Chemical Reaction and Reactor Engineering (Chemical Industries)

J

J

Cj ,N+l

AN+1, N+l

d

= 1' 2, .

0

A N+1 ,i

b. J

=

Cj ,N+1

Bi y M b 2d

, N

( 71)

+

Equation ( 71) is particularly well suited for solution by Newton's method since the nonlinearities appear only in the main diagonal of the Jacobian, while the remaining elements are constants = Cj1· When the catalyst pellet model is solved as part of a fixed-bed reactor simulation, all that is needed is the flux of reactant at the pellet surface or equivalently the average rate of reaction on the pellet:

n = pellet effectiveness factor

=

( 72)

where R(yb) is the rate taken at bulk-phase conditions. The appendixes of Villadsen and Michelsen ( 1978 ) contain a well-tested (nonproprietary) package of subroutines that can be arranged to solve pellet simulation problems as exemplified by Eqs. (69) to (72) . Other programs are published in Finlayson ( 1 98 0) . In general, these programs can be expected to work well as long as the pellet profile y(u) can be reasonably well approximated by a polynomial. A severe diffusion resistance (i.e. , the case where most of the pellet is inactive) is perhaps better solved using other methods (e. g., asymptotic methods), but collocation variants that treat these situations have also been developed. Some com­ ments on these methods are given below. Spline collocation [or "collocation on finite elements" in the nomenclature of Finlayson (19 8 0 ) ] combines the property of finite-difference methods to represent a rapidly varying function by a series of connected curve seg­ ments with the accurate approximation of the function within each interval by interpolation based on orthogonal polynomials.

21

N umerical Methods in Reaction Engineering

-

The interval 0 ..;; x ..;; 1 is divided into subintervals. Collocation is 1 spline point ordinates are de­ applied to each subinterval and the M termined by extra equations that impose continuity of the first derivative of y(x) at each spline point. With Nk collocation points in the interval of length ok to the left of spline point k and Nk+1 collocation points in the interval of length ok+l to the right of spline point k, one obtains

_!_(t o

k

1

k

)

y y + A( ) A(k) N +1,i i Nk +1,Nk+1 s k

=

_ _1 ok+l

(N�+l (k)

2

A

)(73)

(k+l) +A (k+l) y 1 , 1 Ys i 1,i

(k+1) and ft are discretiza­ where Ys is the spline point ordinate and � of the right the to and left the to derivative first the for tion matrices spline point respectively. The collocation equations are written up for each subinterval and the + NM-1 + NM colloca­ final collocation procedure with N = N 1 + N 2 + 1 algebraic equations with a pronounced tion points becomes a set of N + M diagonal block structure. The diagonal elements of Q* and of � are usually larger than the other elements, which means -that the spline point equations may retain their position, and factorization of the coefficient matrix can be done block by bloc k, with a resulting reduction of computa­ tional effort. Quite often, one spline point may be enough to represent an outer pellet region with rapid reaction followed by an inner, almost inactive re­ gion. In recent publications these "penetration front" problems have frequently been solved by one-point spline collocation (typical examples are transient gas-solid reactions where the gaseous reactant is used up in an outer core of the pellet until the solid reactant concentration has de­ creased appreciably). The original idea derives from Patterson and Cresswell ( 197 1) , who proposed to equate y and the derivative of y to zero at the spline point Us (or Xs) and determine the spline point position and the effectiveness factor by collocation in the outer interval. An improvement was suggested in Villadsen and Michelsen (1978, Chap. Here only the derivative of y was equated to zero at Xs, while the position of xs was chosen somewhat arbitrarily (e. g., by solution of a linearized problem). For a first-order irreversible, exothermic reaction on spheres, one obtains

-

•

•

•

7).

y (x) 1

=

sinh A x -�--=:-"r'-xsinh A x r

(74)

if the linearization of R(y) is made at y = 0, which is quite reasonable when the major part of the catalyst pellet is inactive. The spline point may be chosen as the x value where Y 1 (x) = 0. 05yb, and collocation with N = 5 6 in the interval <xs, 1 ) usually gives an excellent value for the true flux at the pellet surface, at least if the solution y(x) in the truncated interval satisfies y(xs> < 0.05yb. If the original interval is split up into only two parts with Na collocation points to the left of Xs and Nb collocation points to the right of Xs, it is not Na + Nb collocation ordinates difficult to express Ys is terms of the N and y (x = 1). Explicit formulas are given in Holk-Nielsen and Villadsen

-

==

22

Villadsen and Michelsen

. ( 19 8 3 ) and t h eir final met hod is indist inguis hable from a global collocation solution of order Na + Nb . Hyperbolic c ollocation is another variant of collocation , which is specific­ ally develop e d to treat the wedge - shaped profiles associated with near­ asymptot ic behav ior of the pellet model . T hi s met hod was originally pro­ p osed by Guertin et al . ( 1977) for one - dimensional hom ogeneous reactor prob lems when thes e are s olved by collocation, applied to the t otal reactor T he method is fully developed and e xplained in Sdlrensen and length. Stewart ( 19 8 2 ) and Sdlrensen ( 198 2 ) . The rate expres s ion for M key sp ecies may be expanded from a refer­ e nce state X.R [as exemplified in Eq . ( 74)]:

!!.

<x.>

=

> < !!. x.R

a��

Cl R +

<�

( 75)

X,R

T his gives a linearized vers ion of Eq . ( 64) :

vx_-lix.=£ 2

Jij

i:lR

=

i 2
l

(76)

X.R

whic h may be solved by standard methods, analogously to Eqs . ( 17) to ( 2 2) , as a linear c omb ination of sinh ( >-r x ) /x ( for spherical geometry and >-r distinct and nonzero) . T he eigenvalues of 11 are and >-r = I 1\ r I are used to c onstruct the app r oximati on functions . If there are many independent reactions, the >-r may give a sufficient numb er of approxi mation functions sinh ( >-r x > /x to prov ide an accurate ap­ If the number of independent reac tions is small ( there prox imat ion for r_. may be only one react ion) , the hyperb olic approximation functions are augmented by ne w funct ions w hich appear by differentiati on of the original set with respec t to "r · For typical p ellet problems, S.Prensen ( 198 2) sug­ . gests ( 1 - x 2 )J, j 1 , 2 , . . . , as multipliers in the higher approx ima­ ti on functions . Wh en >-r < 0.5, the hyperb olic funct ions are easily repre­ s ented by low-order p olyn"o m ials, and hyp erb olic c ollocation merges into the better known polynomial collocation method; but clearly the met hod is a valuable generalization of t he original collocation met hod , since the ap ­ proximate s olution is b ase d on t he structure of the individual p roblem , rather t han on a fixed set of app r oximation functions . Sdlrensen and Stewart ( 1 9 8 2 ) and S.Prensen ( 1 9 8 2 ) illustrate the applica­ tion of hyperbolic coll ocation on s ome very c omplicated p rob lems , and the literature contains num erous examples of the app lication of high - order p oly ­ Consequently, we s hall be content wi th two illustrations . nomial c ollocation . In the firs t illustration the one-point collocation method is discussed as a valuable link between heterogeneous m odels and homogeneous models for reactors (e . g., a stirre d - tank approximation for a pellet ) . In the second illustration collocation is applied to s olve the pellet equations in a fixed - b ed reactor m odel .

1\;

=

Numerical Methods in Reaction Engineering Example 4 One-Point collocation Consider a first-order exothermic reaction on catalyst pellets, and let the pellet model ( 6 4 ) to ( 6 8) be ap­ proximated by one interior interpolation point at (UloYl):

-C [y(l) 1

where 01

- y 1] =

y q, l

!3y =constant= 1

+

[Y ( J] 1 1- 0

exp

2

0(1)

( )

d y 2 du 0 u=1

+

qy ( --q0\

where q 2/( 1 - u1) Equations ( 78) and (79) with Yb El (1), y(1) in terms of Y1: =

0(1)

(77)

!3y(1)

=

=

0b

q ( l)

y

+ +

23

)

(78)

=

qEl(l)

y(l)) El

)

( 1))

( 79)

= 1

are used to express

01

and ( 80)

=

(81)

Now the collocation equation

is simplified to

( 77)

[

-C1( 1- y1) = (�*)2y 1 exp ys* 2 (� * ) R * (y )

-

1 +

:* < ; :_

y1)

]=

(82)

1

s*

=

e

�-=--

1 + q/Bi H

q / B iM

--

1 +

and

Finally, n

=

/1 0

R( )

�

R(y ) b

dxs +1

==

�*

=

1

(1 �) /2 +

B1

q,

(83)

M

1 / y exp 0

( 84)

The left half of Table 1 shows the values of the collocation constants which are needed to construct a one-point collocation solution of (s-1)/2)(u), where sis the geometry u is the zero of P1(01 Eq. (77). 1 factor. (u1,-c1 )

24

Villadsen and Mich elsen

TABLE 1

Parameters for O n e - Point C ollocation

Bi

s

u

0

1 /3

1

2

H

Bi

' Bi finite M

-c

H

-c

B '

\i

+

w

00

w

2

q

u

3

3

1/5

5/ 2

5/6

1/6

1/2

8

4

1 /3

6

3/4

1 /4

3/5

15

5

3/7

7 / 10

3 / 10

1

1

1

1

21 / 2

1

( l ( s l ) / 2) u I n t he specific ca s e Bi H BiM + oo , t h e zero of P 1 , ( ) is pr efe r re d an d n is app roxi m ated by a more accurate t wo poin t quadrat ur e for mu la : ==

-

n

=

wl

R(y ) 1 R(y

b

)

+

w2

( 8 5)

C onstants for t hi s s p ecific situation ( from Villadsen and Michelsen , 1 9 7 8 , C h ap . 5) are shown on the right h an d side of T able 1 . Equation ( 8 2 ) is an approximate s olu tion of the ge n er al catalyst pellet pro b l e m . T here is only one unknown ( y 1 ) , and the form of the equation A is the s ame as one would obtain fr o m a stirred-tank reactor m odel gr ap hic al or alge b rai c solution can be fou n d for an y v alue of t he param­ eters, but t he solution is r easonabl e only w hen y ( u ) can be repr es en t e d by a fair l y l o w o r der p oly n om ial N ote in Eq . ( 8 3 ) that the original S [ = c r ( - li H )D /k T r ] is modified by a fac t o r that can be very la r ge when B i H is s m all . Typical values of B i H and BiM in a fixed bed reactor ar e 2 an d 4 0 , respectively (an in dustrial S0 2 converter) and with sp h eric al catalyst p artic le s , Eq. ( 8 3 ) predic t s amplification by a factor 3 . 1 1 . T he applic a tion of Eq . ( 8 2 ) will be illustrated by t w o n um e ric al exam ­ ples . First con si der the trivial case of a firs t - order i sot herm al reaction with BiH = BiM + oo on s phe rical pellets . The collocation equation has the e xplici t s ol ution -

.

.

-

21

and

n

=

21

7

10

21 + 2
3 + 10

2

( 86 )

cp = 1 , one ob t ain s n = 0 . 9391 3 , which t o the first four fi gur es agrees with the exact solution n = 3 / cp 2 ( cp c oth cp 1) = 0 . 9 3 91 1 . A lso , at the much hi gher value cp 4 , on e obtains a good approximation

For

-

to n :

cp = 4 :

=

y(*)

=

0 . 396 2

and

n = 0 . 577


exac

t

=

0 . 563)

W hen

t h e ge ner al

25

N umerical M e thods in R eac t io n Engineering n

=

J=r

1 n+ 1

,f,

-1

-

12

n+3

'I'

2

( 87)

w hi c h give s n = 0 . 56 2 5 for n = 1 and

= 0. 05,

y = 30 ,

BiH = 2 ,

and B �

= 40

( 88)

The curve marked " e " on Fi g . 1 is the " exact" sol ution n versus

log 'I

FI GURE 1 Effectiveness fac to r n v ers us Thiele modulus

0 ( 1 ) ; Bi u calc ulatea from Eqs . ( 91) and ( 9 2) . ==

8

P

26

Villadsen and Mic helsen

T he lower branch of the n versus ¢ curve is well approxi mated by one- point collocation ( curve marked " c " on Fig. 1 ) . For exam ple , at point A , w here ¢ 2 1 . 2 , one obtains ( ¢ * ) 2 :;;: 1 . 3 5 , and insertin g the modified 0 . 1 5 5 5 ] in Eq . ( 8 2) , one obtain s y 1 = 0 . 8 46 8 value of 6 [ S * :;;: 0 . 0 5 28 /9 an d n "' R ( y 1 ) = 1 . 7 0 2 , which may be compared w ith t h e exact result , 1 . 683. T he value of 0 1 = 1 . 0 2 3 8 , while 0 ( 1 ) is 1 . 0 1 7 0 . One- point colloca­ tion breaks down near the first bifurcation poin t , where the p arabolic ap­ p roximation for the concentration profile insi de t he pellet becomes very poor . There is another model app roximation t hat appears to give remarkably good res ults . T he energy balance ( 6 5) is inte grated over the pellet volume , and if 13 is small , one may ass um e that the pellet is nearly isothermal , in which case the first - order rate exp ression can be inte grated analytically to give the ri ght- han d si de of Eq . ( 8 9) : =

=

•

Bi [ 0 ( 1 ) - 1 ] = SBi H M

¢ 1 coth cp 1 - 1

'1' 1 coth A,

cp 1 + Bl.

M

_

1

( 8 9)

( 90) and e is a representative pellet temperature . p l f w e are on t he upper branch of the n v er s us cp c urve of Fi g . 1, the pellet temperature is so far above the bulk temperature 1 that the reaction is c ompl et e in a thin boundary la ye r . H ere the representative pellet tem ­ perature 0 s hould be equated to 0 ( 1 ) and ( 8 9 ) is an equation to deter­

p mine 0 ( 1 ) 0p. On the lower branch of t he curve , most of the reaction occurs in the 1 . 2 illus trates the difference b e twe e n bulk of the pellet . The case cp 2 0 ( 1 ) = 1 . 01 7 an d G p , which in the one- p oint collocation approximation is taken to be e 1 = 1 . 0 2 3 8 . I n Villadsen and M ic he l s en ( 1 978 , p . 2 8 and C hap . 6) it i s shown t hat the factor 0 { 1) - 1 on the left - h an d side of Eq . ( 8 9) can be replaced by the larger fact o r 0 p - 1 if at the same time BiM is replaced by a s maller , modified value BiH defined by =

=

Bi [ 0 ( 1 ) - 1 ] H

:::

( 91 )

Bi ( S - 1) H

where Bi H is foun d by pert urbation analysis t o be

1

-­ ex =

s + 3

s = 0 , 1 , or 2

( 9 2)

Thus , also for a modest reaction r ate , one obtains an algebraic equation for the representative pellet temperature 0 p . W hether 0 p is taken to be 0 ( 1 ) or the left -hand side of Eq . ( 89) is replaced by Eq . ( 9 1 ) to deter­ mine a 0 p > 0 ( 1 ) , the effectiveness factor is calculated by 3Bi

11 =

7M

cp

1

coth cp 1 - 1

cp 1 cot h cp 1

+

BiM - 1

( 93)

27

N umerical M e t ho ds in Reac tion E ngi neering For 0 p cot h
larger than "' 1 . 2 , one obtains values of

( 94 )

which is easily differentiated to obtain ( G p , cf> ) at the point w here dcp /dE> p 0 ( i . e . , at the upper "nose" of the n versus

obtains

d d0 p

=

0

Also ,

�

d0 p

at 0 p

0 at 0

=

p

1 . 7 2 91

=


= 1. 765

=

0 . 1970

and

and

n

=

( 9 5)

2310

n = 2366

For practical applications of the present model all that is really needed is calculated from very simple formulas ; by one - p oin t collocation , or the ap­ proximation Eqs . ( 8 9 ) and ( 91) to ( 93) , the lower b r anc h of the n versus

The ca talytic reaction

carried out in a reac to r with a given space time 'o VcA o iFA O · The conversion A is xA = 1 - CAs / cA O • while the conversion to B is xB cB s lc A o• cAs and cB s are fluid-phase concentrations of A and B at a given position in the reactor . Inside the catalyst particle the reactan t concentrations are c A and cB , respectively. The effective diffus ivity D is the same for A and B I t is desired to desi gn a reactor with the proper
=

=

•

slab

�

geometry .

