1 √ σII c 3θ1 τyy ∼ √ , (7.2.44c) sin θ1 cos 2 2 2r1 as r1 → 0, where r1 and θ1 are defined as in Figure 7.4. Hence, as in Mode III cracks, the stress diverges like the inverse square root of the distance from
7.2 Static brittle fracture
301
2
S/σII 1 1
0.8
0.6
y0
0.4
0.2
-1
0 -2 -2
-1
0
1
2
x Fig. 7.7 Contour plot of the maximum shear stress S around a Mode II crack, with crack half-length c = 1.
the crack tip. Ahead of the crack, the only nonzero stress component on the plane y = 0 is found, by setting θ1 = 0, to be √ σII c as x ↓ c. (7.2.45) τxy (x, 0) ∼ 2(x − c) We therefore define the stress intensity factor for Mode II cracks by √ (7.2.46) KII = lim 2π (x − c)τxy (x, 0) = σII πc. x↓c
As in Mode III cracks, we postulate that the crack tip will propagate if KII exceeds some critical value. We visualise the stress field in Figure 7.7 by plotting the contours of the maximum shear stress * ∂ 2 A 2 1 ∂ 2 A ∂ 2 A 2 |τ1 − τ2 | = + − = z¯f (z) + g (z) . S= 2 2 2 ∂x∂y 4 ∂x ∂y (7.2.47) As expected, the stress is concentrated near the crack tips and minimised along the crack faces. This conformal mapping approach can in principle be applied to more complicated crack geometries. However, for the special case of a planar crack, an alternative and somewhat simpler way to proceed is to pose the problem in the half-space y > 0, and then solve it using the Papkovich–Neuber potentials defined in (2.8.51). The boundary conditions on the Airy stress
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Fracture and contact
function are clearly A ∼ −σII xy ∂A =0 A= ∂y
as
y → ∞,
(7.2.48)
on y = 0, |x| < c
(7.2.49)
on y = 0, |x| > c,
(7.2.50)
and A=0
but the second boundary condition on y = 0, |x| > c is less obvious. We can either argue on physical grounds that τxx = 0 or use symmetry arguments to say that ∂2A =0 ∂y 2
on y = 0, |x| > c.
(7.2.51)
Once we have solved this problem for A, the displacement is still determined only up to an arbitrary rigid-body motion. To specify the solution uniquely, we focus on the case of a pure shear parallel to the crack face, so that µu ∼ σII y,
v→0
as
y → ∞.
(7.2.52)
We now follow (2.8.58) by employing a Papkovich–Neuber potential of the form Ψ = (0, ψ(x, y), 0)T . It is convenient to subtract off the behaviour (7.2.52) at infinity so that the displacements are given by 1 ∂ 2µu = 2σII y − φ + yψ , (7.2.53) ∂x 2 1 ∂ φ + yψ , (7.2.54) 2µv = 2 (1 − ν) ψ − ∂y 2 while A satisfies ∂φ 1 ∂ ∂A = −σII x − (1 − ν) ψ + + (yψ) . ∂y ∂y 2 ∂y
(7.2.55)
By construction, we require both ψ and ∇φ to tend to zero as y → ∞. On y = 0, we use the fact that φ is a harmonic function to deduce that ∂u ∂v ∂ψ ∂ 2 φ ∂v +λ + = (1 − ν) − 2. (7.2.56) 0 = τyy = 2µ ∂y ∂x ∂y ∂y ∂y Since this holds for all x and since (1 − ν) ψ − ∂φ/∂y is a harmonic function, we conclude that ∂φ ≡ (1 − ν) ψ. (7.2.57) ∂y
7.2 Static brittle fracture
303
y 0.2
0.1
2 (1 − ν) σII /µ = 0 -1
-0.5
0.5
1
x
-0.1
0.25
-0.2
0.5 Fig. 7.8 The displacement of a Mode II crack of half-length c = 1 under increasing shear stress σII .
We can then integrate (7.2.55) to obtain the Airy stress function in the form yψ . (7.2.58) 2 The remaining boundary conditions (7.2.49) and (7.2.50) give that A = −σII xy +
∂ψ (x, 0) = 2σII , ∂x
|x| < c
(7.2.59)
∂ψ (x, 0) = 0, ∂y
|x| > c,
(7.2.60)
and
with ψ → 0 at infinity. Thus our problem effectively reduces to the harmonic conjugate of the Mode III crack problem (7.2.2), and we can deduce from (7.2.11) the solution ψ = 2σII x − 2σII Re (7.2.61) z 2 − c2 . Substitution of this into (7.2.58) reproduces the expression (7.2.41) for A obtained above using conformal mapping. Finally, we can write φ = Im{h(z)} and, using (7.2.57) and (7.2.61), we find that (7.2.62) h (z) = 2(1 − ν)σII z − z 2 − c2 . Hence, since ∂φ/∂x = Im {h (z)}, we can directly evaluate the displacement on the crack faces y = 0±, |x| < c, as 1 2 2 − ν σII x. µu = ±(1 − ν)σII c − x , µv = (7.2.63) 2
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Fracture and contact
σI y x
σI
Fig. 7.9 A Mode I crack.
As depicted in Figure 7.8, the crack is deformed into an ellipse that grows and rotates as the applied shear stress is increased.
7.2.5 Mode I cracks We now move onto the problem of a crack in plane strain under a tension σI , as shown in Figure 7.9. This is arguably a more realistic configuration than that of either Mode II or Mode III but, unfortunately, the solution turns out to be slightly more difficult to derive in this case. We first follow the same approach as in Section 7.2.4, using an Airy stress function A that satisfies the biharmonic equation in the region Ω outside an elliptical stress-free crack, although the condition at infinity is now A∼
σI 2 x 2
as
x2 + y 2 → ∞.
(7.2.64)
The details of the calculation, following the steps used in Section 7.2.4, may be found in Exercise 7.5. This time the Goursat functions f and g take the form σI (7.2.65a) −z + 2 z 2 − c2 , f (z) = 4 σ c2 σ I I g(z) = − log z + z 2 − c2 + z 2 , (7.2.65b) 2 4
7.2 Static brittle fracture
and the stress components are therefore
2z 3 + c2 (¯ z − 3z) τxx = −σI + σI Re 2 (z 2 − c2 )3/2 √ σI c ∼ √ 3 cos(θ1 /2) + cos(5θ1 /2) , 4 2r1
σ I c2 z − z¯ Im τxy = 4 (z 2 − c2 )3/2 √ σI c ∼ √ cos(3θ1 /2) sin θ1 , 2 2r1
2z 3 − c2 (z + z¯) σI Re τyy = 2 (z 2 − c2 )3/2 √ σI c cos3 (θ1 /2) (3 − 2 cos θ1 ) , ∼√ 2r1
305
(7.2.66a)
(7.2.66b)
(7.2.66c)
as r1 → 0. Ahead of the crack, on θ1 = 0, the nonzero stress components are therefore √ σI c as r1 → 0, (7.2.67) τxx , τyy ∼ √ 2r1 so we define the Mode I stress intensity factor as √ KI = lim 2π (x − c)τyy (x, 0) = σI πc. x↓c
(7.2.68)
As shown in Figure 7.10, the stress is again concentrated near the crack and minimised along the crack faces. As in Section 7.2.4, we can instead adopt the Papkovich–Neuber representation, again subtracting the linear far-field displacement, so that 1 ∂ φ + yψ , (7.2.69a) 2µu = −νσI x − ∂x 2 1 ∂ 2µv = (1 − ν)σI y + 2(1 − ν)ψ − φ + yψ , (7.2.69b) ∂y 2 and the Airy stress function satisfies ∂ ∂A = −(1 − ν)ψ + ∂y ∂y
1 φ + yψ . 2
(7.2.70)
We still have the stress-free boundary conditions (7.2.49) on the crack faces, while symmetry implies that ∂A =v=0 ∂y
on y = 0, |x| > c.
(7.2.71)
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Fracture and contact 2
S/σI 1 1
0.8
0.6
y0
0.4
0.2
-1
0 -2 -2
-1
0
1
2
x Fig. 7.10 Contour plot of the maximum shear stress S around a Mode I crack, with crack half-length c = 1.
Notice that ∂A/∂y is equal to zero on the entire x-axis. Thus (7.2.70) leads to the boundary condition 1 ∂φ = −ν ψ (7.2.72) ∂y 2 on y = 0, and, following the same argument as in Section 7.2.4, we deduce that (7.2.72) holds everywhere. We can then use this identity to integrate (7.2.70) with respect to y and thus obtain 1 φ σI x2 A = yψ − + . 2 1 − 2ν 2
(7.2.73)
In terms of ψ, the remaining boundary conditions read ∂ψ = −2σI ∂y ψ=0
on y = 0, |x| < c,
(7.2.74a)
on y = 0, |x| > c,
(7.2.74b)
and, again by analogy with the Mode III solution (7.2.11), we deduce that z 2 − c2 . ψ = −2σI y + 2σI Im (7.2.75) To complete the solution, we let φ = Re{h(z)} for some analytic function h and, using (7.2.72) and (7.2.75), we find that (7.2.76) h (z) = (1 − 2ν)σI z − z 2 − c2 .
7.2 Static brittle fracture
307
y 0.2
0.1
2 (1 − ν) σI /µ = 0 -1
-0.5
0.5
0.25
-0.1
0.5
-0.2
1
x
Fig. 7.11 The displacement of a Mode I crack of half-length c = 1 under increasing normal stress σI .
This may be integrated to give h(z) =
1 − ν σI z 2 − z z 2 − c2 + c2 log z + z 2 − c2 . (7.2.77) 2
By combining (7.2.73), (7.2.75) and (7.2.77), we obtain a solution for the Airy stress function analogous to the Goursat representation (7.2.65). The displacement of the crack may now be found by evaluating (7.2.69) on y = 0±, |x| < c as 2µu = −νσI x − Re h (z) = −(1 − ν)σI x, 2µv = (1 − ν)ψ = ±2(1 − ν)σI c2 − x2 .
(7.2.78a) (7.2.78b)
Figure 7.11 shows that the crack becomes elliptical, growing wider and shorter as the applied normal stress increases. We conclude this discussion with two remarks. First, we note that a general planar crack in two space dimensions will be a linear superposition of Modes I, II and III, and hence the stress near its tip will be characterised by three intensity factors. The calculations carried out above suggest that all three will scale with the square root of the crack length, but unfortunately there are no general rules about the factors to which a crack will be most vulnerable. Second, the most famous three-dimensional crack configuration is the penny-shaped crack which is the radially symmetric version of our earlier Mode I crack and it can be solved explicitly, with a great deal of effort, by transforming to spheroidal coordinates and taking a limit as in Section 7.2.2. Both these configurations, along with many others, are lucidly described in Sneddon & Lowengrub (1969).
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Fracture and contact
7.2.6 Dynamic fracture All the discussion hitherto refers to models of cracks that are static or just about to grow. If, however, we wish to describe structural failure or the response of tectonic plates to earthquakes, for example, we need to be able to predict the speed of penetration of a growing crack. Unfortunately this involves synthesising the theories of elastic wave propagation from Chapter 3 with those of mixed boundary value problems from this chapter, and this task is beyond the scope of this book (see Freund, 1989, for a helpful account). We therefore restrict our attention to the simplest possible model for a semi-infinite Mode III crack propagating at constant speed −V along the x-axis, so its tip is at x = −V t. Although the global stress field away from the crack will be a complicated history-dependent function of the crack geometry, it is reasonable to assume that the local stress field may be approximated by a travelling wave moving with speed −V , at least on sufficiently short time-scales. Hence, the local displacement will satisfy V 2 ∂2w ∂2w + =0 (7.2.79a) 1− 2 cs ∂ξ 2 ∂y 2 everywhere except on y = 0, ξ > 0, with µ
∂w =0 ∂y
on y = 0, ξ > 0,
(7.2.79b)
where ξ = x + V t and cs is the shear wave speed. Notice that this problem generalises the static semi-infinite Mode III crack problem considered in (7.2.3). To close the model (7.2.79), we should impose some conditions at infinity, but this would require us to solve for the stress away from the crack. Even without precise knowledge of this far field, we expect the physically relevant solution to have a square root singularity analogous to (7.2.4) with n = 1. The corresponding solution of (7.2.79) is ) V2 ξ + iy , where B 2 = 1 − 2 , (7.2.80) w = A Re B cs and it is only through the constant A that the global stress field is felt. Now the dynamic stress intensity factor is ) ) 1/4 ∂w √ V2 πB π KIII = µ 2π lim (ξ, 0) = µA = µA 1− 2 . −ξ ξ↑0 ∂y 2 2 cs (7.2.81)
7.3 Contact
309
Hence, provided A is bounded, as in the example of Exercise 7.7, we see that the stress intensity factor tends to zero as the tip speed tends to the shear wave speed. This is comforting because, unless cracks are boosted by internal pressures or other local driving mechanisms, they are always observed to propagate subsonically. Were a crack tip forced to propagate supersonically, we would expect a shock wave to be generated at the tip, with quite a different stress concentration nearby as compared to the subsonic case.
7.3 Contact 7.3.1 Contact of elastic strings We start by considering the simplest elastic contact problem, namely an elastic string making steady contact under a prescribed body force p(x) against a smooth, nearly flat, rigid obstacle Γ. We use the terminology contact set to denote the set of points at which the string makes contact with the obstacle, and non-contact set for those points where it does not. If the transverse displacement w(x) is assumed to be small, then a force balance on a small element of the string in the non-contact set yields the familiar equation T
d2 w = p(x), dx2
(7.3.1)
where the string tension T is spatially uniform. Provided friction is negligible, T is also constant throughout the contact set, where w is simply equal to the prescribed obstacle height f (x) above the x-axis, which is zero in Figure 7.12. Now we must consider how to join the solutions in the contact and noncontact sets, which leads us to the question of the smoothness of the solution at points where contact is lost, a question we also had to address in our discussion of crack tips. Here this problem is resolved immediately by a local force balance, which reveals that T and T dw/dx must both be continuous. Thus, our task is to solve (7.3.1) in the non-contact set, subject to specified boundary conditions at the ends of the string and w = f,
df dw = dx dx
(7.3.2)
at the points where the string meets the obstacle. Let us illustrate the procedure for a string whose ends x = ±1 are fixed a unit distance above a flat surface z = f (x) = 0. If the applied pressure p is spatially uniform, then we can solve (7.3.1), subject to the boundary
310
Fracture and contact
w 1.0
increasing p 0.8
0.6
0.4
0.2
1.0
0.5
0.5
1.0
x
Fig. 7.12 Solution for the contact between a string and a level surface, with applied pressure p/T = 0, 1, 2, 3, 4, 5.
conditions w(−1) = w(1) = 1, to obtain p (7.3.3) w =1− 1 − x2 . 2T As the applied pressure p is increased, the downward displacement at the centre of the string increases, until it first makes contact with z = 0 when p = 2T . If the pressure is increased further, then a contact set forms near the middle of the string. Let us denote the boundaries of this region by x = ±s, where s is to be determined as part of the solution. In this simple problem, we only need to solve for positive x; the solution in x < 0 may then be inferred by symmetry. We therefore solve (7.3.1) in x > s, subject to w(1) = 1 and the continuity conditions dw (s) = 0 dx
(7.3.4)
p (1 − x)(1 + x − 2s) 2T
(7.3.5)
w(s) = to obtain w =1− in x > s, where
* s=1−
2T . p
(7.3.6)
In Figure 7.12 we see how, as increasing pressure is applied, the string is pushed downward, makes contact with the surface beneath, and the contact set then gradually spreads outwards. This simple example shows how the solution of the contact problem hinges on locating the free boundary between the contact and non-contact sets.
7.3 Contact
(a)
1.0
(b)
z
0.5
311
(c)
z
z
0.30
0.30
0.30
0.25
0.25
0.25
0.20
0.20
0.20
0.15
0.15
0.15
0.10
0.10
0.10
0.05
0.05
x
0.5
1.0 1.0
0.5
x
0.05
0.5
1.0 1.0
0.5
x
0.5
1.0
Fig. 7.13 Three candidate solutions for the contact problem between a stress-free string and the surface z = 2x2 − 3x4 .
Such free boundary problems are inevitably nonlinear even when, as in (7.3.1), the governing equation is itself linear. This means that the solutions of contact problems can exhibit phenomena such as non-uniqueness that are impossible for linear problems. To illustrate some of the possible pitfalls, consider now a string, subject to zero body force, stretched over the curved surface z = f (x) = 2x2 − 3x4
(7.3.7)
with its ends fixed at w(−1) = w(1) = 0. With p = 0, (7.3.1) implies that the string must be straight wherever it is out of contact. The most obvious linear function satisfying both boundary conditions is simply w ≡ 0 but, as can be seen in Figure 7.13(a), this would imply that the string penetrates the obstacle, which is impossible. We must therefore allow the string to make contact with the obstacle, as illustrated in Figure 7.13(b). Recalling that the string must meet the obstacle tangentially, the solution in this case is easily constructed as 2 8 (1 + x), −1 x − , 9 3 2 2 (7.3.8) w = 2x2 − 3x4 , − x , 3 3 2 8 (1 − x), x 1. 9 3 We can, however, construct a third solution, shown in Figure 7.13(c), in which the string loses contact with the middle of the obstacle. Again noting that the string is linear when out of contact and must always make contact
312
Fracture and contact
tangentially, we find that this solution takes the form 2 8 (1 + x), −1 x − , 9 3 1 2 2x2 − 3x4 , − x − √ , 3 3 1 1 1 w= , −√ x √ , 3 3 3 2 1 2x2 − 3x4 , √ x , 3 3 2 8 (1 − x), x 1. 9 3
(7.3.9)
We would like to have a mathematical formulation that chooses between possible candidate solutions like those shown in Figure 7.13. The situation shown in Figure 7.13(a) can be avoided by incorporating the requirement w f into our model. Although it is slightly less obvious, Figure 7.13(b) is also physically unrealistic, since there is a tensile normal stress between the string and the obstacle. In general, if R(x) denotes the normal reaction force exerted on the string by the obstacle, then (7.3.1) is modified to T
d2 w = p − R. dx2
(7.3.10)
The reaction force R must be zero outside the contact set. The solution shown in Figure 7.13(b) has negative values of R and is therefore unphysical; the correct solution is therefore (7.3.9). To summarise, we can select a physically relevant solution of the contact problem by insisting that w = f,
T
d2 w −p<0 dx2
in the contact set,
(7.3.11a)
w > f,
T
d2 w −p=0 dx2
in the non-contact set,
(7.3.11b)
and
with continuity of w and dw/dx at the boundaries between the contact and non-contact sets. The two conditions (7.3.11) may usefully be combined to 2 d2 w d w with w f, T 2 − p 0, (7.3.12) (w − f ) T 2 − p = 0, dx dx and this so-called linear complementarity problem can be written in another way which is very convenient computationally.
7.3 Contact
If w satisfies 1 1 dw dw dv − dx p(w − v) dx T dx dx −1 dx −1
313
for all v f,
(7.3.13)
with v and w satisfying the same fixed boundary conditions, then, as shown in Elliott & Ockendon (1982, p. 103), w satisfies (7.3.12). The statement (7.3.13) is called a variational inequality, and, as shown in Exercise 7.8, w satisfies (7.3.13) if and only if it is the minimiser of the functional
1 2 T dv + pv dx 2 dx −1 over all v f . This has the obvious physical interpretation of minimising the elastic energy minus the work done by pressure over the virtual displacements v which prevent inter-penetration of the string and the obstacle. Moreover, this constrained optimisation problem is very much easier to solve numerically than the free boundary problem (7.3.1), (7.3.2).
7.3.2 Other thin solids It is seemingly straightforward to extend the model derived above to describe smooth contact between an elastic beam and a rigid substrate. In the noncontact set, the displacement w of the beam is governed by the equation T
d4 w d2 w − EI − p = 0, dx2 dx4
(7.3.14)
where, as in Chapter 4, EI denotes the bending stiffness. Evidently (7.3.14) reduces to (7.3.1) as the bending stiffness tends to zero. In the contact set, (7.3.14) is simply replaced by the condition w = f . Since (7.3.14) is fourth-order, we expect to need additional boundary conditions to specify a unique solution. Now, by balancing forces and moments at the boundary between the contact and non-contact sets, we deduce that w, dw/dx and d2 w/dx2 must all be continuous there. Let us illustrate the solution procedure in this case by considering a beam that is simply supported at its two ends x = ±1 at a unit height above the horizontal surface z = 0. This is the equivalent for a beam of the string sagging problem analysed in Section 7.3.1, and we will see that the inclusion of bending stiffness leads to interesting new behaviour. Assuming no tension is applied, (7.3.14) reduces to p d4 w , =− 4 dx EI
(7.3.15)
314
Fracture and contact
(a)
(b)
w
1.0
(c)
w
w 1.0
1.0
1.0
0.8
0.8
0.8
0.6
0.6
0.6
0.4
0.4
0.4
0.2
0.2
0.2
0.5
1.0
0.5
1.0
0.5
x
0.5
1.0
1.0
0.5
x
0.5
1.0
x
Fig. 7.14 The contact between a beam and a horizontal surface under a uniform pressure p. (a) The beam sags towards the surface: p/EI = 0, 12/5, 24/5. (b) The beam makes contact at just one point: p/EI = 24/5, 24. (c) The contact set grows: p/EI = 24, 2048/27, 384.
subject to the boundary conditions w(−1) = 1, w(1) = 1,
d2 w (−1) = 0, dx2 d2 w (1) = 0, dx2
and this problem is easily solved to give the displacement p 1 − x2 5 − x2 . w =1− 24EI
(7.3.16a) (7.3.16b)
(7.3.17)
As shown in Figure 7.14(a), the beam sags under increasing applied pressure until it first makes contact with the surface z = 0 when p/EI = 24/5. The solution (7.3.17) cannot remain valid for p/EI > 24/5, because it predicts negative values of w. So, let us instead seek a solution in which the beam makes contact with z = 0 over a region −s x s. We need only solve the problem in x > 0, since we can then infer the solution for negative values of x by symmetry. We therefore replace (7.3.16a) with the free boundary conditions w(s) = 0,
dw (s) = 0, dx
d2 w (s) = 0. dx2
(7.3.16c)
Notice again that, compared with (7.3.16a), we have introduced one more boundary condition to compensate for not knowing the location of the free boundary a priori. Again, the problem is easy to solve and we find that w=
(x − s)3 (2 − s − x) (1 − s)4
(7.3.18a)
in x s, with w ≡ 0 in 0 x s, where s is related to the applied
7.3 Contact
315
pressure by
24 p = EI (1 − s)4
or
s=1−
24EI p
1/4 .
(7.3.18b)
In Figure 7.14(c) we show how the contact set grows as p increases, with s = 0, 1/4, 1/2 when p/EI = 24, 2048/27, 384 respectively. However, since s must lie between 0 and 1, the solution (7.3.18) is only valid when p/EI 24. This begs the question: “what happens for values of p/EI between 24/5 and 24?” The answer is that the beam makes contact at just one point, namely the origin. If we replace (7.3.16c) with w(0) = 0,
dw (0) = 0, dx
(7.3.16d)
then we find w=
x2 (3 − x) p − x2 (1 − x)(3 − 2x), 2 48EI
(7.3.19)
in x 0, with the even extension of (7.3.19) in x 0. As shown in Figure 7.14(b), the beam initially meets z = 0 at one point, then flattens as p increases, until its curvature matches the curvature of the obstacle. Only then does the contact set start to grow. It is easy to verify that (7.3.19) matches (7.3.17) and (7.3.18) when p/EI = 24/5 and 24 respectively. The final surprise comes when we consider the reaction force R exerted by the surface z = 0 on the beam, given by R = p + EI
d4 w . dx4
(7.3.20)
Consider first the solution (7.3.19) in which the contact set is the point x = 0. By differentiating (7.3.19) and using the symmetry about x = 0, we find that d3 w 5p d3 w (0+) = − (0−) = − 3. (7.3.21) 3 3 dx dx 8EI Hence the third derivative of w is discontinuous across x = 0 and (7.3.20) then implies that there is a delta-function in the reaction force: 5p R= − 6EI δ(x). (7.3.22) 4 Similarly, differentiation of (7.3.18) reveals that 1/4 12 3 p 3/4 d3 w (s+) = = , dx3 (1 − s)3 2 EI
(7.3.23)
316
Fracture and contact
so, again, there is a delta-function in the reaction force at x = s with, by symmetry, an equal delta-function at x = −s: 1/4 3EIp3 R=p+ δ(x − s) + δ(x + s) (x s). (7.3.24) 2 We can readily verify that (7.3.24) agrees with (7.3.22) when p/EI = 24. These point forces acting at the boundary of the contact set do not occur in the contact of strings. They are a consequence of the idealisations inherent in beam theory. If we were to focus on a sufficiently small region near the boundary of the contact set, then beam theory would no longer be valid and we would need to consider contact between a linear elastic solid and a rigid boundary. As shown below in Section 7.3.3, this gives rise to a reaction force that, although concentrated near the edge of the contact set, is finite. We can obtain a variational formulation of the contact problem for a beam by incorporating the elastic bending energy into the integrand of (7.3.1), that is
2 1 T dw 2 EI d2 w + + pw dx. (7.3.25) min wf −1 2 dx 2 dx2 It is easy to show that (7.3.14) is the Euler–Lagrange equation associated with (7.3.25) in the absence of any contact. To generalise the above theories into three dimensions, we now consider an elastic membrane with transverse displacement w(x, y) making contact with a smooth obstacle z = f (x, y) under an applied body force p(x, y). Clearly the two-dimensional analogue of (7.3.1) is Poisson’s equation T ∇2 w = p(x, y),
(7.3.26)
where T is the uniform tension in the membrane. A force balance at the boundary of the contact set now reveals that w and its normal derivative must be continuous there, that is ∂f ∂w = on the boundary of the contact set. (7.3.27) ∂n ∂n In other words, w and ∇w must be continuous everywhere. The additional dimension makes analytical progress difficult except in simple cases such as axisymmetric problems (see Exercise 7.10). However, the numerical solution is straightforward in principle using a variational formulation analogous to (7.3.14), that is T 2 |∇w| + pw dxdy, (7.3.28) min wf 2 D w = f,
7.3 Contact
317
y
f (x)
x
c
punch δ Fig. 7.15 Contact between a rigid body and an elastic half-space.
and we can additionally incorporate bending stiffness as follows: T EI 2 2 2 min |∇w| + ∇ w + pw dxdy. wf 2 2 D
(7.3.29)
7.3.3 Smooth contact in plane strain As an intermediate case between the thin contact problems described above and general three-dimensional elastic contact, we will now make some elementary observations about contact in plane strain. For simplicity, we limit our attention to the problem of a rigid body, known as a punch, pushed a distance δ into the elastic half-space y > 0, as shown in Figure 7.15. Let us suppose the geometry is symmetric about x = 0 so that the contact set is −c < x < c for some positive c. Inside this region, the normal displacement is given in terms of the shape f (x) of the punch and, assuming smooth contact, the tangential stress is zero. In addition, there must be a positive reaction force, so that v = δ − f (x),
τxy = 0,
τyy < 0
on
y = 0, |x| < c.
(7.3.30a)
Outside the contact set, the surface traction is zero and there must be no inter-penetration, that is τxy = τyy = 0,
v > δ − f (x)
on y = 0, |x| > c.
(7.3.30b)
Our task, then, is to solve plane strain subject to the mixed boundary conditions (7.3.30) on y = 0 and given behaviour, typically zero stress, at
318
Fracture and contact
infinity. Such problems are almost always so complicated that they must be solved computationally but, enlightened by (7.3.14), we can see that this is not as fearsome a task as might be supposed. One must devise a code that minimises the integral W dxdy, y>0
where W is the strain energy density defined in Section 1.9, over all displacement fields satisfying the constraint v(x, 0) f (x) − δ. The proof of the equivalence of this proposed algorithm to finding a displacement field satisfying the Navier equation and the boundary conditions (7.3.30) relies crucially on the fact that the boundary conditions together with the inequalities in (7.3.30) determine a unique solution with bounded stress everywhere. One cunning way to construct analytic solutions of the contact problem described above is to suppose that we know in advance both the size c of the contact set and the contact pressure, say p(x), exerted by the punch. We thus replace the boundary conditions (7.3.30) with τxy = 0,
τyy = −P (x)
on y = 0,
(7.3.31)
where P (x) =
p(x),
|x| < c,
0,
|x| > c.
(7.3.32)
We can now use the solution obtained in (2.6.85) to calculate the displacement v0 (x) of the boundary y = 0, given by 1−ν v0 (x) = − πµ
c
−c
p(s) log |s − x| ds.
(7.3.33)
In |x| < c, this allows us to recover the shape of the punch that corresponds to the assumed pressure profile p(x). It only remains to check for consistency that there is no inter-penetration in |x| > c. As an example (guided by hindsight), let us consider the pressure profile p(x) = F
c2 − x2 ,
(7.3.34)
where F is constant. By calculating the integral in (7.3.33) for this particular
7.3 Contact
319
v0 1
-10
-5
5
10
x
-1
-2
-3
-4
Fig. 7.16 The penetration of a quadratic punch into an elastic half-space y > 0.
choice, it can be shown that the displacement of the boundary is given by
2µ (1 − ν)F
c ( c2 ' 1 − 2 log − x2 2 2 0, |x| < c, + |x| x2 − c2 − c2 cosh−1 (x/c), |x| > c.
v0 (x) =
(7.3.35)
The suggested pressure profile (7.3.34) therefore corresponds to a quadratic punch, as illustrated in Figure 7.16. We note that the displacement is not bounded at infinity, instead growing like v0 (x) ∼ −
(1 − ν)c2 F log |x| 2µ
as
|x| → ∞.
(7.3.36)
This reflects the weakness in the theory of plane strain noted in Section 2.6.8, and the same difficulty does not occur for more realistic three-dimensional configurations (see Barber, 1993). We can observe in Figure 7.16 that both v0 and its first derivative are continuous across x = ±c. Indeed, it is readily verified from (7.3.35) that the thickness of the void between the punch and the elastic body varies like √ c ( c2 ' 4 2c 2µv0 (x) 2 − (x − c)3/2 (7.3.37) 1 − 2 log +x ∼ (1 − ν)F 2 2 3 as x ↓ c. In contrast, we recall that, in the theory of brittle fracture without cohesion, the crack thickness typically varies as the square root of the distance from the crack tip. Recall also that the stress grows like (x − c)−1/2 as a √ crack tip is approached, while the above example, by construction, has √ p ∼ 2c c − x as x ↑ c.
320
Fracture and contact
These observations prompt the question: “why should the stress singularity in the smooth contact problem be weaker than that in the fracture problem?” The answer lies in the fact that the crack geometry is prescribed a priori; it is perfectly sensible to seek the stress distributions around a crack with arbitrary faces and an arbitrary crack tip surrounding these faces. However the boundary of a smooth contact set is free to decide its location, and it does so in such a way as to prevent the stress intensification that is characteristic of fracture. Notice also that the introduction of cohesion into the tip region of a brittle crack, as shown in Exercise 7.3, can also reduce the strength of the singularity to a 3/2-power as in (7.3.37), when we regard the cohesion length as a free parameter.
7.4 Concluding remarks The role of friction is of great importance in most real contact problems, but thus far we have not mentioned it. This is because of the serious mathematical complications to which it leads. Suppose for example we introduce frictional effects into the smooth contact problems of Section 7.3. If we assume Coulomb friction, then the shear stress |τxy | at the contact set never exceeds the normal stress |τyy | multiplied by the coefficient of friction, µc . This immediately introduces a second component into the free boundary; one component separates the non-contact set from the contact set, and the other divides the contact set into regions where |τxy | < µc |τyy | and |τxy | = µc |τyy | respectively. In the former there is no slip, so the displacement is continuous; but in the latter, slip is possible, and only the normal displacement is continuous. This considerable extra complexity destroys any hope of applying the standard theory of variational inequalities. Unfortunately, theoretical challenges of this sort have to be confronted if we are addressing even the apparently simple problem of finding the forces exerted on the ends of a rigid ladder resting against a wall. This is a nontrivial problem unless limiting friction is assumed at both ends of the ladder. As is usual in frictional contact, without this assumption, the reaction forces are indeterminate, and the only way forward is to consider the geometry of the ends of the ladder in detail, and solve a frictional contact problem along the lines just described. The ladder will be ready to slip when the slipping subset of the contact region is found to occupy almost the whole of the contact region. Strictly speaking, the ladder problem should be solved as an evolution contact problem starting from the time at which the ladder was erected. Such dynamic contact problems are of greatest applicability in the theory of
Exercises
321
impact, where predictions are to be made of, say, coefficients of restitution between various different solids. To carry this out, even in the non-frictional case, requires a combination of the modelling in this chapter and of the elastic waves in Chapter 3. One frictional contact problem of great practical importance which can be solved exactly is the capstan problem, in which a rope is wound around a rough circular cylinder. In polar coordinates, we suppose that the tension in the rope is T (θ) and that the cylinder is given by r = a. Making the assumption of limiting Coulomb friction everywhere, (7.3.1) implies that the normal reaction of the capstan is T (θ)/a, and a force balance equation along the rope gives dT /dθ = µc T , where µc is again the coefficient of friction. The resulting exponential dependence of T on θ explains the effectiveness of capstans. Moreover, this kind of configuration can be used as a building block in a theory of knots (real, not mathematical, ones!).
Exercises 7.1
For the elliptical Mode III crack solution (7.2.9), show that the stress components on y = 0, x > c cosh ε are given by x cosh ε ε τyz = 2τ0 e √ − sinh ε . τxz = 0, x2 − c2 Deduce that the stress at the crack tip is τyz = 2τ0 eε cosech ε ∼
2τ0 ε
as
ε → 0.