One obtainsthe 2 d CA -2d i;;

=

=

followin g mass balances for

c As

=

cosh

L�(k1/D)

the particle phase : ( 9 6)

=

28

2

) d ( cB / c As

dr;2

C

y

=

The

cA

A

dT

8 dT

d <;;2

B

=

C

X

2 [cosh cp 1 - 4> 1 cosh 4> 1

r;

cB s

A

B

XB

1-

y ( l)

an d

]

-
xA >i y

A

( 97)

( l) (

O)

=

0

c 2 1/2 ( ��k )

balances are =

T

0

=

1

A dT

T he value

c-A C

k

dx

dx

--

=

4> 1

fluid

dx

s

-

X

1

=

4> 2

=

a

B

2 d y

=

Villadsen a n d Michelsen

'o

A

L2

O

[

1-

4>

n

2(

(1

p

1 - X

- XA) Ijl 1 y2 )

A)

cp 1 t an h cp 1 2

of -r0 that is

tan h

( 98)

y 2 0f y2 1

w h ere

give

required to

ljl 1

=

a certain

d z;;

xA value

( 99)

is (100)

while the xa

value

is

obtaine d by inte gration of

( 101) (0,0) . solution of a problems. collocation s , causes noexpensive since it requires solution of the nonlinear value problem nonlinear solved it is advantageous to of the collocation ordinates with to to obtain Hence linear the ordinates at next of (102) is is x

x

from ( A , B ) moderate values o f

2 ( e . g . , < 5) Eq . ( 97 ) b y strai ghtfor ward method Every evaluation of the right - hand side of ( 1 0 1 ) i however , boun dary ( 97) transformed into N coupled algeb raic equations . After havin g the collocation e quation s , find the sensitivity respect xA in order good startin g values for the boun dary value the value xA . problem solved by collocation before x A chan ged :

For

z

=

z

( 1) 0 at =

z;;

=

0

and z =

X --�--2 at B

(1

XA )

( 10 2) z;;

=

1

N umerical M e t ho ds in Reac tion Engineering

29

values of (cosh r;/cosh at the collocation the calculationsstored reactions. s for fastpoints, and different xA values. For xA the profile increases overall rate of productionanofinflectionzeropointin (where inner partlocalof pofleproduc­ then decreases tion of is zero) to long ,_!:!2 at part in the obtainspline an accurate , collocation points may notused. be enough collocationvalueor iterations somey other method may have to be ontwohigh-order collocation equationsandare( avoided problem treated as differential equations coupled to algebraic equations: [p.

T hroughout

abscissas are , of course

in a table .

cl>!

( h)

"Figure 2 show s 'Profiles N umerical difficulties ari e � 'L 1 0 , six collocation = 0 to a snarp m.ax\m'l:lm �\. \. "'" \.max (..'\.'-'.� B is the the el t ) , through the rate B a interior of the pellet . To

':1" <. 1:.) fo� � "-

=

,

=

of

an d

six

T he time- con s umin g i f the N

N+1 � .t...J C , . y. ]1 1 i=l

+

( 98 )

is

99)

1

]

+

-

a

( 103)

y. ( 1 ]

2 2

1 .6

1.2

.8

.4

.6

.4

.2

0

.8

profiles for component in k 1cA concentration Parameter on curves:for xA = fluid phase conversion of yield of is obtained the pellet profile has zero slope at FI GUR E 2

A

Pellet

-

A.

B

k 2cB

2

B

xA

C.

Maximum

r;

B

=

1.

"'

0 . 7 5 w here

30

Villadsen and Michelsen

0

=

dy

N+ 2 =

dt

( 1 04 )

1

( 1 0 5)

( 1 06 ) where

x XB N +3 N+2 A' t = dummy in t e g ra t ion variable Y

Y

=

p j

=

p ret ab u lat e d values of cos h

=

4>1 1 / cosh 4> 1

The boundary ordinate YN + 1 is e li mi n a ted an d the r e s ulti ng set o f N + 2 differential - al geb raic e q ua tion s is solved [ e. g . , by the S T I FFALG pac k a ge I n itial values of Yi • i = 1 , 2 , , N , are based on E q s . ( 3 6 ) an d ( 37 ) ] . W hen 1 0 or = 0 . YN + 3 fou n d by s ol utio n of Eq . ( 1 0 3) with Y N + 1 = YN + 2 1 2 collocation p oi nt s are used , the optimum ( xA , x B ) ( 0 . 7 5 1 4 , 0 . 3 2 3 2 ) for 4> 1 10 and a. = 1 is fo u n d wi t h four- t o fi ve - di gi t a c c u r ac y . T he advantages of the p rese nt method are easily summed up : no un­ necessary computation is spent in solving Eq. ( 97 ) " e x ac tly " at every in­ t e gr a tion step , an d all components Y 1 , y 2 , , YN + 2 • YN+ 3 are calculated with a balanced accuracy . For � 1 -+ oo at a fixed value of ex , the pellet equation cannot be solved An asymp totic solution i s , how­ by collocation a s i t stands i n Eq . ( 97 ) . eve r , easily derived u si ng the following transformation . Let u !f> 1 ( 1 - (;) and rewrite ( 97) as •

.

•

=

=

=

.

.

•

=

2

£....¥. d

du

- exp ( - u )

=

2

with y ( u

=

0)

=

- �� -

du

+

a

XB / (1

-

2

(1

-

x )y A

2

XA ) an d y ( u

( 1 0 7)

-+

oo

)

0,

( 1 08) u=O

The b o u n dary condition at " u -+ oo " can be applied at two different u values , say u 5 a n d 8 , and Eq . ( 1 0 7 ) is solved by collocation for each of these va l u es . If there is no apprecia ble change in dy I dul u = O , the solution i s ac ce p t ed ; otherwise, u > 8 i s tried . Alternatively , one may make a secon d transformation to obtain a finite in t e rval : =

v

=

( 1 + u)

-2

where v

=

1 at u = 0 and v = 0 at u

-+

co

( 1 0 9)

N umerical Methods

X

B

in

31

Reaction Engineering

=1 CA0

.8

.6

.4

.2

XA

= 1 - ..,.A. c

"Ao

k 1 /c A okz and of $ = FI G U RE 3 Maximum yield of B as a func tion of s 2 Lp ( k 1 / D }t . C urve s for 4> = 0 , 1 , an d oo ar e shown , and poin t s with s 2 0 , 1 , . . . , 10 are con nected . C om p ar e with Fi g . 7 . 7 of Leven spiel ( 1 9 7 2) for consecuti ve first - order reac tion s , $ 0. =

=

The tran sformation ( 109) is well c hosen in the present ex a mple sinc e fro m Eq . (10 7 ) it is e asily see n that y "' u - 2 fo r lar ge u . Fi gure 3 sho w s the boundary c urves $ 1 = 0 an d 4> 1 + for t he o p timum ( x A , xB ) as a fun c ti o n of 1Ja.2 [ w hic h is c alle d s 2 in the classic al p aper of A dashed line indi ­ Wheeler ( 1 95 1 ) on first -or der consecutive re actions ] . cates the locu s of the $ 1 1 op timum solution s , an d at seven different value s o f 1 /a.2 ( 1 0 , 5 , 2 , 1 , 0 . 5 , 0 . 2 , and 0 . 1) other dashe d lines connect solutions with t he same value of 1 /a2 . The solution w as found by the technique ( 10 3 } to ( 1 06 ) , usin g E q . ( 97) to obtain the collocation equations T he asy mp totic solution 1 0 . Even t h o u gh i n the present ex ample a collocation solution could be found for all $ 1 values , it is worthw hile to remember than an accurate solution o f the boundary value problem c an also be o bt ain e d by forw ard inte gration from r; = 0 or from r; = 1 . T here are positive ei genvalues in the Jacobian of f , and the solution m ay e asily dive r ge , b ut an explicit Run ge - Kutta method is j u st as good as an i m plic i t method . To fin d the solution that satisfies y ( l) xB / ( 1 - XA ) , one p roc e e d s as in E q s . ( 48 ) to ( 5 0} , int e gratin g E q . ( 97 ) to ge t her with the sen sitivity eq u ation for Zy = 'O y / a y : oo

=

=

0

0

Villadsen and Michelsen

32

d 2z

Y

2 d 1;

with z

o

2¢>�ch 1

=

Y o < z;== o >

dz

1

=

( 1 10)

- x A ) y zY o Yo

d r,:

and

I

0

=

0

Havi n g obtained the correct value of Y o for a given ( xA , xB ) , a sin gle in t e gration of E q s . ( 97 ) and ( 1 1 1 ) from � "' 0 to � "' 1 gives the sensitivity

of y with respect to

(l

From the

x

A:

2 2

2

+

XA ) y zXA

2( 1

comp uted values of zx

]

z

X

A

( r,: = 1) and d z x

A

xA.

( 0)

dz

=

XA

� .,

0

=

/d � l _ 1 , one may obtain r,:A First , c alculate dy 0 /dxA ,

the second derivative of xB with respect to equivalent expressions for dy ( l ) :

using the followin g

ay l A

dy ( l ) = a x

1

dx

A

+

a

axy l

or

dy ( l)

=

[

z

x

A

( 1) +

z

Yo

( 1)

B

1

dx

dy 0 ]

dx

-

A

B

=

l

(1

xB

( 111)

0

- XA )

2

+

1 1 -x

dxB

]

--- --

A

d xA

dx

A

( 1 12a)

dx A

( 1 12b )

from which E q . ( 11 3 ) is obtain e d :

=

( 113)

Next ,

( 114) an d fin ally ,

( 1 15 )

33

N umerica l Met hods in Reac tion Engineering w here f ( xA ) 1 ( 114) .

=

- ( cp 1 t anh

cp 1)

-l

dy /d r,;

l

r,;= 1 • and f

A s a comment on t he p rocedure of E q s .

( 97)

1

< 1>

and (

< x ) is found from 1

1 10 ) to ( 1 1 5 ) , one

mi ght add that for explicit inte gration of the di fferential equation ( 97) , it is computationally si mpler to fin d

YO

by the sec ant met hod .

exp lici t inte gration it m ay be pre ferable to calculate z turbation o f E q .

( 97) rather than by E q .

( 111) .

XA

Also , for an

by numeric al per-

The comp utational cost is

the s ame and the computer program is simpler . Very difficult catalyst pellet proble m s have recently been solved by in ­ genious forw ar d inte gration technique s : nonisothermal p ellet s ) ,

K aza et al . ( 1 980 ; methan ation on S un daresan and A m undson ( 1 980 ; diffusion an d re ­

action in a bou n d ary layer surroundin g a c arbon p article ) , Villad sen ( 1 9 8 3 ;

and Holk an d

absorp tion followed by e xothermic reaction in a liquid film ) .

Other examp le s are given in Villadsen and Michelsen ( 1 97 8 , C h ap s .

5 and 9) .

We m ay conclude that t h e model for a single reaction on a c at aly st pelle t can be treated by a standard numerical approach :

finite - difference methods ,

collocation , or for w ard inte gration from t he center of the particle , c ase may be .

as the

E xamp le s with several indepen dent reactions will frequently

require a numeric al technique w hic h is tuned to the specific p roblem .

Ex­

ample 5 has shown some o f the methods that can be used to construct an efficient numerical solution , an d t he refe rences given above illustrate other techniq ues .

As a fin al comment it should be acknowled ged that the catalyst pellet model is virtually the s ame as the model used to calculate absorption with chemic al reaction .

I n particular , t he catalyst effectivene s s factor is closely

relate d to the enhancement factor w hich is used in the film model for chemi ­ cal ab sorption .

The design of m ulticomponent countercurrent gas - liq uid absorbers [ o r

movin g- bed reactors , as i n Peyt z et al .

( 1 98 2 ) )

presents some nasty n umeri ­

c al proble m s - far more difficult than those encountered in the boun dary value problem s as sociated with catalyst pelle t s .

A set of exit concentrations

in the gas phase must be gue s sed , and after in te gration of the gas - phase

and liquid - p hase mass balances t hrou gh the column , one makes a comp arison with the inlet gas composition to o b t ain an iterative c alc ulation procedure .

The differenti al equations are often very stiff , an d it requires careful program min g to achieve a st able iteration .