Show also that the radius of curvature r0 of the tip is given by cosh ε 1 1 = ∼ 2 2 r0 ε c c sinh ε and hence that the shear stress at the tip is approximately ) c τyz ∼ 2τ0 r0 7.2
when r0 is small. √ Show that the right-hand side of (7.2.18) tends to σIII c2 − x2 as y ↓ 0 when |x| < c. Show also that, as y ↓ 0, c c f (ξ) dξ ∂ −1 x − ξ dξ → − , f (ξ) tan ∂y −c y −c ξ − x
322
7.3
Fracture and contact
"
where − denotes the principal value integral defined in Exercise 2.12. Deduce that a solution of the singular integral equation c f (ξ) dξ =1 (|x| < c) − −c ξ − x is f (ξ) = ξ/ π c2 − ξ 2 . Are there any others? Consider a semi-infinite planar Mode III crack along the positive x-axis with a cohesive stress C in a neighbourhood of the crack tip. The antiplane displacement w(x, y) satisfies Laplace’s equation outside the crack, subject to the boundary conditions C, 0 < x < δ, ∂w (x, 0) = w(x, 0) = 0, x < 0, µ ∂y 0, x > δ, and the far-field condition ) √ 2 K Re z w∼ π µ
as
x2 + y 2 → ∞,
where z = x + iy and K is a constant determined by the external stress imposed on the crack. Show that the coordinate transformation (x + iy) = (ξ + iη)2 leads to the chain rule 1 ∂ ∂ ∂ = η + ξ . ∂y 2 (ξ 2 + η 2 ) ∂ξ ∂η Deduce that w is a harmonic function of (ξ, η) in η > 0 satisfying √ 2Cξ, |ξ| < δ, ∂w √ (ξ, 0) = µ ∂η 0, |ξ| > δ, and
) w∼
2 K ξ π µ
as
η → ∞.
Verify that the solution for ∂w/∂η is √
∂w 2C ζ− δ √ = Im ζ log , ∂η πµ ζ+ δ where ζ = ξ + iη, and deduce that
) √ √ 2C ζ+ δ 2 K ∂w √ −2 δ + = Re ζ log . ∂ξ πµ π µ ζ− δ
Exercises
323
Hence show that the stress ahead of the crack is given by . ) √ 2C δ 2 K 1 −x ∂w √ + C 1 − tan−1 (x, 0) = √ − µ ∂y π π δ −x 2π in x < 0, and deduce that the stress at the crack tip is finite if δ= 7.4
πK 2 . 8C 2
By writing the Airy stress function in the form (7.2.24) and using the chain rules (7.2.42), show that the stress components in plane strain are given in terms of the Goursat functions by ∂2A = Re z ¯ f (z) + 2f (z) + g (z) , ∂x2 ∂2A = Re −¯ z f (z) + 2f (z) − g (z) , ∂y 2 ∂2A = Im z¯f (z) + g (z) . − ∂x∂y
7.5
Apply the conformal mapping technique from Section 7.2.4 to a Mode I crack. Show that the far-field condition (7.2.64) corresponds to f ∼ σI z/4 and g ∼ σI z 2 /4 as z → ∞, and that (7.2.35) becomes σI (a + 2b) σI bζ − F¯ (1/ζ) − + 4ζ 4 2 ζ G (ζ) + ζ a + bζ 2 F (ζ) σI (a + 2b) σI bζ − + . = aζ 2 − b 4ζ 4 In the limit a, b → c/2, deduce that F and G are given up to arbitrary integration constants by cσI 1 − 3ζ , F (ζ) = 8 ζ 1 c2 σ I c c2 σ I ζ+ − log . G(ζ) = 16 ζ 2 ζ
7.6
By inverting the conformal mapping, obtain (7.2.65). Show that the displacement components and the Airy stress function in plane strain are related by ∂u ∂v + = ∇2 A, 2(λ + µ) ∂x ∂y
324
Fracture and contact
and deduce that there exists a function ψ(x, y) such that u=
∂A ∂ψ 1 + , 2(λ + µ) ∂x ∂y
v=
1 ∂A ∂ψ − . 2(λ + µ) ∂y ∂x
By eliminating u and v from the constitutive relations, show that A and ψ satisfy 2µ ∂ 2 ψ ∂2A ∂2A , − = − ∂x2 ∂y 2 1 − ν ∂x∂y ∂2A µ ∂2ψ ∂2ψ 2 = − . ∂x∂y 1 − ν ∂x2 ∂y 2 Deduce that ∂2 ∂ z¯2
A−
µ iψ 1−ν
= 0,
where z = x + iy and z¯ = x − iy, and hence that A−
µ iψ = z¯f (z) + g(z), 1−ν
where f and g are arbitrary analytic functions. Hence show that the displacement components are given in terms of f and g by u + iv =
1 z ) − g¯ (¯ z) . (3 − 4ν)f (z) − z f¯ (¯ 2µ
Recalling the boundary condition (7.2.26) satisfied by f and g on a stress-free boundary, show that the displacement of such a boundary is given by u + iv =
7.7
2 (1 − ν) f (z). µ
Finally, use the expression (7.2.65a) for f (z) to reproduce the displacement (7.2.78) of a Mode I crack. Suppose a semi-infinite Mode III crack propagates at constant speed −V along the x-axis in a channel |y| < h, −∞ < x < ∞, so that the displacement w satisfies (7.2.79). Suppose also that antiplane shear displacements are applied on the walls of the channel such that w = ±b on y = ±h, respectively. Deduce that ∂2w ∂w = 0, + ∂X 2 ∂y
Exercises
325
1/2 where x + V t = ξ = 1 − V 2 /c2s X, and verify that the solution is by b w= − Im log 1 + 1 − eπz/h , h π where z = X +iy. [Alternatively, obtain this result by using conformal mapping.] Hence show that b 1 ∂w √ (x, 0) ∼ √ ∂y 2 πh −X as X ↑ 0, and deduce that the propagation speed is given by * K 4 h2 , V = cs 1 − III µ4 b4 7.8
where KIII is the Mode III stress intensity factor. (a) Show that, if 1 T dw 2 + pw dx, U [w] = 2 dx −1 then
U [w] − U [v] = −T
1
−1
dw dx
1
−1
p (w − v) dx
dv dw − dx dx
T dx − 2
1
−1
dw dv − dx dx
2 dx
and deduce that, if w satisfies (7.3.13), then it minimises U . (b) Note that, if v1 and v2 belong to the set {v : v f on (−1, 1)}, then so does αv1 + (1 − α)v2 for 0 < α < 1 [this means that the set is convex]. Show that if w minimises U , then U [w] U [αv + (1 − α)w] for all v f . Expand this inequality for small α to show that dw dw dv − − p(w − v) dx. T 0 dx dx dx −1
7.9
1
Consider the problem of a flexible ruler of unit length being pressed against a horizontal table, as shown in Figure 7.17. Suppose the end x = 0 is simply supported by the table with w = 0, while a bending moment M is applied at the other end, x = 1, which is held at a
326
Fracture and contact
w 1
0.8
Increasing M/EI
0.6
0.4
0.2
0.2
0.4
0.6
1
0.8
x
Fig. 7.17 A flexible ruler flattened against a table with applied bending moment M/EI = 0, 3, 6, 9, 12, 15. w
w 0.01
0.035
V
0.03
0.008
0.025 0.006
0.02 0.004
0.015
0.01 0.002
0.005
-1.5
-1
-0.5
0.5
1
η
1.5
-1.5
-1
-0.5
0.5
1
η
1.5
2
Fig. 7.18 (a) A wave travelling along a rope on the ground. (b) Some higher travelling modes.
7.10
height w = 1 above the table. Show that the vertical displacement of the ruler is given by M w =x− x 1 − x2 , 6EI for M/EI 6. Show also that, when M/EI > 6, theruler makes contact with the table over a region of length s = 1 − 6EI/M . Consider an elastic membrane stretched to a tension T above the horizontal table z = 0. The membrane is fixed with w = 1 at the circular boundary r = 1, where r2 = x2 + y 2 , and sags under a uniform applied pressure p. Show that, as p is increased from zero, the membrane first makes contact with the table when p = 4T . Show also that, when p > 4T , the contact set is given by r < s, where 4T = 1 − s2 + 2s2 log s. p
7.11
A rope with line density and bending stiffness EI lies on the ground. By flicking one end, it is possible to send a wave of length 2
Exercises
327
travelling along the rope at speed V , as illustrated in Figure 7.18(a). Defining the travelling wave coordinate η = x − V t, show that the small transverse displacement w(η) of the rope satisfies EI
2 d4 w 2d w + V + g = 0, dη 4 dη 2
subject to the contact conditions w= Derive the equation w=
g4 2EIk 4
d2 w dw = =0 dη dη 2
at
η = ±.
k2 η2 2 + k 2 − 2 − 2 sec k cos
kη
for the shape of the hump in the rope, and show that the speed is given by * k EI , V = where k satisfies the transcendental equation tan k = k. [This equation has a countably infinite set of solutions; the displacement corresponding to the first is shown in Figure 7.18(a) and the next three are shown in Figure 7.18(b).] Given that the lowest positive root is given by k1 ≈ 9/2, deduce that flicking one end of the rope up and down over a time τ will produce a wave travelling at speed EI 1/4 . V ≈3 τ 2
8 Plasticity
8.1 Introduction It is unfortunate that what are colloquially called “plastics” are polymeric solids that usually behave elastically at room temperature and viscoelastically when hot; hence the word plasticity should not be thought of as applying just to such materials. Indeed, some of the most important examples of plastic behaviour occur in metals. A convenient way to gain some intuition about this phenomenon is to apply an increasing bending moment to a paper clip. There is always a critical bending moment above which the clip fails to revert to its initial state, which means that it has become inelastic. This observation is encapsulated in Figure 8.1, which shows the qualitative stress/strain curve for a metal that yields when some norm of the stress tensor reaches the yield stress τY . If a stress lower than τY is applied, the material responds elastically (although possibly nonlinearly), returning to its original state when the loading is removed. However, when a stress greater than τY is applied and then removed, a nonzero permanent strain remains. Macroscopic plasticity modelling thus poses two key challenges. The first is to explain the existence of a critical yield stress, above which a solid ceases to behave elastically, and the second is to predict the irreversible behaviour that occurs at a stress equal to or greater than this critical value. The part of the loading curve in Figure 8.1(b) above the dotted line is where the material is said to be undergoing work hardening. A limiting case of the behaviour depicted in Figure 8.1, which has proved extremely useful in practical models of plastic behaviour, is known as perfect plasticity. In perfectly plastic theories, the stress is never allowed to exceed the yield stress, and the material can thus exist in one of two distinct states. Below the yield stress, it behaves as an elastic solid and is described by the models presented previously in this book; at and only at the yield 328
8.1 Introduction
(a) stress τY
(b) stress
loading
329
loading
τY unloading
unloading
strain
strain
Fig. 8.1 A typical stress–strain relationship for a plastic material: (a) below the yield stress τY ; (b) when the yield stress is exceeded.
stress, the material becomes plastic and starts to flow irreversibly. Hence the stress–strain relationship of a perfectly plastic material is as sketched in Figure 8.2(a): we can view this as an idealised version of Figure 8.1(a). We will see below that such models arise naturally in describing granular materials and metal plasticity. It is natural to use the word “flow” to describe the permanent deformation that occurs at the yield stress, although, in Chapter 1, we specifically stated that a solid does not flow in response to a stress. A yielding plastic material therefore ceases to be a solid according to the definitions given in Chapter 1. The situation is further complicated by the existence of viscoelastic materials which behave like elastic solids in some situations and like viscous liquids in others, as we will describe in Section 9.2. In fact, there exist materials with ever more complicated mechanical properties that may be characterised as “elastic-plastic”, “visco-plastic”, “elasto-visco-plastic” and so forth. The mathematical models that emerge in each case may be quite different from each other, and they all differ markedly from those used in classical fluid mechanics in one crucial respect. While the behaviour of a classical inviscid or Newtonian fluid is determined completely by its instantaneous velocity field, plastic and viscoelastic materials all exhibit historydependence, in which the behaviour at any time depends on the entire strain history that it has so far experienced. This can be anticipated by returning to your paper clip and cycling the stress so that it loads and unloads above and below τY until it eventually fractures; a typical stress–strain trajectory is shown schematically in Figure 8.2(b). We will spend most of this chapter describing plastic behaviour in metals. However, we will see that the small-scale behaviour underlying Figure 8.2 can only be discerned using very-high magnification microscopes. We therefore
330
Plasticity
(a)
τY un load loa din ing g
τY
(b)
stress
strain
un load loa din ing g
stress
strain
Fig. 8.2 The stress–strain relationship for a perfectly plastic material: (a) under a single loading; (b) under periodic loading/unloading.
start with a brief discussion of plastic flow in granular solids, whose smallscale behaviour is more familiar from everyday experience.
8.2 Models for granular material 8.2.1 Static behaviour The mechanics of granular solids is of wide importance, for example in the transport of powders, foodstuffs and coal and in understanding the behaviour of sand dunes. Let us first consider a single particle at the surface of a granular solid, for example a pile of sugar on a spoon. In addition to its own weight W , the particle experiences a normal reaction force R and tangential frictional force F exerted by the pile underneath, as illustrated in Figure 8.3. We recall from Chapter 7 that R must be non-negative; indeed, it is an everyday observation that dry granular material cannot withstand any tensile stress (in the absence of any additional physical effects, such as moisture-induced cohesion or electrostatic charges). Coulomb’s law of friction is an empirical law which states that |F | R tan φ, where the material parameter φ is called the angle of friction. (In the notation of Section 7.4, tan φ = µc , where µc is the coefficient of friction.) In addition, Coulomb’s law implies that the particle is held in place by friction if |F | < R tan φ and can slide only when |F | = R tan φ. A force balance on the particle illustrated in Figure 8.3 gives R = W cos θ and F = W sin θ, where θ is the angle that the surface makes with the horizontal. From Coulomb’s law, we therefore deduce that the surface slope is bounded by tan φ and that slippage will occur when θ = φ. This indeed agrees with experimental observations that granular materials possess an angle of repose, that is a maximal surface slope
8.2 Models for granular material
331
y R F
11111111111111 00000000000000 00000000000000 11111111111111 00000000000000 11111111111111 00000000000000 11111111111111 W 00000000000000 11111111111111 θ 00000000000000 11111111111111
x
Fig. 8.3 The forces acting on a particle at the surface of a granular material.
which can be sustained without the particles giving way and flowing, for example, via a series of avalanches. It is also characteristic of the perfectly plastic behaviour described in Section 8.1. When the material is piled maximally, it follows that the surface slope must equal tan φ everywhere, and the pile height z = h(x, y) therefore satisfies the equation 2
|∇h| =
∂h ∂x
2
+
∂h ∂y
2 = tan2 φ.
(8.2.1)
This is called the eikonal equation for h and it arises in many other contexts, notably in geometrical optics (see Ockendon et al., 2003, p. 359). Single-valued solutions of (8.2.1) predict shapes that are reminiscent of our everyday experience of piles of granular materials (for example sugar, sand, etc.); see Exercise 8.1.
8.2.2 Granular flow The above discussion gives us confidence that Coulomb’s law provides a good model for a maximally piled granular material, under static conditions at least. To model a flowing granular material, we must apply Coulomb’s law to particles in the interior, and it is much easier to implement this in two dimensions rather than three. Let us then consider the forces acting on a two-dimensional surface element inside a granular medium whose unit normal is n = (cos θ, sin θ)T , as depicted in Figure 8.4. Assuming that the internal stress can be described using a stress tensor τ , we find that the
332
Plasticity
y F
N
1111111111 0000000000 0000000000 1111111111 0000000000 1111111111 0000000000 1111111111 θ 0000000000 1111111111 0000000000 1111111111 0000000000 1111111111 0000000000 1111111111 0000000000 1111111111
x
Fig. 8.4 The normal force N and frictional force F acting on a surface element inside a granular material.
normal traction exerted on the particles below the element by those above is given by
N=
cos θ τxx τxy sin θ τxy τyy 1 1 = (τxx + τyy ) + (τxx − τyy ) cos(2θ) + τxy sin(2θ). (8.2.2) 2 2
(cos θ, sin θ)
As pointed out in Section 8.2.1, we expect the particles to exert a compressive force on each other, but never a tensile one, and N must therefore be non-positive, for all choices of the angle θ. It follows that none of the principal stress components (i.e. the eigenvalues of τ ) can be positive. Similarly, the tangential (frictional) shear stress on our surface element is given by
F =
(− sin θ, cos θ)
τxx τxy cos θ τxy τyy sin θ 1 = (τyy − τxx ) sin(2θ) + τxy cos(2θ). (8.2.3) 2
Now Coulomb’s law implies that |F | must be bounded by N tan φ, for all θ. In addition, flow can occur only if there is some value of θ for which |F | is equal to N tan φ. If so, this direction defines a slip surface along which we expect flow to occur.
8.2 Models for granular material
333
F +
1 4 (τxx
2 − τyy )2 + τxy
φ
−
N
τxx + τyy 2
Fig. 8.5 The Mohr circle in the (N, F )-plane, and the lines where |F | = |N | tan φ.
From (8.2.2) and (8.2.3), we see that, as θ varies, the tractions lie on the so-called Mohr circle in the (N, F ) plane, given by 2 (τxx − τyy )2 1 2 2 + τxy , (8.2.4) F + N − (τxx + τyy ) = 2 4 where different points on the circle correspond to different choices of the angle θ. Since we require N to be non-positive for all θ, the Mohr circle must lie in the half-plane N 0, as shown in Figure 8.5. Coulomb’s law then tells us that |F | |N | tan φ for all θ, and the Mohr circle must therefore lie in the sector N tan φ F −N tan φ. Finally, if the material is flowing, then there must be one value of θ such that |F | = |N | tan φ, and the Mohr circle must therefore be tangent to the lines |F | = |N | tan φ, as shown in Figure 8.5. Elementary trigonometry now tells us that the stress components in a granular material must satisfy 2 1/2 −(τxx + τyy ) cos φ. (8.2.5) 2 τxx τyy − τxy When the material is flowing and equality holds, (8.2.5) is called the Coulomb yield criterion. Notice that (8.2.5) is a relation between the two stress invariants Tr (τ ) and det (τ ). This is reassuring, since it implies that the condition for the material to yield is independent of our choice of coordinate system. We can only make significant analytical progress if we assume that the flow is slow enough for the inertia of the particles to be negligible in
334
Plasticity
comparison with the frictional forces between them and, perhaps, gravity. This assumption is often valid in practice and allows us to neglect the acceleration term in Cauchy’s momentum equation, which thus reduces to ∂τxy ∂τxy ∂τyy ∂τxx + = 0, + + ρg = 0. (8.2.6) ∂x ∂y ∂x ∂y Given our restriction to two dimensions, we see that (8.2.6) and the yield criterion (8.2.5) give us three equations in the three stress components τxx , τxy and τyy . It is therefore possible, in principle, to solve for the stress tensor in a flowing granular material in two dimensions without specifying any particular constitutive relation. This is in stark contrast with all theories of elasticity that we have encountered thus far. The easiest case to analyse occurs when gravity is negligible so we can use (8.2.6) to introduce an Airy stress function A. Then, when the material is flowing, equality in (8.2.5) implies a nonlinear partial differential equation for A, namely 2 2 ∂ A cos2 φ 2 2 ∂2A ∂2A ∇ A . − = (8.2.7) ∂x2 ∂y 2 ∂x∂y 4 When φ = π/2, this reduces to the Monge–Amp`ere equation encountered previously in Chapter 4. When φ ∈ (0, π/2), (8.2.7) is, unexpectedly, a hyperbolic partial differential equation. Even with the body force included, the system (8.2.5), (8.2.6) is likewise hyperbolic, as shown in Exercise 8.3. This means that the stress field in the flowing material is confined to certain regions of influence bounded by the relevant characteristics of (8.2.7). Outside these regions, the inequality in (8.2.5) is strict, so the granular material does not flow but behaves like an elastic solid and hence satisfies elliptic equations. By combining these two regimes, we obtain a perfectly plastic theory, as described in Section 8.1, in which the yield stress is never exceeded. The key to solving such models is to locate the free boundary that separates the flowing and non-flowing regions. The switch in behaviour from hyperbolic to elliptic makes these problems very difficult in general, but there are a handful of symmetric situations where we can find an explicit solution. 8.2.3 Example: a tunnel in granular rock One such configuration is the problem of a circular tunnel of radius a bored through granular rock, subject to a uniform isotropic pressure p∞ at infinity and a positive pressure P at r = a to simulate the tunnel bracing.† To model †
Had we included a depth-dependent hydrostatic pressure at infinity, as in Section 2.6.9, analytical progress would have been considerably more difficult.
8.2 Models for granular material
335
this situation, we seek an axisymmetric solution in which the displacement is purely radial, with u = ur (r)er , and the only nonzero in-plane stress components are τrr (r) and τθθ (r). As in Section 2.6.5, the use of an Airy stress function is somewhat awkward in this multiply connected domain, and it is more convenient to work directly with the plane polar Navier equation τrr − τθθ dτrr + = 0. dr r
(8.2.8)
The boundary conditions on the tunnel wall and in the far field read τrr = −P
on r = a,
τrr → −p∞ ,
τθθ → −p∞
as
(8.2.9a)
r → ∞.
(8.2.9b)
By rotating the axes, we can write (8.2.5) in the form 2 (τrr τθθ )1/2 − cos φ (τrr + τθθ ) .
(8.2.10)
Hence yield occurs when kτrr = τθθ ,
(8.2.11)
where the so-called triaxial stress factor k satisfies 2k 1/2 = (1 + k) cos φ.
(8.2.12)
While the rock remains elastic, we can use the usual constitutive relations (1.11.5): τrr = (λ + 2µ)
ur dur +λ , dr r
τθθ = λ
ur dur + (λ + 2µ) . dr r
(8.2.13)
Then it is straightforward to solve (8.2.8) and (8.2.9) to find ur = −
(P − p∞ )a2 p∞ r + , 2(λ + µ) 2µr
(8.2.14)
and the stress components are then given by τrr = −p∞ + (p∞ − P )
a2 , r2
τθθ = −p∞ − (p∞ − P )
a2 . r2
(8.2.15)
Notice the analogy between (8.2.14) and the gun barrel solution (2.6.41), with the outer radius b tending to infinity and a superimposed isotropic pressure. At the tunnel wall r = a, we have 2p∞ τθθ − 1, = τrr P
(8.2.16)
336
Plasticity
k 20
15
10
5
0.2
0.4
0.6
0.8
1.0
1.2
1.4
φ
Fig. 8.6 The triaxial stress factor k defined by (8.2.18) versus angle of friction φ.
so, as P is lowered below p∞ , yield will first occur when P =
2p∞ . 1+k
(8.2.17)
Since, again at r = a, we have τθθ − τrr = 2(P − p∞ ), we expect |τrr | = −τrr to be less than |τθθ | = −τθθ . This means that we must choose the root of (8.2.12) that exceeds unity, namely k=
1 + sin φ . 1 − sin φ
(8.2.18)
As shown in Figure 8.6, k is an increasing function of φ, with k → ∞ as φ → π/2. Hence (8.2.17) implies that, as the angle of friction increases, a smaller internal pressurisation is needed to prevent yield: the closer φ is to π/2, the stronger will be the tunnel. Once P drops below the value given by (8.2.17), we can seek a composite elastic-plastic solution in which there is a free boundary r = s separating an elastic region in r > s from a perfectly plastic region in a < r < s, with kτrr = τθθ on r = s. Hence, to obtain the elastic solution in r > s, we simply replace P by 2p∞ /(1 + k) and a by s in (8.2.15) to give k − 1 s2 k − 1 s2 , τ = −p − p . (8.2.19) τrr = −p∞ + p∞ ∞ ∞ θθ k + 1 r2 k + 1 r2 Meanwhile, in the plastic region r < s, the quasistatic balance (8.2.8) is now supplemented by the yield condition (8.2.11). The resulting equation 1−k dτrr + τrr = 0, dr r
(8.2.20)
8.3 Dislocation theory
337
along with the boundary condition (8.2.9a), gives r k−1 . (8.2.21) τrr = −P a Finally, equating (8.2.19) and (8.2.21) at r = s gives the radius of the plastic region as 1/(k−1) 2p∞ . (8.2.22) s=a (k + 1)P The above calculation leaves open the role played by the out-of-plane stress tensor τzz , and we will return to this issue shortly. Moreover, we have given no way of predicting the flow velocity itself in the yielded region. We have suggested that the flow might occur along slip surfaces, but, even with that assumption, some additional information is needed to determine the magnitude of the velocity. There are many empirical theories for this, and we shall not attempt to review them here. Of course, matters would be even worse if the velocity were large enough to invalidate our neglecting the acceleration term in (8.2.6), in which case the stress and velocity components would satisfy a fundamentally coupled problem. It is remarkable that the theory that we have presented can successfully be applied to situations ranging from the flow of powders to the design of industrial-scale coal hoppers. Moreover, it is relatively simple to generalise our elastic-plastic theory to granular materials in which cohesive forces act, perhaps as a result of moisture. Then a tensile stress can be sustained, and all we have to do is to replace N by (N + c) in (8.2.4), where c is a positive cohesive force. However, it is far more difficult to extend the analysis to three dimensions. To do this, the first task is to generalise the yield criterion (8.2.5), as shown in Exercise 8.2. However, this condition, along with the momentum equations (8.2.6), gives us only four scalar equations in the six stress components, so the three-dimensional problem is inevitably underdetermined without the imposition of a constitutive relation, and we will discuss this situation further in Section 8.4.3. We now turn our attention to metal plasticity, for which the microscopic mathematical theory is somewhat better developed. 8.3 Dislocation theory Metals can exhibit microstructure at several scales, depending how they have been solidified and whether there are alloying components. From the point of view of plasticity, the basic microstructure is that of a periodic lattice of atoms, and the crucial scale is one small enough for the atom
338
Plasticity
spacing to be noticeable but large enough for the atoms to be thought of as points so that quantum effects are assumed to be largely negligible. Many of the macroscopic properties of the material, such as the elastic constants λ and µ, can be predicted from geometric symmetries of the lattice and knowledge of the inter-atomic forces. However, the same calculations predict that the stress which must be overcome to make a row of atoms push one by one past a neighbouring row should be of the same order as the shear modulus µ, which is vastly greater than experimentally measured values of the yield stress, by a factor of up to 105 (see, for example, Weertman & Weertman, 1992, Chapter 1). This discrepancy implies that the mechanism for yield in metals is quite different from that in granular flow, and it acted as a key stimulus for the development of the theory of metal plasticity. Although the behaviour of atomistic lattices during plastic deformation has only been observable since the introduction of the electron microscope, these observations were anticipated several decades earlier using, surprisingly, the continuum theory of linear elastostatics. The simplest configuration in which we can understand thebasic ideas is antiplane strain, where T the displacement takes the form u = 0, 0, w(x, y) and ∇2 w = 0. We have already seen several solutions of this model, including some with singularities in Chapter 7. Now we ask ourselves what the physical interpretation might be of the displacement field y b tan−1 . (8.3.1) w= 2π x This is a function whose Laplacian is zero except at the origin and on some branch cut emanating from the origin, across which there is a jump of magnitude b in the value of w. If we took tan−1 (y/x) = θ, where (r, θ) are the usual plane polar coordinates with the restriction 0 θ < 2π, the branch cut would be along the positive x-axis. However, by using the formulae of Section 1.11.2, we find that the stress components in cylindrical polar coordinates are all zero except for τθz =
bµ , 2πr
(8.3.2)
which is defined everywhere except at the origin, whatever branch cut is chosen. The displacement field (8.3.1) could in principle be realized by a so-called cut-and-weld operation as shown in Figure 8.7. We simply take a circular cylindrical bar, cut it along a diametral plane from the exterior to the axis,
8.3 Dislocation theory
339
z
x
y
Fig. 8.7 An antiplane cut-and-weld operation leading to the displacement field (8.3.1).
displace one side of the cut by a distance b relative to the other side, and finally weld the two cut faces together again. Clearly there will be a region of very large strain close to the axis, in accordance with (8.3.2). We will thus have created a bar that is in a state of self-stress, so that it is in equilibrium under the action of no external forces, yet there is a nonzero stress distribution in the interior. We can also interpret (8.3.1) in terms of incompatibility. We recall from Section 2.7 that the assumption of a single-valued displacement field gives rise to compatibility relations between the strain components. Since (8.3.1) is not single-valued, we would expect these relations to be violated. Indeed, in Exercise 8.4 we show that w satisfies ∂2w ∂2w − = bδ(x)δ(y), ∂y∂x ∂x∂y
(8.3.3)
where δ denotes the Dirac delta-function defined in Section 2.9.1. We can interpret (8.3.3) as a “failure of single-valuedness” or a line of incompatibility along the z-axis. It is also instructive to introduce an antiplane stress function φ, as in Section 2.4, defined to be the harmonic conjugate of w so that w and φ satisfy the Cauchy–Riemann equations ∂φ ∂w = , ∂x ∂y
∂w ∂φ =− . ∂y ∂x
(8.3.4)
340
Plasticity
(a)
(b)
y
x
y
x
Fig. 8.8 The displacement field in an edge dislocation: (a) pristine material; (b) after the cut-and-weld operation.
Now, the harmonic conjugate of (8.3.1) is φ = −(b/2π) log r, which, as we know from Section 2.9.1, satisfies ∇2 φ = −bδ(x)δ(y),
(8.3.5)
and we can easily verify that (8.3.5) is consistent with (8.3.3). The singularity in (8.3.1) at x = y = 0 is thus analogous to the singularity at the core of a line vortex in inviscid fluid dynamics, where a finite circulation is concentrated on a line in an otherwise irrotational flow. Similar behaviour occurs if we displace one cut face radially relative to the other before welding them back together, as shown in Figure 8.8. This configuration can be described using a plain strain displacement field T u = u(x, y), v(x, y), 0 , in which u is discontinuous across the positive x-axis. We can find such a displacement by using the Papkovich–Neuber representation used in Section 2.8.6, namely ψ1 xψ1 + yψ2 2µu = 2(1 − ν) ψ2 − grad φ + , (8.3.6) 2 0 where ψ1 , ψ2 and φ are all harmonic functions of x and y. Now the required discontinuity in u may be obtained by choosing φ = 0, ψ1 proportional to θ and ψ2 equal to a constant. As shown in Exercise 8.5, this approach leads us to the displacement field b sin θ b θ cos θ u + (8.3.7) = v 2π 0 2π(3 − 4ν) sin θ which is depicted in Figure 8.8. The associated stress field is given in
8.3 Dislocation theory (a)
341
(b)
Fig. 8.9 An edge dislocation in a square crystal lattice: (a) pristine crystal; (b) insertion of an extra row of atoms.
cylindrical polar coordinates by τrr τrθ τrz τrθ τθθ τθz τrz τθz τzz −ν sin(θ) (1 − ν) cos(θ) 0 2µb (1 − ν) cos(θ) −(1 − ν) sin(θ) , (8.3.8) = 0 π(3 − 4ν)r 0 0 −ν sin(θ) so we again have a state of self-stress which is infinite on the line r = 0. Exercise 8.6 shows that (8.3.8) corresponds to an Airy stress function A=
−µb {(1 − 2ν)rθ cos θ + 2(1 − ν)r log r sin θ} , π(3 − 4ν)
which satisfies the equation ∇4 A =
4µb (3 − 4ν)
δ(x)δ (y),
(8.3.9)
(8.3.10)
which is effectively (2.9.48). Now we recall from Section 2.8.2 that the existence of A ensures that the plane strain Navier equations are satisfied, while the biharmonic equation for A was obtained by assuming compatibility between the strain components. Hence, as in (8.3.3), we can interpret (8.3.10) as describing a line of incompatibility along the z-axis. A key insight into the physical mechanism for plastic flow in metals comes when we imagine executing the cut-and-weld operation shown in Figure 8.8 at an atomic scale. For example, on the square lattice shown in Figure 8.9(a), we can achieve this by inserting an extra column of atoms, as depicted in Figure 8.9(b). This figure is effectively the same as Figure 8.8(b) after the “ledge” below the positive x-axis has been removed. Far from the crystal misfit, it simply seems that the atoms below the positive x-axis have been displaced one atom spacing to the right, as in the displacement field (8.3.7). We are thus led to conjecture that, with b equal to a single atomic spacing,
342
(a)
Plasticity
(b)
(c)
(d)
Fig. 8.10 A moving edge dislocation: (a) initial configuration; (b) and (c) the dislocation moves to the left as the atoms realign themselves, eventually (d) leading to a net displacement of the upper block of atoms relative to the lower.
an atomistic calculation of the displacement based on Figure 8.9(b) would tend to (8.3.7) on a scale large compared to b.† The region near the z-axis within a few atomic spacings of the crystal misfit is called the core of an edge dislocation, the corresponding region in the antiplane configuration analogous to Figure 8.7 being the core of a screw dislocation. The dislocation itself, in either case, is the z-axis and the displacement jump as we move around any curve enclosing the dislocation is called the Burgers vector. In our examples, the Burgers vector is (0, 0, b)T for the screw dislocation and (b, 0, 0)T for the edge dislocation. However, it is quite easy to take linear combinations of these to generate a mixed dislocation along the z-axis which is part edge and part screw. In addition, we can envisage dislocations on a macroscopic scale which lie on curved rather than straight lines, by identifying the z-axis with the tangent to the dislocation at any point. In practice, the symmetries of the crystal lattice usually force any dislocations to lie in certain planes, known as slip planes, to which the Burgers vector is tangent (Hirth & Lothe, 1991, p. 271). In contrast with granular flow, where there is just one direction of slip at any point, there may be many slip planes, depending on the symmetries of the crystal structure. These are set in the metal, whereas the slip planes in a granular material depend on the stress state. Anything other than an absolutely perfect crystal must contain many dislocations like that shown in Figure 8.9(b). Now the key observation is that just a small realignment of the atoms near the core is needed for such a dislocation to move irreversibly through the lattice. This is illustrated schematically in Figure 8.10, where a dislocation moves to the left, thereby moving the lower block of atoms bodily with respect to the upper block. †
Of course we are not really justified in using the atomic scale b in a macroscopic model like (8.3.1). Indeed the key challenge in the theoretical modelling of dislocations is to make the connection between atomic and macroscopic scales.