S tead y - S tate T ubular or Fi xed - Bed R eactor Mod e l s Detaile d discussion

of

reactor models appears i n other chapters of thi s book ;

our task is to brin g up some of the common techniques w hich are applicable

in a numerical study of t he models . For this p urpose we need only one mass balance ( 1 1 6 ) and the energy balance ( 1 1 7) . A xial diffusion terms c an b e ne glected i n t he steady - st ate model since they are sm all comp ared to the convective term s . v v

z av

ay a z

=

LD 2 r v t av

_!X .1._ ax

( b:) - � x

ax

V

av

R

( 1 16)

34

Villadsen a n d Miche lsen

v v

a e az

z

-

av

where

2

=

r v pc t ac p

X ax

(x �!)

len gt h L

x

L ( - t. H ) c

+

ive

r a di al coordinate r el at

v

av

pc T p

r

R

( 1 1 7)

r

to t he tube radius rt

flui d - phase re actant concentration and temperature relative

y,e

t o a reference state with concentration c

T

R z

� 'D PC

a

1

axial di s t an c e in r e ac tor relative to the to tal re act or

z

v

Lk

r

and temperat ure

r

==

reaction rate divided by t he re ference concentration c

==

radial velocity distribution in t he reactor tube

==

radial diffu sivity of he at and mass

r

p

I n a " o o neo u s " reactor model R is a fu nct io n of fluid - p hase properties only ; the tubular reactor with or without an inert solid p ackin g is d e s c i bed by this typ e of model . T he c at aly tic fixed- bed reactor is describe d by a " hetero geneous" model in whic h R i s a fu n c t on of particle ­ phase temp erature and concentration , but the se extra variables do not appear explicitly , and in t he numerical treatment of a c a t aly tic fixed- bed reactor mo d e l , the pellet p roblem is treat e d separately from the fluid-phase m od el [ E qs . ( 1 16 ) an d ( 1 1 7) ] - an i d e al case for solution by p artitio n in g . T he in fluence of pellet - p hase variable s on the tot al model appe ar s only in te r m s of the effectivene s s fac tor Tl , an d R i s an implicit function of the flui d - p ha s e variabla s y 9Jld e . C alculation of Tl m ay be more or le s s com ­ p c at e d , r an gin g from the sol u t o n o f simp le al gebraic equations for a sur­ face reaction on impervious pe l e t to the solution of co u p le d nonlinear boundary value p roblem s , as in e a p e s 4 and 5 e ar er in this section . I n all ci rc u m st anc es one s hould try to d uc e the complexity of t he pellet model as far as possible ( Examp le 4 sho we d us how far one can get in this re sp e c t wi thout s a ri fic i n any i mp ortant feature of the pellet model) . The fluid - phase model is itself i t e complicated , an d the in e c e of re actor m acrovariable s (e . g . , the lar ge temp e r ature gradients which o cur radially reactor ) can be studied with sufficient accuracy in the u be s of a re fo r min without too many details in the pelle t - p hase desc ription . I f the r a e of e a t o n is moderate , the radial diffusion terms are small comp ared to the axial gradients , and one m ay r e u c e Eqs . ( 1 1 6 ) and ( 1 17) to a one - dimensional model . T here are c e rt ainly situation s w here this approximation may lead to loss o f major fe atures of the model , but the potential re d c tion in computer expenditure is so s i i ic an t that we feel it n ec s s a y to comment on p rop er aver a gi n techniques for t he radial gradients before we discuss suitab le numerical techniques for solution o f he fu ll od e l .

h m ge

r

i

li

i l s xm l

c

t

t

e

r

li

re

g

qu g

flu n

r ci

c

d

u

gn f

g

t

m

A v e raging o f t he S teady -State Mo de l over t he C ross Section of t he T u b e

r

D

ep

t

A ssume that t he p hy sical p rop e ti e s k I PCp and are i n d en d e n of x an d i nt e gra t e over t h e c ros s s t on of t he t u b e t o obtain t w o couple d ordin ary

ec i

N umerical Methods in Reac t ion E ngineering differential equations reactor position z :

� where R dO dz

L v av

==

dz

{ 1 18 )

a n d ( 1 1 9) for t h e average s of y a n d 0 at

35

( 1 1 8)

R

2 1 J R dx , which is approximated by R ( y , O ) : 0

=

{ 8w -

2LU r v pc t av p

==

0x==1)

L ( - ll H ) c +

v

r pc T av p r

R

( 1 19)

w here O w is t he value of 0 at t h e reactor w all and Ox:: 1 is the value of 8 just inside t he w all . In the same m anner in w hich we introduced a modified pellet heat tran s fer coe fficient in E q . ( 9 1 ) we shall define a modified w all heat tran s fer coe ffic i e n t U : a e ax

- k r t

I

x== 1 =

- 8 ) U{ O w x- 1

U{ Ow

_

( 1 20)

Expre ssion ( 1 2 0 ) is inserted in E q . ( 1 1 9) an d n o w only e and y appear i n the approxim ate reactor mo del , which c an be solved by inte gration from z = O to z = l . It remain s to calculate U in terms of U an d the radial heat conductivity k. In gene r al , U is obtained from ( 1 2 1)

where the con stant a depends on the radial velocity distribution . Villadsen and Michelsen ( 1 97 8 , C hap . 6) disc uss a pert urbation tec h n iq ue by w hich a m ay be c alculate d . T he value of a will fall between 1 / 4 for a flat velocity pro file V z = Vav and 1 1 / 2 4 0. 45 8 3 for the parabolic velocity p rofile of the Typic al result s between t hese values are laminar flow tubular reactor . =

19 48

a = - =

0 . 3958

for

�(1

v

_z_

v

=

2

av

4 - X )

an almost flat profile , and

a ::;

4 9 5b 2 + 2 3 4b + 31 1 2 0 ( 3b

+

1)

2

z

v for

v

=

6( 1 -

av

) (X 3b + 1 X

2

2

+ b)

For b = 1 / 4 this profile h a s a m1m m um at x = 0 an d a m aximum at x 'V 0 . 7 , a feature that is observed in m any experimental studies on packed - bed velocity distribution s . a = 0. 3277 for b 1/4. T he res ult ( 1 1 8) obtained by strai ght forw ar d averaging o f the m as s balance can be improved b y includin g one more t e r m i n pert urbation an aly sis from R 0. For a first -order , isothermal rea c tion ( R = k c /c ) R r =

=

Villadsen and Miche lsen

36

in a tubular re a c t or with p arabolic velocity distribution , one obt ai n s st ead o f E q . ( 1 1 8 ) ,

,

in ­

( 122) where D a = kRL /vav an d the numerical c ons t an t 1 / 48 is calculated by perturbation an a l y si s as discussed in Villadsen and Michelsen ( 1 97 8 , p . 2 7 1) . This result was first given in a famou s p aper b y Sir G eoffr e y Taylor ( 1 953) . Q ualit atively s p e akin g he in te rprete d the radial diffusion term in E q . ( 1 16) where D is now a true molecular di ffu sivi ty in terms of fic ti tiou s " axial dis p er s ion term" in a one - dimension al model : ,

-

� dz

=

_:£__

k L v

y

+

av

2d y 2 dz

1 __ Pe ef

( 1 2 3)

w h e re

Pe

1 92

=

ef

=

Equation ( 1 2 3 ) m� be so l ve d usin g the simple " semi - in finite" bound ary condition ( e . g . , y = 1 at z = 0 and finite for z -+ oo ) or with the more complicated boundary condition y ( O) +

l

1 dy Pe d z z= O f e

--

--

=

1

and

dy dz

l

=

0

z= 1

I n b ot h cases , one obtain s y ( z = 1 ) = exp

[ 0 p�:J J -Da

2

+

0 (p�:J

( 1 2 4)

w hic h is t he same result as that obtained by pert urbation analysis ( 1 2 2 ) . T he final result ( 1 2 4) is well known from e l em ent ary textbooks in re ­ action en gin e e rin g [ e . g . , Levenspiel ( 1 97 2 , pp . 2 8 3 - 2 8 7 ) ] , where a " di spe r sion number" 0 v

ef = L av

1 192

=

is u sed to correct "near plug flow " data obtained in a tubular re actor . T he improvement is substantial , at least for sm all values o f t he disp e rsion Thus a t D a 1, w here Eq . ( 1 1 8) yie l d s the result y( z = 1) = number . exp ( - 1) 0 . 36 7 9 re gardles s of the contribution from t he radi al dispersion , one obtains the followin g results from Eq . ( 1 2 4) : =

=

37

N umerical M e thods in Reac tion Engineeri ng D 1 92 � v L

1

av

y by E q . ( 1 24)

y

by a " true model"

10

5

2

0 . 37 5 2

0. 3818

0 . 3892

0 . 417 9

0 . 3750

0 . 3809

0 . 3919

0 . 4038

""

( 0 . 443)

The bottom line of the table is calculated by hi gh - order collocation- as described belo w - applied to Eqs . ( 1 16 ) for a first - order isothermal reaction 2 2( 1 - x)

� az 1

y(z

=

1)

=

L av 1 1 9 2D f e

v =

a

; ax

2 4( 1 - x ) y ( z

0

=

( �) X ax

- Da y

( 12 5 )

1 , x ) x dx

The case Def -+ oo ( w hich m ay be interpreted as D "' 0 ) corresponds to a comp letely segre gated flow with no cross- sectional mixin g caused by radial gradient s .

N umerical Solution o f S teady -State Reactor Mo del

When E q s . ( 1 1 6 ) and ( 1 17 ) are discreti zed in the x direction , there appears a set of couple d ordinary differential equations (j = 1 , 2 , . . . , N) :

� = dz d6 j dz

T

M -J

a.. . C .

l. - - R ( y . , 6 . ) L

v

av

l

l

( fi T ) =

T

( 126)

m ax

( 1 2 7)

r

T he coefficients Cji are defined in E q . ( 7 0) . T he y have different values dependi n g on the method of discreti zation . Ordinary finite - difference methods , global collocation , G alerki n ' s method , or spline collocation have been used by various authors in numerous comp uter studies over the last 2 0 to 2 5 years . Equations ( 1 2 6 ) and ( 1 2 7 ) can be solved from z 0 by any of the standard p acka ge s for coupled initial value p roblems . A n imp licit or a semi -implicit method is preferable to an exp licit method because of the lar ge spread of the ei genvalue s of Q. T hi s is true in particular when ortho gonal collocation is used to discreti ze the radial derivative ; even for a relatively low order method ( N = 4 or 5) the ratio between the lar gest and the small ­ est eigenvalue can be of t he order of 1 0 0 0 . T he structure on the right ­ hand sides of Eqs . ( 1 2 6 ) and ( 1 2 7 ) is , howeve r , so simple that the Jacobian can be comp uted very easily . It is al so pos sible to disc reti ze E q s . ( 1 2 6 ) and ( 1 2 7) in the z direction to obtain a so -called doub le - collocation method . This method w as origi nally proposed by Villadsen and S�rensen ( 1 96 9 ) , but it w as only recently =

Vi l ladsen and Michelsen

38

elaborated into efficient computer codes by S�rensen ( 1 9 8 2 ) . T hese codes appear to be p articularly suitable w hen applied in a parameter estimation problem .

A sit uation that lends itself q uite n at urally to solution by double col ­ location is t hat of a w all - c at aly zed c hemical reaction : the rate term appears in the boundary con dition of an otherwise linear partial differential equa­ tion [ Eq s . ( 1 1 6 ) and ( 1 1 7 ) without the rate terms] . Michelsen and Villadsen ( 1 98 1 ) give a det aile d discussion of this p articular type of chemical reactor model , w hich m ay be solved either by double collocation or by the S T IFFALG routine [ Eq s . ( 36) and ( 37) ] ; there is one nonlinear algebraic equation ( t he boundary con dition ) and N linear differential equations which can be trans formed into the diagonal form ( 18) and used in this form thro u ghout the calculation T he solution of E q s . ( 1 1 6 ) and ( 1 1 7) for a rate exp ression whic h is linear in y an d 9 ( or has been lineari zed from a given reference state) deserves p articular attention . C rank ( 1 95 7 ) has discussed the multitude o f practical proble m s in re action en gineerin g which are generated from t he same b asic equation , the linear " diffusion equation . " N umerically , all these different problem s are han dled by the same general techniq ue , b ut with sli ght modific ations for different boundary conditions . Let us use a linear mass balance as our " standard p roblem " : •

v( u )

�

_

az -

4 ( 1-s) /2

u

....£..._ ( au

u

( s+ 1 ) / 2

lz.) _ Da y

( 128)

au

where u W hen s = 1 an d v ( u ) i s x 2 and s = 0 , 1 , and 2 . velocity distribution , we have a steady - st ate tubular reactor When v ( u ) = 1 and z is interpreted as contact time , we have transient pellet proble m . Here we use $ 2 = kR rp 2 !D in stead vav as t he dimensionless group of parameters . Equation ( 1 2 8 ) is discreti zed by N t h - order collocation : =

the radial problem . a linear of Da = k L I R

( 129)

�

v ( llj ) , an d the ( C , b j ) are given in E q . ( 7 1) . ¥ is dia gonal with V H Di fferent side con ditions at u = U N + 1 = 1 lead to different problem modifications . _1 Diagonali z ation of M = Y ( Q * - D aD yields the standard form ( 1 8) . Michelsen and Villadseii ( 1 98 1 ) prove t hat all ei genvalues of M are real and distinct if collocation is m ade at the zeros of an d the boundary =

condition at u

( 1957) .

=

P�O , O) (u) ,

1 is any of the linear expressions discussed in C rank

T he solution appears as an N - term expansion in ei gen functions exp ( Aj z) , and t he modi fied Fourier coe fficient s are found by simple m atrix- vector m anip ulations [ see Villadsen and Michelsen ( 1 978 , C hap . 4 ) for the solution of a p articular example ] . For the case Da = 0 , Michelsen ( 1 97 9) proves t hat the ei genvalues and ei genfunctions of Eq . ( 1 2 8 ) with boundary condition

� d du

Bi

M + -2

y = constant at u

=

1

( 1 30 )

39

N umerica l Me t hods in React ion Engi neering

be derived for any value of BiM by a simple algorithm that utilizes t he eigenfunctions obtained at any specific reference value which , for example , may be either zero or infinite . This leads to substantial savings in computer time when estim atin g t he value of BiM ( and a diffusi vi t y ) from a series of measurements of y at different and x . W h en Da f. 0 , t h e diagonalization of M must , however , be performed for each value of Da. Another important speci al case , that of a finite exterior medium , i s t re ate d in Sotirchos an d Villadsen ( 1 9 8 1 ) . The boundary condition at u = 1 is given by an overall mass balance can

eigenvalues an d (BiNI >r ,

z

-

b z

q y ( )

+

l y( x , z)

s 1 dx +

0

=

a

-

(

Jz J1 0

0

R

dx

8+ 1

)

d z'

=

a -

f

( 131)

Outside the reaction medium of volume 1 (or the catalyst pellets as the case may be) there is a radially w ell mixed volume q into which the react ant m ay diffuse . The reactant concentration is Yb in the finite exterior medium at position (or at contact time t) . In Eq . ( 1 31 ) the total "mass" in the re­ actor and the outer medium is equated to the initial "mass" les s the total amount of reacted material. Concentrations in the two media are connected by a boundary condition of type ( 1 3 0 ) where the right - han d - side "con­ stant" = (BiM /2)yb ( z) . Let v( u) = 1 and write the jth collocation equation , z

a,

dy . J dz

N

I:

i=1

b.

]1

_l

c .. y.

q

1

where f is given in

f-

R(

y) ]

.

+ b.

Eq . ( 1 3 1 ) .

- b

J

1

0

For a eq

an

y dx

s+

1

N

=

L 1

�

( 1 32)

] q

j

( 2AN+1 ·) w. q

___!

+

1

J0

R dx

,1

w1. y1.

nonlinear reaction rate the N e q uations uation for t he average rate of reaction :

df dz

B\J

s+l

=

( 132)

are solved together with

N

L w.R(y ) 1 1.

for a first-order reaction the numerical approach Eq . ( 1 2 9) :

but in

( 1 3 3)

1

is j ust

like that used

Villadsen and Michelsen

40

dY =

dz

y

=

� -y

+

b*

(y 1 , Y2 ' ' ' ' , yN '

f)

T

,bN '

b*

�

(¥ =

- Da� T D aw

( 134)

0 }T

E q . ( 1 3 2 ) to ( 1 9 8 1 ) have been corrected . o ( 1 34 ) can

In

s

( 1 34) the unfortunate misp rint s in Sotirchos and Villadsen A number of important ap p li c ation s of Eq . ( 132) , ( 133) , r be easily listed : Ab sorption o f a reactant gas from a gas phase and reaction in the liquid phase [ gas flow rate va (m 3 /h) , liq uid flow rate vL( m 3 /h) , and q vL /vo l . 2 . Determination of reaction rate constant and pellet diffusivity by 1.

=

3.

concentration me asurements in a finite volume of well stirred liquid in w hich the c a taly st particles are sus pen d ed . All reactant is ori gin all y in the fluid outside the particles . Analysis of membrane reactors : a certain amount of reactant v( m 3 /h) flow s in a tub e coated with a catalyst l ayer of thickness o . R e ac t an t diffuses into the catalyst layer and reacts there . It is desired to c alculate t he len gth of t u b e required to obtain a c e rt ain average concentration in the flowin g liquid .

As a final illustration of the ge ner al numerical approach to linear steady­ state reactor models , one may consider Eqs . ( 128) and ( 130) with the addi ­ tion of a s mall axial diffusion term ( 1 / Pe M ) ( d 2y / a z2) on the right - hand side of E q . ( 1 2 8 ) . T he p roble m has only ma rginal in terest in indus tri al reactor design ( radial diffusion may be accounted for by a fictitious axial dispersion term as discussed earlier , but an axial diffusion term per se is almost always insi gni fi c ant ) . A ddition of the second derivative with re ­ spect to z in the p ar tial differential equation ( 128) does , however , lead to formidable numerical complications which have intrigued many authors [ see , e . g. , Papoutsakis et al . ( 1 980) or Michelsen and Vil lads en ( 1981) ] . It is interesting t h at wit h the exception of the inlet zone of the reactor , one may study the influence of an axial di ffusion term ( 1 /Pet\11 ) ( a 2y I a z 2 ) on the solution of E q . ( 128) , using only the eigenfunctions and eigenvalues o f the radial diffusion operator . The technique and its application to the "extended Graetz problem" discussed here and to the much more interesting asymptotic stability analysis of catalyst pellet mo dels are developed in Villadsen and Mic hels en ( 1978 , Chap . 9) . Every one of the numerical methods that have been described in this section have been based on an approximation of the x prof'J..le by a poly ­ nomial . High -order methods such as collocation will not be able to handle th e near discontinuitie s t hat appear in t he profiles close to the reactor entrance ( t he inlet concentration m ay be 1 at all interior points an d zero at u 1 for z 0+ ) . Spline collocation with a spline point that gradually moves away from u = 1 as z incre as e s has b een successful in the computa­ tion of "penetration front s in the inlet zone of the re actor . One example =

=

"

N umerical Metho ds in Reaction Engineering

41

is given in Holk - Nielsen an d Villadsen ( 1 98 3 ) , and other exa mples are shown in Villadsen and Michelsen ( 1 9 7 8 , C hap . 7 ) . Another , qui te different but apparently versatile approach is to intro ­ duce a variable trans formation n = f( z , x ) w hich as far as possible describes the combined influence of z and x on the solution near z = 0. T his is called " similarity transform ation" and i s treated in most textbooks on partial differential equations . T he reduction of the model into a problem with only one independent variable succeeds only in trivial cases , and one will usual­ ly en d up with two independent variables n an d z in the transformed equa­ tion as well as in the boundary conditions . I f , however , n has been judiciously chosen , a perturbation analysis of the transformed equation from z = 0 will give an accurate solution of the original problem in the inlet zone . T here are several examples in Villadsen and Michelsen ( 1 97 8 , C hap . 4) where this technique has been used to solve linear reactor problems , and a pellet model with a concentration dependent diffusivity is treated in the same re ference p . 3 3 9 ) . U n steady - S tate Fi xed- Bed Reac to r Mod e l s

Except for re gions of hot spots , the steady - st ate axial temperature and concentration p rofiles in a fixed bed are smooth functions of z , and the radial profiles can almost always be represented by low - order polynomials ­ if they are not averaged aw ay as discussed in the preceedin g section . Thus ste ady- state reactor simulation is a rat her modest affair on a hi gh ­ speed computer , requirin g at most a couple o f seconds comp utin g time to obt ain e ( x , z ) and y ( x , z ) . W hen a time derivative is included in Eq s . ( 116) and ( 1 17) there is a fundamental change in the nature of the solution . Sharp concentration and temper ature front s m ay be formed , and these front s move slowly through the reactor . To simulate the dynamic response of the reactor to a control action in the inlet ( e . g . , a jump in reactant concentration ) , one has to fol­ low the reactor profiles o f the dependent variables through many thousands This , of course , means t hat the amount of of fluid - p hase time constants . computation incre ases drastically , and 2 5 to 40 sec of computer time per simulation is not at all extravagant . Q uite apart from the cost of the com ­ putation , the time it t akes to make a computer sim ulation of the unsteady­ state reactor makes it very difficult to use the result , for instance , in a computer control of the reactor . A compromise must be m ade bet ween the demand for accurate modelin g of the reactor and a reasonable computational effort . T he literat ure on un ­ steady - st ate reactor sim ulation offers a bewilderin g array of model simplifi­ cations and numerical s hortcuts . Some of the simplifications are j ustified and should certainly be generally accepted , but others are downright silly and will lead to order-of-magnitude errors in , for example , the b reak ­ through time of a cat alyst poison . T hus for gaseous reactants it is reasonable to ne glect accumulation terms in the reactor fluid-phase mass and energy balances and in the pellet mass balances . T he time constant for convective transport of mass through the reactor and for diffusion into t he pellet are order s - o f- m agnitude smaller than the velocity of t he reaction zone . T he pellet temperature is taken to be independent of position in the pellet ( as in Examp le 4 ) , and while the pellet time constant for ener gy transport is certainly larger than the time constant for mass transport , it is still much smaller than the thermal

42

Villadsen and

Michelsen

residence tim e for the bed , an ob servation that may justify a fur th er as ­ sumption that Bp = e g at any time . To reduce the dimensionality o f the proble m , it is common practice to ne glect t he cros s - sectional conductive term in Eq . ( 1 1 7 ) w hen solvin g unsteady - state reactor models . This m ay be justifiable w hen the diameter -to-len gth ratio of the bed is larger than 2 0 , b ut a r adial gradient c an also be incorporated as a fictitious axial dispersion term and there is experi mental evidence that true axial conduc­ tive terms m ay have to be taken into account in modelin g of transient fixed­ bed reactor behavior . It is usually dan gerous to t amper with the rate expression to obtain comp utational advant ages . If it is reasonable to suspect a substantial re ­ sistance to mass transfer in the pellet s , it will not do to ne glect this dis ­ persin g effect , since breakthro u gh times that are much different from those observed experiment ally are likely to be c alc ulated . Our discussion of the pellet proble m for a sin gle reaction has also shown t hat a complicated rate expres sion is treated with almost t he sam e e ffor t as a simpler rate expres ­ sion . T herefore , it is usually not advisable to j eopardi ze the trust wort hi ­ ness of t he simulation b y ne glectin g the in fluence of one o r more reactants on the rate of reaction . Unstead y - state reactor models display such a variation in complexity that it b eco m es impossible to discuss s uitable solution techniques in general . At one end of t he spectrum one fin ds t he one - component isothermal gas adsorption unit w hich can be treate d analytically ( Aris and A m undson , 1 97 3 ) . At the other en d of t he spectrum there are studies of reactor con ­ trol with several independent variables , steep temp erature front s , and with time - chan gin g kinetic and transport p arameters . Simulation of reactors for reduction o f mineral ore and simulation of explosion fronts are other com ­ plex problems . An example that illustrates major feat ure s of unstead y - s t ate reactor behavior without bein g very complicated is discussed in Michelsen et al . ( 1 97 3 ) and Villadsen and Michelsen ( 1 978 , C hap . 9) : The reaction t akes place in t h e fluid phase , but the inert p ackin g m aterial of the reactor in­ troduces a l ar ge thermal residence time . A fter linearization t he model is analy zed in term s of transfer functions , u sin g collocation to account for the axial variation of the variables y and e . In the present chapter we use an example of moderate complexity to illustrate certain numerical techniques which we believe can also be applied in many other situations . Examp le 6: Simulation of co ke b urning in a fixe d - bed reac to r A re ­ formin g cat alyst is slowly deactivated due to deposition of tarry m aterial in t he pore s . T his so -called " coke" has to be burned o ff periodic ally , and a reliab le sim ulation is important to minimize the len gth of the burn - off period without sinterin g the metal cryst allites by excessive overhe atin g of the pellets . O ri ginally , t he coke is homogeneously distributed on t he particles wi th concentration c00 • Nitro gen co n t aini n g a small proportion of oxy gen ( concentration Coi ) is fed to the reactor inlet at temperat ure T gi . A reaction zone develops and moves slowly throu gh t he reactor . When the reaction zone passes out of t he reactor the b urn is complete , an d it is succes s ful if only a sm all residual coke concent ration cc ( z) is left behind and if the temperature at no time has exceeded T max anyw here in the re­ actor . Durin g the operation of t he reactor a temperature wave p asses through t he b e d . I t m ay move faster or slower than t he reaction zone ­ can be used to control t he relative the inlet oxygen concentration c oi

43

N umerical M e t ho d s in Reac tio n Engineeri n g

Both front s move exceedingly slowly comp ared velocities are 0 . 1 m / h fo r the r e ctio n zone and 0 . 9 m /h for the temperature front . A model with three equations [ ( 1 3 5 ) to ( 1 3 7 ) ] for the pellet p hase and two [ ( 1 3 8) and ( 1 3 9) ] for the phase w as proposed by Liaw et al . ( 1982) .

movement of t he t w o front s .

to the gas residence time in t he reactor .

a

Typical

fluid

y

c

c

-

=

c

c

co

=

1 at t

=

0

( 135)

( 1 36 )

1

t

ae ----2. ax

H

=

H <e - e ) + a Da n y p g p g

- .-£. p T . T

e

gl

e

T

g

=

_g T gi

( 1 37)

c

-Da ny ae

�z

g

y

g

..EK = c .

( 1 3 8)

01

H (9 - e g) p p

=

a

( 1 3 9)

The many in E q s . ( 1 3 5) to ( 1 39) ( t R c h r act eri s t ic reaction time , t H = therm al residence time , Hp = fluid -to-pellet heat tran s fer units ,
constants

=

a

burned)

is

z and

a also used

The inlet gas s

the e ing

c

n

T

the

in

gradient

kcc

phase ,

44

Villadsen and Michelsen

less justified assumptions t hat have been made in p revious s t u di es o f the p roblem . T he present model does not assume " a constant burnin g rate , " low -temperature bu rnin g " ( where cp � c g ) , or " di ffusion - controlled b urn­ in g" ( where t he rate is almost independent o f te mper at u re ) , and con se­ quently the p redicted b urn t is close to t hat o b t ained in lab or atory e xp e ri ment s . T he model has recently been critically reviewed from a n u m eri c al poi n t of view by F un der ( 1 9 8 2 ) , and as a result the computation time per burn ­ out w s reduced from about 5 mi n in Liaw et al . ( 1 9 82 ) to a o ut 35 to 40 s . We shall re vi ew some of his conclusions . 1. It is me nin gle s s to si mp li f the model as sumption e g 9s = e . T his i s fre q ue n tl y done in n u meric al st udies o f u n stead - st te reactor models , an d the resultin g " h omo geneous " model with

ou history

simulation a

b

a

y

ae az in ste ad o f E q s .

=

1 t

H

by the

y

=

a

( 1 40)

SD a n y g

( 1 3 7 ) and ( 1 3 9} is amenable to s o lution by t he met ho d o f

char acteristics u s i n g increments related by

dt

T here

a

=

t

H

may

de

dz =

( 141)

SD a n y g

b e about 1 0 % s a vin g in comp uter time w hen this app roxim ation

r

is m de , but si gnificant errors in t he tem p e at u r e peak may

also by

occ ur .

2. T he implicit th re e - point inte gration scheme su g ge sted C hristian ­ sen and An dersen ( 1 980) i s ve r s uit able for inte gration of the fluid b alances in a re c t an gul ar grid . T he pellet mass b alance is approximated 3 or 4] , an d the resultin g co llo c atio n [ usin g PN ( O , O ) ( x 2 ) wit h N equation s for Y g • an d { ( Yp • Y c > ; j = 1 , 2 , . . . , N } are solved a Newt o n method for each grid poin t . A ll z values at a given t are t r eate d before t i s increased . where­ 3. Fun der ( 1 9 8 2 ) poi nts to an i nte r esti g model approxim ation : as it i incorrect to a ss u me a c o n st ant the p ellets ( e xcept w hen the pellet is far from the react io n zone) , it is q uite reasonable to assume a const an t coke level or a coke profile t hat ch an ge s in a few step s . W hen Yc is assumed to be pie ce w i s e constant in t he pellet , it is possi ble to solve t he pellet model analytically , and in c e n is t he only "output" of the pellet m a s s balance , t he problem is reduced from one in 2N + 3 vari ­ ables to ( ideally ) one in four or five variables . The resulting red u ction in c o mp t e r time is very si gni fic an t ( from 35 to 4 to 6 pe burnout simulatio n ) an d the result s are only a few percent age points different from those obtained by the full model , probably b e c a use the sharply decreasin g oxygen profile in the p e lle t i s very little influenced t he coke profile as lon g as t he correct average coke concentration i s u s e d . C haracteristically , the solution of the unsteady - st ate reactor model is smoot h except in t he reaction zone an d in the temperature front . In Exam ­ ple 6 the oxygen concen t r ation is zero down stre am from the re ac t ion zone , and it incre ases rapidly to the inlet value c at po ition s upstream from the 0i reaction zone . Glob al colloc ati n doe s not give a satis facto r y represent ation of the p rofile when two , more o r less flat p art s are joined a st e e p front .

y

by

eg , � ·

by

=

n oxygen level in

s

s

u

s

by

s

o

by

r

N umerical M e t hods in Reaction Engi neering

45

Spline collocation is a possibility , but a suitable al gorithm must be con ­ structed to move the zone with m any collocation points at the same speed as the reaction zone . With several reacti n g species an d an energy balance , the front s will move with different speeds , and unle s s the program auto­ matically follow s eac h o f the fronts , spline collocation will also be imp ractical . An ideal code should :

1. 2.