8.3 Dislocation theory
343
This can be achieved without forcing large numbers of atoms to slide over each other, and this explains the huge discrepancy noted above between predictions of the yield stress based on inter-atomic forces and experimentally measured values. We also note for future reference that the configurational changes illustrated in Figure 8.10 take place with no appreciable change in volume of the crystal. All these observations led theoreticians in the 1930s and earlier to suggest that macroscopic metal plasticity could be explained by the motion of dislocations, and it was a great day when, two decades later, electron micrographs of metal crystals that had undergone plastic deformation were able to confirm the theory. They revealed countless (up to 1012 cm−2 ) black curves in regions which would have been invisible had the crystal been perfect. Each of these curves represented a dislocation bounding a plane region of slip in the crystal and, the more the metal had been deformed plastically, the more black lines were observed. Since any realistic sample contains so many dislocations, it is impractical to track each one individually. Instead, any macroscopic theory must use a density, which is in fact a tensor,† that characterises the direction and Burgers vector averaged over a large number of dislocations. Moreover, it would need a rule for how dislocations move, analogous to that used to obtain a model for collective motion of vortices in an inviscid fluid or of superconducting vortices in a type-II superconductor. Unfortunately, it has proved much harder to carry this out in practice for dislocations, and a definitive macroscopic model does not yet exist. Rather than delving further into this fascinating open problem, we will simply use microscopic thought-experiments like Figure 8.10 to suggest the following guidelines that will be employed below to obtain a closed macroscopic model for metal plasticity. (i) Dislocations may move under the action of an applied shear stress, but are generally impervious to any isotropic pressure. (ii) Collective motion of many dislocations can only occur when a sufficiently high shear stress exists at every point. The critical yield stress is a constant for any given metal. (iii) Plastic flow, which results from collective dislocation motion, is essentially incompressible. These conjectures can be tested experimentally or by performing atomistic computations on a discrete lattice. †
furthermore, such a density tensor would have to vanish in regions in which the incompatibility tensor (2.9.46) vanishes
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Plasticity
We conclude by mentioning two further benefits that accrue from dislocation theory. One concerns what happens when a metal is repeatedly deformed so strongly that many new families of dislocations are created on different slip planes. These impede further movement, since dislocations cannot easily pass through each other. This gives a theoretical explanation of work hardening, whereby a metal becomes more resistant to yield if it has already gone through several stress cycles. There is one other interesting macroscopic interpretation of dislocations which is purely of theoretical interest. This concerns the modelling of brittle fracture when no plastic effects are taken into consideration. It is a simple matter (see Exercise 7.2) to see that the displacement field (7.2.11) near a Mode III crack can be represented as a distribution of virtual screw dislocations along the crack. Similarly, the displacement fields near a Mode I or Mode II crack can be thought of as being caused by a distribution of edge dislocations, all these displacements having closely related Papkovich– Neuber representations. This situation is reminiscent of the theory of flight, in which a thin aerofoil can be regarded as a distribution of vortices in an otherwise irrotational fluid. Of course, the stress intensification near the tips of a crack in the theory of brittle fracture implies the existence of plastic regions near these tips, and these will contain real, not virtual, dislocations.
8.4 Perfect plasticity theory for metals 8.4.1 Torsion problems The observed, and simulated, behaviour of dislocations suggests that metals can be well described using a perfectly plastic theory: either some measure of the stress is below a critical value, in which case the metal is elastic, or the stress is sufficient to cause bulk dislocation motion and flow. The first question we must address is thus the yield criterion that distinguishes elastic from plastic behaviour. We begin as we did for granular plasticity by considering the tractions on all small surface elements through a point P in the metal. However, as explained at the end of Section 8.3, instead of involving a limiting friction concept, it is more natural to associate dislocation motion with the existence of a critical shear stress independent of the normal stress. We first consider the simplest case of antiplane shear, in which the only stresses are shear stresses which give rise to a traction 0 cos θ 0 0 τxz (8.4.1) τn = 0 0 τyz sin θ = (τxz cos θ + τyz sin θ) 0 τxz τyz 0 0 1
8.4 Perfect plasticity theory for metals
345
on a surface element normal to n = (cos θ, sin θ, 0)T . We require the amplitude of the shear stress to be bounded by a critical yield stress τY for all such surface elements, and this leads to the inequality + 2 + τ2 τ , τxz (8.4.2) Y yz with equality when the material is flowing. To illustrate the mathematical structure in this relatively simple case, let us return to the elastic torsion bar problem from Section 2.4. We recall that the displacement field is given by u = Ω (−yz, xz, ψ(x, y))T ,
(8.4.3)
where Ω represents the twist of the bar about its axis. We also recall the elastic stress function φ defined such that τxz = µΩ
∂φ , ∂y
τyz = −µΩ
∂φ , ∂x
(8.4.4)
where φ satisfies Poisson’s equation ∇2 φ = −2,
(8.4.5)
subject to φ = 0 on the boundary of the bar. For example, if the cross-section is circular, with radius a, (2.4.19) gives a2 − r2 , (8.4.6) 2 but for this solution to be valid, we must check that the shear stress does not exceed the critical value τY . The inequality (8.4.2) reads φ=
µΩ |∇φ| τY ,
(8.4.7)
µΩr τY .
(8.4.8)
which, with (8.4.6), requires
The left-hand side is maximised when r = a, and we deduce that the bar will first yield at its surface when the twist Ω reaches a critical value τY . (8.4.9) Ωc = µa When Ω > Ωc , the condition (8.4.8) is violated, so our solution (8.4.6) is no longer valid. Instead, as in the tunnel problem of Section 8.2.3, there will be a plastic region near the boundary of the bar where the metal has yielded, although we expect the material at the centre still to be elastic. We therefore again have to introduce a free boundary, say r = s, that separates the yielded and unyielded material, where s is to be determined as part of
346
Plasticity
the solution, and repeat the key assumption that, even when the material has yielded, it flows slowly enough for the inertia terms to be neglected. We can thus employ a stress function φ throughout the bar, satisfying (8.4.5) in 0 r < s and the yield condition µΩ |∇φ| = τY
(8.4.10)
in s < r < a, again subject to φ = 0 on r = a. Continuity of traction requires φ and its normal derivative to be continuous across r = s. We soon find that s2 + r2 , 0 r < s, as − (8.4.11) φ= 2 s(a − r), s < r < a, where s=
τY . Ωµ
(8.4.12)
We thus see how the plastic region grows as Ω increases past its critical value Ωc , and the nonzero stress components are easily found to be −µΩy, 0 r < s, µΩx, 0 r < s, τxz = τyz = (8.4.13) −µΩys/r, s < r < a, µΩxs/r, s < r < a. We note that as τY tends to zero, a stress singularity develops at r = 0, which reflects the fact that (8.4.10) is a hyperbolic equation for φ; the introduction of even a small amount of elasticity removes the singularity. As in Section 2.4, we can use (8.4.13) to calculate the torque M applied to the bar as a function of the twist (xτyz − yτxz ) dxdy M= cross-section 3 πa τY Ω , Ω Ωc , 2 Ωc (8.4.14) = 3 πa τY Ω3c 4 − 3 , Ω > Ωc . 6 Ω Figure 8.11 shows how the torque increases linearly with the twist until Ω reaches its critical value Ωc . Thereafter, it tails off rapidly, and we observe that only a finite torque 2πa3 τY /3 is required for the bar to fail completely. Now suppose that, once a maximum twist ΩM has been applied, so the bar has yielded down to some radius r = sM =
Ωc a τY = , ΩM µ ΩM
(8.4.15)
8.4 Perfect plasticity theory for metals
347
2M/πa3 τY 1.4 1.2 1.0 0.8 0.6 0.4 0.2
0
1
2
3
4
Ω/Ωc
Fig. 8.11 The normalised torque M versus twist Ω applied to an elastic-plastic cylindrical bar.
the applied torque is then removed sufficiently slowly that we can still use a quasistatic model. We would expect the bar to recover and twist back towards its starting configuration. We denote this subsequent displacement ˜ ; in other words, u ˜ is the displacement relative to the state just before by u we released the torque. Consistent with our assumption of perfect plasticity is the further assumption that, as soon as the torque is decreased, all the once-yielded material instantly returns to being elastic. However, it will now ˜ is zero. start with the nonzero stress (8.4.13) when u ˜ has the same structure (8.4.3) as the original disLet us suppose that u placement, that is ˜ (−yz, xz, 0)T , ˜ =Ω (8.4.16) u since we recall from Section 8.2 that ψ ≡ 0 for a circular bar. The net twist ˜ so we expect Ω ˜ to start at zero when Ω = ΩM of the bar is given by ΩM + Ω, and then fall to negative values as the bar is unloaded. The total stress consists of the elastic stress corresponding to (8.4.16) added to the initial stress (8.4.13) reached at the end of the plastic phase, that is ˜ + ΩM , 0 r < sM , Ω τxz −y =µ × (8.4.17) τyz x ˜ + ΩM sM /r , sM < r < a. Ω A calculation analogous to (8.4.14) leads to the following formula for the applied torque during the recovery phase: Ω3c Ωc 2M ˜ (8.4.18) 4− 3 . =Ω+ πµa4 3 ΩM The final resultant twist Ω0 when the torque has been completely released
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Plasticity
2M/πa3 τY
plastic
ΩM /Ωc
1.2 1.0 0.8 0.6 0.4 0.2
0.0
elastic 0.5
1.0
recovery 1.5
2.0
2.5
3.0
Ω/Ωc
Ω0 /Ωc Fig. 8.12 The normalised torque M versus twist Ω applied to an elastic-plastic cylindrical bar, showing the recovery phase when the torque is released.
˜ is thus found by setting M = 0 in (8.4.18) and recalling that Ω = ΩM + Ω: ΩM Ω3 4 Ω0 = + c3 − . Ωc Ωc 3 3ΩM
(8.4.19)
When ΩM = Ωc (so the bar has never yielded), we see that Ω0 = 0, so the bar returns to its original configuration upon unloading. However, as the maximum twist ΩM is increased, a decreasing fraction of it is recovered when the torque is released, as illustrated in Figure 8.12. The bar behaves elastically until Ω = Ωc and then starts to yield. When M returns to zero, a nonzero twist remains, and this qualitative behaviour is typical of elasticplastic systems. The final crucial observation is that, even when the bar has recovered and there is no net torque on it, the internal stress components (8.4.17) are nonzero, and the bar is said to contain residual stress. This is bound to happen because the recovery phase starts with an initial stress field (8.4.13) that does not satisfy the compatibility conditions. This means that there is no elastic deformation that the material can adopt that will completely relieve the stress. Without the assumption of radial symmetry, the problem must in general be solved numerically, but it still possesses a very helpful mathematical structure, in which the general scenario is sketched in Figure 8.13. There is a plastic region near the boundary in which we have to solve the eikonal equation (8.4.10). This equation is hyperbolic and, given φ = 0 on the surface of the bar, can in principle be solved for φ throughout the plastic region. In the elastic region, φ still satisfies Poisson’s equation, subject to
8.4 Perfect plasticity theory for metals
349
Plastic τ2 |∇φ|2 = 2Y 2 µΩ Elastic ∇2 φ = −2 # $ ∂φ φ = =0 ∂n
y
φ=0
x
Fig. 8.13 The free-boundary problem for an elastic-perfectly plastic torsion bar.
two boundary conditions, namely that both φ and its normal derivative are continuous. In principle, this problem determines both φ and the position of the free boundary between the elastic and plastic regions. This switch in behaviour across the free boundary is reminiscent of the complementarity conditions encountered when modelling contact problems in Chapter 7. Indeed, the free-boundary problem depicted in Figure 8.13 may be cast as a variational inequality and hence proved to be well posed, despite the nonlinearity and the change of type from hyperbolic to elliptic. Moreover, in most practical cases it can be proved to be equivalent to the problem of minimising
|∇φ|2 − 4φ dxdy
D
over all sufficiently smooth functions that vanish on the outer boundary and are such that |∇φ| τY /µΩ. We also note that, as in our models for granular materials, although the yield condition enables us to determine the stress, it tells us nothing about the displacement in the bar once it has yielded. We will return to this point in Section 8.10.
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Plasticity
8.4.2 Plane strain The next simplest situation is that of plane strain, where we can follow the approach of Section 8.2.2 to calculate the shear stress on a surface element with unit normal n = (cos θ, sin θ, 0)T . Indeed, we can read off the maximum tangential traction F by inspecting the Mohr circle in Figure 8.5, and hence deduce the inequality + 1 2 2 (8.4.20) 4 (τxx − τyy ) + τxy τY , with equality when the material has yielded. As in Section 8.4.1, our task is very much easier if we assume that any plastic flow occurs sufficiently slowly for the momentum terms in the Navier equation to be negligible. Hence, we can conveniently use an Airy stress function A throughout the material. Where the material has not yielded (so the inequality in (8.4.20) is strict), we obtain ∇4 A = 0,
(8.4.21)
as in Section 2.6.2. However, when yield occurs, we have equality in (8.4.20), and A satisfies
2 2 2 ∂2A ∂2A ∂2A = 4τY2 . − (8.4.22) ∇ A +4 ∂x∂y ∂x2 ∂y 2 As always the key aspect of the problem is to locate the boundary where the switch from (8.4.21) to (8.4.22) occurs. Here, a traction balance shows that A and its first and second partial derivatives must all be continuous across such a boundary. The nonlinear partial differential equation (8.4.22) satisfied by A when the material has yielded is another generalisation of the Monge–Amp`ere equation, and closely resembles the equation (8.2.7) for granular flow in plane strain. It is not immediately classifiable using the standard theory of secondorder partial differential equations, but the method of Exercise 4.12 shows that it is hyperbolic, with two families of real characteristics satisfying 2 / 2 dy ∂ A ∂ A ∂2A =2 ± τY − . (8.4.23) dx ∂x∂y ∂x2 ∂y 2 These correspond to the directions in which the shear stress is maximal (see Exercise 8.8), and hence the characteristics of (8.4.22) are the slip surfaces, along which we might expect the material to flow.
8.4 Perfect plasticity theory for metals
351
As in Section 8.4.1, analytic solutions of this nonlinear free-boundary problem are unlikely to be available unless the geometry is very simple. A famous example is the gun barrel problem of Section 2.6.5, which we will only sketch briefly because of its similarity to the tunnel problem of Section 8.2.3. Also, for simplicity, we will only treat thick gun barrels, by letting the outer radius b tend to infinity while the inner radius a stays finite. Hence (2.6.42) gives τrr = −
P a2 , r2
τθθ =
P a2 r2
(8.4.24)
as long as the material remains fully elastic (recall that P is the pressure applied to the inner surface r = a). As in the case of granular flow, the yield condition simplifies considerably when there is radial symmetry, and (8.4.20) reduces to (τrr − τθθ )2 4τY2 ,
(8.4.25)
with equality when the material has yielded. The choice of square root is dictated by (8.4.24) and hence the material yields when τθθ − τrr = 2τY .
(8.4.26)
This first occurs at r = a when P = τY , which is consistent with (2.6.45) in the limit b → ∞. When the applied pressure exceeds τY , the material becomes plastic in some region a < r < s, where the radius s of the free boundary is to be determined. In the elastic region r > s, (8.4.24) generalises to τrr = −
τY s2 , r2
τθθ =
τY s2 , r2
(8.4.27)
where we have applied the yield condition (8.4.26) on r = s. In the plastic region, we solve the radial Navier equation τrr − τθθ dτrr + = 0, dr r
(8.4.28)
and the yield condition (8.4.26) simultaneously, with the boundary condition τrr = −P on r = a, to obtain r r τrr = −P + 2τY log , τθθ = −P + 2τY + 2τY log . (8.4.29) a a
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Plasticity
(τθθ − τrr ) /τY
PM = 2τY
0.5
0.0
1.5
0.5
2.0
PM = τ Y
2.5
3.0
r/a
1.0 1.5 2.0
Fig. 8.14 Residual shear stress τθ θ − τr r in a gun barrel versus radial distance r for different values of the maximum internal pressurisation: PM /τY = 1, 1.25, 1.5, 1.75, 2.
Hence, when we balance the normal traction τrr at r = s, we find that 1 P . (8.4.30) − s = a exp 2τY 2 This shows how the plastic region grows rapidly as P increases through τY . We can now perform an unloading analysis similar to that in Section 8.4.1. Suppose P increases to a value PM greater than τY , before decreasing to zero. Our assumption that the material instantaneously becomes elastic when P < PM means that, as in (8.4.17), the free boundary remains stuck at its maximum value sM = a exp (PM /2τY − 1/2). The subsequent response is purely elastic so that τrr = −
τY s2M a2 (PM − P ) + , r2 r2
τθθ =
τY s2M a2 (PM − P ) − r2 r2
(8.4.31)
in r > sM , while r
a2 (PM − P ) + , (8.4.32a) a r2 r a2 (P − P ) M τθθ = −PM + 2τY + 2τY log − (8.4.32b) a r2 in a < r < sM . As in the torsion bar problem of Section 8.4.1, there remains a residual stress field when the loading P has returned to zero. As shown in Figure 8.14, the residual shear stress τθθ − τrr increases in magnitude as PM is increased past τY . The boundary r = a ends up in a state of negative shear stress which, if PM > 2τY , will be large enough to cause the metal to yield again as it recovers! τrr = −PM + 2τY log
8.4 Perfect plasticity theory for metals
353
We have still given no procedure to calculate the displacements in the plastic region. We also caution that the above calculation completely ignores the rˆ ole of τzz , and we will address this issue next. 8.4.3 Three-dimensional yield conditions As we will soon discover, generalising the yield condition to three dimensions introduces new complications not encountered in the antiplane and plane strain examples considered above. In general, and not just for metals, we expect to impose an inequality of the form f (τij ) τY ,
(8.4.33)
where the yield function f is some appropriate measure of the stress. Now we ask ourselves what restrictions need to be imposed on the function f to ensure that (8.4.33) is physically realistic. If we assume that our metal is isotropic, then f must be invariant under rotation of the axes. It follows that f can be written as a function of the three stress invariants (cf Section 5.3.2) 1 Tr (τ )2 − Tr τ 2 , I3 (τ ) = det (τ ), (8.4.34) I1 (τ ) = Tr (τ ), I2 (τ ) = 2 and we have therefore reduced f from six degrees of freedom (the elements of the symmetric tensor τij ) to three. Recall, for example, that the Coulomb yield criterion (8.2.5) for granular material in two dimensions depends only on I1 (τ ) and I3 (τ ). For metals, further simplification can be achieved by recalling the experimental evidence that they do not deform plastically under an isotopic stress, for which τij = −pδij , say; indeed it is intuitively reasonable that a pressure could not cause a dislocation like that sketched in Figure 8.9 to move.† Hence we expect that our yield function f should not vary if τij is replaced by τij + cδij , where c is any scalar, that is f (τij + cδij ) ≡ f (τij ) .
(8.4.35)
We can understand the implications of this constraint on f if we regard it not as a function of the six independent variables τij but as a function of the variables 1 1 and p = − τkk . (8.4.36) τij = τij − (τkk )δij 3 3 = 0, the τ comprise only five independent variables and they Since τkk ij †
Other materials, for example glass, can, however, flow under sufficient hydrostatic pressure.
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Plasticity
define a symmetric trace-free tensor known as the deviatoric part of τij or the stress deviator, while p may be identified with the net isotropic pressure. We can thus write f (τij ) ≡ f τij , p , (8.4.37) say, and, in terms of f , the constraint (8.4.35) is transformed to f τij , p − c ≡ f τij , p .
(8.4.38)
Since this holds for all c, we deduce that f is independent of p and therefore just a function of τij . Now we can impose invariance under both rigid-body rotation and isotropic pressure by writing f τij = f τ1 , τ2 , τ3 , (8.4.39) where τk are the eigenvalues of τij . It is easy to see that the principal axes of τij and τij coincide, and that τk are related to the principal stresses τk (k = 1, 2, 3) by τk = τk + p,
where
p=−
τ1 + τ 2 + τ 3 . 3
(8.4.40)
Since τ1 + τ2 + τ3 = 0, there are only two independent degrees of freedom remaining in the function f . Henceforth we will simply write f (τk ) to mean f (τk ), hopefully without causing too much confusion. One physically plausible possibility is again to define f as the maximum shear stress acting on all possible surface elements. As shown in Exercise 2.9 (see also Exercise 8.2), this leads to 1 f τ1 , τ2 , τ3 = max |τ1 − τ2 |, |τ2 − τ3 |, |τ3 − τ1 | , 2 and the corresponding yield condition max |τ1 − τ2 |, |τ2 − τ3 |, |τ3 − τ1 | = 2τY .
(8.4.41)
(8.4.42)
is called the Tresca condition. Notice that the function (8.4.41) is symmetric with respect to permutation of its arguments, so that there are no preferred directions. In antiplane strain, with the stress tensor given in (8.4.1), the principal deviatoric stresses are easily found to be + + 2 + τ2 , 2 + τ2 , τxz τ = τ3 = 0, (8.4.43) τ1 = − τxz yz yz 2
8.4 Perfect plasticity theory for metals
(a)
(b) 2
4
0
355
τ2
−2 −4
4
1.0
2
0.5
τ3 0 −1.0 −2
−0.5
0.5
1.0
τ1
−0.5
τ2
−4 −4
−2
0
τ1
2
−1.0
4
Fig. 8.15 (a) The Tresca yield surface (8.4.42) plotted in the space of principal stress deviators (τ1 , τ2 , τ3 ) (normalised with τY ), showing the intersection with the π-plane τ1 + τ2 + τ3 = 0. (b) The projection in the (τ1 , τ2 )-plane.
so that the Tresca condition reproduces (8.4.2). In plane strain, we find that + τxx + τyy − 2τzz 2 −τ τ − 14 (τxx + τyy )2 + τxy (8.4.44a) τ1 = xx yy , 6 + τxx + τyy − 2τzz 2 −τ τ + 14 (τxx + τyy )2 + τxy (8.4.44b) τ2 = xx yy , 6 2τzz − τxx − τyy , (8.4.44c) τ3 = 3 so the Tresca condition is consistent with (8.4.20) provided τ3 lies between τ1 and τ2 . This explains the role played by τzz in the examples in Section 8.4.1 and Section 8.4.2, and Exercise 8.9 gives the basis for how τzz should be incorporated into these examples. In three-dimensional problems, we can represent (8.4.42) as a surface, known as the yield surface, in (τ1 , τ2 , τ3 )-space. As shown in Figure 8.15(a), the Tresca yield surface is a cylinder whose axis is in the direction (1, 1, 1)T and whose cross-section viewed along the axis in the π-plane τ1 + τ2 + τ3 = 0 is a hexagon. By also using the constraint τ1 + τ2 + τ3 = 0, we can project this surface onto (for example) the (τ1 , τ2 )-plane as the polygon (8.4.45) max |τ1 − τ2 |, |2τ2 + τ1 |, |2τ1 + τ2 | = 2τY , depicted in Figure 8.15(b). In antiplane strain, we have τ3 = 0 and hence τ1 +τ2 = 0. This straight line intersects the polygon shown in Figure 8.15(b) at the two points (τ1 , τ2 ) = (±τY , ∓τY ), so the yield surface degenerates to just two points
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Plasticity
(a)
(b) 2
4
τ2
0 −2 −4 1.0
4
0.5
2
τ3 0 −1.0
−0.5
0.5
1.0
τ1
−2 −0.5
τ2
−4 −4
−2
−1.0
0
2
τ1
4
Fig. 8.16 (a) The von Mises yield surface plotted in the space of principal stress deviators (τ1 , τ2 , τ3 ) (normalised with τY ), showing the intersection with the π-plane τ1 + τ2 + τ3 = 0. (b) The projection in the (τ1 , τ2 )-plane.
in antiplane strain. However, even in plane strain, the whole hexagon comes into play in general (see Exercise 8.9), and the situation is even worse in three dimensions. The presence of the corners in the yield surface is worrying, since it implies non-smooth dependence of the solution on the stress components. It also makes the Tresca condition awkward to implement in general, and this has led to the adoption of the von Mises yield function f τ1 , τ2 , τ3 =
(τ1 − τ2 )2 + (τ2 − τ3 )2 + (τ3 − τ1 )2 6
1/2 .
(8.4.46)
By construction, this is a valid measure of the stress with all the required properties of invariance although, unlike the Tresca yield function, it has no immediate interpretation in terms of a maximal shear stress. In (8.4.46), we have defined f such that τY is still the critical yield stress under pure shear. However, under a uniaxial stress, with τ2 = √τ3 = 0, the von Mises criterion predicts that yield will occur when τ1 = 3τY , in contrast with the value 2τY predicted by the Tresca condition. The yield surface corresponding to (8.4.46), shown in Figure 8.16(a), is still a cylinder whose axis points in the direction (1, 1, 1)T . However, elementary geometry implies that its cross-section is circular so, in contrast with Figure 8.15, the von Mises yield surface is smooth. Again we can use the constraint τ1 + τ2 + τ3 to project the surface onto the (τ1 , τ2 )-plane, where
8.4 Perfect plasticity theory for metals
357
it takes the form of an ellipse, namely τ1 + τ1 τ2 + τ2 = 2
2
3 (τ1 + τ2 )2 (τ1 − τ2 )2 + = τY , 4 4
(8.4.47)
as shown in Figure 8.16(b). In antiplane strain, the Tresca and von Mises yield criteria coincide, but in higher dimensions (8.4.46) is often easier to implement, especially when we notice that it may be written in terms of the non-principal stress components as 2 1 1 = Tr (τ )2 = τij τij . f τ 2 2
(8.4.48)
The assumed indifference of f to isotropic stress means that the yield surface corresponding to any valid choice of yield function must always be a cylinder pointing in the direction (1, 1, 1)T . The corresponding picture in granular flow is quite different. First, we recall that none of the principal stresses in a granular material may be positive. Second, the yield criterion for a granular material depends explicitly on the normal as well as the shear stress, so no advantage is gained by introducing the stress deviator. Exercise 8.2 shows that, provided the principal stresses are numbered in order, the Coulomb yield condition is equivalent to τ1 − τ3 = (τ1 + τ3 ) sin φ
when
τ1 τ2 τ3 0.
(8.4.49)
This represents a segment of a plane through the origin in (τ1 , τ2 , τ3 )-space, and six other segments are obtained by switching the orders of the principal stress components. Hence, the analogue of the hexagonal cylinder of Figure 8.15 is a six-sided pyramid, the faces of the pyramid corresponding to the six permutations of the indices in (8.4.49). Indeed, invariance with respect to permutation of the principal stresses implies that the yield surface in any isotropic medium must share the six-fold symmetry evident in Figures 8.15 and 8.17. We have seen above that, in both antiplane and plane strain, the yield criterion and the steady Navier equations form a closed system of equations for the stress components. However, the same is not true of genuinely threedimensional problems, since we now have just one yield criterion and three Navier equations for the six stress components. Moreover if the plastic flow is sufficiently strong for the material inertia to be comparable to the yield stress, the resulting system is under-determined even in two dimensions. As in granular flow, the problem must be closed by incorporating a flow rule that determines how the material responds to stress once it has yielded.
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Plasticity 0 −2 −4 0
−2
τ3
−4
τ2
−4
τ1
−2 0
Fig. 8.17 The Coulomb yield surface plotted in the space of principal stresses (τ1 , τ2 , τ3 ) (with φ = π/6).
8.5 Kinematics This is the first time in this book that we have tried to write down a mathematical model for irreversible flow, as opposed to elastic strain. Such models are inevitably more readily stated in terms of the velocity of the medium, rather than the displacement. We therefore introduce the velocity vector v(x, t) defined as ∂u ∂x = , (8.5.1) v= ∂t ∂t X
X
where the time derivative is taken with the Lagrangian coordinate X held fixed. It is convenient to introduce a shorthand for this convective or material derivative, namely ∂ ∂ D = ≡ + (v · ∇) , (8.5.2) Dt ∂t X ∂t x the latter identity following from the chain rule. By applying the convective derivative to u, we obtain a kinematic relationship, v=
∂u + (v · ∇) u, ∂t
(8.5.3)
between the displacement and velocity. We can rearrange this to an explicit
8.5 Kinematics
359
equation for v, namely −1 ∂u v = I − ∇uT , (8.5.4) ∂t recalling that ∇u denotes the displacement gradient tensor with entries ∂uj /∂xi . Hence we can linearise, approximating v as simply the Eulerian time derivative of u, provided the displacement gradients are small. This assumption is usually fine for small displacements of elastic materials, and leads to the theory of linear elasticity as we have seen. However, a characteristic of plastic behaviour is the ability to suffer large permanent displacement without breaking. To describe such situations as the bending of a paper clip, we would need to retain the nonlinear terms in (8.5.3) and distinguish carefully between Lagrangian and Eulerian time derivatives, as in Chapter 5. As shown in Exercise 8.10, conservation of mass in a material flowing with velocity v and density ρ leads to the equation Dρ + ρ div v = 0. (8.5.5) Dt In an incompressible medium, the density of each material element is conserved, and the velocity must therefore satisfy div v = 0. Next, to describe the deformation of a flowing material, we introduce the concept of rate-of-strain. We recall that the strain tensor describes the change in length of a small line element in the material, compared with its initial length. Once a material is flowing, it starts to “forget” its initial rest state, so it no longer makes sense to use the initial length as a benchmark. Instead, it is more natural to examine the instantaneous variation in a line element over a small time increment. This is not a book about fluid mechanics, so we will not spell out all the details here (but see Exercise 8.11). Suffice it to say that the rate of change of the length of a line element δx = (δx1 , δx2 , δx3 )T takes the form d |δx|2 = 2δxT Dδx, (8.5.6) dt where the rate-of-strain tensor is defined by† ∂vj 1 1 ∂vi or D = Dij = + ∇v + ∇v T . 2 ∂xj ∂xi 2
(8.5.7)
If the strains are small enough for us to neglect the nonlinear terms in (8.5.3), then Dij is simply the time derivative of the linear strain tensor eij . Otherwise, the relationship between strain and rate-of-strain is complicated, †
Note that fluid mechanics textbooks often omit the factor of 1/2 in the definition of Di j
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Plasticity
but it is of fundamental importance in describing large strains of viscoelastic materials, as we will see in Section 9.2.
8.6 Conservation of momentum By applying the convective derivative to the velocity vector, we find that the acceleration of the medium is given by ∂v Dv = + (v · ∇) v, Dt ∂t
(8.6.1)
and we can therefore write Cauchy’s momentum equation in the form ∂v + (v · ∇) v = ∇ · τ + ρg. (8.6.2) ρ ∂t Along with the yield condition f (τ ) = τY ,
(8.6.3)
this gives us four scalar equations so far for the nine unknowns τij and vi . Now our task is to obtain a constitutive relation for the stress field associated with a given flow velocity v. Before doing so, we will first derive an equation representing conservation of energy.
8.7 Conservation of energy In Chapter 1, we showed that the net mechanical energy, i.e. the sum of the kinetic and strain energies, is conserved in a linear elastic solid. In Chapter 5, we found that the same is true in a nonlinear elastic material provided we use a hyperelastic constitutive law. However, irreversible plastic flow involves a loss of mechanical energy, which is dissipated as heat: by flexing a large paper clip a few times, one can get it to warm up appreciably. We can quantify this heating by performing an energy balance on a material volume V (t) that moves with the deforming medium. We now make the important assumption that no elastic strain energy is stored once the material has yielded (this assumption will be revisited in Section 8.9). The net energy in V (t) is therefore given by 1 2 ρ|v| + ρcT dx, (8.7.1) U= V (t) 2 where the terms in the integrand correspond respectively to the kinetic energy and the thermal energy associated with the absolute temperature T .
8.7 Conservation of energy
361
We will assume that the parameter c, called the specific heat capacity (at constant volume), is constant. In accordance with the first law of thermodynamics, the energy inside V will change because of (i) work done by stress on the boundary ∂V , (ii) work done by the body force g on the interior of V and (iii) heat conduction through ∂V . Combining these effects together, we obtain dU = v · (τ n) dS + v · (ρg) dx + k∇T · n dS dt ∂V (t) V (t) ∂V (t) = {div (τ v) + ρv · g + div (k∇T )} dx, (8.7.2) V (t)
after using the divergence theorem, where k is the thermal conductivity. In differentiating U , it is helpful to transform the integral in (8.7.1) to Lagrangian variables, so that d 1 dU 2 = ρ0 |v| + ρ0 cT dX dt dt V (0) 2 ∂v ∂T ρ0 v · dX = + ρ0 c ∂t X ∂t X V (0) DT Dv = + ρc ρv · dx, (8.7.3) Dt Dt V (t) noting that the integration variable X must be held constant when differentiating through the integral. Since (8.7.2) and (8.7.3) are equal for all material volumes V (t), we deduce that the integrands (if continuous) must be equal. The resulting equation may be simplified using (8.6.2) to obtain the energy equation in the form ∂T ρc + v · ∇T − div (k∇T ) = Φ, (8.7.4) ∂t where the dissipation function is defined by Φ = Dij τij .
(8.7.5)
If Φ = 0, (8.7.4) is the familiar equation describing the conduction and convection of heat in a material moving with velocity v. The dissipation acts as a source term, representing the rate at which mechanical energy is lost and heat is produced. In a hyperelastic material, with a strain energy density W(C), where C is the Green deformation tensor, direct differentiation reveals that W d dx, (8.7.6) Φ dx = dt V (t) V (t) J
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Plasticity
so the dissipation is exactly balanced by the change in W, and the net mechanical energy is conserved.† The production of heat is thus a consequence of our assumption that a flowing plastic material (like a viscous fluid) does not store any elastic energy, and we will return to this point in Section 8.9.