Ensure that eac h front i s followed by a sufficient number o f nodal points . Move nodal point s in and out of the fronts - not too fast ( since otherwise all nodes would be sucked into t he front s ) and not too slow ( the fronts will be inaccurately represente d )

W hen t he profile s are given i n terms of Yj ( t ) at positions � ( t ) [ e . g . , between ( Yj , Zj ) and ( Y + 1 • �+ 1 ) 1 , one j must req uire that ( Yj • Zj > quickly settle down to become smooth functions of t. This cert ainly requ1res that condition 1 is satisified . I f a number of nodes pass quickly throu gh the front , the profiles ( yj , Zj ) will oscillate wildly with t . Since the e quations that determine t he ( Yj , Zj ) are surely goin g to be "stiff , " an implicit or semi -implicit inte gration method in t must be used . T he most p romisin g recent develop ment tow ard a general al gorithm for solvin g problems wit h steep front s ( or schocks ) is due to Miller an d coworkers ( Miller an d Miller , 1 98 1 ) . T heir method employs a complicated system of " sprin g force s " and " viscosity forces" to move the node s - q uickly

as a set of piecewise linear functions

but not too quickly-in and out of the fronts . Comp utin g times ( with an implicit Gear m ethod to solve the differential equations for the time develop ­ ment of the profile s ) appear to be rem arkably small . We have used the in ­ formation given in t he published articles to test their method , both on B urgers' eq uation ( t heir test example ) and on a chrom atographic separation example . Our comp utation times are , how eve r , three to four times as hi gh as stated by Mille r , but undoubtedly the method deserve s further study , since the b asic ideas seem to be j ust right for solution of some extremely complicated proble ms of great practical interest . PA R AM E T E R F I T T I N G I N

R E A C T I O N E N G I N E E R I N G MO D E LS

Up to this point we have presented various n umerical technique s w hich are suitable for reactor sim ulation (i . e . , computation of reac t ant concentration , temperature , etc . ) as functions of the independent variables in the reactor model . We shall now apply these techniques to determine a set of parameters in a postulate d rate expression , heat transfer model , or reactor model . At n specified values of t he ( possibly multidimension al) independent variable x , there are measurements of some or all the components of the M - dimen ­ Sional state variables in the postulated model . The experiment al values are ( y 1 , Y 2 • · . . , yM ) k for k T hey are collected into an 1, 2, . . . , n. experimental state vector � . T he experimental values of � are s upposed to be free of exp erimental error , w hile the experimental error of � e is sup ­ posed to b e normally distributed with a m ean o f zero ( this i s possibly not true , but it is often as good as any other guess , and the bias in the estimated E. that results i f the assumption is incorrect will be difficult to assess ) . =

46

Villads en and Michelsen

T he postulated model contains m p arameters ( P 1 • P 2 • p ) E.• and for a give n value of 2. the model can be used to c alculate vr:fi ues r. s of the state vector at t he exp erimental positions x . T he parameters will be determined by minimi zation o f an object function

•

•

,

=

( 142) The (n x n) covariance m atrix 1; for t he experiment al data is assumed to be diagonal ( uncorrelate d dat a ) -and the diagon al elements are I:ii V ( yi ) = =

the vari ance of the ith experimental point . � is assumed to be known 2 except for a scalar cr Differentiation of .p with respect to 2. yields the followin g algorithm for improvement of an initial estimate e,o for e,:

cr�, 1

where

T his is t he G au ss - Newton algorithm , w hic h can be applied iteratively until

< E: and 2. �. the maxim um likelihood estimate for E.· T he variance -covariance matrix y is obtained from the estimate g ( � for the Hessian matrix that result s after conver gence has been reached in Eq . ( 1 43) :

l t� EI

=

¥

=

E [ ( E - e_)T(E_ -

2

£) ] = s g

-1

(

�)

( 1 44)

where

cr

2

1 2 "2 tv cr = s = --­ n - m

"" <2.>

( 1 4 5)

Gaus s - N e wton ' s al gorith m is at least linearly convergent , but it may fail to Most stan d ­ converge even w hen excellent st artin g values 2. o are provided . ard codes for parameter estim ation with a n e xplicit object function e mploy one of t he several variants of Levenberg-Marquardt' s restricted step T he simplest version is t hat in which g + v!_ is used instead al gorithms . of g in E q . ( 1 4 3 ) , but an arbitrary positive - definite matrix m ay be used inste ad of the identity m atrix !_. At the start of the ite ration a rather lar ge value is chosen for the Levenberg p a rameter v , and v is gradually reduced when ll £ + _1!. T hus the method start s as a steepest- descent method and it may en d as a Gaus s - Newton method in the last iterations . It is rob ust and often works well , although it is not spectacularly fast . A good , recent description of Levenber g-Marquardt methods is Fletcher

47

N umerical Methods in Reac t io n E ngineering

( 1 980 ,

Chap s .

In the followin g w e assume that one of t he

5 and 6) .

Levenber g-M arquardt

lib r ary

. .

codes ( e g

, IMSL or a I. I a �

calcu l ate d values of I. s an d of it s gradient

tt

T he parameters to be determined fall in t w

1. 2.

H arwell ) with externally is available .

group s :

( R TD ) ,

Kinetic parameters ( rate constants an d equilibrium constant s )

R e ac t or

bution

p arameters [ re sidence - time dist ri

i

sectional velocity - and heat cond uct vit

t

tran s fer coe fficients , pellet - o - fl

dispersion , etc .

)

uid

y

cross­

distribution , w all heat

transfe r parameters , axial

The measurements can be of wildly differe n t co mplexity .

in clu d e :

T h ey m ay

1.

Direct me asurement of the reaction rate at given conversion and

2.

Me asurement o f the average con ve r sion and temperature p ro files

space time ( recirculation reactor )

h

in t e axial direction of a

fixe d - bed

reactor , or profiles of con ­

version versus time in a batch reactor

3.

Radial an d axial temperature and in a

fi xe d - be d

reactor at

x ri ments

T he e asie st e p e reactor .

( p o ssib ly )

di fferen t

concentration pro files

value s of time

to analy ze are those o b t ai ne d in a recirculation

The experimental procedure is slow comp ared to batch reactor

experiment s - only one se t of outlet conc e n t r ation and temperat ure is found for each ste ady - st ate experiment - but in principle it is possible to obtain

a

complete pict ure of the rate expres sion w it h o ut w or ryin g about inter­

ference

fro m

E xp erimen t s over the whole range of i gui sh as far as possible betw een differ­ for o xi d ation of C O , t h e pure first - order

t he reactor parameters .

conversion s hould be used to dis t n

ent kinetic p arameters .

T hus ,

behavior is seen for me as u rem en t s t aken at conversion close to 1 , while the

" ne gative

order kinetics" ( i . e . , the in fluence of CO inhibition ) is observed

n e i lar ge inlet CO concentration . I n tr ap ar ticle mass tran s fer resi st anc e is measured on pellets of differ­ ent si ze . Jackson ( 1 9 7 7 , C h ap . 10) reviews t he subj ect of di ffu si vit y me asurement s by steady - st ate methods as w e l l as by t r an sie nt me t ho d s . It may be safer to meas ure t he transport parameters un der re ac tin g condi ­ tions . O n e o r more standard reactions with known ( an d simple ) kinetics may be u se d , but in m any st udies it has also been proved t hat kinetic parameters can be fou n d simultaneously with the p e llet m ass tr ans fer re ­ sistance . Similarly , the pellet he at co n d u c ti vity c an be m e as u re d independently , followed by measurements of t he pellet - to - fluid phase transfer properties , radial heat c on ducti vit y , w all heat transfer coefficient , an d so on , in the packed bed op erated as a heat rec up e rato r . U n fortunately , different ex­ for small co v r s on and

perimental methods may

gi ve

( see , e . g . , Hoffm ann et al . ,

very different values of these parameters

1 97 8) , an d many authors doubt that the

parameters can also be applied for sim ulation of the reactor u nde r reac

condition s .

tin g

A word of warnin g s hou ld fin al ly be given c onc e r nin g recirculation re ­ ri ment s : w hen the conve rsion is very hi gh , the recirculation ratio is likely to be too sm all , and for m e asu r em en t s at small co nve r sio n t he amount of catalyst m ay be too small to give a homo geneous bed - or t here actor e xp e

48

Villadsen and Miche lsen

may be severe s hort - circ uitin g in the reactor itself. Wedel and Villadsen ( 1 98 3 ) show some nasty systematic error s that m ay arise in the in t e rp re ta ­ tion of recirculation reactor data e rror s whic h could not be avoided by including R TD me as ure me nt s in the data analysis . Still , as far a s possible , one s hould try to proceed as in dicate d above , usi n g different equipment to extr ac t i n for m at ion re g ar di n g different groups It is far more difficult , from both an experiment al and from of par amet e r s , a sim u l ation point of view , to determine kinetic and t r an s p ort parameters simultaneously . The mo s t prob able outcome is that the p hy si c al p arameters ( which fr e q u en tly have a m u c h smaller in fluence on t he conversion than the kinetic pa rame t ers ) will be d ete r mine d very poorly . M any authors (see , e . g. , Clement and J�r ge n sen ( 1 98 3 ) ) have ob ser ve d that the par am ­ eters obtained by t he "buildin g-block" app ro ac h fail to give s ati s fac tory prediction of the reactor pe r for m an c e unde r reactin g conditions . H e n c e they feel that it is nec e ss ary to d et e r mine all ( or most ) of the parameters si m ult an eo u sly in or d er to give a reactor model that can be used for inter­ polation and for control purposes . One m ay argue that the failure o f the b ui l di n g - block method m ust indicate t hat there is som e misconception of the kinetic model or of the flow p attern in the reactor , and t h at these un ­ certainties had better be re solve d . I f the re are errors in the model , the predicted parameters are of dubious value fo r lar ge - scale extrapolation , and for control purposes a very simple b u t s e l f - ad ap t in g algorit hm is s at is fac to ry if the di s turb an c e s are small in magnitude . The fin al goal o f the model work is to understand the un derlyin g physics and c he m ist ry of t h e syste m , and t hi s goal will not he re ac h e d un ­ l e ss the complete reactor performance can be patched to ge ther by the build­ ing block met ho d . N u m e r i ca l

Techniques T he lib rary rou tine s for be g en er a te d extemally ,

parameter e s ti m a tion r e q uire that

E.

=

•

=

•

=

.

•

•

.

49

N umerical M e t ho ds in Reac tio n Engineering

TAB LE

2

S teps lea din g to .12. ( or

Recirculation

el

Plu g- flow ( or batch) reactor mod

b ackmi x )

reactor model

Model :

E;,

� :::: TR ( � . J2.) T ::::

Algebrai c

F

equation :

i D e ri v ati ve

T. 1

=

1

-

d E;,

1

E;,

i

=

.-

�

1

T. 1

E;,i

-

i

n

-

i

0

R ( E;, i , E._) :::: 0

1, 2,

dF.

of F . :

Iteration :

E;,i :::: - -

1

�

d r,;

R ( l,; , J2.)

(

dF

dF

E;, 1.

.

dE;,:

r

d This leatheds

For each i repeat the conver gence . Next , u p at e .12. usin g matri x ( a �J a �) :

=

d l;

F

i

E;, .

1

1, 2,

.

•

.

, n

1.

i

1 R.

1

=

: =

dFi /dE;,i ,

E;. .

1

+

R. F . 1

1

of F i , and � E;, i until = � s at t he given £ :::: E o · followin g procedure wit h a diagonal

calculation

to

�

Gradient of z:

for bot h reactor m o de l s

C ! t �. "

Finally , use Eq . ( 1 43) or

a

similar for m ula

s 12 ( : � ) �¥_ R

to update .12..

d r,;

50

Vil ladsen and Miche lsen

S till , a close analo gy exists i f t he differential equation model is approx ­ imated by a discrete model from T = 0 to T m ax · T his can be done , for example , by global colloc ation . I f the colloc ation order N is hi gh enough , t he di sc rete model is an adequate representation of the original model , and the solution :l. sc is c los� to :l_ s · Hence , w hen t here is t he us ual no_! se in t he dat a , the estimate £. is not statistic ally inferior to t he estimate :e_ which would be obtained by an "exact" solution of the model . When t he N t h - order collocation model is solved to m achine accuracy , the sensitivitie s are calculated wit h only a s mall extra effort , and they are based on t he exact solution of t he ( approximate ) model at T i • j ust as is t he case for solution of the ( exact ) algebraic equation model whic h describe s recirc ulation reactor dat a . T his is import an t : if there is an inconsistency bet ween 'l. s and a l. / a e_ , the parameter- fittin g algorithm converges slowly s or not at all . A remark on this p oin t was made earlier in the section on sensitivity function s . Most autom atic inte gration routines , whether they are b ased on explicit or semi -imp licit R u n ge - Ku tta procedures or on Gear ' s method , operate wit h a fixed accuracy i n each step or w i t h some other de ­ vice that is outside t he u ser' s cont rol , and i t i s difficult to obtain cor ­ respondin g value s of l. s and a l. s I a £.. A truly implicit , stepwise inte gration routine will give consistent sen ­ sitivities when t he sensitivity equation s are solved one by one after con ­ ver gence of :l_s has been reached in t he step [ see E q . ( 46) ] . When u sin g an exp licit or a semi - implicit inte gration method , one s hould solve the state equation s to gether with m numerically perturbed equations . ( £_ = P l . P 2 · , Pm > · T his is no more diffic ult t han the p rocedure ( 4 6 ) when t he method is explicit . For a semi -imp licit method where all ( m + l) M e quation s have to be solved sim ultaneously , it is hi ghly pro fit able to modi fy t he LU decomposition routine to utili ze the (M x M ) block diagonal structure of the [ M ( m + 1 ) ] - dimen sional J acob ian matrix . Collocation applied to p arameter estimation in di ffe rential equations was first proposed by Van den B o sc h an d H ellinckx ( 1 97 4 ) . As explained above , it m ay be an excellent app roac h to transform each differential equa­ tion into N collocation equation s , but u n fortun ately a n umber o f misconcep ­ tions about the proper use of the method are app arent from the literat ure , the most misleadin g bei n g that " the experimental points should be chosen at value s o f the indepen dent v ariable ( axi al position , etc . ) whic h are zeros of a specific J acobi polynomial . " Obviously , the N collocation points s hould be chosen to m ake t he ap p ro xim ate solution l.sc a s close to :l. s as po ssible . T he collocation order N in one particular coordinate m ay have to be m uch hi gher than the available number of data points n in this direction - a situation t hat occurs i f Y s i s not a smoot h function o f t hi s particular in ­ dependent variable . A fte r havin g solved t he model by a sufficiently hi gh order collocation method , one m ay ( without los s of acc urac y ) interpolate the solution to t he values of the independent variable w here the experi ment al value s X.e are available . I f , on t he other hand , there are m any more e xperiment s t han required for comp arison with a collocation solution of sufficiently hi gh order N ( t his may be t he case if t he experimental results are recorded autom atically ) , one applies N t h - order polynomial least - sq uare s fittin g o f the ori ginal data to obtain a synt hetic data base :X.ec at the same values o f t he independent variable where the collocation solution is constructed . B aden and Villadsen ( 1 98 2 ) give a c ritic al review of collocatio n - based T hey emp hasi ze t he i mportance of choosin g parameter estimation met hods . .

•

.

N umerical Me t ho ds in Reactio n Engineeri n g a co llocation met hod that give s t he b e s t po s sible fit between t he solution to t he ap p ro ximate model an d t he ( u n know n ) solution � s of the exact l.sc model . T heir model B is t he same as t hat proposed above : solve t he collocation e qu a t ion s , fi n d the gr adien t dr_ sc / de_ an d up d ate 2.· One m ay

51

,

either choose to solve t he collocation equations to m ac hine accuracy be fore

calculatin g l'l 2. or take j u s t on e step in t h e iteration towar d t he solution o f

t h e collocation equations be fore u p d at in g

method A ) eters .

only

E.·

A p articular variant ( their

m ay b e valu a b le to find good startin g value s

E_

for the p aram ­

If the differenti al eq u at ion model is line ar in t he parameters ( or

sli ghtly no n lin e ar ) , a sit uation t hat fre q u e n tl y occurs , one obtains a

very good e s timate for

£. b y

( 1 46 )

ON is t he re sidual of the differential equations when the dependent v ari ab le

l. is

rep l ac e d by �e c , t he " synt hetic" data b ase re ferred to the c ollocation points as described above , '!F 1 is an e stimate for the di spe r si on m atrix for

the re sid u al O N .

I t is only a weak function of p and may be evaluated at

any re aso n abl e point E. o .

( 147)

T h e g ene r al co llocation method m ay ,

however , b e ap p li e d for models that are nonlinear· in t he parameters as well as i n the state variab le �· I t is equally ap p li cab l e for p arameter estim ation in n onlinear coupled ordinary ­ differen tial - eq u ation mode l s ( w here it competes wit h t h e e x plici t or semi ­

implicit initial value tec hniq ue s ) an d for p arameter estimation in boundary value pr o b l em s .

The best doc u m e nt e d general code for p a r amet e r e st i m at io n u sin g col ­

location i s developed b y S �rensen a n d S tewart .

in app en di x e s to SISren sen ( 1 982).

T h e soft w are i s shown

Special attention should be given to t he linear bo un dary value proble m s

which ar e the b a sis for Fourier expan sion o f lin e ar PD E [ e . g . , variant s o f Eq . ( 128) ] , since the se models occ u r so freq uently .

Michelsen ( 1 97 9) convincin gly demonstrated that the transport p ar am ­

eters ( radi al d isper si on and a wall transfer num be r )

can be e stimated with o n ly one di ago n ali z at ion o f the collocation matrix ( for B iM -+- oo ) and sen ­ sitivi ties calculat e d analytically

from the e i ge nvalue s an d ei genvectors o f

C.

T he resultin g reduction o f computer time comp ared t o p re vious c alc ul a ­

one

W hen v z ( x ) = 1 , a situation that c ertainly occurs in pellet problems , m ay find the radial transport p arameter , t he wall transport parameter ,

tion s

on t he same dat a bas e w as at le ast by a factor of 2 0 .

and Da simultaneo u sly .

dure

of Michelsen

l_( T , D a )

=

T here are only trival modi fications in the proce ­

( 1 979) :

The solution with Da

exp ( - Da T ) �( T , D a

=

0)

f. 0

is si m p ly

( 1 4 8)

52

Villadsen a n d Michelsen

where dx_/d T = < Q - D a !) x_ an d x_( T , Da = 0) is found by the procedure ( 1 2 8 ) and ( 1 2 9) with D a = 0 . W hen V z ( x ) depends on x , a new diagonali zation i s required for each

value of Da but the sensitivity wit h respect to Da can still be de ri ve d C onsider the system quite inexpensively . 1

d dT ( x_)

Dap

\¥'X,

=

with solution

�

exp ( �

T )�

-1

x_ 0

( 1 49)

The sen sitivity zo a with respect to Da is found by solution o f the inhomo­ geneous linear differential equation d (! ) oa dT

=

Mz

= -D a

- V - 1v =

Jl...

w here z 0

- a

( T = 0)

=

0

( 150)

with solution

�

- ex p ( � h )

Da

J

T

0

1 exp ( - � t ) ;¥ - _l( t ) dt =

w here

s.. 1]

and

=

{ ()..�

Tr . 11

for i 4: j

r . . is an element of � = 1]

( 1 51)

exp O.. T ) 1

for i = j

� - 1;¥ - 1�

When the rate term is nonlinear i n x_ s , one p ro c ee ds more o r le s s a s described abo ve for the linear partial di fferential equation . Collocation i s used t o discreti ze t h e P D E i n the x direction b ut now t he collocation equa ­ tions are in t e gr ated in the T di rec tio n , either by collocation as proposed by Sorensen ( 1 98 2 ) or by a step wise p rocedure . Sen sitivities can be c alculate d by numerical pert urb ation , but at least 1

for t he case of a sin gle reaction it is also pos sible to use a semi -implicit Ru n ge - K utta routine to inte gr a te the N s tate equations and the N x · m analy ti c ally derived sensitivity e quations . T he calculation of the two highet i n E q . ( 4 7 ) is not difficult since , in contrast to d eri v ati ve s fyy and fp y the case of M coupled mdependent reactions , the collocation differential equations have a very simp le structure . T he nonlinearities are found only in the m ain di a go n al of the Jacobian ;[ , w he r e as all the other ele m ent s in l are constant s . It is n ear l y impossible to give a balanced picture of the subject of parameter e st i mation within the framework o f one section of one chapter in a boo k . So many things are involved , and most o f t hem have more to do with common sense en gineerin g that with mathe m atics : the p roper choice

N umerical Metho ds in Reactio n E n gi neering

53

of experimental equipment an d analytical method , p lannin g of experiment s , and a gener al pessimism concerning the influence of all the variab les w hich for one re ason or another were not included in the investi gation .

T he methods t hat we have c hosen to discuss have been used by us and by others in many different situations , but still m any topics have been left out . It is hoped that E xample s 7 and 8 , which m ark the end of our review , will also emphasi ze some of the facets of p arameter estimation that could not be adequately covered in the p recedin g text . sion

Examp le 7 : Determination of a firs t -order ra te cons tant and a disper­ coefficient fro m exp eriments in a laminar flow t ub ular reactor Consider

the mass balance ( 1 2 5 ) with zero mass flux at t he wall , and consider a series of experiments in which t he velocity - average d outlet concentration y in Eq . ( 1 2 5 ) has been measured at di fferent axial positions z iri a reactor tube of given diameter . It is desired to estimate the rate constant kR and Experimental result s of t hi s kind were obtained the radi al diffusivity D . b y C leland and Wilhelm ( 1 9 56) , w ho determined D assumin g that kR was

known . T h e experimental setup is also described by Seinfeld ( 1 96 9 ) , Sein ­ feld and Lapidus ( 1 97 4 ) , and Van den B osch and Hellinckx ( 1 9 7 4 ) , w here kR was to be determine d w hile the dispersion n umber w as assumed to be known from independent measurement s . We shall consider the possibility of simultaneous estimation of the two parameters . Write E q . ( 1 2 5 ) as

( 152) where 1/J gi ve

2 D /k R r . t

=

N

Y

=

L

The solution of Eq . ( 1 5 2 ) by collocation is averaged to

c. exp ( >. . Da z )

1

( 1 53)

1

1

w here the con stants Cj an d >. i are functions of 1jl only . A set of equivalent e xp eriments would comprise variation of va v at fixed tot al reactor len gth and diameter . Let Dar = k R L /vav r and , Da z

=

r

Da z'

where z '

z

v

av , r v av

---

( 154)

1 , the value of z' = vav r /v av . Numeric al values of Ci and of A i are c alc'ulated for 1jl = 0 . 1 , the value used by Seinfeld ( 1 96 9 ) and Lapidus and S ein feld ( 1 97 4 ) :

and the outlet

1

2 3

>. . 1

,

z=

1

c.

- 0 . 842 9

0 . 92 1 1

- 2 . 30

0. 069

- 5 . 26

0 . 007

54

Vi lladsen and Michelsen

A perturbation analysis for

l ar ge 1)1 [ see E q . ( 1 2 2 )

for the first term ]

yields A.

c

1

1 -1 + - 4 8 1j1

=

1

1 -

=

1 7681j1

2

1 1 9201)!

2

+ 0 ( 1)1 - 3 )

( 155)

3 O ( lji- )

+

2 while A. i 1\, O ( lji- 1 ) and � 1\, O ( f > for i > 1 . W hen ljJ is large enou gh to allow terms in ljJ- 2 to be neglected ( ljJ 0. 1 is barely large enou gh to permit this approximation ) , the expansion ( 1 5 3) can be truncated after the first t e r m : =

Y�

exp

[ ( Da

r

-1

+

�

4 1)1

) ]

( 156)

z'

and measurement s of y alone are not sufficient t o determine sep arate values of D� and lji. Only the product Dar ( - 1 + 1 / 4 8 \jJ) will be found by plotti n g In y versus z' We have c o n s t ruc ted the followin g " mea s u r e me n t s " of y for Dar = 2 and ljJ = 0 . 1 by high - order collocation of E q . ( 1 5 2 ) and truncatin g t he results after the third digit : •

z'

y

- In y

- In y/ z'

0. 1

0 . 826

0 . 1 912

1. 912

0. 2

0 . 687

0 . 3752

1 . 877

0. 3

0 . 555

0 . 5551

0. 4

0 . 48 1

0 . 7319

1 . 850 1 . 830

0. 5

0 . 404

0 . 90 6 3

1 . 813

0. 6

0 . 340

1 . 079

1 . 798

0. 7

0 . 286

1 . 252

1. 788

0. 8

0 . 2 41

1 . 42 3

1 . 779

0. 9

0. 203

1 . 5 95

1 . 772

1

0 . 172

1. 7 6 0

1 . 760

A c c o r di n g t o E q . ( 1 5 6 ) , t h e ratio ln y / z ' sh o u l d b e constant , an d since this is not quite so , we m ay be able to determine both parameters D ar and

lji.

Linear regres sion of t he data with z ' > 0 . 5 yields In y - 0 . 0 5 3 - 1 . 7 1 z' now , from Eq . ( 1 5 3 ) , truncate d after the first term ( w hich is certainly adequate fo r lar ge z ' , say z' > 0 . 5 ) , one obtains i ni tial estimates for Dar =

and

an d 1)!:

"Y �

(

l -

1

-

7 68lji

2

)

( 157)

55

N umerical Methods in Reac t ion Engine e ri n g

The re s ul t i s 2. o

( DRr , lji) o = ( 1 . 9 3 , 0 . 1 5 7 } . These values are used as initial values in a comp le t e least - squares pro­ ce dure b ased on Eq . ( 1 5 2) , which i� solved by t hre e - p oin t collocation , and on all the " experimental" p oin t s ( z' , y ) . T he sen sitivity with re sp e c t to DRr is found by differentiation of Eq . =

( 1 52) : N

>. . z ' c . 1 1

L:

d dD a

1

1'

1

exp ( >..Da

r

( 158)

z')

while the sen si ti vi ty with respect t o 1jJ i s found by numerical p e rt urbation ( although an a ly tical differentiation could also be used ) . C on ver gence is ob t ai n e d in a few iteration s , and total c om p uti n g time ( WATFlV compiler , H ar w e ll VB0 1AD p a rame t e r estim ation pro gram ) is 0 . 2 s.

The results are 1j!

1 . 994 ± 0 . 1 %

=

( 1 59 )

0 . 104 ± 2 %

1j! is su b s t an tial , con sidering that the data are accurate to di gits , an accuracy that is n o t likely to be found in practice . T he rate constant is , however , determined w i t h t he expected small s t an d ard deviation . The two parameters are s tro n gly correlated ( correlation coe f­ ficient 0 . 95) and t hi s , combined with the large standard deviation of lji , show s that t he use o f l a mi n ar flow reactor data for y are u n suit able for determination of lj! , b a s e d on a " known " value of D a . A small error in the rate constant will be stron gly m a gni fie d when 1/J is e sti mate d . Converse­ ly , an approXimate value for 1j! is all we need to determine a very good The

error o f

three

estimate

for t he rate constant , us in g exactly the same dat a . Finally , it sho ul d be m e ntio n e d that concentration measurements at t he e xi t of t h e tube , but at the centerline ( i . e . , m e as u r e m e n t s on samples

taken through a small-bore tube which is centrally placed in the reactor tube) will be much better suited for determination of the two p arameters . We have repeated t he estimation , but based on 10 " measurements" taken at x = 0 and with the same " ex p e rime n t al error . " Now 1jJ is found to 0 . 1 0 04 wi th a standard d eviat ion o f on ly 0 . 4% , while the value of D a is 1 . 997 and has the s a m e standard deviation ( 0 . 4 %) as be fore . The result , which is o bt ai n e d by a si m p le n u m e ric al analy sis of t he model from whi c h the parameters are to be extracted , illustrate s how an experimental program can be gui d e d by si m ul at ion studies .

Examp le 8: Kinetics of a homogeneous liq u i d -p h a se subs t i tutio n reactio n ( " the Dow C hemical Company tes t p ro blem " ) In 1 9 8 1 , B lau et al . from the Dow C he mi c al Company p ub li s he d the formulation of a multi-response ­ parameter estimation problem . T he problem is co n c er n e d with an i nd u s t ri al reaction , " hidden" behind the followin g symbolic nomenclature :

HA + 2BM

=

It is a liquid - p hase re ac tion

M- an d Q+ .

( 160)

AB + HMBM c at al y z e d b y Q M ,

which i s fully

di s sociated to

56

Villadsen

and

Mic he lsen

T he problem w as given t o a number o f research group s in t he U nited State s and in E urope w ho were s upposed to cont ri bute with a solution . A com pari so n of t he solutions would , it w as hop e d , give a review of the state of the art in p ar ameter fit tin g for r eaction en gi n eerin g m o dels H ere w e sum m ari z e t he more ge n e ral conclu sions from the solution that w as sub ­ mitt e d by o ur group ( S arup , 1 98 2 ) . T he postulated mechanism is ( B lau et al . , 1 98 1 ) : .

K

HA

2

-- A- +

H

+

HABM ( - H )

MBM

-

+

H

+

+

HMBM

T able 3 summari zes t he T he reaction is carried out in a b at c h re actor . co nc en t r ation - t i m e p r ofi le s for one of the t hree temperatures used in t he e x p er i me n tal w or k T here ar e three rate co nst an t s , k 1 , k _ 1 , a n d k2 , an d there are t hree equilibrium constant s , K 1 , K 2 , and K 3 . A ctivation energy and frequency fac t or for t he t h re e rate constants and value s o f t he three t e m p e r at ure i n depe n den t e quilibri u m constants are d esired . T he 10 s p ecies HA , B M , HABM , AB , HMBM , M-, A-, H+ , ABM , and MBM- are given by mass balances six ordinary differential e q uation s coupled w it h three eq uilibrium relation s and one condition that expresses electroneutrality . At t = 0 o n l y HA and B M are present with a s m all amount of c atalyst QM . - 17 I nitial estim ates for all p arameters are given by B lau et al . ( 1 9 8 1 ) . From the set of initial e st i m at es we shall mention only t h at K = K = 1 0 3 1 and K 2 10- 1 1 Our solution of t he problem p roc eeds in t he fo llowin g t hree step s : 1 . A na lysis of t he o ri gi nal dat a . A closer study of the dat a in T able 2 reveals an al ar min g fit o f the mass balan c e for B . Except for obvious misprints it is seen t hat .

­

-

,

=

c

BM

=

c

BM

-

c

H AB M

- 2c

AB

( 161)

T he data were an aly ze d by t h e method of B o x ( 1 9 7 3) an d i t w as found that t here is not o n ly one , but two linear relations between t he " ori ginal" dat a . C orr e s po nd en c e with B lau gave the following s upplementary information : a. b.

Cs M was not me asured , but back - c alc ulated from t he m ass balance ( 16 1 ) . T he concentrations of HA , H ABM , an d AB were all measured , but t heir s um was normali zed to a gree with a " known" initi al concentra­

tion of HA :

57

N umerical Metho ds in R eactio n E ngi neering

Concentration Versus Time Profiles for Dow C hemic al Company Test Example ( T 4 00 C )

TAB LE 3

T he

=

Concentrations ( g mol /kg)

Ti m e

BM

HA

HABM

AB

0 . 00

8 . 3 20 0

1 . 7066

0 . 0000

0 . 0000

0 . 08

8 . 3065

1 . 6 96 0

0 . 0077

0 . 0029

0. 58

8 . 2 95 4

1 . 6 82 6

0 0 2 34

0 . 0 00 6

1 . 58

8 . 2 7 30

1 . 6 5 96

0 . 0 47 0

2 . 75

8 . 2 4 37

1 . 6 3 05

0 . 0763

3. 75

8 . 2277

1 . 6143

o . 0 92 3

4 . 75

8 . 2026

1 . 5 8 92

0. 1174

5 . 75

8. 1781

1 . 567 3

0 . 1 37 1

8 . 75

8 . 126 5

1 . 5133

0 1 93 5

23. 05

8. 0 167

1. 4075

0 . 2 94 9

21 . 75

7 . 8440

1 . 2308

0 . 4760

2 8 75 .