8.8 The flow rule We are at last in a position to pose a constitutive relation for the stress τ associated with a given velocity v. The second law of thermodynamics tells us that dissipation can only heat the material up and not cool it down, so that the conversion of mechanical energy to thermal energy is irreversible. Hence any physically acceptable constitutive relation must be such that Φ 0 for any possible flow. Indeed, we might expect the material to flow in such a way as to maximise the rate at which it dissipates energy. This hypothesis prompts us to pose the question: what value of the stress components τij , satisfying the yield condition f (τij ) = τY , would give rise to the maximum value of Φ? This is a straightforward constrained optimisation problem, namely maximise
Dij τij
subject to
f (τij ) = τY ,
(8.8.1)
whose solution is Dij = Λ
∂f , ∂τij
(8.8.2)
where Λ is a Lagrange multiplier which, in general, can be a scalar function of x and t. A geometrical interpretation of (8.8.2) is that the rate-of-strain is perpendicular to the yield surface, when viewed in stress-space as in Figure 8.16. Equation (8.8.2) is the associated flow rule to the yield function f . If we adopt this rule to relate the stress to the rate-of-strain, then we gain six scalar equations and one further unknown, namely Λ. In total, therefore, the momentum equation (8.6.2), the yield condition (8.6.3) and the flow rule (8.8.2) comprise ten scalar equations, so we finally have a closed system for τij , vi and Λ. We should point out that it is by no means necessary for the stress to be such as to maximise the dissipation. Indeed, there are several alternative non-associated flow rules which are not derived from the yield function. However, (8.8.2) is generally found to agree well with experiment and guarantees that the flow shares all the same symmetry properties that we have †
Note that this would not be true if W depended explicitly on T ; see Exercise 9.7.
8.8 The flow rule
363
already imposed on the yield criterion. For example, an isotropic yield function will lead to an isotropic flow rule. In addition, our insistence that the yield criterion be insensitive to isotropic stress means that f must satisfy ∂f =0 ∂τkk
(8.8.3)
(summing over k), and then (8.8.2) implies that Dkk = div v = 0,
(8.8.4)
and hence that the flow is incompressible. This is in encouraging agreement with the experimental evidence that plastic deformation does not appreciably change the density of a metal. As we noted in Section 8.3, atomistic simulations suggest both that dislocations do not respond to isotropic stress and that, when dislocations do flow, they do so with no appreciable volume change. The flow rule (8.8.2) suggests that these two properties of insensitivity to isotropic stress and incompressibility are actually linked at a macroscopic level. We could therefore think of (8.8.2) as a hypothesis that the yielding of a plastic material and the way it subsequently flows are essentially controlled by same underlying mechanism. We begin by applying (8.8.2) to the Tresca yield function, defined by (8.4.41), which takes the form τ3 − τ 1 , (8.8.5) 2 provided the principal stresses are ordered such that τ1 τ2 τ3 . We therefore deduce from (8.8.2) that D shares the same principal axes as τ and has principal components f (τ ) =
Λ Λ D2 = 0, (8.8.6) D3 = . D1 = − , 2 2 However, this is often awkward to implement in practice because of the corners that occur in the yield surface when the principal stresses cross each other (see Calladine, 2000). In three-dimensional problems, the von Mises yield function (8.4.48) is therefore usually preferred. In this case, (8.8.2) simply tells us that the rate-of-strain tensor is proportional to the stress deviator, that is Λ τij , (8.8.7) Dij = 2τY as shown in Exercise 8.13. This is called the Levy–von Mises flow rule, and it again implies that the principal axes of stress and strain-rate coincide.
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Plasticity
The flow rule (8.8.7) closely resembles the constitutive relation for an inole of viscosity compressible Newtonian viscous fluid, with τY /Λ playing the rˆ (see, for example, Ockendon & Ockendon, 1995, Chapter 1). Unlike the situation in a Newtonian fluid, the effective viscosity is unknown in advance and must be determined as part of the solution, using the fact that the stress is bounded by τY . However, by using (8.8.7), we can write the dissipation (8.7.5) in the form Λ τ τ . (8.8.8) Φ= 2τY ij ij We must therefore ensure that Λ is non-negative, so that the plastic flow dissipates mechanical energy rather than gaining it. It is straightforward to reach the same conclusion for the Tresca flow rule (8.8.6). In summary, when we adopt the von Mises yield function, the mathematical model comprises the three first-order differential equations (8.6.2), relating τ and v and the seven algebraic relations (8.6.3), (8.8.7), which also involve the unknown scalar Λ.
8.9 Simultaneous elasticity and plasticity The theory of plasticity described above assumes that there is an instantaneous transition from a purely elastic material to a purely plastic one. Unfortunately, the situation in practice is somewhat more complicated. Careful experiments reveal that the heat dissipated during plastic flow may be significantly less than that predicted by (8.7.5). The interpretation of these observations is that the material continues to store elastic energy even after it has yielded. We must therefore construct a theory that combines both elastic and plastic displacements simultaneously. This is a significant challenge, and we will limit our attention here to small displacements so that we can use the linearised strain tensor eij and approximate the strain rate as simply the Eulerian time derivative of eij . We decompose the strain into an elastic component and a plastic component, say eij = eeij + epij .
(8.9.1)
We assume that these are related to the stress τij by the usual isotropic linear elastic relation (1.7.6) and the plastic flow rule (8.8.7) respectively. Thus ∂epij Λ e = τij , (8.9.2) Eeij = (1 + ν) τij − ντkk δij , ∂t 2τY
8.10 Examples
and the net strain-rate components are therefore given by ∂τij ∂eij ∂τkk EΛ = (1 + ν) −ν δij + E τij . ∂t ∂t ∂t 2τY
365
(8.9.3)
Combining (8.9.3) with the momentum equation (8.6.2) and the yield condition (8.6.3), we obtain a closed system of ten equations for the six stress components τij , the three displacement components ui and the scalar Λ. To fix ideas, let us suppose that inertia and gravity are negligible so that the momentum equation (8.6.2) reduces to ∂τij = 0. (8.9.4) ∂xj This holds in both elastic and plastic regions, as does (8.9.3) provided we set Λ = 0 when the material is elastic. On the other hand, when the material is plastic, we know that Λ must be positive and the yield condition (8.6.3) must be satisfied. The problem thus boils down to the system (8.9.4) and (8.9.3), along with the complementarity conditions f (τij ) τY , Λ 0. (8.9.5) f (τij ) − τY Λ = 0, To solve this problem, we would need to specify the initial displacement (typically zero) and three boundary conditions on either the displacement or the stress. In addition, the strain and displacement must both be continuous across the free boundary separating the elastic and plastic regions. We will now illustrate the procedure using three simple examples. 8.10 Examples 8.10.1 Torsion revisited First we return to the torsion bar example from Section 8.4.1. If we limit our attention to circular bars, we can conveniently use cylindrical polar coordinates, seeking a solution in which the displacement takes the form u = Ω(t)rzeθ . This automatically enforces continuity of strain and displacement throughout the bar. According to (1.11.6), the only nonzero strain component is Ωr , (8.10.1) eθz = 2 so that (8.9.3) gives us the equation µ ∂τθz dΩ + (8.10.2) Λτθz = µr ∂t τY dt for τθz (r, t). The initial condition is τθz (r, 0) = 0, but, before we can solve (8.10.2), we need a further condition to determine Λ.
366
Plasticity
While the material remains elastic, we have Λ = 0, and integration of (8.10.2) leads to τθz = µrΩ.
(8.10.3)
Yield first occurs when τθz = τY at r = a, that is when Ω = Ωc = τY /µa. For larger values of Ω, (8.10.3) only applies in r < s, where s = Ωc /Ω. In r > s, the material has become plastic, so Λ is no longer zero but we instead impose the yield condition τθz = τY . Then (8.10.2) enables us to determine Λ as Λ=r
dΩ dt
(8.10.4)
in s < r < a. Hence we see that Λ is positive as long as Ω is an increasing function of t. If the twist reaches a maximum and then starts to decrease, then (8.10.4) gives us a negative value of Λ, which is thermodynamically unacceptable. Hence it is because of the imposed non-negativity of Λ that the bar must revert to being entirely elastic as it unloads, as was assumed in Section 8.4.1.
8.10.2 Gun barrel revisited Next we turn our attention to the behaviour of an elastic-plastic material occupying the region r > a and subject to a pressure P (t) on r = a. In Section 8.4.2, we used the Tresca yield condition to solve for the stresses in the elastic and plastic regions. We will now calculate the associated displacement and, for consistency, we will also base our flow rule on the Tresca yield function. The results of Section 8.4.2 suggest that the stress components should satisfy τrr τzz τθθ ,
(8.10.5)
in which case (8.8.6) gives the plastic strain rate as p
∂eθθ Λ Λ ∂epzz ∂eprr =− , = , = 0. (8.10.6) ∂t 2 ∂t 2 ∂t By combining the elastic and plastic strain components as in Section 8.9, we thus obtain the equations ∂err ∂τrr ∂τθθ ∂τzz = −ν −ν − ∂t ∂t ∂t ∂t ∂τθθ ∂τzz ∂τrr ∂eθθ = −ν −ν + E ∂t ∂t ∂t ∂t ∂τzz ∂τrr ∂τθθ ∂ezz = −ν −ν . E ∂t ∂t ∂t ∂t E
EΛ , 2 EΛ , 2
(8.10.7a) (8.10.7b) (8.10.7c)
8.10 Examples
367
We consider a plane radial displacement of the form u = ur (r, t)er , so that the principal strains are given by ∂ur ur (8.10.8) , eθθ = , ezz = 0. ∂r r Hence, by integrating (8.10.7c) with respect to t we deduce that the axial stress is given by err =
τzz = ν (τrr + τθθ ) .
(8.10.9)
Similarly, by adding (8.10.7a) and (8.10.7b), we obtain the identity ur ∂ur + = (1 − ν) (τrr + τθθ ) − 2ντzz E ∂r r = (1 + ν)(1 − 2ν) (τrr + τθθ ) . Finally, by subtracting (8.10.7a) from (8.10.7b), we find that ∂ur ∂ ur ∂ − E = (1 + ν) (τθθ − τrr ) + EΛ. ∂t r ∂r ∂t
(8.10.10)
(8.10.11)
While P τY , the material remains elastic, so that Λ is zero, and integration of (8.10.10) leads to ur ∂ur E − = (1 + ν) (τθθ − τrr ) . (8.10.12) r ∂r We therefore find that ∂ur ur = τrr − ντθθ = τθθ − ντrr , E E (8.10.13) ∂r r and the pure elastic stress field (8.4.24) gives us the displacement ur =
P a2 , 2µr
(8.10.14)
in agreement with (2.6.41). When P > τY , the displacement associated with the stress field (8.4.27) in the elastic region r > s is similarly found to be ur =
τY s2 , 2µr
(8.10.15)
where s is given by (8.4.30). In the plastic region a < r < s, Λ is no longer zero, but we can use the stress components already calculated in Section 8.4.2, conveniently written in the form r r , τθθ = τY + 2τY log . (8.10.16) τrr = −τY + 2τY log s s
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Plasticity
(Incidentally, we can use these and (8.10.9) to verify that the inequalities in (8.10.5) are indeed satisfied.) Hence (8.10.10) takes the form r ur 2(1 − 2ν)τY ∂ur + = log , (8.10.17) ∂r r µ s which is easily integrated with respect to r to r (1 − ν)τY r log − ur = µ s
give C(t) 1 + . 2 r
(8.10.18)
We determine the integration function C(t) by requiring ur to be continuous across the boundary r = s, and the plastic displacement is thus found to be r 1 (1 − ν)s2 τY (1 − 2ν)r log − + . (8.10.19) ur = µ s 2 r Finally, substitution of (8.10.19) into (8.10.11) leads to ds 4(1 − ν)τY s . Λ= 2 µr dt
(8.10.20)
Hence Λ 0 as long as the plastic region is growing; if the applied pressure is ever a decreasing function of t, then the yielded material must instantaneously return to being elastic, as was assumed in Section 8.4.2.
8.10.3 L¨ uders bands One of the most famous manifestations of metal plasticity is the formation of L¨ uders bands in polished bars or sheets placed under a sufficiently large tensile stress to cause plastic flow (see, for example, Thomas, 1961, p. 100). As illustrated in Figure 8.18, surface roughness associated with plastic strain is observed in bands inclined at a well-defined angle φ to the direction in which the tension is applied. To describe this situation fully necessitates the solution of a difficult two-dimensional free-boundary problem. We therefore focus on the simplified model problem of an infinite plate lying in the (x, y)plane, with a straight line separating an elastic region in y < mx from a plastic region in y > mx. The √ elastic region is subject to a uniaxial stress T , which must be equal to 3τY under the von Mises criterion. In the plastic region, we have a plane stress field of the form τxx τxy 0 τ = τxy τyy 0 , (8.10.21) 0 0 0
8.10 Examples
369
y
T
T φ
T
x T
Fig. 8.18 L¨ uders bands in a thin sheet of metal.
so that the deviatoric stress tensor is 2τxx − τyy 3τxy 0 1 . τ = 3τxy 2τyy − τxx 0 3 0 0 −τxx − τyy
(8.10.22)
We assume that these stress components are spatially uniform, which would clearly be inadequate to describe a finite plate with stress-free edges. Continuity of traction across y = mx implies that τxx − mτxy = −mT,
τxy − mτyy = 0,
(8.10.23)
while the von Mises criterion (8.4.48) takes the form 2 2 2 + τyy − τxx τyy + 3τxy = 3τY2 = T 2 . τxx
(8.10.24)
This gives only three equations for the four unknowns τxx , τxy , τyy and m. The last piece of information comes from the zz-component of (8.9.3), namely E
∂ EΛ ∂ezz = −ν (τxx + τyy ) − (τxx + τyy ) . ∂t ∂t 6τY
(8.10.25)
In the elastic region, ezz is constant and given by −νT /E. Hence, by continuity of strain at the elastic–plastic interface, ∂ezz /∂t = 0 and (8.10.25) becomes ∂ EΛ (τxx + τyy ) + (τxx + τyy ) = 0. (8.10.26) ∂t 6ντY Although Λ is as yet undetermined, we know that it must be positive whenever plastic flow is taking place, so that (τxx + τyy ) necessarily tends
370
Plasticity
to zero as time progresses. The large-time solution of (8.10.23) and (8.10.24) is thus found to be √ 1 T 2T (8.10.27) , τxy = , m = ±√ , −τxx = τyy = ± 3 3 2 and the elastic-plastic boundary therefore makes an angle of √ φ = cot−1 2 ≈ 35◦
(8.10.28)
with the x-axis. Notice that only one component of (8.9.3) was required to get this result; the others may be used subsequently to calculate the plastic strain and the flow parameter Λ.
8.11 Concluding remarks We have just seen how a flow rule such as the Levy–von Mises relation (8.8.7) leads to successful mathematical models for many practical problems in metal plasticity which can, in simple situations, be solved analytically. Numerous analogous flow rules have been posed for granular plasticity, but they generally rest on somewhat less firm theoretical ground, and we have therefore not attempted to describe them here. Another practically important issue that we have not addressed is work hardening. This is an experimentally observed phenomenon whereby plastic deformation of a material causes it to become stronger. At a microscopic level, this is known to result from accumulation of dislocations. From a modelling perspective, it can be described by allowing the yield stress τY to vary, typically increasing as a function of the plastic strain. Despite our restriction to small strains, the elastic-plastic evolution model constructed in Section 8.9 is nonlinear because of the free boundary that separates the elastic and plastic regions. Thus, in more realistic geometries than the simple symmetric examples considered here, it will usually be necessary to solve (8.9.3) numerically. It is often convenient to do so by iterating through several small time-steps dt and calculating the stress and strain increments dτij and deij that occur in each step. These are related by the Prandtl–Reuss model, in which (8.9.3) is discretised as Eτij ˜ + (1 + ν) dτij − νδij dτkk , dΛ (8.11.1) Edeij = 2τY ˜ = Λdt. The solution scheme involves choosing physically acceptwhere dΛ able paths for the stress deviator and the elastic and plastic strains, as described in Hill (1998, Chapter II.5). Time does not appear explicitly in
8.11 Concluding remarks
371
the iteration, which can therefore only predict the sequence of configurations and hence any ultimate steady state. In all the plastic models that we have considered, analytical progress is almost always impossible if the inertial terms are included on the left-hand side of the momentum equation (8.6.2). Fortunately they are often negligible in practice. We can determine when this is true by calculating the appropriate dimensionless parameter as follows. First we write (8.6.2) in terms of the deviatoric stress as ρ
∂v + (v · ∇) v ∂t
= −∇p + ∇ · τ + ρg.
(8.11.2)
If the material is flowing plastically at a typical speed V over a region of typical length-scale L, we can see that the left-hand side is of order ρV 2 /L, while the stress term on the right-hand side may be estimated as τY /L. The relative importance of the inertial terms is thus determined by the dimensionless parameter Re =
ρV 2 . τY
(8.11.3)
For example, the density and yield stress of low-strength steel are approximately 8000 kg m−3 and 5 × 108 N m−2 respectively. Hence, if we bend a paper clip at about 10 cm s−1 , then the corresponding value of Re is roughly 10−7 , and inertia is certainly negligible. We note, however, that there is also a high-Re regime in which the plastic flow is so fast that the inertia term in (8.11.2) is dominant, and the plastic stress is negligible in comparison. This limit applies, for example, to the violent metal plasticity caused by a device called a shaped charge, in which a metal cone is compressed by an explosive to such an extent that its vertex emits a plastic metal jet moving at enormous speed (up to 14 kilometres per second). This exerts a pressure on the target that can be orders of magnitude larger than its yield stress, and the target therefore gives way plastically as the jet forces its way through. Shaped charges are chillingly effective, able to penetrate over a metre of steel. When Re is very large, (8.11.2) and (8.8.4) reduce to the Euler equations of incompressible inviscid fluid dynamics: the target flows like an incompressible inviscid liquid to lowest order. Thus shaped charge penetration is relatively simple to model compared with plastic penetration at lower stresses.
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Plasticity
Exercises 8.1
8.2
(a) Show that the height of sand piled maximally on a horizontal circular table bounded by the circle r = a in plane polar coordinates is given by z = (a − r) tan φ. (b) Show that if the table is instead the rectangle |x| a, |y| b, then the sand pile takes the shape of a roof with ridge line y = 0, |x| < a − b, when a > b. (c) Show that, if the table is bounded by the ellipse {(a cos s, b sin s) : s ∈ [0, 2π)} , then the ridge line is y = 0, |x| < a2 − b2 /a. Consider a three-dimensional stress field expressed with respect to principal axes so that τ = diag (τ1 , τ2 , τ3 ), where τk are the principal stresses. Recall that, in Figure 8.4, the normal and tangential tractions on a surface element with unit normal n are given by N = n · (τ n) ,
F = τ n − N n.
(a) Deduce that N and F = |F | satisfy the relations 2 1 (τ1 − τ2 )2 2 + (τ1 − τ3 ) (τ2 − τ3 ) n23 , F + N − (τ1 + τ2 ) = 2 4 2 1 (τ2 − τ3 )2 2 + (τ2 − τ1 ) (τ3 − τ1 ) n21 , F + N − (τ2 + τ3 ) = 2 4 2 1 (τ3 − τ1 )2 2 + (τ3 − τ2 ) (τ1 − τ2 ) n22 , F + N − (τ3 + τ1 ) = 2 4 where nk are the components of n. Hence show that N and F lie on points in the (N, F )-plane bounded by three semicircular arcs, as illustrated in Figure 8.19. (b) Assuming (without loss of generality) that the stresses are ordered such that τ1 τ2 τ3 0, deduce that the Coulomb yield criterion is equivalent to τ3 − τ1 = − (τ3 + τ1 ) sin φ, where φ is the angle of friction. (c) Show also that the maximum value of F is given by (τ3 −τ1 )/2. 8.3
Follow the approach of Exercise 4.12 to show that the equation (8.2.7) governing two-dimensional granular flow with no body force is hyperbolic.
Exercises
373
F
φ τ1
τ2
τ3
N
Fig. 8.19 The Mohr surface in the (N, F )-plane for three-dimensional granular flow, and the line F = |N | tan φ. The region where solutions exist is shaded.
8.4
Reach the same conclusion for the system (8.2.5) (with equality), (8.2.6) including a body force. (a) For the displacement field (8.3.1) corresponding to a screw dislocation, calculate the jump in w as a simple closed contour C in the (x, y)-plane is traversed, and hence show that # $ b if C encloses the origin, ∂w ∂w dx + dy = w C = ∂x ∂y 0 otherwise. C Show that 2 b if S contains the origin, ∂ w ∂2w − dxdy = ∂x∂y ∂y∂x 0 otherwise, S where S is the interior of C. Deduce that w satisfies (8.3.3). (b) Alternatively, observe that, although w has a jump of magnitude b across the positive x-axis, ∂w/∂x is continuous. Hence explain why −by ∂w = , ∂x 2π (x2 + y 2 )
8.5
∂w bx = − b H(x)δ(y), ∂y 2π (x2 + y 2 )
where H denotes the Heaviside function (3.5.7), and, by crossdifferentiating, obtain (8.3.3). Verify that the Papkovich–Neuber potentials φ = 0,
ψ1 =
2µbθ , (3 − 4ν)π
lead to the displacement field (8.3.7).
ψ2 =
2µb (3 − 4ν)2 π
374
8.6
Plasticity
Using the relations (2.6.20) for the polar stress components in terms of the Airy stress function A, show that (8.3.8) is consistent with A = c1 rθ cos θ + c2 r log r sin θ, and determine the appropriate values of the constants c1 and c2 . Hence show that A satisfies Eb Eb sin θ ∂θ 2 =− , ∇ A= π(1 + ν)(3 − 4ν) r π(1 + ν)(3 − 4ν) ∂x
8.7
where θ is the usual polar angle. Assuming that 0 θ < 2π, and using the results of Exercise 8.4, deduce that A satisfies (8.3.10). Return to the calculation of elastic-plastic behaviour in a circular torsion bar from Section 8.4.1. Show that the net torque M exerted by the stress field (8.4.17) is given by ˜ Ω Ω3c 1 2M + 4 − = , πa3 τY 3 Ωc Ω3M and hence evaluate the residual twist in the bar when M = 0. Suppose we now twist the bar in the opposite direction, so that M is negative. Use (8.4.17) to show that the bar yields again at r = a when ˜ = −2Ωc , Ω
Ω3c 2M 2 − = − > −1. πa3 τY 3 3Ω3M
[Thus, after the bar has yielded in one direction, a smaller torque is required to make it subsequently yield in the opposite direction. This is known as the Bauschinger effect.] Show that the stress in the bar is then given by ˜ 0 r < sm , Ω + ΩM , −y τxz ˜ + ΩM sm /r, sm < r < η, =µ × Ω τyz x η < r < a, −τY /µr, where the position of the new yield boundary is r=η=−
Ωc a . ˜ Ω
Hence show that the associated torque is given by 2M Ω3c 4 16Ω3c − = − − ˜3 πa3 τY 3 3Ω3M 3Ω
Exercises
375
2M/πa3 τY 2
1.0
0.5
3
2
1
1 1
1.0
2
3
Ω/Ωc
4
0.5
6
3
5
Fig. 8.20 The normalised torque M versus twist Ω applied to an elastic-plastic cylindrical bar undergoing a loading cycle. The bar deforms elastically (1), then yields (2), then recovers elastically (3) when the load is released. When a load is now applied in the opposite direction (4), the bar yields at a lower critical torque (5) and then deforms plastically. Finally, the load is released (6) and a permanent negative twist remains.
8.8
˜ < −2Ωc . Figure 8.20 shows how the twist varies as for −2ΩM < Ω the torque cycles through positive and negative values. ˜ < −2ΩM ? What happens when Ω Deduce from (8.2.3) that, in plane strain, the shear stress on a surface element with unit tangent (cos α, sin α, 0)T is 1 F = (τyy − τxx ) sin(2α) − τxy cos(2α). 2 Show that F takes its maximum and minimum values where τxx − τyy tan(2α) = . 2τxy If the maximum value of F is equal to τY , deduce that tan α =
8.9
2 (τxy ± τY ) . τxx − τyy
From the linear elastic constitutive relations in plane strain, show that the normal stress is given by τzz = ν (τxx + τyy ) , where ν is Poisson’s ratio. Deduce that the normal deviatoric stress τ3 is related to the principal in-plane deviatoric stresses and the pressure p by τ3 = (1 − 2ν)p + ν τ1 + τ2
376
Plasticity
and hence obtain the relation τ1
+
τ2
=−
1 − 2ν 1+ν
p.
For each fixed value of p, this gives us a straight line in the (τ1 , τ2 )plane. By considering the intersection of this line with the polygon in Figure 8.15(b), show that the plane strain Tresca yield condition is |τ1 − τ2 | = 2τY provided |p|
8.10
2(1 + ν)τY . 3(1 − 2ν)
[If this condition is violated, then the normal stress τzz that must be applied to prevent out-of-plane displacement will cause the material to yield in the z-direction.] (a) Recall that ∂xi J = det ∂Xj is the Jacobian of the transformation from Lagrangian to Eulerian variables. Prove Euler’s identity DJ = J div v, Dt where D/Dt is the convective derivative. Deduce that the density ρ satisfies the continuity equation ∂ρ + div(ρv) = 0. ∂t (b) Hence prove Reynolds’ transport theorem: for any volume V (t) that is convected with velocity v(x, t) and any differentiable function F (x, t), DF d ρ dx. F ρ dx = dt V (t) V (t) Dt
8.11
Consider a material flowing with velocity field v(x, t). A material point occupying position x at time t is therefore convected to position x + v(x, t)δt after a small time δt. Show that a neighbouring point x + δx is convected to a position with coordinates ∂vi xi + δxi + vi (x, t) + (x, t)δxj δt ∂xj
Exercises
377
(using the summation convention). Deduce that the rate of change of the line element δx satisfies ∂vi d (δxi ) = δxj , dt ∂xj and, by appropriate choice of the dummy summation indices, obtain the equations δxi
8.12
∂vj d ∂vi (δxi ) = δxi δxj = δxi δxj . dt ∂xj ∂xi
Hence show that the length of the line element satisfies (8.5.6). Include elastic energy in (8.7.1) by writing 1 W 2 ρ|v| + ρcT + dx. U= J V (t) 2 The strain energy density W is a function of the elastic deformation gradient tensor Fije (see (5.2.2)) satisfying e −1 ∂W = Jτik Fjk . e ∂Fij Show that DW e = JDij τij , Dt e is the elastic rate-of-strain tensor. Deduce that the dissiwhere Dij pation function in (8.7.4) becomes p τij , Φ = Dij
8.13
p where Dij is the plastic rate-of-strain, so that the net rate-of-strain e + Dp . is given by Dij = Dij ij (a) Show that the flow rule (8.8.2) is invariant under rotations of the coordinate axes. (b) Show that the Levy–von Mises flow rule leads to (8.8.7) when we choose principal axes in which the stress tensor is diagonal. (c) Deduce that (8.8.7) is valid with respect to any chosen axes.
9 More general theories
9.1 Introduction We will now mention a wide range of important solid mechanics phenomena that warrant discussion even in a mathematically-oriented book but have been ignored or scarcely mentioned so far. A phenomenon of interest in industries ranging from food to glass is that of viscoelasticity. Here the molecular structure of the material is such that it flows under any applied stress, no matter how small. As we will see in Section 9.2, viscoelastic materials are quite unlike plastic materials. Their behaviour depends critically on the time-scale of the observer; for example when a ball of “silly putty” or suitably dilute custard impacts a wall, it rebounds almost elastically but, if left on a table, it will slowly spread horizontally under the action of gravity. Yet another attribute of solids is well-known to be of great practical importance in the kitchen, when glass can be observed to break in hot water, and in the railway industry, where track can distort in high summer. This is thermoelasticity, which describes the response of elastic solids to temperature variations. To model this response ab initio, even at a macroscopic scale, requires more thermodynamics than is appropriate for this text, and in Section 9.3 we will only present the simplest ad hoc model that can give useful realistic results. Even the above list of diverse phenomena only relates to solids that are fairly homogeneous on a macroscopic scale. Hence this book would certainly not be a fair introduction to the mathematics of solid mechanics without some discussion of the increasingly important properties of composites. These are solids in which the elastic properties vary on a length-scale much smaller than any macroscopic length-scale of practical relevance but not so small as to render a continuum model inappropriate. They range from 378
9.2 Viscoelasticity
379
ceramics to metallic foams, in which voids may be distributed throughout the material, to fibre-reinforced solids, wood, fabrics and many other biomaterials. In Section 9.4 we will briefly introduce the mathematical technique of homogenisation, which allows the macroscopic properties of a composite to be determined from knowledge of the geometry of the microstructure. There are also many important materials consisting of a porous elastic matrix where the pores are filled with a viscous fluid. This description applies, for example, to saturated rock or soil, as well as many biological tissues. In these materials, the elastic deformation and fluid flow are intimately coupled: compression of the matrix forces the fluid to flow (as in squeezing a wet sponge), and the flowing fluid in turn exerts a drag on the matrix. In Section 9.5, we will derive a simple model for these poroelastic materials. Finally, in Section 9.6, we will discuss briefly what can be said about anisotropy, which is often a consequence of homogenisation. 9.2 Viscoelasticity 9.2.1 Introduction Viscoelasticity concerns materials which respond to an applied stress by exhibiting a combination of an elastic displacement and a viscous flow. This is another vast area of the theoretical mechanics to which we can only provide an elementary introduction. Such materials exist all around us. Consider rock, for example, which is elastic on human time-scales but flows over geological time-scales, for example when mountains are formed by collision between tectonic plates. Indeed, we will discover shortly that the key dimensionless parameter that characterises viscoelastic behaviour is the Deborah number, which was named after the Old Testament prophet Deborah, quoted as saying “The mountains flowed before the Lord” (Judges 5:5). We note two important distinctions between viscoelastic and plastic behaviour. First, a viscoelastic material always exhibits a combination of elasticity and flow: no yield stress needs be exceeded for flow to occur. Second, as the examples above demonstrate, the response of a viscoelastic material to a given stress is crucially dependent on the time-scale over which that stress is applied. In contrast, plastic flow depends only on the magnitude of the stress. In Chapter 1, we based our elastic constitutive law between stress and strain on Hooke’s law. We will therefore begin by considering how Hooke’s law can be generalised to describe viscoelastic behaviour. We will then show how such a law may be used to construct a continuum model for a viscoelastic material.
380
More general theories
(a)
(b)
u
T
u T
T
T
(d)
(c) Te
Te
ue T
Tv
T uv
Tv u
Fig. 9.1 (a) A spring; (b) a dashpot; (c) a spring and dashpot connected in parallel; (d) a spring and dashpot connected in series.