7 . 6 97 7

1. 0931

0 . 6047

0 . 0088

46 . 2 5

7 . 3234

0 . 7268

0 . 95 30

0 . 026 8

52 2 5 .

7 . 14 95

0 . 5773

0 . 0881

0. 0412

76 . 2 5

6 6123

0 . 206 5

1 . 2 92 9

0 20 7 4

106 . 2 5

6 2309

0 . 06 5 0

1 1 94 1

0 . 4475

124. 2 5

6 . 1220

0 . 0391

1 . 1 37 0

0 . 5 3 05

1 47 . 75

6 . 0084

0 02 44

1 . 0528

0 . 6 2 94

172 . 2 5

5 9 1 93

0 . 0 1 45

0 98 3 5

0 . 7086

1 96 . 2 5

5 . 8556

0 . 0083

0 . 9326

0 . 76 5 9

2 1 9 . 75

5 . 8037

0 0 074

0 . 882 1

0 . 81 71

2 40 . 2 5

5 . 7680

0 . 0050

0 . 8 4 92

0 . 8514

274. 25

5. 7222

0 0047

0 . 8064

0 . 8 957

2 92 . 2 5

5 . 702 1

0 . 0042

0 . 7869

0. 9155

3 16 . 2 5

5 6 72 2

0 . 00 1 5

0 76 2 8

0 . 94 2 5

340 . 75

5 6 5 93

0 . 0017

0 7 495

0 . 9556

36 4 2 5

5 . 6351

0 . 7263

0 . 97 9 3

3 86 . 7 5

5 . 6176

0 . 7112

0 . 9956

412 . 2 5

5. 6131

0 . 7063

1 . 0 00 3

4 4 2 . 75

5 . 5 99 1

0 6 92 7

1 . 0 141

460 . 7 5

5 . 5 95 9

0 . 6871

1 . 0 1 95

( hrs)

.

.

.

.

.

.

.

.

.

.

0 . 0024

.

.

.

.

.

.

0 . 0 0 42

.

58

Villadsen and Mic he lsen

TAB LE 2 ( C on ti n u e d ) C onc e nt r ati on s ( g mol /kg)

T ime ( hrs )

HA

BM

HA B M

AB

4 83 . 7 5

5 . 5 90 5

0 . 6837

1 . 0229

5 07 . 2 5

5 . 5 7 . 36

0 . 6672

1 . 0 3 96

55 3 . 7 5

5 . 5568

0 . 6 4 94

1 . 0574

580. 75

5 . 5631

0 . 6467

1 . 0551

651 . 25

5 . 5472

0 . 6408

1 . 0660

673. 25

5 . 5516

0 . 6452

1 . 0616

842 . 75

5 . 5 465

0 . 6 3 97

1 . 0669

So urce :

0 . 0 0 46

B lau ( 1 9 8 1 ) .

H

C A

=

CH

A

+

C HA BM

+

c

( 162)

AB

T his normali zation is common practice i n analysis of chromatographic dat a an d t he error is not as " crude" as that involved in ( a ) . Still , when normali zed m e as u r e me n ts are used , the error structure of t he true measurements is completely distorted and one m ay u se a stand­ ard le ast - sq uares app ro ach rather than one o f the more sop histicated statistical criteria .

.

T he comments re garding the data base should not be co nstr ue d as a criticism of the author of t he p ro bl em A preli minary analysis of the raw data is alw ays valuable , and t he flaws in the original data m aterial are p robably typical for what can be e xpe cted in pr actice . O u r conclusion has been to delete t he concentration meas u r em e n t s o f c from t he dat a b ase since they con t ain n o independent information . BM 2 . Preliminary analysis of the model . Total m ass b alances for A , B , and M and the three equilibrium relation s can be used to eliminate 6 out o f 10 dependent variable s to give a set of three coupled di fferential equations and one algebraic equation . T he postulate d values of the dissociation const ants K 1 , K 2 , and K 3 are so small t hat the acids are almost totally undissociated . One mi ght assume that the concentration of H+ is nearly zero , an d this reduces the model to thre e differential equations in t hree components , chosen as H A , B M , and M-. C - , CABM , and c MB M - are given by A c

A

_

=

(1

+

K

3

K2

c

HABM c HA

+

Kl

c M H BM K cH A 2

)

-1 (c

Q

+

_

c

M

-

)

( 163)

59

N umerical Metho ds in R eac tion E ngineeri ng K c

HBM-

1

c

K2

=

C HMB M Ac HA

while c A B , cA B , an d c H M B M are calculated from t he total m ass balan c e s M H for A , B , and M . E xc e p t for the ass u mp tion c 8 + "' 0 , t he r e are no ap ­ proxim ations involved re l ati ve to the original model , and we have c he c k ed that our results for the parameters are virtually unaffected by t he assump ­ tion c H+ "' 0 . With this assumption - which appears to b e q uite realistic-it i s impos ­ sib le to find ab so lu te values for the equilibrium constants K 1 , K 2 , and K 3 . Only their ratios K 3 / K 2 an d K 1 /K 2 can be foun d . I f these ratios are as sm all ( c a . 10 - 6 ) a s in dicate d in t he p ro b le m de scription , the s ys t e m is extremely stiff : cH A will decrease al m o s t to zero , following p seudo - ze r o - o r der kinetic s . When cH A h as b e c o me of t he order of K 1 /K 2 , t he rate e xp re s sion chan ge s t o pseudo first or d e r in cHA . All H A would essentially have to react before the " dead- end" reaction to HABM rever ses direction an d st arts to s e n d A B M- b ack into t he main reac ­

tion sequence .

3. Sim u lation and parame ter es timatio n . To s im ul at e the solution � of the mode l , we used the IMSL ro ut in e D GEAR , which w as modified to include algebraic ( " e x act" ) evaluation o f the sen sitivitie s with respect to t he p aram ­ e t er s T here are in all ei g h t parameters in k 1 , k_ 1 , k 2 , K 1 /K 2 , an d K 3 /K 2 , but s en si tiviti e s wit h respect to activation ener gy Ej and fre q ue n c y fac to r ex;, of t he rate con stants lq c an easily be co m p ut e d from t he sen sitivities with re spect to ki :

.

.£.1: a

a.

=

ll.

ll. a k

·a k a

��

aE

exp

=

a

ak aE

- �

T

=

(- � ) ll. (- � ) � T

exp

ak

( 164)

ok

T

2 4 s en siti vi t y e q u at io ns With thi s simple device the o ri gi n al 3( 2 • 3 + 2 ) are reduced to 15 e q uatio n s . Also , it is important to re sc ale the p arameters since the m a gnitude of a an d E are so diffe ren t t hat it become s difficult to har mo ni ze t he sensitivi ­ ties . Instead of <X and E , we u s e k ( T o ) an d E / 0 d e fin e d by =

k

=

a

( �)

exp -

=

[

T

k ( T ) exp 0 T

E

(1

O

T :)]

( 16 5 )

w here T i s a sui t able re fe rence temperat ure ( chosen a s t h e middle o f the o t hree te m per at u r e s used in the e xp er i me n t a l investi gation ) . W it h t he re ­ scaled p ar amet er s a lar ge part of the inherent correlation between t he two par am e t er s involved in k is removed . In ge ner al if a new p arameter P t f( p 0 ) is introduced inste ad of p 0 , one obtains the sensitivity wit h respect to p 1 by the simple al gorithm

,

=

Vi llads en and Mic he lsen

60

( 166)

T he Harwell code VB 01AD was used for the leas t - s quares minimization . The routine is b ased on the Levenberg- M arq uardt method , and it require s an alytic derivative s of the error vector with respect to the p ar ameters . T here w as no diffic ulty in obtainin g the minimum of the sum of least square s - about 1 0 s of CPU ti me to determine all eight parameters ( w hic h corresponds to ca . 0 . 5 s per inte gration of t he model and the 1 5 sensitivity differential equation s ) .

It i s remarkable that the inte gration of t he three equations for C H A , CS M , an d eM - t o get her with all the sensitivity equations - requires only H ere it is twice t he time used for the three quation s o f the state vector . m uc h better to use exactly derived s ensi t i vit y equations than to use numeri ­ cal perturb ation of the parameters , w hich is consider ably slower ( by a fac ­ tor of 6) and requires a m uc h hi gher inte gration acc uracy to give meaning­ ful re sults . A lso , a comment on t he initial values of K 3 /K 1 an d K 1 /K 2 i s necessary . To obt ai n the best e stim ate s for these p arameters ( 1 . 43 and 0 . 0 6 7 2 , re ­

spectively) it w as necess ary to start with an initial estim ate of K 1 /K 2 which w as decidedly larger than the small value 1 0 - 6 su gge sted by B lau

( 1981) .

It is not difficult to se e from T able 3 t hat c H A B M starts to decrease much before H A has been consumed , and consequently that K 1 /K 2 has to be lar ger th an w - 6 . It is , however , not at all obvious that the routine K 1 /K 2 and q 3 = K 3 /K 2 if the fails to predict the correct values of q 1 ori gi n al e stimate o f the parameters is used . T he reason is that the object function is affected only by t he ratio q 3 /q 1 , not by their absolute values when they are as small as 1 0 - 6 , and it becomes impos sible for the routine to drag the parameter values all t he w ay from 10- 6 to t heir correct values 1 of about 1 o - . =

The integration routine is much faster w hen ( K 1 /K 2 , K 3 / K 2 ) are of the T he reason is the sudden increase order of 1 t han w hen they are c a . w - 6 . of stiffness that occurs when c H A "' 0 , and t he apparent reaction order o f the reaction A- + B M -+- A B M - c han ges from zero to 1 . T he problem m ay occur q uite frequently in t he app lic ation of standard " kinetic codes , " an d it m ay be illustrated by the sim p le rate exp re ssio n ( 1 6 7 ) :

with k

"'

1 an d K

"'

10

-6

( 167)

Even a good numerical inte gration routine ( e . g . , DGEAR ) will fail to notice the rapid chan ge in the structure o f the solution when yA "' 1 0 - 6 and will happily i n t e gr at e to ne gative concentrations of A . This m ay have a disas ­ terous e ffect on the computation of other reaction species , w hich m ay be heavily influenced by the concentration level o f component A .

R E F E R E N C ES Aris , R .

T he Mathema t ical T heory of Diffusio n and R eac tion in Permeab le C a t aly s t s , C l are n do n P re s s , Oxford ( 1 97 5 ) .

N umerical Metho ds in Reac tio n Engineering

61

Aris , R . , and N . R . Amun dson , Firs t O rder Partial Differen tial Eq uatio ns with A p p lications , Prentice - H all , En glewood Cliffs , N . J . ( 1 97 3) . B aden , N . , and J . Villadsen , A Family of collocation based methods for parameter estimation in differential equations , C hern . En g . J . , 23 , 1 ( 1 982 ) . B lau , G . , L . Kirkby , and M . M arks , An industrial kinetics problem for testin g nonlinear p arameter estim ation al gorithm s , The D ow C hemical Company , Midlan d , Mich . ( 1 98 1 ) . Box , G . E . P . , W . G . H unter , J . McGre gor , and J . Erj avec , Some problem s associated with the analy si s of multiresponse data , Techno ­ metrics , 1 5 , 33 ( 1 9 7 3) . B yrne , C . D . , Some software for solvin g ordinary differential equations , in Fo u ndatio n s of Comp uter-A ided C hemical Process Design , Vol . 1 , S . H . M ah an d W . D . Seider , eds . , E n gineering Foundation , New York , 1981 , p . 403 . C aillaud , J . B . and L . Padmanha.b an , A n improved semi-implicit Run ge­ Kutt a met ho d for stiff system s , C hern . En g . J. , 2 , 2 2 7 ( 1 97 1 ) . Christian sen , L . J . and S . L . Andersen , T ransient profiles in sulphur poi sonin g of steam re formers , C hern . En g . Sci . , 3 5 , 3 1 4 ( 1 9 8 0 ) . Cleland , F . A . and R . H . Wilhelm , Diffusion and re action in viscous flow tubular reactor , A I C hE J . , 2 , 4 8 9 ( 1 9 5 6 ) . Clement , K . and S . B . Jor ge n sen , E xperimental investi gation of axial and radial t herm al dispersion in a p acked bed , C hern . E n g . Sci . , 38 , 8 3 5 ( 1 98 3 ) .

Crank , J . , Mathemat ics of Diffusio n , Clarendon Press , Oxfor d ( 1 95 7 ) . Finlayson , B . A . , T he Met ho d of W ei gh ted Residuals and Variat io nal Princ i p l e s Academic Press , New Y ork ( 1 97 2 ) . Finlay son , B . A . , Orthogonal collocation in c hemic al reaction en gineerin g , C atal . Rev . Sci . E n g . , 1 0 , 6 9 ( 1 97 4 } . Finlayson , B . A . , N o n linear A na l y s i s in C hemical E n gi neering, McG raw -Hill , New York ( 1 980 } . Fletcher , R . , U nco ns trained O p timizatio n , Wiley , New York , ( 1 980) . Funder , C . R . , M . Sc . thesis (in D ani sh ) , I n stituttet for Kemiteknik ( 1 98 2 ) . Gear , C . W . , N umeri cal Initial V alue Prob lems i n O rdi nary D i fferential Eq uations , Prentice - H all , En gle wood Cliffs , N . J . ( 1 97 1) . Guertin , E . W . , J . P . Soren sen , and W . E . Stewart , E xponenti al colloca­ tion of stiff reactor models , Comp . C hern . En g . , 1 , 1 97 ( 1 97 7) . Hoffman , U . G . Emi g , an d H . Hofmann , C omp arison of different me thods for determination of e ffective thermal con ductivity of porous catalysts , A C S Symp . S er . , 65 , 1 8 9 ( 1 97 8 ) . Holk-Nielsen , P . , and J . Villadsen , Ab sorption with exothermic reaction in a fallin g film column , C hern . En g . Sci . , 3 8 , 1 4 3 9 ( 1 98 3 ) . Jackson , R . , T ransport in Poro us Catalysts , Elsevier , Amsterdam ( 1 97 7 ) . K aza , K . R . , Villadsen , J. , and R . J ackson , Intraparticle diffusion effect s i n the methan ation reaction , C hern . En g . S ci . , 35 , 1 7 ( 1 980) . Levenspiel , 0 . , C hemi c al Reac t io n Engineering, 2nd ed . , Wiley , New York , ( 1972) . Liaw , W . K . , J . Villadsen , and R . J ackson , A sim ulation of coke burnin g in a fixed bed reactor , A C S Symp . Ser . , 1 96 , 3 9 ( 1 982 ) . Michelsen , M . L . A fast solution technique for a class of linear PDE , and Estimation of he at transfer parameter s in packed beds from radial temperature measurements , C hern . En g . J . , 1 8 , 59 , 67 ( 1 97 9} . Michelsen , M . L . and J . V . Villadsen , Polynomial solution of differential equations , in Fo u ndatio ns of Comp uter-A i ded C hemical Process Design , ,