9.2.2 Springs and dashpots Let us first consider a spring subject to a tension T , as illustrated in Figure 9.1(a). According to Hooke’s law, the extension u of the spring is related to T by T = ku,
(9.2.1)
where k is the spring constant. In constructing the constitutive equation (1.7.6) for a linear elastic solid, we appealed to Hooke’s law, arguing that each line element in the solid should behave in a manner analogous to a linear spring. For a viscous fluid, the corresponding fundamental element is the dashpot, illustrated in Figure 9.1(b). Dashpots are used, for example, in shock absorbers in motor car suspensions, as well as the mechanisms that prevent doors from slamming. They are mechanical devices designed to offer a resistance proportional to the velocity at which they are extended or compressed. The law corresponding to (9.2.1) for a linear dashpot is T =Y
du , dt
(9.2.2)
where Y is called the impedance of the dashpot. The two simple systems (9.2.1) and (9.2.2) encapsulate the contrast between solid and fluid behaviour, as we now illustrate with a thought experiment. Suppose we apply a time-dependent tension T (t) described by a ramp function, as shown in Figure 9.2. For a spring, the displacement is simply proportional to T , so u will behave in exactly the same way as T . In
9.2 Viscoelasticity
T
(a)
te
u
381
(b)
t
u
(c)
t
t
Fig. 9.2 (a) Applied tension T as a function of time t; te is the characteristic time-scale of the experiment. (b) Resultant displacement of a linear elastic spring. (c) Resultant displacement of a linear dashpot.
particular, a constant tension causes a constant displacement, and u returns to zero when T does so. The dashpot, however, continues to extend as long as a positive tension is applied to it, and a nonzero residual displacement remains after the tension has been released. Heuristically, we might say that the dashpot has no memory of its initial state: the resistance it exerts depends only on its instantaneous velocity, which is a defining characteristic of a viscous fluid. In contrast, the spring, like an elastic solid, has a fixed rest state at u = 0 which it “remembers”, and the tension is nonzero whenever the spring departs from this state. We can now construct model viscoelastic elements by sticking together springs and dashpots, and two obvious possibilities are to connect them in parallel or in series, as shown in Figure 9.1(c) and (d) respectively. In Figure 9.1(c), which illustrates what is known as a Voigt element, we see that the displacements in the spring and the dashpot are equal, by construction, and the tension T is the sum of the tensions in the spring and in the dashpot. We therefore obtain T = T e + Tv ,
where
Te = ku,
Tv = Y
du , dt
(9.2.3)
where the subscripts e and v stand for the elastic and viscous contributions respectively. These are easily combined to give the Voigt constitutive equation Y du du + ku = k tr +u , where tr = , (9.2.4) T =Y dt dt k and tr is known as the relaxation time of the Voigt element. The qualitative behaviour depends crucially on the size of the relaxation time compared with the characteristic time-scale te of any given experiment, and we therefore define a dimensionless parameter, called the Deborah
382
More general theories
u
(a)
u
(b)
t
t
Fig. 9.3 Displacement of a Voigt element due to the applied tension shown in Figure 9.2(a). (a) Small Deborah number; the corresponding response of an elastic spring is shown as a dashed curve. (b) Large Deborah number; the corresponding response of a dashpot is shown as a dashed curve.
number, by De =
tr . te
(9.2.5)
When De is small, the time derivative in (9.2.4) has a small influence, and the element therefore behaves somewhat like an elastic spring. In Figure 9.3(a) we show the response of such an element to the same applied tension as in Figure 9.2(a). Here we see that the displacement lags slightly behind the corresponding elastic displacement (shown as a dashed curve), where the time lag is of order tr . However, when De is large, the time derivative is the dominant term on the right-hand side of (9.2.4), so the Voigt element responds like a dashpot, as shown in Figure 9.3(b). However, if we wait long enough, the displacement will always decay to zero, over a time-scale tr , when the tension is released. The Voigt constitutive relation (9.2.4) therefore describes the basic building block for a damped solid. On the other hand, Figure 9.1(d) illustrates what is known as a Maxwell element, in which the spring and dashpot experience the same tension T and the net displacement is the sum of the elastic and viscous contributions; hence duv . (9.2.6) where T = kue , T = Y u = u e + uv , dt Now differentiation with respect to t leads to the Maxwell constitutive equation d T dT du =Y + T = tr + T, (9.2.7) Y dt dt k dt where tr = Y/k is again the relaxation time. Now, when De 1, the time derivative term is small, so (9.2.7) is approximately that of a dashpot, as shown in Figure 9.4(a). The response when
9.2 Viscoelasticity
u
(a)
u
383
(b)
t
t
Fig. 9.4 Displacement of a Maxwell element due to the applied tension shown in Figure 9.2(a). (a) Small Deborah number; the corresponding response of a dashpot is shown as a dashed curve. (b) Large Deborah number; the corresponding response of an elastic spring is shown as a dashed curve.
the Deborah number is large, shown in Figure 9.4(b), is close to that of an elastic spring except in two crucial respects. First, the element continues to extend slightly, or creep, when the tension is held constant. Second, a nonzero permanent displacement remains when the tension is released. We can therefore think of (9.2.7) as describing an elastic fluid or a fluid with memory. By inspecting Figures 9.3 and 9.4, we can contrast the Voigt and Maxwell constitutive relations as follows. The Voigt element exhibits viscous behaviour over short time-scales and elastic behaviour over long time-scales. An example of such a response is a soft rubber toy which can initially be deformed like a fluid but then slowly recovers its initial shape. The Maxwell element has the opposite response, behaving elastically over short time-scales but flowing over long time-scales. This might describe rock or silly putty, for example. By combining springs and dashpots in other configurations, one can construct systems with ever more complicated responses. However, all such linear systems may be viewed as special cases of the general linear constitutive law t dT t dt , K t − t (9.2.8) u(t) = dt −∞ where K(t), known as the creep function, characterises the viscoelastic response of the system. For example, the Voigt and Maxwell constitutive laws may be cast in the form (9.2.8), with the creep function given by K(t) =
1 − e−t/tr k
respectively (see Exercise 9.1).
and
K(t) =
tr + t , Y
(9.2.9)
384
More general theories
We point out that one-dimensional linear viscoelasticity can be approached by generalising Exercise 1.3 and taking the continuum limit of a series of spring and dashpot elements. Some of the different possibilities are described in Exercise 9.2. 9.2.3 Three-dimensional linear viscoelasticity When constructing the constitutive relationship for a linear elastic medium in Chapter 1, we supposed that each infinitesimal line element in the material obeys a version of Hooke’s law. Now we can incorporate viscoelastic effects by replacing Hooke’s law with a rate-dependent constitutive law such as (9.2.4) or (9.2.7). There is no hard-and-fast rule for doing this: for any given material the choice of constitutive law must be based on its qualitative properties, for example whether it behaves like a fluid or a solid over short and long time-scales, and must then be verified experimentally. The Voigt element Figure 9.1(c), for example, could be generalised to three dimensions as follows. We imagine that the stress tensor τij at each point is provided by an elastic contribution τije and a viscous contribution τijv . We then assume that these satisfy the standard linear elastic and Newtonian constitutive relations, so that τij = τije + τijv ,
τije = λ (ekk ) δij + 2µeij ,
τijv = ξ (Dkk ) δij + 2ηDij , (9.2.10)
where λ and µ are the usual Lam´e constants, while ξ and η are called the dilatational viscosity and shear viscosity respectively. As explained in Section 8.8, the rate-of-strain tensor Dij may be approximated as simply the time derivative of the strain tensor eij provided the displacement gradients are small enough for linear elasticity to be valid. If we make the simplifying assumption that the elastic and viscous components have the same Poisson’s ratio, then we can define a single relaxation time η ξ (9.2.11) tr = = . λ µ Then, by collecting the terms in (9.2.10), we obtain the constitutive relation ∂ (λ (ekk ) δij + 2µeij ) , (9.2.12) τij = 1 + tr ∂t for small displacements of a Voigt solid. Alternatively, we can base a Maxwell model on the idea that the stress at any point gives rise to both an elastic strain eeij and a viscous strain evij .
9.2 Viscoelasticity
385
Again we assume that these are both small enough to be described by linear theory and that the viscous and elastic components have the same Poisson’s ratio to obtain ∂ λ (evkk ) δij + 2µevij . eij = eeij + evij , τij = λ (eekk ) δij + 2µeeij = tr ∂t (9.2.13) Now these are easily combined to give the linear Maxwell model ∂τij ∂ (9.2.14) + τij = tr (λ (ekk ) δij + 2µeij ) . ∂t ∂t Let us illustrate the equations that result from a viscoelastic constitutive relation by returning to the model for compressional waves in a bar. We recall from Section 4.2 that Newton’s second law leads to the equation tr
∂T ∂2u , (9.2.15) = ∂t2 ∂x where ρ and A are the density and cross-sectional area of the bar. To close the model we need to specify a constitutive relation between the tension T and the displacement u. The Voigt model (9.2.12) leads to ∂u ∂2u T = EA + tr , (9.2.16) ∂x ∂x∂t ρA
where E is Young’s modulus, so that (9.2.15) reads 2 ∂2u ∂ u ∂3u ρ 2 =E . + tr 2 ∂t ∂x2 ∂x ∂t
(9.2.17)
The standard wave equation, which is retrieved when tr = 0, conserves energy, so that any initial displacement will give rise to waves that propagate indefinitely. The Voigt model (9.2.17) incorporates the physically important effect of damping, so that all disturbances eventually decay to zero. On the other hand, the tension in a Maxwell material satisfies tr
∂2u ∂T + T = EA , ∂t ∂x∂t
(9.2.18)
so that (9.2.15) leads to
3 ∂3u ∂ u ∂2u ρ tr 3 + 2 = E 2 . ∂t ∂t ∂x ∂t
(9.2.19)
This equation admits steady solutions in which u is an arbitrary function of x, so that any displacement of such a bar can give rise to permanent deformation.
386
More general theories
More generally, we can think of (9.2.12) and (9.2.14) as special cases of the general linear three-dimensional constitutive relation t ∂τk Kijk t − t (9.2.20) eij = x, t dt , ∂t −∞ where the creep function is now in general a fourth-rank tensor. If the material is isotropic, then (9.2.20) may be characterised using just two scalar creep functions L(t) and M (t) by writing t ∂τkk ∂τij x, t δij + M t − t x, t dt . L t−t eij = ∂t ∂t −∞ (9.2.21) In either case, the integral should really be performed with the Lagrangian variable X held fixed, and we must emphasise once more that all these linear theories are only valid for small strains. We can expect them to work well for small displacements of a damped solid or for small creep of an elastic fluid, but for a fluid that undergoes a substantial deformation, a more sophisticated approach is required, as we will now briefly explain.
9.2.4 Large-strain viscoelasticity In viscoelastic fluids, the strains are frequently so large that, as in Chapter 5, we must resort to Lagrangian variables to deal with the geometric nonlinearity. While such materials may undergo large deformations, their compressibility is nearly always small in comparison, and it is therefore usual to model them as incompressible. We therefore introduce a pressure p and a deviatoric stress τ , as in Section 8.4.3, so that Cauchy’s momentum equation takes the form ∂v ρ + (v · ∇) v = −∇p + ∇ · τ + ρg, (9.2.22) ∂t where v is the velocity vector. Since we would not expect a Voigt solid to undergo particularly large displacements, we concentrate on the example of a Maxwell fluid, in which the deformation is decomposed into an elastic component and a viscous component. As described in any book on viscous flow (for example Ockendon & Ockendon, 1995), the constitutive relation for a Newtonian viscous fluid is simply τij = 2ηDij ,
(9.2.23)
where Dij is the rate-of-strain tensor and η is again the shear viscosity.
9.2 Viscoelasticity
387
On the other hand, a neo-Hookean solid, with strain energy density given by (5.3.58a), obeys the constitutive relation τij = µ (Bij − δij ) ,
(9.2.24)
where the Finger strain tensor Bij is defined in (5.2.14). By differentiating the Finger tensor with respect to t, as shown in Exercise 9.4, we find that ∂vj DBij ∂vi = Bkj + Bik , Dt ∂xk ∂xk
(9.2.25)
that is DB = ∇v T B + B∇v, (9.2.26) Dt where D/Dt = ∂/∂t + (v · ∇) is the “usual” convective derivative. The neo-Hookean stress tensor (9.2.24) therefore satisfies the equation
τ = 2µD,
(9.2.27)
denotes the upper convected derivative, defined for an arbitrary where tensor function A by DA − ∇v T A − A∇v. (9.2.28) Dt By combining (9.2.23) and (9.2.27), a viscoelastic fluid whose elastic component is neo-Hookean could be described by
A=
tr τ + τ = 2ηD,
(9.2.29)
which is known as the upper convected Maxwell model. As another example of an elastic constitutive relation, let us consider the Mooney–Rivlin strain energy density (5.3.58b), with c1 = 0, c2 = µ/2, which leads to −1 . τij = µ δij − Bij
(9.2.30)
Again using (9.2.25), we discover that this stress tensor satisfies
τ = 2µD,
(9.2.31)
where the lower convected derivative of a tensor A is defined by
A=
DA + ∇vA + A∇v T . Dt
We obtain the lower convected Maxwell model by using (9.2.28).
(9.2.32)
instead of
in
388
More general theories
Both and are special cases of a one-parameter family of convected derivatives, defined by
A=
DA − ΩA + AΩ − a (DA + AD) , Dt
where Ω is the rotation tensor, that is ∂vj 1 ∂vi . Ωij = − 2 ∂xj ∂xi
(9.2.33)
(9.2.34)
The upper and lower convected derivatives are obtained when a = 1 and when a = −1 respectively, and another common choice is the Jaumann ◦
or corotational derivative A, corresponding to a = 0. In any viscoelastic constitutive relation, a is a material parameter that must be determined from experiments. For any value of a, the derivative defined by (9.2.33) is objective. By this we mean that it is invariant under rigid-body transformations, and crucially this includes unsteady transformations. This means that it is the same for all observers, in contrast with the usual convective derivative DA/Dt. Hence, when we construct a constitutive relation using , we can be sure that the resulting mechanical behaviour will be independent of the frame in which it is measured. Nonetheless, whichever member of (9.2.33) we choose, the resulting large-strain viscoelastic model will couple (9.2.22) with an equally complicated nonlinear evolution equation for τ . Hence analytical progress can usually only be made in the case of small strains, in which case is approximately ∂/∂t. Finally, we must mention that the identification and classification of convective derivatives of tensors is one that arises in many branches of mathematics, and it is interesting that these derivatives have a geometrical interpretation, as shown in Exercise 9.5.
9.3 Thermoelasticity Thermal effects in solids can be dramatic, even if we exclude the possibility of the solid melting into a liquid. For example, the easiest way in which to fracture an ice cube is to put it into even lukewarm water. We note that density variations are already allowed for in the mass- and momentum-conservation equations (1.3.6) and (1.6.5). Hence it only remains for us to incorporate thermal effects in the constitutive equation (1.7.6) and then to include heat in the energy calculation from Section 1.9. We will assume throughout that the displacement gradients are small enough for linear elasticity to be valid.
9.3 Thermoelasticity
389
We begin to construct a linear thermoelastic constitutive relation by considering an unconstrained elastic solid whose absolute temperature is raised from T0 in the reference state to a new temperature T . There is ample experimental evidence that many common materials undergo a uniform isotropic volume change, namely an expansion if T > T0 or a contraction if T < T0 . For moderate temperature variations, the thermal expansion is found to vary linearly with temperature, so that α (9.3.1) eij = (T − T0 )δij , 3 where α is called the coefficient of thermal expansion. By referring to Section 2.2.1, we can interpret α as the relative volume expansion caused by a unit increase in temperature. We are therefore prompted to propose the constitutive relation 2 (9.3.2) τij = 2µeij + λekk δij − λ + µ α(T − T0 )δij . 3 This is the only linear relation between τij , eij and T which reduces to (1.7.6) when T = T0 and to (9.3.1) when τij = 0. In a linear theory, the Lam´e constants are assumed not to vary significantly over the temperature ranges of interest. When we use (9.3.2) in the momentum equation (1.6.5), we find that the Navier equation generalises to ∂2u 2 2 (9.3.3) ρ 2 = ρg + (λ + µ) grad div u + µ∇ u − λ + µ α∇T, ∂t 3 so that the temperature gradient generates an effective body force in the Navier equation. At first glance, it might appear from (9.3.3) that a uniform temperature change, with ∇T = 0, could not drive a displacement. However, whenever boundary conditions are specified on the displacement, the constitutive relation (9.3.2) will lead to nontrivial stress, and vice versa. We illustrate this by returning to the steady uniaxial loading of a bar, considered previously in Section 2.2.3. Here we examine the effect of heating the bar uniformly to some temperature T . If we seek a displacement of the form u = (βx, −γy, −γz)T , then the stress tensor is given by (9.3.2) as β 0 0 2µ τ = 2µ 0 −γ 0 + λ(β − 2γ) − λ + α(T − T0 ) I. 3 0 0 −γ
(9.3.4)
(9.3.5)
390
More general theories
By ensuring that the lateral stress components τyy and τzz are zero, we find that the transverse strain is given by γ=
(3λ + 2µ)α(T − T0 ) 1+ν λβ − = νβ − α(T − T0 ), 2(λ + µ) 6(λ + µ) 3
(9.3.6)
where ν is Poisson’s ratio. The only remaining nonzero stress component is 1 τxx = β − α(T − T0 ) E, (9.3.7) 3 where E is Young’s modulus. We can use this result to calculate the thermal stress in a length of railway track.† If the two ends of the track are fixed, then we must have β = 0, and hence the net compressive force is given by P =
EA α(T − T0 ), 3
(9.3.8)
where A is the cross-sectional area. Note that heating the track will cause a compressive force and cooling a tensile force, as expected. From Section 4.4.3, we know that the track will buckle if the compressive stress is too large, and (9.3.8) tells us that the maximum temperature that can be sustained before buckling occurs is T − T0 =
3π 2 I , AL2 α
(9.3.9)
where I is the moment of inertia of the cross-section. In general, we cannot assume that temperature is known, but must determine it as part of the solution. We now obtain an equation for T by performing an energy balance. The net energy U in a control volume V is given by
2 1 ∂u U= ρ + W + ρcT dx, (9.3.10) 2 ∂t V where, referring to Section 1.9, we recognise the first two terms in the integrand as the kinetic energy and the strain energy. The final term is the thermal energy, with c denoting the specific heat capacity,‡ a material parameter which we will assume to be constant. As in Section 8.7 and Exercise 8.12, the first law of thermodynamics tells us that all three forms of energy are †
‡
In the days before “continuously-welded” rails, gaps had to be left between sections of track to allow for thermal expansion to take place without stress generation. These gaps caused track and wheels to wear and led to many accidents. As usual, this should be defined “at constant volume”
9.4 Composite materials and homogenisation
391
equivalent and mutually convertible. However, in contrast with Section 8.7, our solid now has a strain energy density W such that τij = ∂W/∂eij . The energy inside V will change due to the work done by gravity, the work done by stress on the boundary ∂V , and the flux of heat through ∂V . Collecting these effects together, we arrive at the energy conservation equation dU ∂u ∂u = dx + da − ρg · (τ n) · q · n da, (9.3.11) dt ∂t ∂t V ∂V ∂V where n is the unit normal to ∂V and q is the heat flux. Now we have to substitute (9.3.10) into (9.3.11) and simplify the resulting expression. As shown in Exercise 9.7, for sufficiently small temperature variations, this leads to ∂T ρc + div q = 0, (9.3.12) ∂t which is the standard equation for heat flow in a rigid sample. In other words, there is no leading-order coupling between thermal expansion and heat flow: we can solve (9.3.12) for T and then substitute the result into (9.3.3) to determine the resulting displacement. For most materials, the heat flux is given by Fourier’s law, namely q = −k∇T where k is the thermal conductivity. Provided k is constant, (9.3.12) just becomes the linear heat equation ∂T = κ∇2 T, (9.3.13) ∂t where κ = k/ρc is called the thermal diffusivity. We note in passing that the situation is much more complicated when thermal radiation is significant, as often happens in semi-transparent materials such as glass. 9.4 Composite materials and homogenisation 9.4.1 One-dimensional homogenisation Many practically important materials have properties which vary over a very fine scale, for example composites consisting of alternating layers with two different properties. To describe deformations of such a material, it is usually impractical to analyse each individual layer. In this section, we briefly outline a homogenisation technique that allows us to average over the fine scale and hence determine effective mechanical properties for largescale deformations of the material as a whole. The word homogenisation is often used synonymously with “multi-scaling” or “coarse-graining”. We will only consider configurations where the short scale greatly exceeds molecular length-scales.
392
More general theories
E E1
(a)
u
(b)
E2 x
x
Fig. 9.5 (a) The variation of Young’s modulus with position in a bar. (b) The corresponding longitudinal displacement u(x); the approximation (9.4.6) is shown as a dashed line.
Our first example concerns longitudinal displacement of an elastic bar, with uniform cross-sectional area A and length L, whose Young’s modulus E is a rapidly varying function of position x. We recall from Section 4.2 that the displacement u(x) in such a bar satisfies AE(x)
du = T, dx
(9.4.1)
where the tension T is constant under static conditions. To fix ideas, we focus for the moment on a composite bar consisting of 2N alternating sections with moduli E1 and E2 , so that nL/N < x < (n + φ)L/N, E1 , (9.4.2) E(x) = (n + φ)L/N < x < (n + 1)L/N, E2 , where n = 0, 1, . . . , N − 1 and φ is the volume case, it is easy to solve (9.4.1) and find (1 − φ)nL 1 x 1 + − , N E2 E1 T E1 u(x) = A φ(n + 1)L 1 1 x , + − E2 N E1 E2
fraction of phase 1. In this
(n + φ)L nL <x< , N N
(n + 1)L (n + φ)L <x< . N N (9.4.3) In Figure 9.5, we plot a typical piecewise constant Young’s modulus profile and the corresponding displacement u(x). We can see that u(x) fluctuates rapidly in response to the variations in E. However, on the scale of the whole bar, these fluctuations are barely noticeable, and the displacement appears to be approximately linear in x. Indeed, from the exact solution (9.4.3), we
9.4 Composite materials and homogenisation
393
can see that u(x) satisfies the condition
φ (1 − φ) TL + u(x + L/n) − u(x) = N A E1 E2 TL (1/E), = NA
where N (1/E) = L
L/N
0
dx E(x)
(9.4.4)
(9.4.5)
is the average of 1/E over a periodic cell. From (9.4.4) we deduce that u(x) − (T x/A)(1/E) is periodic over the fine scale and hence, on a scale large enough for these periodic fluctuations to be negligible, Tx (1/E) + const.. (9.4.6) u(x) ∼ A In Figure 9.5 it is clear that (9.4.6) approximates the overall behaviour of the full solution (9.4.4) very well. We can rewrite (9.4.6) as AEeff
du ∼ T, dx
(9.4.7)
where the effective Young’s modulus of the composite bar is the harmonic average of E, that is 1 . (9.4.8) Eeff = (1/E) This illustrates what the point of homogenisation theory is. When we consider the bar as a whole, the complicated fine-scale variations in E become irrelevant, and the bar behaves like a uniform medium whose modulus is given by (9.4.8). Now we show how a formal asymptotic method, known as the method of multiple scales (see Kevorkian & Cole, 1981), may be used to reach the same conclusions in more general configurations. These techniques come into their own in more complicated problems where explicit solutions like (9.4.3) do not exist. As always, before attempting any asymptotic analysis, it is necessary to non-dimensionalise the problem. Here, we scale x with the bar length L, E with a typical value E1 and u with T L/E1 A to obtain E
du = 1. dx
(9.4.9)
Now x lies between 0 and 1, but E varies over a much smaller length-scale,
394
More general theories
of order ε, say. We therefore write E in the form E = E (x, ξ) ,
(9.4.10)
where ξ = x/ε and E is assumed to be periodic, with period one, with respect to its second argument. In our example (9.4.2), ε = 1/N and E depends only on the fine scale ξ. Here we allow E also to vary on the scale of the whole bar, for example if we had allowed E1 and E2 in (9.4.2) to vary slowly with x. With E given by (9.4.10), we must now take u to be a function of the two length-scales x and ξ; this means that we have moved from a model that is one-dimensional in the variable x to one that is two-dimensional in the plane (x, ξ). However, physical space is just the line x = εξ in the (x, ξ) plane, and on this line the chain rule implies that ∂u 1 ∂u du = + . dx ∂x ε ∂ξ Hence (9.4.9) becomes
E(x, ξ)
∂u ∂u +ε ∂ξ ∂x
(9.4.11)
= ε.
(9.4.12)
To obtain a unique representation of u in terms of x and ξ, we insist that u, like E, must be periodic with respect to ξ.† Now we take the limit ε → 0 and seek the solution as an asymptotic expansion of the form u ∼ u0 + εu1 + · · · . When we equate terms of O (1), we discover that ∂u0 = 0, (9.4.13) ∂ξ so that u0 is a function of x alone, and then, at order ε, du0 ∂u1 + = 1. E(x, ξ) ∂ξ dx
(9.4.14)
The assumed periodicity of u with respect to ξ leads to the condition Eeff (x) where
/
1
Eeff (x) = 1 0 †
du0 = 1, dx dξ E(x, ξ)
(9.4.15)
=
1 (1/E)
.
(9.4.16)
This is a very convenient assumption but, as discussed in Kevorkian & Cole (1981), it is not necessary for more general problems in which the micro-geometry is not known in advance, and can be replaced by the condition that u not grow as |ξ| → ∞.
9.4 Composite materials and homogenisation
E E1
(a)
u
395
(b)
E2 x
x
Fig. 9.6 (a) The variation of Young’s modulus with position in a bar with ε = 1/5; the effective Young’s modulus is shown as a dashed curve. (b) The corresponding longitudinal displacement u(x); the leading-order approximation, given by (9.4.15), is shown as a dashed curve.
This is equivalent to (9.4.8) when E depends on ξ alone, but (9.4.16) allows for E also to vary slowly with x. To illustrate this result, let us return to the piecewise constant example (9.4.2), but now allow E1 and E2 to be functions of x. In terms of dimensionless variables, we can therefore write E as a periodic function of ξ given by E1 (x), 0 < ξ < φ, (9.4.17) E(x, ξ) = E2 (x), φ < ξ < 1. We show a typical example in Figure 9.6(a), along with the effective modulus −1 1 E1 (x)E2 (x) dξ , (9.4.18) = Eeff (x) = E(x, ξ) (1 − φ)E 1 (x) + φE2 (x) 0 which averages out the fine scale variations. We see in Figure 9.6(b) that the displacement calculated using Eeff (x) (dashed curve) provides an excellent approximation to the exact solution (solid curve), even though ε = 1/5 is not particularly small.
9.4.2 Two-dimensional homogenisation Let us now consider a less trivial application of this method, namely antiplane strain in a bar whose shear modulus µ varies over the cross-section. It is straightforward, following the ideas of Section 2.3, to see that, in suitable dimensionless variables, the axial displacement w(x, y) satisfies ∇ · (µ∇w) = 0.
(9.4.19)
396
More general theories
b µ1 η
µ2
ξ
1
Fig. 9.7 A periodic microstructured shear modulus.
We suppose that µ varies both rapidly over a short length-scale ε and gradually across the whole cross-section, so that we can write µ = µ(x, y, ξ, η),
(9.4.20)
where (ξ, η) = (x, y)/ε. We also assume that µ is periodic in both directions over the fine scale, so that µ(x, y, ξ + 1, η) ≡ µ(x, y, ξ, η),
µ(x, y, ξ, η + b) ≡ µ(x, y, ξ, η).
(9.4.21)
We choose ε such that the period in ξ is equal to 1, and then define b to be the period in the η-direction. A typical setup is illustrated in Figure 9.7, where the modulus µ is piecewise constant on the fine scale, although µ1 (x, y) and µ2 (x, y) might vary over the long scale. Now, as in Section 9.4.1, we allow the displacement field w(x, y, ξ, η) to vary over both length-scales, provided it shares the same periodicity (9.4.21) as µ. The chain rule thus transforms (9.4.19) into ∇ξ · (µ∇ξ w) + ε {∇ξ · (µ∇xw) + ∇x · (µ∇ξ w)} + ε2 ∇x · (µ∇xw) = 0, (9.4.22) where ∇x = (∂/∂x, ∂/∂y)T , ∇ξ = (∂/∂ξ, ∂/∂η)T . The assumed periodicity means that we need only solve (9.4.22) on a single rectangular cell [0, 1]×[0, b]
9.4 Composite materials and homogenisation
397
and then apply the periodic boundary conditions w(x, y, 1, η) ≡ w(x, y, 0, η), ∂w ∂w (x, y, 1, η) ≡ (x, y, 0, η), ∂ξ ∂ξ
w(x, y, ξ, b) ≡ w(x, y, ξ, 0), (9.4.23a) ∂w ∂w (x, y, ξ, b) ≡ (x, y, ξ, 0). (9.4.23b) ∂η ∂η
When we again seek the solution as an asymptotic expansion of the form w ∼ w0 + εw1 + ε2 w2 + · · · ,
(9.4.24)
we immediately discover that w0 satisfies ∇ξ · (µ∇ξ w0 ) = 0.
(9.4.25)
This equation and the boundary conditions (9.4.23) are identically satisfied if w0 is independent of ξ and η, so that w0 = w0 (x, y), and it may be shown (see Exercise 9.10) that this is the only solution. As we might have hoped, the displacement therefore does not vary on the fine length-scale to leading order. Comparing the terms at O (ε), we obtain ∂w1 ∂ ∂w1 ∂µ ∂w0 ∂µ ∂w0 ∂ µ + µ =− − = R1 (x, y, ξ, η), say, ∂ξ ∂ξ ∂η ∂η ∂ξ ∂x ∂η ∂y (9.4.26) which is a linear elliptic partial differential equation for w1 driven by ∇xw0 . As shown in Exercise 9.10, equation (9.4.26) admits periodic solutions for w1 only if the right-hand side has zero mean, so that 1 b R1 (x, y, ξ, η) dξdη = 0. (9.4.27) 0
0
This requirement is satisfied identically here, and we can write the solution in the form ∂w0 ∂w0 w1 = W (1) (x, y, ξ, η) + W (2) (x, y, ξ, η) , (9.4.28) ∂x ∂y where W (1) and W (2) satisfy the equations ∂W (1) ∂ ∂W (1) ∂µ ∂ µ + µ =− ∂ξ ∂ξ ∂η ∂η ∂ξ and ∂ ∂ξ
∂W (2) µ ∂ξ
∂ + ∂η
with the periodic conditions (9.4.23).
∂W (2) µ ∂η
=−
∂µ , ∂η
(9.4.29)
(9.4.30)
398
More general theories
It can be shown that (9.4.29) and (9.4.30) have unique periodic solutions for W (1) and W (2) , up to arbitrary additive functions of (x, y). Although it is usually not possible to obtain these solutions in closed form, it is straightforward in principle to compute them numerically for any given modulus function µ(x, y, ξ, η). Finally, proceeding to the terms of O ε2 in (9.4.22), we find that w2 satisfies an equation analogous to (9.4.26), but with the right-hand side replaced by ∂ ∂w1 ∂ ∂w1 µ + µ R2 (x, y, ξ, η) = − ∂ξ ∂x ∂η ∂y ∂w1 ∂ ∂w1 ∂ µ + µ − ∂x ∂ξ ∂y ∂η ∂w0 ∂ ∂w0 ∂ µ + µ , (9.4.31) − ∂x ∂x ∂y ∂y and again we need this to have zero mean over our periodic cell in (ξ, η). The first term satisfies this requirement identically, and, when we substitute for w1 from (9.4.28), we find that 1 b 0= R2 (x, y, ξ, η) dξdη 0 0 - . 1 b ∂w0 ∂W (2) ∂w0 ∂W (1) ∂ µ +1 +µ =− ∂x ∂ξ ∂x ∂ξ ∂y 0 0 .
∂W (1) ∂w0 ∂W (1) ∂w0 ∂ µ +µ +1 dξdη. (9.4.32) + ∂y ∂η ∂x ∂η ∂y Thus our homogenised displacement w0 (x, y) satisfies the anisotropic model ∂ ∂ ∂ ∂w0 ∂w0 ∂w0 ∂w0 ∂ + + + = 0, µ11 µ12 µ21 µ22 ∂x ∂x ∂x ∂y ∂y ∂x ∂y ∂y (9.4.33) where b 1 b 1 ∂W (1) ∂W (1) dξdη, dξdη, µ11 = µ 1+ µ21 = µ ∂ξ ∂η 0 0 0 0 b µ22 =
1
µ 1+
0
0
∂W (2) ∂η
b dξdη,
µ12 =
(9.4.34a) 1
µ 0
0
∂W (2) dξdη. ∂ξ (9.4.34b)
9.4 Composite materials and homogenisation
399
Thankfully, (9.4.33) can be shown to be elliptic. Equally reassuringly, when µ is independent of ξ, we can take W (1) = 0 and ∂W (2) /∂ξ = 0, so that b ∂W (2) = b − 1. ∂η dη µ 0 µ Hence the effective moduli are given by b µ11 = µdη, µ21 = µ12 = 0, 0
(9.4.35)
/
b
2
µ22 = b
0
dη , µ
(9.4.36)
which is a generalisation of (9.4.16). For truly two-dimensional geometries, it is almost never possible to evaluate the effective moduli explicitly. One famous example where significant progress can be made occurs when the shear modulus µ is piecewise constant, taking one value µ2 on some region D2 inside our rectangular cell, and another value µ1 in the complementary region D1 = [0, 1] × [0, b] \ D2 . When we make the substitutions φ(1) = W (1) + ξ,
φ(2) = W (2) + η,
(9.4.37)
the equations (9.4.29) and (9.4.30) for W (1) and W (2) are transformed to (9.4.38) ∇ξ · µ∇ξ φ(1) = ∇ξ · µ∇ξ φ(2) = 0, where
µ=
µ1 , (ξ, η) ∈ D1 , µ2 , (ξ, η) ∈ D2 .
(9.4.39)
Hence φ(1) and φ(2) both satisfy Laplace’s equation in each of D1 and D2 , along with the continuity conditions . ( ' ∂φ(j) (j) =0 (9.4.40) = µ φ ∂n on the boundary ∂D2 between them. Crucially, we now assume that the geometry possesses reflectional symmetry in both the ξ- and the η-direction. Using this symmetry and the periodicity of W (j) , we deduce that φ(j) must satisfy the boundary conditions φ(1) (0, η) = 0,
φ(1) (1, η) = 1,
φ(2) (ξ, 0) = 0,
φ(2) (ξ, b) = b,
as illustrated in Figure 9.8(a).
∂φ(1) (ξ, 0) = ∂η ∂φ(2) (0, η) = ∂ξ
∂φ(1) (ξ, b) = 0, ∂η ∂φ(2) (1, η) = 0, ∂ξ
(9.4.41a) (9.4.41b)
400
More general theories η
(a) ∂φ(1) =0 ∂η
η φ(2) =b
(b) ∂ψ (2) =0 ψ (1) =β ∂η
b (1)
φ
=0
D1
φ(1) =1
ψ (2) =0
ψ (2) =α
D2 ∂φ(2) =0 ∂ξ
∂φ(2) =0 ∂ξ ξ
µ2 µ1
∂D2
∂φ(1) =0 ∂η
φ(2) =0 1
∂ψ (1) =0 ∂ξ ∂ψ (2) =0 ∂η
ψ (1) =0 1
∂ψ (1) =0 ∂ξ ξ
Fig. 9.8 A symmetric, piecewise constant shear modulus distribution; the symmetry axes are shown as dot-dashed lines. (a) The boundary conditions satisfied by φ(1) and φ(2) . (b) The corresponding boundary conditions for the harmonic conjugate functions ψ (1) and ψ (2) .
Now, since φ(j) satisfy Laplace’s equation in each separate region, we can introduce the harmonic conjugates ψ (j) which satisfy the Cauchy–Riemann equations ∂ψ (j) ∂φ(j) = , ∂ξ ∂η
∂φ(j) ∂ψ (j) =− . ∂η ∂ξ
(9.4.42)
The continuity conditions (9.4.40) for φ(j) are transformed to ' µψ
(j)
(
-
∂ψ (j) = ∂n
. = 0,
(9.4.43)
# $ where again denotes the jump across ∂D2 . The boundary conditions (9.4.41) become ψ (1) (ξ, 0) = 0,
ψ (1) (ξ, b) = β,
ψ (2) (0, η) = 0, ψ (2) (1, η) = α,
∂ψ (1) ∂ψ (1) (0, η) = (1, η) = 0, (9.4.44a) ∂ξ ∂ξ ∂ψ (2) ∂ψ (2) (ξ, 0) = (ξ, b) = 0, (9.4.44b) ∂η ∂η
as shown in Figure 9.8(b), where the constants α and β are unknown in advance. It is straightforward to calculate the effective elastic constants using ψ (j) , because the continuity conditions (9.4.43) allow us to integrate directly
9.4 Composite materials and homogenisation
401
across the cell. For example, b µ11 =
0
0
1
∂φ(1) dξdη = µ ∂ξ
b
1
∂ψ (1) dξdη ∂η 1' (η=b (1) µψ dξ = µ1 β, (9.4.45) = µ
0
0
η=0
0
and analogous calculations yield µ22 = −µ1 bα,
µ21 = µ12 = 0,
(9.4.46)
so the assumed symmetry of the geometry eliminates the off-diagonal terms. Now the key observation is that the problem satisfied by ψ (2) closely resembles that for φ(1) (and vice versa). Indeed, if we define µ2 ψ (2) φ%(1) = , αµ1
(9.4.47)
then the boundary conditions for φ%(1) are identical to (9.4.41a), although the continuity conditions on ∂D2 read %(1) %(1) ∂ φ ∂ φ (1) (1) µ2 (9.4.48) φ% = φ% , = µ1 . ∂n ∂n D1 D2 D1
D2
Hence φ%(1) is what φ(1) would be if we switched the values of µ1 and µ2 . We can use the same technique as above to calculate the corresponding elastic constants, noting that the harmonic conjugate of φ%(1) is (2)
so that
µ2 φ , ψ%(1) = − αµ1
(9.4.49)
' (η=b µ2 b . =− µ %11 = µ2 ψ%(1) α η=0
(9.4.50)
Eliminating α between (9.4.46) and (9.4.50), we obtain the intriguing relation µ %11 µ22 = b2 µ1 µ2
(9.4.51)
between the stiffness µ22 in the η-direction and the corresponding stiffness µ %11 in the ξ-direction with µ1 and µ2 switched. This has particularly startling implications if b = 1 and the geometry is anti-symmetric about a diagonal in the resulting square cell, as in the examples shown in Figure 9.9. In such configurations, swapping µ1 and µ2 is equivalent to swapping ξ and η, so
402
More general theories
Fig. 9.9 Some modulus distributions that are antisymmetric about the diagonals of a square.
that µ %11 ≡ µ22 . Hence a homogenised bar consisting of such cells is isotropic with √ µ11 = µ22 = µ1 µ2 . (9.4.52) Such results provide an invaluable check on the numerical methods to which one usually has to resort to calculate the effective elastic constants.
9.4.3 Three-dimensional homogenisation Now that we have the ideas of Section 9.4.2 at our disposal, we can derive the homogenised equations for a three-dimensional elastic matrix quite quickly starting from the equilibrium macroscopic model ∇ · τ = 0,
τij = Cijk ek = Cijk
∂uk , ∂x
(9.4.53)
where C(x) is a symmetric tensor incorporating the elastic constants. As in Section 1.7, for an isotropic material C is given by Cijk (x) = λ(x)δij δk + 2µ(x)δik δj ,
(9.4.54)
but it is more convenient here to persist for the moment with the more general case (9.4.53), which we can write symbolically as a tensor product: τ = C∇u.
(9.4.55)
We note that it is straightforward to incorporate a body force in (9.4.53), but unsteady effects can cause significant complications, depending crucially on the ratio of the elastic wave-length to the length-scale of the microstructure, as we will describe below. As in Section 9.4.2, we suppose that the elastic constants in C vary over two length-scales: a macroscopic scale and a micro-scale which is smaller by a factor of ε. In suitable dimensionless variables, we can therefore write C = C(x, ξ), where ξ = x/ε, and similarly for u and τ . We again assume
9.4 Composite materials and homogenisation
403
that C, u and τ are all periodic on some representative cell D, for example a cuboid, in ξ-space. The advantage of working with the first-order system (9.4.53), rather than the Navier equations, is that when we expand u ∼ u0 (x, ξ) + εu1 (x, ξ) + · · · , τ ∼ τ0 (x, ξ) + ετ1 (x, ξ) + · · · , (9.4.56) we only need to consider terms up to O (ε), in contrast with Section 9.4.2 where we had to proceed to O ε2 . At leading order, we soon find that ∇ξ · τ0 = 0,
(9.4.57)
C∇ξ u0 = 0,
(9.4.58)
the second of which implies that u0 is a rigid body motion as a function of ξ, and our assumed periodicity implies that u0 = u0 (x),
(9.4.59)
as in (9.4.25). At order ε, we obtain the equations ∇ξ · τ1 + ∇x · τ0 = 0, τ0 = C∇ξ u1 + C∇xu0 .
(9.4.60) (9.4.61)
If we operate with ∇ξ on (9.4.61) then, by virtue of (9.4.57), we obtain a linear problem for u1 , namely ∇ξ · (C∇ξ u1 ) = − (∇ξ · C) (∇xu0 ) ,
(9.4.62)
which is driven by a term proportional to ∇xu0 . Hence, as in (9.4.28), we can formally write u1 in the form u1 = A(x, ξ)∇xu0 ,
(9.4.63)
where A = (Aijk ) is rank-three tensor which in principle is determined by solving (9.4.62); usually this will have to be done numerically. Backsubstitution into (9.4.61), as demonstrated in Exercise 9.12, gives that τ0 (x, ξ) is related to u0 by τ0 = (C∇ξ A) ∇xu0 + C∇xu0 .
(9.4.64)
As always, the final step is to demand that τ be periodic on our unit cell D. This means that ∇ξ · τ1 dξ ≡ 0, (9.4.65) D
404
More general theories
and we therefore deduce from (9.4.60) that ∇x · τ 0 = 0,
(9.4.66)
where τ 0 again denotes the average of τ0 over D. Hence, on the macroscopic scale, the leading-order displacement u0 satisfies the homogenised equation ∇x · (Ceff ∇xu0 ) = 0,
where
Ceff (x) = (C∇ξ A + C).
(9.4.67)
We remark again that the effective elastic constants can rarely be evaluated explicitly, although, for any given microstructure, they can in principle be calculated numerically over a representative unit cell. Another crucial observation is that, even if the matrix is constructed from isotropic material, so that C is given by (9.4.54), the averaging will in general lead to an anisotropic macroscopic constitutive law. Of course, most natural heterogeneous media do not have a regular periodic microstructure. For such materials, we must view D as a representative cell that is characteristic of the medium as a whole. Unless the microstructure has a particular directionality, we might expect a random geometry to lead to isotropic macroscopic behaviour. 9.4.4 Waves in periodic media We conclude this section with a short discussion of waves in composite media. Unfortunately, the multiple reflections, refractions and diffractions that can occur make the theory much more complicated than in the static cases considered above. However, it is very similar to the theory of electromagnetic wave propagation through lattices, which underpins much of solid state physics, so we will illustrate the basic ideas by considering one-dimensional motion of an elastic bar. The generalisation of (4.2.4) to an inhomogeneous bar is ∂u ∂2u ∂ E(x) =ρ 2. (9.4.68) ∂x ∂x ∂t When we seek solutions in the frequency domain and non-dimensionalise as in (9.4.10), we obtain the ordinary differential equation du k2 d E(x, x/ε) + 2 u = 0, (9.4.69) dx dx ε where
) k = ωεL
εL ρ , = E1 Λ
(9.4.70)
and Λ represents the typical wave-length of elastic waves in the bar.
9.4 Composite materials and homogenisation
405
The character of the problem depends crucially on the size of k. If the wave-length is the same order as the length of the bar, then k = O (ε) and (9.4.69) may easily be analysed using the same approach as in Section 9.4.1 (see Exercise 9.13). Here we focus on the much more interesting case where the wave-length is comparable to the microstructure of the medium, so that k = O (1). For simplicity, we neglect the dependence on the slow lengthscale, so that E is a function only of ξ = x/ε, and (9.4.69) takes the form du d (9.4.71) E(ξ) + k 2 u = 0. dξ dξ We assume as before that E is periodic so that E(ξ + 1) ≡ E(ξ). However, in contrast with Section 9.4.1, u will in general be a nontrivial function of ξ that does not share the same periodicity. One possible approach to the differential equation (9.4.71) is to use Floquet theory, as follows. Let u1 (ξ) and u2 (ξ) be independent solutions of (9.4.71), for example satisfying the initial conditions u1 (0) = 1,
du1 (x, 0) = 0, dξ
u2 (x, 0) = 0,
du2 (0) = 1. dξ
(9.4.72)
Using the standard theory of linear ordinary differential equations (see, for example, Boyce & DiPrima, 2004, Chapter 3), we easily find that the Wronskian du2 du1 − u2 (9.4.73) W = u1 dξ dξ satisfies E(ξ)W (ξ) ≡ const. = 1,
(9.4.74)
if we choose our scaling for E such that E(0) = 1. We can write any other solution of (9.4.71) in terms of u1 and u2 as u(ξ) = Au1 (ξ) + Bu2 (ξ),
(9.4.75)
where A and B are arbitrary constants. The first key observation is that u(ξ + 1) also satisfies (9.4.71), and hence u1 (ξ + 1) = Au1 (ξ) + Bu2 (ξ),
(9.4.76)
u2 (ξ + 1) = Cu1 (ξ) + Du2 (ξ),
(9.4.77)
where A = u1 (1),
B=
du1 (1), dξ
C = u2 (1),
D=
du2 (1). dξ
(9.4.78)
406
More general theories
These coefficients form the elements of the monodromy matrix A C M= , B D
(9.4.79)
and we deduce from (9.4.74) that det(M ) = 1. Now we look for the possibility of waves by seeking solutions u(ξ) such that u(ξ + 1) ≡ ru(ξ), where r is constant. It is easy to see that this can only happen if r is one of the eigenvalues r1 , r2 of M . Hence we can write the general solution of (9.4.71) as a linear combination of eλ1 ξ P1 (ξ) and eλ2 ξ P2 (ξ), where λ1,2 = log r1,2 and P1,2 (ξ) have period 1. Moreover, since r1 r2 = det(M ) = 1, the exponents λ1 and λ2 are either purely real, purely imaginary, or of the form iπ ± log |r|. Whenever λ1,2 have nonzero real part, then u(ξ) grows exponentially as |ξ| → ∞. The effect of the microscale is thus much more dramatic than in the static solutions considered in Section 9.4.1. Instead of simply altering the “effective” wave-speed, it may prevent waves from propagating through the medium altogether. The eigenvalues of M are given by 1 (9.4.80) T ± T2 − 4 , r1,2 = 2 where T = Tr(M ) = u1 (1) +
du2 (1). dξ
(9.4.81)
Given the periodic function E(ξ), we can compute T (k) for each value of k by solving (9.4.71) and (9.4.72) numerically. If |T (k)| < 2 then the roots (9.4.80) are complex with unit magnitude, and hence λ1,2 are pure imaginary. We infer that waves can propagate, although they will not in general be periodic, and the corresponding values of k are called the pass bands. The stop bands, in which waves cannot be supported, occur where |T (k)| > 2. In Figure 9.10 we show the pass and stop bands when the Young’s modulus takes the form E(ξ) = 1 + δ sin(2πξ).
(9.4.82)
The shaded region is the stop band in which |T | > 2. The parameter δ measures the non-uniformity in E: when δ = 0, we have E ≡ 1 and all waves are transmitted through the medium without attenuation. When δ slightly exceeds zero, a narrow stop band appears near k = π, and grows as δ increases. We can confirm this behaviour by analysing the problem asymptotically in the limit δ → 0. As indicated by Figure 9.10, we expect the stop band to
9.4 Composite materials and homogenisation
407
k/π
δ Fig. 9.10 Dimensionless wave-number k versus non-uniformity parameter δ when the Young’s modulus is given by (9.4.82). The stop band is shaded and the asymptotic approximation (9.4.88) is shown using dashed lines.
be in a neighbourhood of k = π, and we therefore let k = π + δk1 so that (9.4.71) takes the form du d + (π + δk1 )2 u = 0. (9.4.83) 1 + δ sin(2πξ) dξ dξ Now we can write u1 (ξ, δ) and u2 (ξ, δ) as asymptotic expansions in powers of δ and thus obtain the leading-order behaviour of T as δ → 0. Unfortunately, this involves considerable tedious algebraic manipulation, which is obviated by the method of multiple scales. As in Section 9.4.1, we seek a solution of (9.4.83) in the form u(ξ, δ) ∼ u(0) (x, ξ) + δu(1) (x, ξ) + · · · ,
(9.4.84)
where x = δξ. At leading order in δ, we find the equation ∂ 2 u(0) + π 2 u(0) = 0, ∂ξ 2
(9.4.85)
u(0) (x, ξ) = A(x) cos(πξ) + B(x) sin(πξ).
(9.4.86)
whose general solution is
As usual, we must proceed to O (δ) to obtain equations for the amplitude
408
More general theories
functions A and B, and we discover that u(1) satisfies the equation 3π 2 3π 2 ∂ 2 u(1) + π 2 u(1) = − B cos(3πξ) + A sin(3πξ) 2 ∂ξ 2 2 π dB + k1 A + B cos(πξ) − 2π dx 4 dA π − A − k1 B sin(πξ). + 2π dx 4
(9.4.87)
The appearance of sin(πξ) and cos(πξ) on the right-hand side of (9.4.87) will give rise to secular terms, proportional to ξ sin(πξ) and ξ cos(πξ), in u(1) . To ensure that u(1) remains bounded as |ξ| → ∞, we must therefore insist that the coefficients in braces be zero. This gives us two coupled linear differential equations for A(x) and B(x), whose solutions are either exponential or sinusoidal, depending on the value of k1 . The stop band, in which A and B are exponential, occurs when |k1 | < π/4, that is when k − 1 < δ . (9.4.88) 4 π In Figure 9.10, we show that this successfully predicts the behaviour of the stop band near δ = 0. Alas, the generalisation of Floquet theory to describe wave propagation through a periodic medium in higher dimensions poses significant additional mathematical difficulties. Nevertheless, the same basic idea applies, namely that the ability of the medium to transmit a given wave can be characterised by analysing a single representative cell, known as a Brillouin zone in the reciprocal lattice (see Brillouin, 2003).
9.5 Poroelasticity The theory of Section 9.4.3 may be applied, for example, to a solid that takes the form of a homogeneous elastic matrix in which are embedded many small-scale voids or pores. For such a material, the elastic constants Cijk would be constant in the elastic matrix and zero in the voids. The situation is much more interesting, though, when the pores are sufficiently connected for a viscous fluid to pass through them, as in a liquid-filled sponge, for example. Other important deformable porous media include oil reservoirs and biological tissue. In principle, one could follow a homogenisation procedure to derive an averaged macroscopic model governing the deformation of such a medium. However, the need to couple the Navier equations for the solid
9.5 Poroelasticity
409
matrix to the Navier–Stokes equations for the fluid makes this task considerably more complicated than any of the examples encountered in Section 9.4, so we will bypass most of the difficulties associated with the fluid dynamics. We know from (9.4.67) that we can express the elastic contribution to the stress in the form τe = Ceff ∇u,
(9.5.1)
where u is the displacement of the medium and Ceff is the matrix of effective elastic constants. If the medium is isotropic, then we can write τe = λeff (∇ · u) I + µeff ∇u + ∇uT , (9.5.2) although the effective elastic constants λeff and µeff will be quite different from the Lam´e constants of the solid material from which the matrix is constructed. A detailed analysis of the fluid dynamics would require us to consider the shear and normal stresses set up in the fluid as it moves through the complicated pore structure. In order to avoid this complication, we will assume the well-substantiated Terzaghi principle (see, for example, Fowler, 1997, p. 107) that, on a scale of many pore sizes, the stress in the fluid averages to an isotropic pore pressure P . The net stress in the medium is thus given by τ = −P I + τe
(9.5.3)
and the equilibrium Navier equation reads (λeff + µeff ) grad div u + µeff ∇2 u = ∇P.
(9.5.4)
We therefore have a situation similar to thermoelasticity, with the pore pressure playing the rˆ ole of the temperature. The pressure gradient term in (9.5.4) represents the drag exerted by the fluid on the solid matrix. The average velocity v at which the fluid flows through the pores is governed by Darcy’s law. This is the physically plausible statement that the difference between the fluid and solid velocities should be proportional to the pressure gradient. In the context of linear elasticity, we can approximate the velocity of the solid matrix as the Eulerian time derivative of the displacement, so that Darcy’s law reads v=
∂u k − ∇P, ∂t η
(9.5.5)
where η is the viscosity of the fluid and k is known as the permeability of the medium. This law is confirmed by experiments, and the permeability
410
More general theories
is empirically well characterised for many important porous media. It has the dimensions of (length)2 and is of order d2 , where d is a typical pore radius. It is also possible to derive (9.5.5) from the underlying Navier–Stokes equations via a homogenisation procedure analogous to that used in Section 9.4.3. For an anisotropic medium, k must be replaced by a positive definite permeability tensor. To close the problem, we must consider conservation of mass. Each representative cell of the fluid will contain a volume fraction α, say, of fluid, and the corresponding solid fraction is therefore 1 − α. We can thus use the approach of Section 2.2.1 and the result of Exercise 9.15 to calculate the relative volume change due to a displacement u and hence obtain α = α0 + (1 − α0 )∇ · u.
(9.5.6)
On the other hand, conservation of mass for the fluid leads to the equation ∂α + α0 ∇ · v = 0. (9.5.7) ∂t By combining these two equations, we find that, as also shown in Exercise 9.15, 1 − α0 ∂ (∇ · u) , (9.5.8) ∇·v =− α0 ∂t which shows how compression of the matrix forces the fluid to flow. For simplicity, we have neglected the compressibility of the solid and fluid phases. We emphasise, though, that the matrix as a whole certainly will be compressible; for example, it is quite possible to compress a sponge made out of incompressible rubber. We have also assumed that α is always close to its initial value α0 , which is consistent with our assumption that linear elasticity is valid, and that the deformation is sufficiently slow for the inertia terms in the Navier equations to be ignored. Equations (9.5.2)–(9.5.7) thus comprise the very simplest model that couples elastic deformation to fluid flow. If we assume that the parameters λeff , µeff , k and η are all constant, then a straightforward cross-differentiation reveals that div u satisfies the linear diffusion equation: ∂ (λeff + 2µeff ) α0 k (div u) = ∇2 (div u) . (9.5.9) ∂t η Hence, the effects of elasticity, viscosity and permeability are all collected in the effective diffusion coefficient (λeff + 2µeff ) α0 k . (9.5.10) D= η
9.5 Poroelasticity
411
V
P =0
11111111 00000000 00000000 11111111 00000000 11111111 00000000L 11111111
F x
Fig. 9.11 The one-dimensional squeezing of a sponge.
If D is large (in a suitable dimensionless sense), then the left-hand side of (9.5.9) is negligible and the medium behaves like an elastic solid. Increasing the stiffness of the matrix thus has a similar overall effect to decreasing the fluid viscosity or increasing the permeability. As a simple illustration, let us consider one-dimensional T squeezing of a T sponge. With u = u(x, t), 0, 0 and v = v(x, t), 0, 0 , we can combine the equilibrium equation (9.5.4) and Darcy’s law (9.5.5) to obtain η ∂u ∂2u ∂P = −v . (9.5.11) (λeff + 2µeff ) 2 = ∂x ∂x k ∂t In one dimension, the mass-conservation equation (9.5.8) may be integrated directly with respect to x, leading to (1 − α0 )
∂u + α0 v = q(t), ∂t
(9.5.12)
where q(t) represents the net volume flux of both solid and fluid phases. We can use (9.5.12) to eliminate v from (9.5.11) and thus find that u satisfies a forced heat equation ∂2u ∂u − D 2 = q(t), ∂t ∂x
(9.5.13)
where D is again defined by (9.5.10). To fix ideas, let us consider the situation shown in Figure 9.11, where one end x = 0 of the sponge is held fixed, although fluid is free to flow into a reservoir at zero pressure, while the other end x = L is squeezed at a constant velocity −V by an impermeable plunger. This implies the boundary conditions u = P = 0 at
x = 0,
∂u = v = −V ∂t
at
x = L,
(9.5.14)
noting that, in linear elasticity, the motion of the boundary x = L is neglected. It follows that q = −V , and (9.5.13) may then readily be solved by
412
More general theories
F/(λeff + 2µeff ) 3 2 1 Pe = 0
2.0
1.5
1.0
0.5
0.2
0.4
0.6
0.8
1.0
V t/L Fig. 9.12 Dimensionless stress applied to a sponge versus dimensionless time for different values of the P´eclet number Pe; the large-t limits are shown as dotted lines.
separation of variables: if u = 0 initially, then ∞ (L − x)(2L − x) 2V L2 sin (nπx/L) −n 2 π 2 Dt/L 2 t+ + 3 e . 6D π D n3 n=1 (9.5.15) We can use this to calculate, for example, the net compressive stress F that we would need to apply to the plunger to force it to move at constant speed. From (9.5.2)–(9.5.4), we find that Vx u(x, t) = − L
∂u F = P − (λeff + 2µeff ) ∂x
x=L
∂u = − (λeff + 2µeff ) , ∂x x=0
(9.5.16)
and the result of substituting (9.5.15) into this is plotted in Figure 9.12. The behaviour depends on the key dimensionless parameter known as the P´eclet number Pe = LV /D. When Pe = 0, the effect of the fluid is negligible, so the stress just increases linearly as the elastic matrix contracts. However, for nonzero Pe, the initial response is dominated by the need to force the fluid through the matrix. After some time, the behaviour becomes linear again, with V t Pe F − ∼ λeff + 2µeff L 3
as
t → ∞,
(9.5.17)
as indicated by the dotted lines in Figure 9.12. As the P´eclet number increases, the fluid has an increasing influence, and a longer time is taken for the solution to settle down to (9.5.17).
9.6 Anisotropy
413
9.6 Anisotropy We conclude the chapter with a brief account of the effects of anisotropy, which, as we have just seen, is an endemic property of macroscopic models of heterogeneous elastic media. Moreover, wood and fibre-reinforced materials, for example, have strongly anisotropic response to stress. In Section 1.7, we saw that the most general linear relation between elastic stress τij and linear strain eij is τij = Cijk ek ,
(9.6.1)
which defines Cijk as a tensor with 81 components. Since there are only six independent components in the symmetric tensors τij and eij , we could also write the relation above as τxx exx τ e yy yy τ zz ezz (9.6.2) = A , τyz 2eyz τxz 2exz τxy 2exy where A = (Aij ) is a 6 × 6 matrix with entries A11 = C1111 , A12 = C1122 , A13 = C1133 , . . . and the factor of 2 multiplying the off-diagonal strain components accounts for the fact that they appear twice in (9.6.1). The existence of a strain energy density W such that τij = ∂W/∂eij implies, by cross-differentiation, that the matrix (Aij ) is symmetric. We are thus left with at most 21 independent elastic moduli. In terms of C, this can be summarised by the relations Cijk = Cjik = Cijk = Ckij .
(9.6.3)
The only other restriction we can impose in general is that A must be positive definite, to ensure that W is a positive definite function of the strain components. Let us now consider a rotation of the coordinate axes by an orthogonal matrix P . In the rotated frame, (9.6.1) becomes ek , τij = Cijk
where
Cijk = Pim Pjn Pkr Ps Cmnrs .
(9.6.4)
For the isotropic materials considered in Section 1.7, we asserted that the relationship between τ and e is the same as that between τ and e for any orthogonal matrix P . Now we can only say that this is true for each orthogonal matrix P representing a material symmetry. For every such P ,
414
More general theories
we therefore have 21 independent equations of the form Cijk = Pim Pjn Pkr Ps Cmnrs .
(9.6.5)
Usually, most of these equations are satisfied trivially, but some of them may imply nontrivial relationships between the elastic constants Cijk . The simplest symmetry that we can encounter is reflectional symmetry with respect to the (x, y)-plane. Such materials are called homoclinic. To fix ideas, we will focus on the example of a material containing fibres oriented in the z-direction. In this case, (9.6.5) should be satisfied with 1 0 0 P = 0 1 0 , (9.6.6) 0 0 −1 or, in a more compact notation, Pij = (−1)δi 3 δij . We must therefore have Cijk = (−1)δi 3 +δj 3 +δk 3 +δ 3 Cijk , and hence Cijk vanishes if the index 3 appears an odd number of times. This leaves 13 nonzero entries in Aij , namely 0 0 A16 A11 A12 A13 A 0 0 A26 12 A22 A23 0 0 A36 A13 A23 A33 (9.6.7) A= . 0 0 A44 A45 0 0 0 0 0 0 A45 A55 0 0 A66 A16 A26 A36 Continuing with our example of z-oriented fibres, let us further assume that they are positioned in the (x, y)-plane regularly enough to impose in addition reflectional symmetry with respect to the (x, z)- and (y, z)-planes. Such a material with three orthogonal planes of symmetry is called orthotropic. In this case (9.6.5) must hold simultaneously with the three transformations Pijz = (−1)δi 3 δij , Pijx = (−1)δi 1 δij and Pijy = (−1)δi 2 δij . Hence, following the same reasoning as in the monoclinic case, Cijk vanishes whenever any of the indices 1, 2 or 3 appears an odd number of times. In particular, C1112 = C2212 = C3312 = C2313 = 0, so that (9.6.7) reduces to 0 0 0 A11 A12 A13 A 0 0 0 12 A22 A23 0 0 0 A13 A23 A33 A= (9.6.8) . 0 0 0 0 A44 0 0 0 0 0 0 A55 0 0 0 0 0 A66
9.6 Anisotropy
415
If, on the other hand, the fibres are randomly positioned in the xy-plane, then, on a macroscopic scale, the material is transversely isotropic. The resulting matrix (Aij ) will clearly be a special case of (9.6.8) and we first note that, in the absence of preferred direction in the (x, y)-plane, A11 = A22 , A23 = A13 and A44 = A55 . Furthermore if we restrict the displacements to be in the (x, y)-plane only, then we have an isotropic problem in plane strain. Thus, as in (1.7.6), there must exist two constants c1 and c2 such that τxx = c1 (exx + eyy ) + c2 exx ,
(9.6.9a)
τxy = c2 exy ,
(9.6.9b)
τyy = c1 (exx + eyy ) + c2 eyy ,
(9.6.9c)
while (9.6.8) gives us τxx = A11 exx + A12 eyy , τxy = 2A66 exy , τyy = A12 exx + A11 eyy . (9.6.10) This imposes the condition 2A66 = A11 − A12 , so that only five independent elastic constants remain: 0 0 0 A11 A12 A13 A 0 0 0 12 A11 A13 0 0 0 A13 A13 A33 A= (9.6.11) . 0 0 A44 0 0 0 0 0 0 0 A44 0 0 0 0 0 0 (A11 − A12 )/ 2 Note that the same conclusion could be reached by a blind use of (9.6.5) with the family of orthogonal transformations cos θ sin θ 0 B = − sin θ cos θ 0 , (9.6.12) 0 0 1 but with considerably more effort. As a simple example, let us generalise the analysis of Section 2.4 to model the torsion of an orthotropic bar. For a displacement field of the form (2.4.1), the only nonzero strain components are exz and eyz , and, according to (9.6.8), the nonzero stress components are ∂ψ ∂ψ −y , τyz = A44 Ω +x . (9.6.13) τxz = A55 Ω ∂x ∂y Hence, instead of Laplace’s equation, ψ now satisfies A55
∂2ψ ∂2ψ + A = 0, 44 ∂x2 ∂y 2
(9.6.14)
416
More general theories
where A44 and A55 are both positive, and the no-stress boundary condition is dy dx ∂ψ ∂ψ −y − A44 +x = 0, (9.6.15) A55 ∂x ds ∂y ds on the boundary of the bar. We recall from Section 2.4 that, once we have solved for ψ(x, y), we can evaluate the torsional rigidity using 1 (xτyz − yτxz ) dxdy R= Ω D ∂ψ ∂ψ + x − A55 y −y dxdy. (9.6.16) A44 x = ∂y ∂x D The most striking implication of this model is that the elastic constants A44 and A55 can be eliminated from the problem by rescaling x and y appropriately. If we define A44 1/4 A55 1/4 X, y= Y, (9.6.17) x= A44 A55 then, with respect to the new variables, ψ satisfies ∂2ψ ∂2ψ + = 0, ∂X 2 ∂Y 2
(9.6.18)
dX ∂ψ 1 d 2 dY ∂ψ − = X +Y2 ds ∂X ds ∂Y 2 ds
(9.6.19)
subject to
on the boundary of the bar, while (9.6.16) is transformed to ∂ψ 2 ∂ψ −Y + X +Y2 dxdy. X R = A44 A55 ∂Y ∂X D
(9.6.20)
Equations (9.6.18)–(9.6.20) are identical to those found for an isotropic bar in Section 2.4. Hence an orthotropic bar behaves under torsion just like an isotropic bar whose transverse dimensions are stretched according to the rule (9.6.17). For example, a circular orthotropic bar is mechanically equivalent to an elliptical isotropic bar. We conclude by mentioning an important consequence of anisotropy for the propagation of elastic waves. For an anisotropic material, the timedependent momentum equation is ρ
∂τij ∂ 2 ui ∂ 2 um = = C . ijmn ∂t2 ∂xj ∂xj ∂xn
(9.6.21)
9.7 Concluding remarks
417
As in Section 3.2.4, we look for a solution in the form of a plane wave u = aei(k·x−ωt) . A simple substitution into (9.6.21) yields the system Cijmn kj kn am − ρω 2 ai = 0,
(9.6.22)
and, if nontrivial waves are to exist, they must therefore satisfy the dispersion relation det Cijmn kj kn − ρω 2 δim = 0. (9.6.23) This generalises the dispersion relations (3.2.37) governing P -waves and S waves in an isotropic solid. One of the main consequences of (9.6.23) is that the waves are dispersive, so that the phase speed ω/ |k| of plane waves generally depends on the wave vector k. This is in contrast with waves in an infinite isotropic solid, which propagate with phase speed equal to either cp or cs . Recall, though, that the presence of boundaries can give rise to dispersion even in an isotropic medium; for example, Love waves and waves in beams are both dispersive.
9.7 Concluding remarks This chapter has revealed the amazing variety of mathematical models and challenges to which macroscopic solid mechanics can give rise when it is coupled with other physical mechanisms. More will be said about this in the Epilogue. Perhaps the most serious scientific issue that has emerged concerns nonlinear viscoelasticity, as discussed in Section 9.2.4. We saw in Chapter 5 that nonlinear elasticity demands much more sophisticated modelling and analytical techniques than does linear elasticity, but the issues confronted there now seem comparatively trivial, especially when thermal effects are also important.
Exercises 9.1
Show that the constitutive law for the linear Jeffreys viscoelastic element shown in Figure 9.13 is dT du trT + T = k tru +u . (E9.1) dt dt Find expressions for the modulus k and the relaxation times trT and tru , in terms of the spring constants and impedance of the individual components, and hence show that tru trT .
418
More general theories
Fig. 9.13 A Jeffreys viscoelastic element. Tn−1
Tn−1
m
Tn
Tn
m
un−1
un
m un+1
Fig. 9.14 A system of masses connected by springs and dashpots in parallel along the x-axis.
Show that the creep function for this element is K(t) =
9.2
1 − (1 − trT /tru ) e−t/tru . k
Obtain the Voigt and Maxwell creep functions (9.2.9) by taking the limits trT → 0 and tru → ∞ respectively. (a) Suppose parallel spring/dashpot elements separate a linear array of masses m, each displaced a distance un (t) from its equilibrium position nL, as shown in Figure 9.14. Show that Tn = Tne + Tnv , dun dun+1 e v − , Tn = k(un+1 − un ), Tn = Y dt dt in the notation of Section 9.2.2. Use the equation of motion for the nth mass to show that m
d2 un d = Y (un+1 − 2un + un−1 ) 2 dt dt + k (un+1 − 2un + un−1 )
and show that this is a discretisation of the one-dimensional Voigt model (9.2.17) as L → 0.
Exercises Tn−1
Tn−1
m
419
Tn
Tn
m
un−1
m
un
un+1
Fig. 9.15 A system of masses connected by springs and dashpots in series along the x-axis.
9.3
(b) Repeat the above calculation for the series elements shown in Figure 9.15 and show that the result is a discretisation of the one-dimensional Maxwell model (9.2.19). A standard rheological test an oscillatory displacement is to impose on a sample, say u = Re ae−iωt , and measure the resulting force T (t). For a linear material, T (t) will also be proportional to e−iωt , and we define the complex modulus G = T /u. The complex modulus is then decomposed into its real and imaginary parts: G = G + iG , where G is called the storage modulus and G the loss modulus. Show that the average work done in each period is 2π/ω 1 du ω dt = − |a|2 G ω. T 2π 0 dt 2 For the Jeffreys model (E9.1), show that G =
9.4
ktru k (tru − trT ) , − trT trT 1 + t2rT ω 2
k (tru − trT ) ω . trT 1 + t2rT ω 2
Deduce that the rate at which the Jeffreys element dissipates energy is a non-negative increasing function of ω. Recall from Chapter 5 the definitions of deformation gradient and of the Green and Finger deformation tensors, namely Fij =
∂xi , ∂Xj
C = F T F,
Prove the identities DC = F T ∇v + ∇v T F, Dt 9.5
G = −
B = F F T.
DB = ∇v T B + B∇v, Dt
where ∇v is the velocity gradient tensor with components (∂vj /∂xi ). Recall that a scalar function f (x, t) is conserved by a flow v(x, t) if ∂f Df = + v · ∇f = 0. Dt ∂t
420
More general theories
Now consider a vector field f (x, t) that convects and rotates with the flow. Following the procedure in Exercise 8.11, show that f must satisfy Df = (f · ∇) v. Dt Finally, suppose that the tensor field A(x, t) is such that, if Af = g at time t, then Af = g for all t, whenever f (x, t) and g(x, t) are both convected by the flow in the above sense. Deduce that A must satisfy DA + A∇v T − ∇v T A = 0. Dt ◦
9.6
◦
If A is symmetric, deduce that A = 0, where A is the Jaumann derivative (9.2.33) with a = 0. In a linear thermoelastic solid, the strain energy density is zero for a uniform isotropic expansion in which ekk = α(T − T0 ). By referring to Exercise 1.7, obtain the formula 2 λ ekk − α(T − T0 ) 2 α α + µ eij − (T − T0 )δij eij − (T − T0 )δij . 3 3 Show that, with this definition of W, the linear thermoelastic constitutive relation (9.3.2) is consistent with τij = ∂W/∂eij (where the derivative is taken with T held fixed). By using the divergence theorem and the momentum equation, deduce from (9.3.11) and (9.3.10) that T satisfies ∂W ∂T + div q = 0. ρc + ∂T ∂t W=
9.7
For the strain energy density calculated in Exercise 9.6, show that α ∂W = − τkk . ∂T 3 We can use (9.3.2) to estimate the stress induced by a temperature variation ∆T as τkk = O (Eα∆T ), where E is Young’s modulus. Deduce that ∂W/∂T is negligible in comparison with ρc for temperature variations ∆T such that Eα2 ∆T /ρc 1. [Steel, for example, has ρ ≈ 7800 kg m−3 , c ≈ 500 J kg−1 K−1 , E ≈ 200 GPa and α ≈ 13 × 10−6 K−1 , so that ∆T must be much less than 105 K for the estimate to be valid.]
Exercises
9.8
421
Consider one-dimensional heat flow in an infinite uniform insulated thermoelastic bar of density ρ, Young’s modulus E, thermal expansion coefficient α and thermal diffusivity κ. By combining (9.3.7) and (4.2.2), show that the longitudinal displacement u(x, t) and temperature T (x, t) satisfy ∂T ∂2T ∂ 2 u α ∂T 1 ∂2u , = κ = − , c2 ∂t2 ∂x2 3 ∂x ∂t ∂x2 where c = E/ρ. Suppose the bar starts from rest at zero stress with a temperature profile T (x, 0) = T0 H(x), where H is the Heaviside function given by (3.5.7). Show that, for x ∼ ct κ/c, thermal diffusion is negligible and u approximately satisfies 1 ∂2u ∂2u 1 = − αT0 δ(x), c2 ∂t2 ∂x2 3 where δ is the Dirac delta-function. Obtain the solution u(x, t) =
αT0 2|x| − |x − ct| − |x + ct| , 12
and deduce that the maximum tensile stress caused in the bar is given by αET0 /6. 9.9
Following Exercise 9.8, now consider a finite bar of length L with one end (x = L) held fixed and thermally insulated while the other end (x = 0) is unstressed. Suppose the bar is initially stationary and unstressed at uniform temperature T0 before, at time t = 0, the temperature of the end x = 0 is suddenly decreased to a value T1 . Derive the dimensionless equations ∂2T ∂T = , ∂t ∂x2
1 ∂2u ∂ 2 u ∂T , = − 2 ∂t2 ∂x2 ∂x
governing this situation, where = Lc/κ. Also derive the initial and boundary conditions ∂u = 0, ∂x ∂T = 0, u = 0, ∂x ∂u = 0, T = 1, u = ∂t T = 0,
x = 0, t > 0, x = 1, t > 0, t = 0, 0 < x < 1,
422
More general theories
and obtain the solution ∞ 2 sin (n + 1/2)πx −(n+1/2)2 π 2 t e , T = π n + 1/2 n=0 ∞ cos (n + 1/2)πx 2 2 2 u= 2 −e−(n+1/2) π t 2 2 2 2 π (n + 1/2) ( + (n + 1/2) π ) n=0 + cos (n + 1/2)πt − (n + 1/2)π sin (n + 1/2)πt . 9.10
(a) Prove the identity ∂w ds = µw w∇ξ · (µ∇ξ w) dξdη ∂n ∂D D µ|∇ξ w|2 dξdη, + D
where w is twice continuously differentiable on the closed bounded region D of the (ξ, η)-plane. Deduce that, if w satisfies (9.4.25) and periodic boundary conditions on a rectangular cell [0, 1] × [0, b], then w must be independent of ξ and η. (b) Next suppose that w satisfies ∇ξ · (µ∇ξ w) = R(x, y, ξ, η) and periodic conditions on the boundary of the rectangle [0, 1] × [0, b]. Show that R must have zero mean, that is 1 b R dξdη = 0. 0
9.11
0
Consider the solutions of (9.4.29) and (9.4.30) with periodic boundary conditions on a rectangular cell in which the modulus µ is piecewise constant, as shown in Figure 9.7. If no symmetry is assumed, show that the function φ(1) defined by (9.4.37) satisfies the boundary conditions φ(1) (1, η) − φ(1) (0, η) = 1, φ(1) (ξ, b) − φ(1) (ξ, 0) = 0,
∂φ(1) ∂φ(1) (1, η) − (0, η) = 0, ∂ξ ∂ξ ∂φ(1) ∂φ(1) (ξ, b) − (ξ, 0) = 0, ∂η ∂η
and find the corresponding boundary conditions for φ(2) and the harmonic conjugate functions ψ (1) and ψ (2) .
Exercises
423
Following the procedure used at the end of Section 9.4.2, derive the following relations between the effective elastic constants µij and the corresponding constants µ %ij when µ1 and µ2 are swapped: µ %11 µ %21 µ %12 µ %22 b2 µ1 µ2 = = = = . µ11 µ12 µ21 µ22 µ11 µ22 − µ21 µ12 9.12
Using the symmetry properties of C, show that equation (9.4.62) may be written in component form as ∂Cijk ∂u0k ∂ ∂u1k Cijk =− . ∂ξi ∂ξ ∂ξi ∂x Deduce that the solution may be written as u1i = Aijk
∂u0j , ∂xk
where Aijk ≡ Aikj and ∂Cijmn ∂ ∂Amn Cijk =− . ∂ξj ∂ξk ∂ξi Verify that this gives us 18 independent equations for the 18 independent functions Aijk (x, ξ). By substituting for u1 in (9.4.61), show that τ0 is given by ∂u0m ∂Akmn + Cijmn . τ0ij = Cijk ∂ξ ∂xn 9.13
When k = O (ε), write (9.4.69) as the system dT du = T, + κ2 u = 0, dx dx where κ = k/ε. Seek a multiple-scales solution, with u = u(x, ξ), T = T (x, ξ) and x = εξ, and show that the leading-order displacement u0 (x) satisfies the homogenised equation d du0 Eeff (x) + κ2 u0 = 0, dx dx E(x, x/ε)
9.14
with Eeff (x) given by (9.4.16). Solve (9.4.71) and (9.4.72) for u1 (ξ) and u2 (ξ) when E(ξ) is the piecewise constant function 0 ξ < 1/4, 1, E(ξ) = E2 , 1/4 ξ < 3/4, 1, 3/4 ξ < 1.
424
More general theories
k/π
E2 Fig. 9.16 Dimensionless wavenumber k versus Young’s modulus contrast E2 for a piecewise uniform bar. The stop bands are shaded.
[Hint: both u and Edu/dξ must be continuous.] Show that the trace T of themonodromy matrix is given by 1 + E2 k k k k √ √ − √ . cos sin sin T = 2 cos 2 2 2 E2 E2 2 E2 The stop bands where |T | > 2 are shown as shaded regions in Figure 9.16. Show that, when E2 is close to 1, the boundaries of these bands are given asymptotically by (2n + 1)π 1 k ∼ (2n + 1)π + ± (E2 − 1) + · · · , 4 2 nπ nπ nπ (E2 − 1) + − ± (E2 − 1)2 + · · · , or k ∼ 2nπ + 2 4 8 where n is an integer. 9.15
(a) Consider a control volume V in a porous elastic solid, with initial fluid fraction equal to α0 . Show that, after a small displacement u, the same solid material occupies a volume V (1 + ∇ · u), and deduce that the solid fraction becomes 1−α=
1 − α0 ∼ (1 − α0 ) (1 − ∇ · u) . 1+∇·u
Exercises
425
(b) Now consider a fixed volume V , whose boundary ∂V has unit normal n, and suppose that fluid with density ρf occupies a volume fraction α. Use the principle ofconservation of mass to obtain the equation d ρf α dx = − ρf αv · n da, dt V ∂V where v is the average fluid velocity, and deduce that ∂ (ρf α) + ∇ · (ρf αv) = 0. ∂t Show that this reduces to (9.5.7) when the fluid density is constant and α ≈ α0 .
Epilogue
There are three main themes to this book. 1. In Chapters 1–5, we have provided an elementary exposition of the basic concepts in classical solid mechanics, namely linear elasticity, elastostatics, elastodynamics, models for thin structures and nonlinear elasticity. In each case, we have focused on practical examples that highlight the most interesting modelling and mathematical issues. 2. In Chapter 6, our aim was to show how formal perturbation methods, widely used in fluid dynamics, can be applied to many problems in solid mechanics involving bodies that are thin or slender. Although the remainder of the book does not rely on this chapter, we firmly believe that the techniques demonstrated there form an invaluable component of any applied mathematician’s armoury. 3. Finally, in Chapters 7–9, we have given necessarily brief introductions to some of the important physical situations where classical solid mechanics fails, and the elementary theories from Chapters 1–5 must be re-examined. Inevitably, the mathematical problems involved here become more challenging, and we have therefore limited our attention to idealised models that clearly illustrate the fundamental concepts. The diversity and open-endedness of the topics described in Chapter 9 reflect the fact that we have not done justice to many scientific ideas in theoretical solid mechanics. Fracture, plasticity and viscoelasticity, for example, are subjects of enormous practical importance, and there are many texts describing both the practical and the mathematical aspects in much greater detail than the contents of Chapters 7–9. We have not touched at all upon the crucial phase changes that can occur in solids, especially metals and their alloys, as a result of heat treatment and/or mechanical processing. For example, steel can have several different crystalline microstructures which can depend crucially on its chemical composition, and these different phases have very different mechanical 426
Epilogue
427
properties. In certain circumstances, the geometry of the phase boundaries can be elegantly described in terms of hyperelasticity, with a strain energy density possessing multiple minima corresponding to the different phases. This naturally opens up exciting new problems in the calculus of variations, as does the related subject of “shape memory” alloys, where the strain energy depends on temperature. The resulting relaxation phenomena associated with different phases depend on thermal histories in the same way that viscoelastic relaxation depends on the stress or strain histories. Another fascinating mathematical challenge that we have not addressed is to find self-contained theories of solids, such as piezoelectric or ferromagnetic materials, whose mechanical properties depend on electromagnetic fields. A background in electromagnetism would be a prerequisite for any applied mathematician wishing to understand the modelling of such materials. Finally from the modelling point of view, we must also point out that we have avoided any serious discussion of ceramics, which could in fact be defined as any solids that are not metals. Although the mechanics of materials such as rock can be perfectly well described by linear elasticity at sufficiently small stress, little of the theories expounded in Chapters 7 and 8 is helpful in understanding how a glass or piece of crockery shatters under impact, although many ad hoc macroscale models have been proposed. On the theoretical side, easily our most glaring omission is our failure to discuss the many ingenious numerical schemes that have been specifically developed to solve the kinds of models we have been describing in this book. Indeed, solid mechanics has provided one of the principal stimuli for the widely-used finite element method, which is so appropriate for finding energy minima in complicated real-world configurations of elastic solids. Moreover, computers have now reached the stage where discrete “particlebased” algorithms can be tailored to simulate the mechanics of a solid, be it elastic, plastic or any of the combinations mentioned in this book. At an even more fundamental level, “atomistic” computations are now routinely available to simulate many, many atoms as points of the solid interacting via suitable force potentials. Such simulations can give invaluable new insights into, say, dislocation interactions and many other nanoscale phenomena. Despite these qualifications, we hope that this book has shown that a little systematic mathematical modelling and analysis can go a long way towards providing a firm theoretical formulation for the science of solid mechanics. Even more, we hope that readers will be attracted by the many topics that await mathematical attention in an area so important to modern natural science.
Appendix Orthogonal curvilinear coordinates
A1 Framework Consider a general parametrisation of three-dimensional space, in which the position vector r of any point is given by r = r(ξ1 , ξ2 , ξ3 ),
(A1.1)
in terms of three spatial coordinates ξ1 , ξ2 and ξ3 . For this to form a sensible coordinate system, there should be a one-to-one correspondence between the position vector r of any point and its coordinates (ξ1 , ξ2 , ξ3 ) = ξ. This is the case provided the Jacobian of the transformation from r to ξ is bounded away from zero, that is ∂r ∂r ∂r ∂r = , (A1.2) , , 0 < J < ∞, J = det ∂ξ ∂ξ1 ∂ξ2 ∂ξ3 where [·, ·, ·] denotes the triple scalar product between three vectors. By ordering the coordinates appropriately, we may assume that the tangent vectors form a right-handed system and, hence, that J is positive. A coordinate system is orthogonal if the three tangent vectors created by varying each of the coordinates in turn are mutually orthogonal, that is ∂r ∂r · =0 ∂xi ∂xj
whenever i = j.
In this case we define the scaling factors hi by ∂r , hi = ∂ξi
(A1.3)
(A1.4)
and the Jacobian is simply given by J = h1 h2 h3 . 428
(A1.5)
A2 Vectors and tensors
429
We can then define a right-handed, mutually orthogonal set of unit vectors {e1 , e2 , e3 } by ei =
1 ∂r hi ∂ξi
(A1.6)
(here the summation convention is not invoked). The most straightforward and familiar coordinate system is Cartesian coordinates x = (x1 , x2 , x3 ), with respect to which the position vector is given by r = (x1 , x2 , x3 )T . This system is clearly orthogonal, with scale factors all equal to 1. As another example, consider cylindrical polar coordinates (r, θ, z), with respect to which r = (r cos θ, r sin θ, z)T . It is straightforward to show that this coordinate system is also orthogonal, with scaling factors hr = 1,
hθ = r,
hz = 1.
(A1.7)
It follows that J = r, so the Jacobian vanishes on the symmetry axis r = 0. This reflects the fact that θ is indeterminate when r = 0 and leads to the possibility of singular behaviour as r → 0 when solutions of (say) Laplace’s equation are sought in cylindrical polar coordinates.
A2 Vectors and tensors Consider a vector v with components vi in Cartesian coordinates, that is v = (v1 , v2 , v3 )T . It is natural to define its components ui in curvilinear coordinates as ui = v · ei , where ei are the basis vectors defined by (A1.6). If we denote the vector formed by these components by u = (u1 , u2 , u3 )T , then we have e1 · v u1 (A2.1) u = u2 = e2 · v , e3 · v u3 or
eT 1 P = eT . 2 T e3
u = Pv
where
(A2.2)
At each point in space, therefore, our curvilinear coordinate basis is found by rotating the usual Cartesian basis, the rotation being characterised by the orthogonal matrix P whose rows are the basis vectors.
430
Orthogonal curvilinear coordinates
Now consider a second-rank tensor with elements denoted by B = (bij ) in Cartesian coordinates and A = (aij ) in curvilinear coordinates. If B is indeed a tensor then, by analogy with Chapter 1, we must have A = P BP T ,
(A2.3)
so the curvilinear components of B are given by aij = eT i Bej .
(A2.4)
It is thus possible to write any tensor B in terms of its curvilinear components and the so-called outer products of the basis vectors: B= aij ei eT (A2.5) j . ij
A3 Derivatives of basis vectors In most orthogonal coordinate systems, including cylindrical polars and other familiar examples, the basis vectors ej vary with position, and this is the property that really distinguishes them from Cartesian coordinates. It will be useful for future reference to calculate the derivatives of the basis vectors as follows. In general, we can write ∂ei = cijk ek , (A3.1) ∂ξj k
so there are 27 constants cijk to be determined.† Since ei · ej = δij , we must have ∂ej ∂ei · ej + ei · ≡0 (A3.2) ∂ξk ∂ξk for all i, j and k. This provides 18 independent equations (since it is invariant if i and j are swapped). The further nine equations may be obtained by calculating ∂r/∂ξi ∂ξj in two different ways as follows: ∂ ∂ hj ej ≡ hi ei (A3.3) ∂ξi ∂ξj for all i and j. It is thus a straightforward but tedious exercise in algebraic manipulation to deduce the following: ek ∂hi ej ∂hj ∂ei = − δij . (A3.4) ∂ξj hi ∂ξi hk ∂ξk k
†
These constants are related to the so-called Christoffel symbols; see Aris (1962) Section 7.53.
A4 Scalar and vector fields; grad, div and curl
431
A4 Scalar and vector fields; grad, div and curl We can think of any scalar field f that varies with position r as being a function of our coordinate variables: f = f (ξ). Similarly, any vector field may be written as u = u(ξ), and the components of u with respect to this system are now written as (u1 , u2 , u3 )T , where ui = u · ei . The gradient of a scalar field is defined in the usual way in Cartesian variables, that is grad f = ∇f =
∂f ∂f ∂f , , ∂x1 ∂x2 ∂x3
T .
(A4.1)
The chain rule leads to ∂f ∂r = · ∇f = hi ei · ∇f ∂ξi ∂ξi
(A4.2)
and, since the ei are orthonormal, it follows that ∇f =
1 ∂f ek . hk ∂ξk
(A4.3)
k
A useful special case occurs if f is one of the variables ξi , when (A4.3) implies that ei (A4.4) ∇ξi = . hi Now the divergence of a vector field u may be written in terms of Cartesian coordinates as ∂u div u = ∇ · u = · ∇xk . (A4.5) ∂xk k
If we rewrite the gradient using (A4.3) and use the chain rule, we find 1 ∂uk ek ∂u u ∂ek . (A4.6) · = − · ∇·u= hk ∂ξk hk ∂ξk hk ∂ξk k
k
Now we apply (A3.4) to the final term and rearrange to obtain 1 ∂ ∂ ∂ ∇·u = h2 h3 u1 + h1 h3 u2 + h1 h2 u3 . (A4.7) h1 h2 h3 ∂ξ1 ∂ξ2 ∂ξ3
432
Orthogonal curvilinear coordinates
e3
h2δξ2
h1δξ1 e2
h3δξ3 e1
Fig. A1.1 A small reference box B.
Having derived the gradient and divergence, we may now express the Laplacian operator ∇2 f = ∇ · (∇f ) in terms of arbitrary orthogonal coordinates: 1 ∇ f= h1 h2 h3 2
∂ ∂ξ1
h2 h3 ∂f h1 ∂ξ1 h1 h3 ∂f ∂ h1 h2 ∂f ∂ + + . (A4.8) ∂ξ2 h2 ∂ξ2 ∂ξ3 h3 ∂ξ3
Next, we define the curl of a vector field by curl u = ∇×u =
∇xk ×
k
ek ∂u ∂u = × . ∂xk hk ∂ξk
(A4.9)
k
By rearranging the right-hand side and using (A3.4), this may be transformed to ∇×u =
ei ×ej ∂ 1 ∂ u ∂ek ek ×u + × hj uj , (A4.10) = hk ∂ξk hk ∂ξk hi hj ∂ξi i,j
k
which may be written conveniently as h1 e1 h2 e2 h3 e3 ∂ ∂ ∂ 1 ∇×u= . ∂ξ2 ∂ξ3 h1 h2 h3 ∂ξ1 h1 u1 h2 u2 h3 u3
(A4.11)
A4 Scalar and vector fields; grad, div and curl
433
An instructive alternative derivation of (A4.7) may be obtained by applying the divergence theorem to the small box B illustrated in Figure A1.1:
∇ · u dx = u · n dS = [u1 h2 h3 ]ξξ11 +δξ1 dξ2 dξ3 ∂B ξ2 +δξ2 + [u2 h1 h3 ]ξ2 dξ1 dξ3 + [u3 h1 h2 ]ξξ33 +δξ3 dξ1 dξ2 , (A4.12)
B
where the integrals on the right-hand side are over the faces ξ1 = const., ξ2 = const. and ξ3 = const. respectively. In the limit δξ → 0, we therefore obtain
∂ (h2 h3 u1 ) ∂ξ1 B ∂ ∂ (h1 h3 u2 ) + (h1 h2 u3 ) dξ1 dξ1 dξ3 (A4.13) + ∂ξ2 ∂ξ3
(∇ · u)h1 h2 h3 dξ1 dξ2 dξ3 ∼ B
and, since this must hold for all such boxes B, (A4.7) follows. This approach is useful in finding the divergence of a tensor A in curvilinear coordinates. By analogy with (A4.5), this is defined in Cartesian coordinates to be div A = ∇ · A =
∂AT k
∂xj
∇xk .
(A4.14)
An dS
(A4.15)
By applying the identity
∇· A
T
dx =
B
∂B
to the box B and letting δξ → 0 as above, we find that
∂ ∂ ∂ (h2 h3 Ae1 ) + (h1 h3 Ae2 ) + (h1 h2 Ae3 ) . ∂ξ1 ∂ξ2 ∂ξ3 (A4.16) Now we expand the derivatives and use (A3.4) to obtain ∇ · AT =
1 h1 h2 h3
∇ · AT =
i,j
ei ∂ J ∂ξj
aij J hi
aij + hi
ek ∂hi ej ∂hj − δij hi ∂ξi hk ∂ξk
,
k
(A4.17) where aij are the curvilinear components of A. Hence we find the ei -component
434
Orthogonal curvilinear coordinates
of ∇ · A in the form 1 ei · (∇ · A) = h1 h2 h3
∂ ∂ ∂ (h2 h3 a1i ) + (h1 h3 a2i ) + (h1 h2 a3i ) ∂ξ1 ∂ξ2 ∂ξ3 1 ∂hi ∂hk aik . (A4.18) + − akk hi hk ∂ξk ∂ξi k
A5 Strain in curvilinear coordinates Now we repeat the calculation from Section 1.4 to derive an expression for the strain tensor in an arbitary orthogonal coordinate system. We define the Lagrangian coordinates X = (X1 , X2 , X3 ) of a material point to be the parametrisation corresponding to its initial position X, that is X = r(X ).
(A5.1)
At any subsequent time t, the same material point moves to a new position x parametrised by its Eulerian coordinates ξ = (ξ1 , ξ2 , ξ3 ), so that x = r ξ(X , t) . (A5.2) Consider a small line element joining two points with Lagrangian coordinates X and X + δX . The initial Cartesian position vectors of the end points are thus X and X + δX, where hk (X )ek (X )δXk , (A5.3) δX = k
and the initial length L of the line element satisfies hk (X )2 δXk2 . L2 = |δX|2 =
(A5.4)
k
At a later time t, the line element is transformed to δx, where, by repeated use of the chain rule, ∂xi ∂ξj ∂ξj δXk , or δx = hj (ξ)ej (ξ) δXk . (A5.5) δxi = ∂ξj ∂Xk ∂Xk j,k
j,k
Notice that, since ej and hj are not in general constant, we must distinguish between their values at a particle’s initial position X and at its current position ξ. By comparing (A5.3) and (A5.5), we see that δx = F δX,
(A5.6)
A5 Strain in curvilinear coordinates
435
where the deformation gradient tensor F is given by F =
hi (ξ) ∂ξi ei (ξ)eT j (X ). hj (X ) ∂Xj
(A5.7)
i,j
The length of the deformed line element is thus given by 2 = δxT δx = δX T C δX, where the Green deformation tensor is defined by C = F TF = Cij ei (X )eT j (X ),
(A5.8)
(A5.9)
i,j
and the curvilinear components of C are Cij =
k
∂ξk ∂ξk hk (ξ)2 . hi (X )hj (X ) ∂Xi ∂Xj
(A5.10)
The nonlinear strain tensor is then found using 1 E = (C − I). 2
(A5.11)
Further simplification may be achieved if the strains are small enough for linear elasticity to be valid. If each material point is only slightly disturbed from its initial position, then the Eulerian and Lagrangian coordinates are approximately equal. We may therefore write ξi = Xi + so that x∼X+
ui (X , t) , hi (X )
(A5.12)
ui ei + · · ·
(A5.13)
i
when the displacements ui are small. By substituting (A5.12) into (A5.10) and linearising, we find uk ∂hj hj ∂ uj ui hi ∂ + + 2δij + · · · (A5.14) Cij ∼ δij + hj ∂ξj hi hi ∂ξi hj hj hk ∂ξk k
436
Orthogonal curvilinear coordinates
where it is no longer necessary to distinguish between ξ and X within the linear theory. The linearised strain components in curvilinear coordinates therefore read 1 eij = 2
uj ∂hj 1 ∂ui ui ∂hi 1 ∂uj − + − hj ∂ξj hi hj ∂ξj hi ∂ξi hi hj ∂ξi
+ δij
uk ∂hj . hj hk ∂ξk k (A5.15)
A6 Stress in curvilinear coordinates As in Section 1.5, we define the Cauchy stress τij to be the component in the ei -direction of the stress acting on a surface element whose normal points along ej . Although the basis vectors ei may now vary with position, at any fixed location, the curvilinear components τij of the stress tensor are found by simply rotating the Cartesian components through the orthogonal matrix P introduced in Section A2. It is easily shown that the symmetry of τij in Cartesian coordinates is maintained in an arbitrary orthogonal coordinate system. In Section 1.7, we introduced the constitutive relation τij = λ (ekk ) δij + 2µeij ,
(A6.1)
which links the stress and linearised strain tensors in a linear elastic material. Note that, since τij and eij are tensors, they both obey the transformation rule (A2.3) if the coordinate axes are rotated by an orthogonal matrix P , which may be a function of position. Hence, although the relation (A6.1) was originally posed using fixed Cartesian coordinates, it actually holds in any orthogonal coordinate system.
A7 Examples of orthogonal coordinate systems A7.1 Cylindrical polar coordinates The Cartesian position vector is given in terms of the coordinate variables (r, θ, z) by r = (r cos θ, r sin θ, z)T , as illustrated in Figure A1.2. The scaling factors are given by (A1.7), and therefore the formulae for the gradient,
A7 Examples of orthogonal coordinate systems z
437
r
z
y
θ x Fig. A1.2 Cylindrical polar coordinates.
divergence, Laplacian and curl in this coordinate system are 1 ∂f ∂f ∂f er + eθ + ez , (A7.1a) ∂r r ∂θ ∂z ∂uz 1 ∂ 1 ∂uθ (rur ) + + , (A7.1b) ∇·u= r ∂r r ∂θ ∂z ∂f 1 ∂2f 1 ∂ ∂2f ∇2 f = r + 2 2 + 2, (A7.1c) r ∂r ∂r r ∂θ ∂z ∂uθ ∂uz ∂ur 1 ∂ ∂ur 1 ∂uz − er + − eθ + (ruθ ) − ez , ∇×u = r ∂θ ∂z ∂z ∂r r ∂r ∂θ (A7.1d) ∇f =
where f is any scalar field and u = ur er + uθ eθ + uz ez is any vector field (both suitably differentiable). The components of the linearised strain tensor corresponding to a displacement field u are given by ∂ur , ∂r 1 ∂uθ + ur , = r ∂θ ∂uz , = ∂z
∂uθ uθ 1 ∂ur + − , r ∂θ ∂r r ∂uz ∂ur + , = ∂z ∂r 1 ∂uz ∂uθ + . = ∂z r ∂θ
err =
2erθ =
(A7.2a)
eθθ
2erz
(A7.2b)
ezz
2eθz
(A7.2c)
438
Orthogonal curvilinear coordinates z
θ
r
y φ
x
Fig. A1.3 Spherical polar coordinates.
The divergence of a tensor A with components aij (i, j = r, θ, z) is given by ∂azr aθθ 1 ∂(rarr ) 1 ∂aθr + + − er ∇·A= r ∂r r ∂θ ∂z r 1 ∂(rarθ ) 1 ∂aθθ ∂azθ aθr + + + + eθ r ∂r r ∂θ ∂z r ∂azz 1 ∂(rarz ) 1 ∂aθz + + ez . (A7.3) + r ∂r r ∂θ ∂z A7.2 Spherical polar coordinates The position vector of any point is given in terms of the spherical polar coordinates (r, θ, φ) by r = (r sin θ cos φ, r sin θ sin φ, r cos θ)T , as illustrated in Figure A1.3. The scaling factors are hr = 1,
hθ = r,
hφ = r sin θ,
(A7.4)
and it follows that 1 ∂f 1 ∂f ∂f er + eθ + eφ , ∂r r ∂θ r sin θ ∂φ 1 ∂uφ 1 ∂ 1 ∂ 2 r ur + (sin θuθ ) + , ∇·u= 2 r ∂r r sin θ ∂θ r sin θ ∂φ 1 ∂ ∂f 1 1 ∂ ∂f ∂2f r2 + 2 sin θ + 2 2 ∇2 f = 2 , r ∂r ∂r r sin θ ∂θ ∂θ r sin θ ∂φ2 ∇f =
(A7.5a) (A7.5b) (A7.5c)
A7 Examples of orthogonal coordinate systems
1 ∇×u = r sin θ +
439
∂uθ ∂ (sin θuφ ) − er ∂θ ∂φ ∂uφ 1 ∂ur 1 ∂ ∂ur − eθ + (ruθ ) − eφ , (A7.5d) r sin θ ∂φ ∂r r ∂r ∂θ
for any suitably differentiable f and u = ur er +uθ eθ +uφ eφ . The components of the linear strain tensor in spherical polars read err = 2erθ = eθθ = 2erφ = eφφ = 2eθφ =
∂ur , ∂r ∂uθ uθ 1 ∂ur + − , r ∂θ ∂r r 1 ∂uθ + ur , r ∂θ ∂uφ uφ 1 ∂ur + − , r sin θ ∂φ ∂r r ur cot θuθ 1 ∂uφ + + , r sin θ ∂φ r r cot θuφ 1 ∂uφ 1 ∂uθ + − , r sin θ ∂φ r ∂θ r
(A7.6a) (A7.6b) (A7.6c) (A7.6d) (A7.6e) (A7.6f)
and the divergence of a tensor A is given by aθθ + aφφ 1 ∂(sin θaθr ) 1 ∂aφr 1 ∂(r2 arr ) + + − er ∇·A= r2 ∂r r sin θ ∂θ r sin θ ∂φ r aθr − cot θaφφ 1 ∂(sin θaθθ ) 1 ∂aφθ 1 ∂(r2 arθ ) + + + eθ + r2 ∂r r sin θ ∂θ r sin θ ∂φ r aφr + cot θaφθ 1 ∂(sin θaθφ ) 1 ∂aφφ 1 ∂(r2 arφ ) + + + eφ . + r2 ∂r r sin θ ∂θ r sin θ ∂φ r (A7.7)
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Index
aerofoil, 293, 344 airliner, 287 Airy function, 212 Airy stress function, 47–68, 71, 82, 171, 176, 179, 252, 264, 297, 304, 307, 323, 334, 341, 350, 374 boundary conditions, 49–51, 297 modified, 66, 86, 98 plane stress, 74 polar coordinates, 51 uniqueness, 48, 50 Airy’s equation, 212 alloy, 426 shape memory, 427 alternating symbol, 82, 100 analytic continuation, 296, 299 angle of friction, 330, 336, 372 angle of incidence, 116, 145 angle of reflection, 116, 145 angle of repose, 330 angular momentum, 9, 25, 154, 197, 268, 274 angular velocity, 196, 197 anisotropy, 379, 398, 404, 410, 413–417 annulus plane strain in, 53–56 torsion in, 44 anticlastic shell, 181, 184 anticlastic surface, 179 antiplane strain, 37–39, 80, 246–248, 258, 283, 338, 395 dynamic, 117, 135, 308, 324 in a strip, 247 yield criterion, 345 antiplane stress function, 41, 82, 97, 339, 345 uniqueness, 41 associated flow rule, 362 asymptotic expansion, 194, 245, 247, 257, 275, 394, 397, 403, 407 atomistic model, 1, 337–344, 427 auxetic material, 33, 55, 93 axe, 289 balloon, 235, 244
bar, 104, 150–152, 242 boundary conditions, 152, 189 composite, 392–395, 404–408 constitutive relation, 152 multiply-conected, 42 thermoelastic, 389, 421 torsion, 39, 42, 93 viscoelastic, 385 basis vectors, 27, 279, 429, 430 Bauschinger effect, 374 beam, 150 bending, 76 boundary conditions, 156 compression, 156, 158, 191–195 constitutive relation, 154, 189 contact, 313, 325 linear, 153–158, 205, 206, 213 nonlinear, 187–195, 197, 210, 211 unsteady, 200–204 beam equation Euler–Bernoulli, 189 linear, 155 nonlinear, 189 bending, 76, 174, 183, 196, 198 bending moment, 61, 62, 154, 159, 163–165, 189, 251, 252, 263, 266, 271, 275, 277 bending stiffness, 150, 154, 158, 160, 165, 170, 208, 281, 313 Bessel function, 108, 109, 113, 124, 131 Bessel’s equation, 107, 109, 126 inhomogeneous, 127 biaxial strain, 33–35, 76, 171, 234 bicycle frame, 46 bifurcation, 195, 235 biharmonic equation, 48, 56, 71, 74, 168, 171, 253, 296, 304, 350 axisymmetric, 77 boundary conditions, 96 inhomogeneous, 66, 77, 78, 168, 341 polar coordinates, 51 biomaterial, 14, 379 body force, 10, 219 conservative, 65
442
Index in plane strain, 65–68 boundary conditions, 16–18 Airy stress function, 49–51, 297 between two solids, 18, 118 Cauchy, 18 clamped, 156, 166, 168, 189, 191 Dirichlet, 16, 39, 41, 44, 181 elliptic, 18 free, 156, 166 mixed, 18, 296, 317 natural, 26, 39, 167, 168, 209 Neumann, 17, 39, 40, 259, 276, 290 on a bar, 152, 189 on a beam, 156 on a plate, 166–168, 171, 176, 208, 253–261 on a rod, 160 periodic, 397, 422 point force, 87 pressure, 51 Robin, 27 simply supported, 156, 166, 168, 170, 189, 208 stress-free, 31, 33, 40, 50, 54, 66, 86, 121, 124, 125, 128, 130, 131, 248, 250, 263, 274, 290 traction, 17, 26, 38, 49, 56, 58, 62, 66, 156, 254 boundary element method, 90 boundary layer, 46, 167, 182, 247, 253–261 branch cut, 292, 338 Brillouin zone, 408 brittle fracture, 288, 344 buckling, 2, 157, 191–195, 205, 212, 213, 390 bulk modulus, 30 Burgers vector, 342 cable, 198 calculus of variations, 26, 39, 51, 168, 176, 209, 210, 229, 239, 427 capstan, 321 car panel, 150 suspension, 39, 380 tyre, 13, 287 Cartesian coordinates, 19–20, 429 cartilage, 13 catenary, 210 Cauchy data, 18 Cauchy stress tensor, 9, 218, 219, 225, 229, 232, 242, 280 Cauchy’s momentum equation, 10, 219, 250, 255, 273, 334, 360, 386 Cartesian coordinates, 20 cylindrical polar coordinates, 21 Lagrangian form, 220, 263, 268 plane polar coordinates, 335 spherical polar coordinates, 23, 238 Cauchy–Riemann equations, 339, 400 causality, 141 cavitation, 237, 289 cavity, 91, 237, 243
443
Cayley–Hamilton theorem, 223 centroid, 274 ceramic, 379, 427 characteristic, 137, 148, 210, 221, 282, 334, 350 characteristic cone, 137, 148 characteristic polynomial, 222, 223 Christoffel symbols, 430 coal, 117, 146, 330 coarse-graining, 391 coefficient of friction, 320 of reflection, 112, 116, 144, 145 of restitution, 321 of thermal expansion, 389 of transmission, 112, 144 cohesion, 294, 322, 337 compatibility, 54, 68–70, 82, 97, 100, 174, 339, 348 in terms of stress, 72, 100, 101 plane strain, 69, 101 three-dimensional, 69 complementarity conditions, 312, 349, 365 completeness, 61 complex eigenvalues, 60 complex modulus, 419 composite, 378, 391–408 compressibility, 410 cone, 175 characteristic, 137, 148 Mach, 141, 143 two-sheeted, 137, 143 conformal transformation, 291, 295, 298, 322, 323, 325 conjugate function, 298 conservative body force, 65 constitutive relation, 3, 11 Cartesian coordinates, 19 cylindrical polar coordinates, 20 elastic-plastic, 365, 366 for a bar, 152 for a beam, 154, 189, 271 for a plate, 164, 171, 271 for a rod, 160, 161, 196, 276 for a shell, 281 homoclinic, 414 incompressible, 232 isotropic, 12, 225, 241, 402 Jeffreys, 417, 419 linear, 12, 32, 68, 231, 256, 265, 270, 275, 402, 413 Maxwell, 382, 383, 385, 419 Mooney–Rivlin, 232, 234, 236, 387 neo-Hookean, 232, 238, 387 nonlinear, 221–233 objective, 224, 228 Ogden, 232 one-dimensional, 220 orthotropic, 414 spherical polar coordinates, 22 thermoelastic, 389 transversely isotropic, 415
444 Varga, 232 Voigt, 381, 383–385, 418 contact, 287, 309–320 bonded, 18 frictional, 18, 320 of a beam, 313, 325 of a membrane, 316, 326 of a plate, 317 of a string, 309–313 plane strain, 317–320 smooth, 18 contact set, 287, 309 continuum, 3 convected derivative corotational, 388, 420 Jaumann, 388, 420 lower, 387 upper, 387 convective derivative, 358, 376, 387, 388, 419 convolution, 63, 96 coordinates Cartesian, 19–20, 429 curvilinear, 278, 428–439 cylindrical polar, 20–22, 365, 429, 436–438 elliptic, 291 Eulerian, 3, 11, 172, 216, 267, 376, 434 Lagrangian, 3, 11, 172, 188, 196, 216, 218, 219, 267, 376, 434 orthogonal, 19, 278, 428 spherical polar, 22–24, 235, 237, 438–439 copper, 13 corotational derivative, 388, 420 Coulomb friction, 320, 330, 332 Coulomb yield criterion, 333, 335, 353, 357, 372 Coulomb yield surface, 358 crack, 287–309 elliptical, 291, 297, 304, 321 Griffith, 289 Mode I, 304–307, 323, 344 Mode II, 296–304, 344 Mode III, 290–295, 308, 321, 322, 324, 344 penny-shaped, 307 crack face, 288 crack tip, 287, 288, 290, 321, 344 crease, 182, 187 creep, 383 creep function, 383, 386 curl curvilinear coordinates, 432 cylindrical polar coordinates, 437 spherical polar coordinates, 439 tensor, 70, 82, 100 curl curl, 13 curtain rod, 150 curvature, 154, 165, 166, 189, 236, 271, 315 Gaussian, 168, 170, 174, 176, 178, 181, 282 lines of, 278 mean, 168 principal, 168, 174, 279 radius of, 188, 293, 321
Index curvature tensor, 281 curvilinear coordinates, 278, 428–439 custard, 378 cut-and-weld operation, 338, 340 cut-off frequency, 120, 125 cylinder, 175, 178, 183, 281 waves in, 124–128 cylindrical polar coordinates, 20–22, 365, 429, 436–438 d’Alembert solution, 132, 148 damped solid, 382 Darcy’s law, 409 dashpot, 380 Deborah number, 379, 382 deformable porous medium, 408 deformation gradient, 216, 221, 224, 264, 270, 377, 419 del squared, 13 delta-function, 82–84, 88, 133, 139, 149, 167, 206, 315, 339, 421 derivative of, 92 multidimensional, 83 density line, 18, 24, 152 reference, 4, 219 surface, 104, 162 volume, 4, 11, 219, 376 determinant, 119, 126, 128, 146 developable shell, 181, 183, 188 developable surface, 174, 178 deviatoric stress, 354, 363, 369, 375, 386 diamond, 13 diffusion coefficient, 410 diffusion equation, 410 dilatational viscosity, 384 directivity function, 113 Dirichlet problem, 16, 39, 41, 44, 181 disc plane strain in, 51–53 dislocation, 337–344 edge, 342 mixed, 342 screw, 342, 373 virtual, 295, 344 dispersion relation, 110 anisotropic, 417 for a beam, 158 of Love waves, 120, 145 dispersive wave, 111, 119 displacement, 1, 3, 358 linear, 29–37 single-valued, 44, 54, 67, 98, 99 virtual, 26, 176, 209, 232, 313 displacement gradient, 35, 100, 359 dissipation, 2, 361, 364, 419 maximal, 362 distinguished limit, 202, 262 distribution, 83 divergence, 10 curvilinear coordinates, 431, 434
Index cylindrical polar coordinates, 21, 437, 438 spherical polar coordinates, 24, 438, 439 diving board, 187, 190–191, 211 diving cylinder, 53 door slamming, 380 drag, 379, 409 drill, 289 drum, 107, 150 ductile fracture, 289 Duffing equation, 194 dynamic antiplane strain, 117, 135, 308, 324 dynamic fracture, 308, 324 dynamic Love function, 122, 123, 125, 142 dynamic plane strain, 122, 142, 147 in a half-space, 120 earthquake, 114, 121, 308 edge dislocation, 342 eigenfunctions, 61, 96, 107, 157 eigenvalue problem nonlinear, 192 not self-adjoint, 60 eigenvalues, 35, 36, 96, 107, 157, 221, 406 complex, 60 eigenvectors, 35, 222, 225 eikonal equation, 331, 348 elastic energy, 15, 39, 226, 229, 377, 390 elastic fluid, 383 elastic modulus, 3, 32, 413 effective, 399, 401, 404, 409, 423 elastic strain, 364, 377, 384 electromagnetic wave, 104, 137, 404 electromagnetism, 427 electron micrograph, 343 elliptic boundary conditions, 18 elliptic coordinates, 291 elliptic integral, 191, 213 energy bending, 316 conservation of, 14–16, 24, 226–227, 360–362, 391 elastic, 15, 39, 226, 229, 377, 390 kinetic, 15, 226, 360, 390 surface, 289 thermal, 360, 390 energy equation, 361, 391, 420 envelope, 137, 148 equivoluminal wave, 114, 122 Euler differential equation, 52 Euler strut, 192, 210, 212 Euler’s identity, 376 Euler–Bernoulli beam equation, 189 Euler–Lagrange equation, 316 Eulerian coordinates, 3, 11, 172, 216, 267, 376, 434 fabric, 379 ferromagnetism, 427 fibre-reinforced material, 12, 379, 413 Finger tensor, 217, 223, 225, 387, 419 finite element method, 229, 427
445
first fundamental form, 278 first law of thermodynamics, 361, 390 flexural wave, 126, 128, 283 Floquet theory, 405 flow rule, 362–364 associated, 362 Levy–von Mises, 363, 377 non-associated, 362 Tresca, 363, 366 fluid elastic, 383 inviscid, 7, 82, 340, 343, 371 lower convected Maxwell, 387 Maxwell, 386 Newtonian, 364, 386 upper convected Maxwell, 387 viscous, 379, 380, 408 with memory, 383 fluid fraction, 410, 424 food, 330, 378 force balance, 17, 39, 53, 56, 188, 309, 313, 330 Fourier series, 57, 106, 248 Fourier transform, 62, 87, 96, 101, 106, 111, 115, 213, 296 three-dimensional, 99 Fourier’s law of conduction, 391 fracture, 2, 287–309, 426 brittle, 288, 344 ductile, 289 dynamic, 308, 324 frame indifference, 224, 228 Fredholm Alternative, 17 free boundary problem, 287, 310, 334, 349, 350, 365 frequency, 110 cut-off, 120, 125 frequency domain, 105, 404 friction, 320 angle of, 330, 336, 372 coefficient of, 320 Coulomb, 320, 330, 332 Frobenius’ method, 108, 131 fundamental form first, 278 second, 278 fundamental solution, 82, 133–136 one-dimensional, 133 three-dimensional, 136 two-dimensional, 135 Galerkin representation, 78–79 garden hose, 198 gauge invariance Airy stress function, 48, 50 antiplane stress function, 41 Love function, 74 Papkovich–Neuber potentials, 81 Gaussian curvature, 168, 170, 174, 176, 178, 181, 282 generalised function, 83 generator, 175, 178, 183, 188, 282
446
Index
geometric nonlinearity, 11, 151, 172, 174, 188, 215, 231, 262, 282, 386 glass, 13, 150, 169, 353, 378, 391 Goursat representation, 49, 80, 95, 297, 304, 323, 324 grad div, 13 gradient curvilinear coordinates, 431 cylindrical polar coordinates, 437 spherical polar coordinates, 438 granite, 13 granular plasticity, 330–337 Green deformation tensor, 216, 222, 361, 419, 435 left, 217 Green’s function, 88, 140 Green’s tensor, 88–90 plane strain, 89 three-dimensional, 99 Griffith crack, 289 group velocity, 146 guitar, 153 gun barrel, 37, 53, 91, 335, 351 elastic-plastic, 366–368 failure, 55 gyroscope, 198 hair, 150, 213 half-space dynamic plane strain in, 120 plane strain in, 62–65, 86, 317–320 Hankel function, 113 harmonic average, 393 harmonic conjugate, 41, 45, 303, 339, 400, 422 harmonic wave, 110, 113 harmonics, 105, 158 out of tune, 109 heat equation, 391, 411 heat flux, 391 Heaviside function, 134, 207, 373, 421 Helmholtz equation, 107 plane polar coordinates, 109, 144 radially symmetric, 107 two-dimensional, 112 Helmholtz representation, 71, 78 Hilbert transform, 64, 97 inverse, 97 history-dependence, 329 homoclinic material, 414 homogenisation, 379, 391–408, 410, 422–424 three-dimensional, 402–404 two-dimensional, 395–402 Hooke’s law, 2, 12, 152, 380 hoop stress, 55, 68, 99 Hopkinson bar test, 207 Huygens’ principle, 136 hydrostatic stress, 30, 99 hyperboloid, 175 hyperelasticity, 215, 227–230, 361, 427 I-beam, 161
ice cube, 388 ice sheet, 138 impedance, 380, 417 in-plane strain, 34, 171 incidence angle of, 116, 145 incident wave, 112, 115, 207 incompatibility, 70, 72 line, 339, 341 point, 91–92 tensor, 92, 343 incompressibility, 13, 26, 33, 143, 231–232, 343, 359, 363, 386 inertia, 333, 346, 350, 365, 371, 410 inertia tensor, 160, 197, 278 inextensibility, 188, 196, 205, 269, 272 initial-value problem, 132 instability, 158, 195, 211 integral equation, 90, 296, 322 inverse problem, 143, 169–170, 208 inverse scattering, 113, 199 irreversibility, 2, 328, 362 irrotational wave, 114, 122 isometry, 174, 178 isotropic expansion, 29, 30, 389, 420 isotropic invariant, 222 isotropy, 12, 224, 228, 230, 241, 353 Jacobian, 4, 11, 218, 231, 376, 428 Jaumann derivative, 388, 420 Jeffreys constitutive relation, 417, 419 Jeffreys creep function, 418 Jeffreys element, 417, 419 KdV equation, 204, 214 kinetic energy, 15, 226, 360, 390 kink, 200 Kirchhoff analogy, 198 knot, 321 Kronecker delta, 12 L¨ u ders bands, 368–370 ladder, 320 Lagrange multiplier, 26, 95, 231, 362 Lagrangian coordinates, 3, 11, 172, 188, 196, 216, 218, 219, 267, 376, 434 Lam´e constants, 12, 13, 29, 32, 230, 338, 384, 389, 409 Lam´e equation, 13 Laplace’s equation, 38, 79, 93, 258, 276, 290, 399, 416 general solution, 48, 94 Laplacian curvilinear coordinates, 432 cylindrical polar coordinates, 21, 437 spherical polar coordinates, 24, 438 two-dimensional, 104 lawn-mower, 214 left Green deformation tensor, 217 Legendre polynomial, 131 Levi–Civita symbol, 82, 100
Index Levy–von Mises flow rule, 363, 377 line density, 18, 24, 152 linear displacement, 29–37 linear elasticity, 11–13, 230 lines of curvature, 278 Liouville’s theorem, 299 longitudinal wave, 114, 115, 125, 151, 207, 221, 283 loss modulus, 419 Love function, 82 axisymmetric, 76–78, 100 dynamic, 122, 123, 125, 142 plane strain, 73–74, 78, 84, 86 uniqueness, 74 Love wave, 117–120, 145, 417 lower convected derivative, 387 lower convected Maxwell fluid, 387 Mach cone, 141, 143 Mach number, 140, 142, 201 mass conservation of, 4, 359, 376, 410, 425 matching condition, 61, 248, 256 material symmetry, 413 matrix monodromy, 406, 424 orthogonal, 6, 9, 12, 35, 37, 216, 217, 221, 223, 224, 240, 241, 413 positive definite, 221, 413 maximal dissipation, 362 maximum shear stress, 37, 55, 85, 95, 301, 306, 354 Maxwell constitutive relation, 382, 383, 385, 419 Maxwell creep function, 383, 418 Maxwell element, 382, 383 Maxwell fluid, 386 Maxwell stress functions, 81–82 Maxwell’s equations, 137 mean curvature, 168 mechanical linearity, 174, 188, 215, 220, 231, 265, 270 membrane, 39, 93, 104, 135, 140, 150, 165, 234, 235, 262 contact, 316, 326 metal plasticity, 337–370 method of images, 86 method of multiple scales, 393, 396, 403, 407, 423 Miura transform, 214 mixed dislocation, 342 mode conversion, 103, 115–117 Mode I crack, 304–307, 323, 344 Mode II crack, 296–304, 344 Mode III crack, 290–295, 308, 321, 322, 324, 344 modified KdV equation, 204, 214 modulus of compression, 30 Mohr circle, 333, 350 Mohr surface, 373
447
moment balance, 9, 17, 26, 56, 154, 159, 162, 163, 188, 198, 313 moment of inertia, 154, 155 momentum conservation of, 10–11, 219–220, 360 momentum equation, 10, 219, 250, 255, 273, 334, 360, 386 Cartesian coordinates, 20 cylindrical polar coordinates, 21 Lagrangian form, 220, 263, 268 plane polar coordinates, 335 spherical polar coordinates, 23, 238 Monge–Amp`ere equation, 174, 209, 334, 350 inhomogeneous, 178 monodromy matrix, 406, 424 Mooney–Rivlin constitutive relation, 232, 234, 236, 387 Morera stress functions, 81–82 moving source, 138–143, 149 multi-scaling, 391 multiple scales method of, 393, 396, 403, 407, 423 multiply-connected domains, 42–47, 53–56, 67 musical instruments, 105 natural boundary conditions, 26, 39, 167, 168, 209 natural frequencies of a drum, 108 of a membrane, 107, 143 of a piano string, 205 of a sphere, 130 of a string, 105 Navier equation, 13, 137 anisotropic, 416 axisymmetric, 76 Cartesian coordinates, 20 cylindrical polar coordinates, 21 general solution, 115 incompressible, 26 poroelastic, 409 spherical polar coordinates, 23 steady, 16, 29 steady plane strain, 47 thermoelastic, 389 unsteady, 113 neo-Hookean constitutive relation, 232, 238, 387 Neumann problem, 17, 39, 40, 259, 276, 290 Newton’s second law, 8, 10, 151, 153, 158, 162, 219 Newton’s third law, 7 non-associated flow rule, 362 non-contact set, 309 non-destructive testing, 143 non-dimensionalisation, 180, 193, 202, 246, 249, 262, 267, 273, 279, 393, 404, 421 non-dispersive wave, 111 nonlinear beam equation, 189 nonlinear wave, 198–204, 220–221 normal modes, 104–109
448
Index
of a membrane, 107 of a string, 105 superposition, 106 normal reaction, 330 normal stress, 37, 332, 372 nucleus of strain, 92, 102 objectivity, 217, 224, 228, 388 obstacle, 309 Ogden constitutive relation, 232 oil reservoir, 408 orthogonal coordinates, 19, 278, 428 orthogonal matrix, 6, 9, 12, 35, 37, 216, 217, 221, 223, 224, 240, 241, 413 orthotropic material, 414 outer product, 430 π-plane, 355 P -wave, 103, 114, 221, 417 reflection, 115 P´eclet number, 412 pantograph, 138 paper, 150, 160, 165, 174, 183 paper clip, 2, 198, 328, 359, 360, 371 paper model, 33, 93 Papkovich–Neuber potentials, 79–81, 87, 296, 301, 305, 340, 344, 373 antiplane strain, 80 plane strain, 80, 100 uniquness, 81 partial differential equation change of type, 153, 170, 334, 349 completely integrable, 199 discriminant, 170, 181 elliptic, 16, 140, 143, 155, 179, 181, 282, 334, 399 hyperbolic, 137, 140, 155, 170, 179, 181, 282, 334, 346, 350, 372 mixed type, 143, 170 parabolic, 178, 282 quasi-linear, 209 pass band, 406 pendulum, 190, 198 penny-shaped crack, 307 perfect plasticity, 328, 331, 334, 344–357 periodic cell, 393, 397, 403, 422 permanent strain, 328, 348, 374, 385 permeability, 409 phase change, 426 phase velocity, 110 piano, 109, 158, 205 piezoelectricity, 427 ping-pong ball, 150, 186 Piola–Kirchhoff stress tensor, 218–219 first, 219, 227, 263, 264, 268 second, 219, 224, 225, 228, 242, 265 pitchfork bifurcation, 195 plane polar coordinates, 27 plane strain, 35, 47–68, 71–74, 80, 84, 99, 165, 171, 296, 297, 304, 340, 375 contact, 317–320
dynamic, 120, 122, 142, 147 elastic-plastic, 350–353 in a disc, 51–53 in a half-space, 62–65, 86, 317–320 in a rectangle, 56–58 in a strip, 58–62 in an annulus, 53–56 with a body force, 65–68 yield criterion, 350, 376 plane stress, 74–76, 99, 155, 159, 163, 368 plane wave, 110–111, 137 plastic bottle, 184 plastic flow, 2 plastic strain, 364, 370 plastic yield, 37, 85, 294 plasticity, 289, 328–377, 379, 426 granular, 330–337 metal, 337–370 perfect, 328, 331, 334, 344–357 plate, 33–35, 150, 368 antiplane strain in, 246–248, 283 boundary conditions, 166–168, 171, 176, 208, 253–261 circular, 168, 208 constitutive relation, 164, 171, 271 contact, 317 linear, 162–171, 248–253 nonlinear, 267–273 rectangular, 169 strain energy density, 168, 176, 209 strain in, 173 von K´ a rm´a n, 172–176, 261–267 plate equation linear, 165, 171, 253 von K´ a rm´ a n, 176, 267 point force in a half-space, 86 on a half-space, 87 plane strain, 84, 101 three-dimensional, 85, 100 point incompatibility, 91–92 Poisson’s equation, 41, 79, 140, 316, 345 singular solutions, 84 Poisson’s ratio, 32, 165, 384, 390 negative, 33, 55, 93 polar decomposition, 221, 241 polarised wave, 114 polystyrene, 13 pore pressure, 409 poroelasticity, 2, 379, 408–412, 424–425 positive definite matrix, 221, 413 Prandtl–Reuss model, 370 pre-stressed material, 12 pressure, 14, 30, 231, 354, 375, 386 hydrostatic, 232 pore, 409 pressure wave, 114 primary wave, 114 principal axes, 35, 36, 160, 197 principal curvature, 168, 174, 279 principal direction, 35, 175, 222
Index principal strain, 35, 222, 230 principal stress, 36, 55, 85, 95, 229, 234, 242, 332, 354, 363, 372 principal stretch, 222, 230 principal value integral, 64, 97, 322 punch, 317 quadratic form, 5 quantum mechanics, 130 quasi-static problem, 93 radiation condition, 112 radius of curvature, 293, 321 railway track, 378, 390 underground, 66 rate-of-strain tensor, 359, 363, 377, 386 Rayleigh wave, 120–121, 146 razor blade, 214 reaction force, 206, 312, 315, 317 rectangle plane strain in, 56–58 reference density, 4, 219 reference state, 1, 3, 215, 216, 222, 389 reflected wave, 116, 207 reflection angle of, 116, 145 of a P -wave, 115 of an S -wave, 144 specular, 116 total internal, 117, 145 reflection coefficient, 112, 116, 144, 145 region of influence, 179, 334 relaxation time, 381, 382, 384, 417 residual stress, 12, 348, 352 response diagram, 192, 195, 212, 213, 235 retarded potential, 136 Reynolds’ transport theorem, 376 rheological test, 419 Riemann function, 133 Riemann zeta function, 94 rigid-body motion, 6, 17, 25, 35, 48, 174, 216, 217, 223, 224, 228, 231, 239, 302, 403 small, 12 unsteady, 388 rivet, 287 Robin problem, 27 rock, 117, 334, 379 rod, 150 boundary conditions, 160 constitutive relation, 160, 161, 196, 276 linear, 158–162, 196, 273–278, 283, 285 nonlinear, 195–198 rod equation linear, 160 rope, 200, 321, 326 rotation tensor, 388 rubber, 13, 14, 215, 227, 237, 410 rubber band, 2, 198 ruled surface, 175 ruler, 150, 154, 325
449
S -wave, 103, 114, 417 reflection, 144 S H -wave, 118 S V -wave, 118 Saint-Venant’s principle, 62, 156, 167, 253–261 sand, 330, 372 sausage Belgian, 53 scaling factors, 279, 428 cylindrical polar coordinates, 429 spherical polar coordinates, 438 scattering, 111–113, 144 Schr¨ o dinger equation, 155 screw dislocation, 342, 373 second fundamental form, 278 second law of thermodynamics, 362 secondary wave, 114 secular term, 408 seismology, 111, 114, 121 self-stress, 92, 339, 341 separable solution, 52, 57, 95, 109, 124, 169, 248, 260, 291, 412 non-orthogonal, 58, 61, 169 shape memory alloy, 427 shaped charge, 289, 371 shear force in a beam, 153, 189 in a plate, 162, 167, 251, 263, 271 in a rod, 158, 274 in plane strain, 61 shear modulus, 12, 31 shear stress, 37, 332, 344, 350, 372, 375 maximum, 37, 55, 85, 95, 301, 306, 354 shear viscosity, 384 shear wave, 114 shell, 150, 161, 278–282 anticlastic, 181, 184 constitutive relation, 281 cylindrical, 285 developable, 181, 183, 188 spherical, 285 strain in, 178 synclastic, 181, 185 thin, 180–187 weakly curved, 177–187, 209, 284 shell equations, 280 weakly nonlinear, 179 shock absorber, 380 shock wave, 221, 309 silly putty, 378, 383 simple shear, 30, 31, 36, 302 sine–Gordon equation, 199 slenderness parameter, 245, 246, 249, 262, 273 slip plane, 342 slip surface, 332, 350 soil, 379 solid fraction, 410, 424 soliton, 199 solvability condition, 17, 39, 40, 53, 194, 247, 259, 283 Sommerfeld radiation condition, 112
450
Index
sonic boom, 141 source moving, 138–143, 149 spaghetti, 208 specific heat capacity, 361, 390 specular reflection, 116 sphere waves in, 128–132, 147 spherical harmonics, 130 spherical polar coordinates, 22–24, 235, 237, 438–439 spinning top, 198 sponge, 379, 408, 410, 411 spoon, 330 spring, 2, 15, 24, 380 spring constant, 2, 24, 380, 417 St¨ u rm–Liouville problem, 60 steel, 13, 420, 426 step function, 134 stop band, 406, 408, 424 storage modulus, 419 strain, 3–6, 216–217 antiplane, 37–39, 80, 246–248, 258, 283, 290, 338, 395 biaxial, 33–35, 76, 171, 234 Cartesian coordinates, 19 curvilinear coordinates, 434–436 cylindrical polar coordinates, 20, 437 elastic, 364, 377, 384 in a plate, 173 in a shell, 178 in-plane, 34, 171 permanent, 328, 348, 374, 385 plane, 35, 47–68, 71–74, 80, 84, 99, 165, 171, 296, 297, 304, 317–320, 340, 350–353, 375 plastic, 364, 370 principal, 35, 222, 230 spherical polar coordinates, 23, 439 surface, 281 viscous, 384 strain energy density, 15, 16, 26, 39, 227, 289, 318, 361, 377, 391, 413, 427 convexity, 15, 26, 33, 230 in a plate, 168, 176, 209 isotropic, 228 Mooney–Rivlin, 232 neo-Hookean, 232, 238 objective, 228 Ogden, 232 plane strain, 50 quasi-convexity, 229 thermoelastic, 420 Varga, 232 strain invariant, 222–223, 228, 231, 234, 242 strain tensor, 6, 12, 25, 217, 270, 284, 359 linear, 35 linearised, 11, 35, 239, 436 stream function, 41 stress, 7–10 deviatoric, 354, 363, 369, 375, 386
hoop, 55, 68, 99 maximum shear, 37, 55, 85, 95, 301, 306, 354 normal, 37, 332, 372 plane, 74–76, 99, 155, 159, 163, 368 principal, 36, 55, 85, 95, 229, 234, 242, 332, 354, 363, 372 residual, 12, 348, 352 shear, 37, 332, 344, 350, 372, 375 thermal, 390 uniaxial, 30–34, 233, 242, 277, 356, 368, 389 viscous, 384 yield, 37, 55, 328, 338, 343, 345, 370, 379 stress deviator, 354, 363, 369, 375, 386 stress function, see stress potential stress intensity factor, 287, 307 dynamic, 308 Mode I, 305 Mode II, 301 Mode III, 295, 325 stress invariant, 333 stress potential, 70–82 Airy, 47–68, 71, 82, 171, 176, 179, 252, 264, 297, 304, 307, 323, 334, 341, 350, 374 antiplane, 41, 82, 97, 339, 345 dynamic, 121–123, 147 Galerkin, 78–79 Goursat, 49, 80, 95, 297, 304, 323, 324 Helmholtz, 71, 78 Love, 73–74, 76–78, 82, 84, 86, 100, 122, 123, 125, 142 Maxwell, 81–82 Morera, 81–82 Papkovich–Neuber, 79–81, 87, 296, 301, 305, 340, 344, 373 plane stress, 76 stress tensor, 12 antiplane, 38 Cauchy, 9, 218, 219, 225, 229, 232, 242, 280 curvilinear coordinates, 436 Piola–Kirchhoff, 218–219 plane strain, 47 stretch, 5, 217, 222 of a plate, 273 principal, 222, 230 string, 18, 104, 112, 134, 139, 150, 152–153, 210 contact, 309–313 normal modes, 105 strip antiplane strain in, 247 plane strain in, 58–62 subsonic motion, 140, 143, 309 subsonic wave, 200 sugar, 330 summation convention, 5 supersonic motion, 140, 143, 309 surface anticlastic, 179 developable, 174, 178 ruled, 175 synclastic, 179
Index surface density, 104, 162 surface energy, 289, 294 surface gradient, 281 surface strain, 281 surface tension, 289 synclastic shell, 181, 185 synclastic surface, 179 table circular, 372 elliptical, 372 rectangular, 372 Taylor expansion, 35 temperature, 360, 389, 420 tension anisotropic, 171 in a bar, 32, 151 in a beam, 153, 189 in a membrane, 93, 104 in a plate, 34, 162, 171, 251, 252, 263, 266, 271, 273 in a rod, 158, 274, 277 in a spring, 2, 380 in a string, 18, 104, 152 in plane strain, 61 isotropic, 166, 171 tensor, 6 in curvilinear coordinates, 430 Terzaghi principle, 409 test function, 83, 92 thermal conductivity, 361, 391 thermal diffusivity, 391 thermal energy, 360, 390 thermal stress, 390 thermoelasticity, 2, 378, 388–391, 420–422 time domain, 132 tomography, 111, 143 topology, 42, 47 torque, 40, 41, 159, 161, 274, 346, 374 torsion, 39–42, 161, 198, 276 elastic-plastic, 344–349, 365–366, 374 torsion bar, 39 annular, 44 cut annular, 46, 94 elliptical, 93 multiply-connected, 42 orthotropic, 415 torsional rigidity, 40, 42, 162, 276 circular bar, 42, 94 circular tube, 45 cut tube, 47, 94 elliptical bar, 93 mutliply-connected bar, 43 orthotropic bar, 416 thin tube, 46 torsional wave, 124, 130, 147, 162, 198–200, 283 total internal reflection, 117, 145 trace, 36, 406, 424 traction, 7, 38 train, 138
451
transmission coefficient, 112, 144 transonic motion, 143 transverse wave, 114, 116, 152, 154 transversely isotropic material, 415 Tresca flow rule, 363, 366 Tresca yield criterion, 37, 55, 354 Tresca yield function, 354, 363 Tresca yield surface, 355 triaxial stress factor, 335 tube, 44, 183, 243 tunnel, 66, 98, 334 twist, 40, 161, 196, 197, 345 ultrasonic testing, 111 underground railway, 66 uniaxial stress, 30–34, 233, 242, 277, 356, 368, 389 uniqueness, 16–18, 229, 291, 311 Airy stress function, 48, 50 antiplane stress function, 41 Love function, 74 Papkovich–Neuber potentials, 81 plane strain, 50 Robin problem, 27 upper convected derivative, 387 upper convected Maxwell fluid, 387 Varga constitutive relation, 232 variational inequality, 313, 325, 349 velocity, 1, 358, 386, 409 velocity gradient, 419 violin, 109 virtual dislocation, 295, 344 virtual displacement, 26, 176, 209, 232, 313 viscoelasticity, 2, 329, 378–388, 417–420, 426 large-strain, 386–388 linear, 384 one-dimensional, 384 three-dimensional, 384–386 viscosity, 364, 409 dilatational, 384 shear, 384, 386 viscous strain, 384 viscous stress, 384 Voigt constitutive relation, 381, 383–385, 418 Voigt creep function, 383, 418 Voigt element, 381, 383 volume density, 4, 11, 219, 376 volume flux, 411 von K´ a rm´ a n plate, 172–176, 261–267 von Mises yield criterion, 369 von Mises yield function, 356, 363 von Mises yield surface, 356 von K´ a rm´ a n plate equations, 176, 267 vortex, 82, 340, 343, 344 wave anisotropic, 416 dispersive, 111, 119, 417 electromagnetic, 104, 137, 404 equivoluminal, 114, 122
452
Index
flexural, 126, 128, 283 harmonic, 110, 113 in a bar, 104 in a cylinder, 124–128 in a periodic medium, 404–408, 423–424 in a sphere, 128–132, 147 incident, 112, 115, 207 irrotational, 114, 122 longitudinal, 104, 114, 115, 125, 151, 207, 221, 283 Love, 117–120, 145, 417 non-dispersive, 111 nonlinear, 198–204, 220–221 on a beam, 158, 417 P -, 103, 114, 221, 417 plane, 110–111, 137 polarised, 114 pressure, 114 primary, 114 Rayleigh, 120–121, 146 reflected, 116, 207 S -, 103, 114, 417 S H -, 118 S V -, 118 secondary, 114 shear, 114 shock, 221, 309 subsonic, 200 torsional, 124, 130, 147, 162, 198–200, 283 transverse, 114, 116, 152, 154 wave equation axially symmetric, 148 general solution, 104, 111, 132, 136, 147 inhomogeneous, 122 one-dimensional, 18, 104, 132, 133, 149, 152, 162 radially symmetric, 136 three-dimensional, 104, 111 two-dimensional, 104, 107, 110, 117, 135 wave-front, 137 wave-guide, 118, 125 wave-length, 110, 404 wave-number, 110 wave-vector, 110 weakly nonlinear theory, 194, 202, 262 well-posedness, 16–18, 153, 181, 230, 239, 349 Wiener–Hopf method, 296 windscreen, 169–170, 289 WKBJ method, 144 wood, 12, 379, 413 work hardening, 328, 344, 370 Wronskian, 405 yield criterion antiplane strain, 345 Coulomb, 333, 335, 353, 357, 372 plane strain, 350, 376 three-dimensional, 353–357 Tresca, 37, 55, 354 von Mises, 369 yield function, 353, 362
isotropic, 353 Tresca, 354, 363 von Mises, 356, 363 yield stress, 37, 55, 328, 338, 343, 345, 370, 379 yield surface Coulomb, 358 Tresca, 355 von Mises, 356 Young’s modulus, 32, 152, 205, 390 composite, 392, 423 effective, 393, 395, 423 periodic, 406