,

,

62

Villadsen and Mic he lsen

Vol . 1 , S . H . M ah an d W . D . S eider , eds . , En gi neering Fou nd atio n , New York , 1 9 8 1 , p . 3 4 1 . Mic helsen , M . L . , H . B . Vakil , and A . S . Foss , S tate space form ulation of fixed bed reacto r d ynam ic s , Ind . En g . C hern . Fundam . , 1 2 , 3 2 3 ( 1 97 3) . Miller , K . and R . Miller , Movin g finite element s , Siam J . N umer . Anal . , 1 8 , 1 0 1 0 , 10 3 3 ( 1 9 8 1 ) . Papout saki s , E . , D . R a mkris h na , and H . C . Lim , The extended Graetz problem with p r e s cri be d w all flux , A I C h E J . , 2 6 , 779 ( 1 980) . Patter son , W . R . , and D . L . Cresswell , A S imple method for the calcula­ tion of effectiveness factors , C hern . E n g . Sci . , 2 6 , 605 ( 1 97 1 ) . Peyt z , M . J . , H . Livbjerg , and J . Villadsen , S t eady state operation of a dual reactor system with liquid catalyst , C hern . E n g . S ci . , 3 7 , 1 0 9 5 ( 1 98 2 ) . S ar u p , B . , M . S c . th e si s (in D anish) , I n s tituttet for K e mit e kni k ( 1 98 2 ) . S e i n feld , J . H . , I dentification of p arameters in PDE , C hern . E n gr . S ci . , 24 , 6 5 ( 1 96 9 ) . S ein fe ld , J . H . an d L . L a pi d u s , Process Mo deling, Es timatio n , and Identi­ ficatio n , Prentice - H all , En glewood C li ffs , N . J . ( 1 97 4 ) . Sotircho s , S . V . an d J . Vill a d s e n , Diffusion and reaction with a limited amount of re actant , C he rn . E n g . Comm un . , 1 3 , 1 4 5 ( 1 9 8 1 ) . S un dare san , S . and N . R . A mu n d son , Diffusion and reaction in a stagnant boun dary laye r about a c arbon particle , I nd . En g . C hern . Fundam . , 1 9, 3 4 4 , 3 5 1 ( 1 9 8 1 ) . S�rensen , J . P . , S im u l a t io n , Regressio n , and C o n t ro l of Chem i c al Reac tors by Co llocatio n Techniq ues , Polyteknisk For lag , Lyn gby , Denmar k ( 1982) . S� r e n s e n , J . P . and W . E . S tewart , Collocation analy sis of m ulticomponent di ffu si on and re a ctions in porous c at alysts , C hern . En g . S ci . , 3 7 , 1 1 0 3 ( 1 98 2 ) . T aylor , G . , Di s p e r si o n of s ol uble m atter in so lve nt flo w i n g slowly through a tube , Proc . R . Soc . , A 21 9 , 1 86 ( 1 95 3 ) . V an den Bosch , B . , an d L . H e llin c k x , A ne w m e t ho d for the estimation o f p arameters i n differential e q uat i on s , A I C hE J . , 20, 2 5 0 ( 1 97 4 ) . Villadsen , J . , Se lec ted A p p rox im a t io n Methods fo r C he m i ca l Engineering Prob lems , I n s t itu t t et for Kemiteknik , Lyn gby , D enmark ( 1 97 0 ) . V i llad se n , J . and M . L . M i c he l s e n , So lution of Diffe ren tial E q uation Models by Po lynomial A p p roximation , Prentice - H all , E n gl ew ood Cli ffs , N . J . ( 1978) . V illad s e n , J . and W . E . S tew art , Solution of boundary - value problems by ort hogonal collocation , C hern . En g . S ci . , 22 , 1 48 3 ( 1 9 6 7 ) . Vi ll a dsen , J . and J . P . S � rensen , S olutio n of parabolic PDE by a doubl e collocation metho d , C hern . E n g . Sci . , 2 4 , 1 3 37 ( 1 9 6 9 ) . Wedel , S . and D . L us s , A r ational approxim ation of t he e ffectiveness fac ­ tor , C hern . E n g . Commun . , 7, 2 4 5 ( 1 980) . Wedel , S . and J . Vi l l adsen , Falsification of kinetic p arameters by i nc orr ect treatment of recirculation reactor data , C he rn . E n g . S ci . , 24 , 1 34 6 ( 1 98 3 ) . W heeler , A . , Reaction rates and selec ti vit y in c at aly st pores , Adv . C atal . , 3 , 316 ( 1951) .

2 Use of Residence- and Contact-Time

Distributions in Reactor Design REUEL S H I N N AR

N ew

The C ity Col lege of t h e City U ntversity of New York , York , N ew Y o rk

I N T RO D U C T I O N

Tracer experiments an d residenc e - time di s trib u ti on s m eas u rem en t s have been used b y reac tion en gineers for 5 0 y e a r s . They are a p ow erful tool with an i n cr e asi n g number of application s . T he fi r s t ri go ro u s p re s e n tation was given by Danckwerts ( 19 5 3) . S i n c e then a large b o dy of literature has accumulated an d the topics are discussed in several textbooks (Froment and Bischoff , 1979 ; Himmelblau and Bischoff , 1968 ; Sein fel d and L api d u s , 1 9 7 4 ; Nauman , 198 3 ; Le v e n s p iel and B i s c ho f f , 1 9 6 3 ) an d revie w articles ( S hin n a r 1 977 ; P e t ho and N oble , 1 98 2 ; N auman , 1 9 8 1 ; Weinstein and Adler , 1967) . T racer experiments and residence- time d i st ri b u ti on s are useful to re ­ a ction en gineers in several ways . T hey p r o vi de a di a gn os tic tool for t h e detection of m aldistrib utions and the flow pattern in side a react or . T hey a re useful in experim entally measuri n g the parameters of simplified flow models and p rovi d e i d e a s an d gui d e lin e s for creatin g and testin g such models . Finally , u n d e r s t an din g the concept of residence - time distrib ution gr e at ly sim plifie s the solution of many p roblems in reactor desi gn , incl u din g the choice of reactor confi guration , op ti mi z a ti on , and scaleup , and allows one to solve t hem without complex and ti m e c on sumin g c o mp u t a tion s . One must , however , be c ar e fu l not to expect more from the t echn iq ue s than they can deliver . It is extremely rare that one can eit her construct a reactor m o d e l o r p re di c t a r e act or p erfo r m an c e b ased solely on a residence ­ time di s t rib u tion ( S hinnar , 1 97 8 ) in a s it uation involvin g c o m p lex flo w s . Most reac tor s are heterogeneous , and the theory as p re sented in most text­ books is rigorously a p p li c ab l e only to ho m o ge neou s reactors . It is t herefore important to understand the a d van t a ge s as well as the li m i tati on s of the method . This writer has been in volved both in d evel opi n g som e of t he theoretic al c on ce p t s related to their u se and in their p r ac tic a l ap plic at ion s ( N aor an d Shinnar , 1 9 6 3 ; S hinnar and N aor , 1 9 67 ; K rambeck et al . , 1 969; Shinnar et al . , 1 97 2 ; N ao r et al . , 1 97 2 ; Zvirin and S hinnar , 1 9 7 5 ; Glasser et al . , 1 9 7 3 ; K rambeck et al . , 1 9 6 7 ; Silverstein and S hinnar , 1 9 7 5 ; S h in n ar et al . , 1 973) . I n the followin g sections I t ry to p re s e n t the subjec t in a way t h a t ,

-

63

64

S h innar

s e es a al pplicatuson discussing ad ta h sorand fal s e t c al work which the future u presents a personal viewpo applicability int r c c and in that sense chapter th h the re r with based on my re n original no historical mp t be m full Theng theoretical concepts for h mog n us systems are de d in the t c u the r in the measurements and their use and a li a ns in reactor mod of industrial reactors. Next, we deal with a t on he s n ofttepletih moge ous ac o s w h m ti has e tracers. Following a i ro u contact-time distributions, a e residence-time h is useful catalytic re­ actors. cwat summari c re zce thedeuse of residence-time co ta t me

t r ss p r ctic a i s both van ge pi t l . T hus , by necessity , I m t exclude a large amount of t e i may b ecome useful in b t has yet to p rove its in p a ti e , this ad e own experience . Al o ug I try to p rovide fere c e s to the literature , at te will a d e to give proper credits to p ap ers or to develop ment . o e eo rive fo l lo wi sec tion . Then we discuss experimental e hn iq e s for i pp c ti o eli n g and s ng p p lic a i s to t de i g o ne re ti n a n d it ul p systems and the use of m ul­ i t h t we n t d c e c on c p t similar to distribution t at in Finally e and n c ti di stributions in a ly t i a tor si gn ,

,

-

.

D E F I N I T I O N S O F T H E R E S I D E N C E- T I M E D I S T R I B U T I O N , AG E , A N D F U T U R E L I F ET I M E D I ST R I B U T I O N

a homogeneous rat i outlet streams are completely t the s stable and steady and that the inlet and a timer mixed. Let us now assume t a each fluid a e e that is activated when it t rs or a t ne a i gl exit from w h nn return to s i e with the ac tor. Each r e at th exit has a e Thisscalar property i , one the rfinesi thecedistribution timetimefor thatofp t As with any b ac o rti l This h less h a given t (see Fig. fr cti F(t) eis the s s rib atige as t e im orl arl F(O) aha m i ice with Res idence- T i me D i s t r i bution

e c or as shown in F g u re 1.

Consider flow i

Ass ume tha

p r ti c l is quip p e d with the reactor and stops when it exits . I t is i mp t n to d e fi s n e hic the particle c a ot pa tic l e tim t a s oc a t d it , w hich re measures the it s en in the reactor . q uan t ty is defined as e de n p article . can de this p roperty y the fr ti n of the p a c e s for which t e residence time is t an value 2) . a on defined a the residence- time distribution . [ Alternatively , one can d e fin residence - time di t u on h fraction of p articles molecules which s a residence time l r r than t , s ply 1 F ( t) . ] C e y 0 n d F ( t ) m us t b e a on o to n c ally n r a si n g function F ( oo ) = 1 . h t

·

en e

­

-

,

=

ro a dF(t) d

D e n s i ty Function For any p f(t)

I n le t f l ow

F I G U RE 1

b b ili ty

=

distribution , F(t) , the

derivative t a

h t is defined by

( 1)

t

R E AC TOR volu m e V

Q

e

S t ad y s ta -

t

Out

let

f l ow Q

e homogeneous reactor.

65

Residence- and Con tact- T ime Dis trib u t ions 1.0

u. z

0

1:::> IIl a:: 1(/)

0.8

0.6

F - F r a c t i on o f p a r t i c l e s w i t h re s i d e n ce t i m e in the r e a c tor less thon (t)

Cl

::!; j:::

w

w (.) z w 0 (/) w a::

0. 4

0. 2

0.0

0.0

1.0

2.0

TIME ( I )

(a) 0. 8

---

3.0

4.0

5.0

-- -- ----

0.7

0.6 0
::!; 0.5 !E

:::>

�

)(

0.4

0.3

0. 2 0.1

0.0

IDEAL S T I R R E D TA N K 1.0

2 .0

3.0

4.0

(b) FI G U R E 2

D e finition o f resi dence - time di st rib ution .

5.0

66

Shin nar

is called the den sity fun c t ion and is often of great in te r est .

In the case where F ( t ) is a residence - time distribution , f( t ) dt corresponds to the frac­ tion of fluid p ar tic l es whose resi dence time is bet w een t an d t + dt . S ome typical distrib utions of F ( t ) and f( t ) are given in Fi gure 3 . The way such distribution s are measured an d comp uted will be shown in the next s ectio n Some properties of the function will be discussed next . One should note that in the chemical en gineerin g literat ure the density function f( t ) is often designated E ( t ) and is sometimes called the res idence­ time dis t rib u tion . [1 F( t ) ] is often d esi gnated as l ( t ) . As there is a large literature on the mathematical p rop er ti e s of re si den ce time distribution outside the chemical en gineerin g literature , the standard notation F ( t ) and f( t ) will be used in this chapter . .

-

-

M ea n , Va ria nce , a n d Momen ts of f ( t )

The expected value or mean of t he den sity function f(t ) i s defined by 1"

=

Il l

f

00

00

=

E (t)

f

=

tf( t ) dt

=

0

f0

[1

- F ( t ) ] dt

( 2)

T his is also equal to the first moment of f(t) and is a widely accep ted meas ure of the central value of a di s t ri b ution In react or systems with con ­ stant density , it is equal to the volume or liquid hol d up of the reaction , divided by the flow rate : .

1"

=

v

( 2a )

Q

and is also known as the time c o n s t a n t of the syste m . For purposes of com ­ parison , it i s often useful to n or mali ze the residence- time distribution s uc h Therefore , we define that the time con stan t or mean value is unity .

e

=

t

( 2b )

w here e i s a dimensionless normali zed variable . Most of the graphs in this chapter use e . Another importan t measure i s the variance o f a distrib ution , V f ( t ) , which is defined by 00

=

f

[t

0

-

2 E r < t ) l f( t ) dt

=

2 Er
( 3)

V f ( t ) can also be c o m p ute d directly from F ( t ) by

{

00

2

t [ 1 - F ( t ) ] dt

( 3a )

The variance ( or the second moment wit h respec t t o the average ) meas ures dis t rib u tion Relative disperison is also frequently characteri zed by the coefficient of variation , the dispersion of a

.

67

Residence- a n d Con tac t- Tim e Dis trib u tio ns 1.0

2 .

/ ._ _ _ _ _ _ // /

v�

0. 8

'I

0.6

F(8 )

-- S t i r r e d To n k

0. 4

- · -

�

0.2 0.0

1 0 S t i r r e d To n k s i n S e r i e s

- - - - One Dim. D i f f u s ion

2

0

e

(a)

=

10

3

4

3

4

1 . 50

·'\

1. 25 1 . 00

I (8)

,1\ \ '/ \ .\ \ '\�

0.75

I I

0. 5 0

I I ,

0. 2 5 0.0

0

II ;

/,,

I '

./ '\

I.

1

\

\

\ .

·

(b) ( a ) Residence- time distribution , ( b ) residence- time den sity function for some simple theoretical flow models .

FI GURE 3

S h in nar

68

( 4)

y (t) W hen needed , hi gher momen t s can b e com p u t e d u si n g stan dard methods . T he rth moment of the density function f ( t ) is defined as 00

=

J

O

t

r

f( t ) dt = y

00

J

0

ty- l[ 1

-

( 5)

F ( t ) ] dt

I t sh o u l d be stressed that the function s f , F , and ( 1 - F ) refer to t he distrib ution of the resi dence times of particles as they app ear at t he exi t of the flow s y s tem . Li n ea r P r o pe rti e s of Resi dence- T i m e D i s t r i b u t i o n s Residence- time distrib ution s have t h e p rop er tie s o f linear function s . T hus if two systems are put in series ( see Fi g . 4a ) , the den sity function of t he total system is t he convolution of the two sy stem s , an d if they are par a llel , it is t he weighted average ( Fi g . 4b ) . T h us for mathe matical operations it is usef ul to ap ply the Laplace tran sform of f ( t ) , L [ f( t ) 1

00

f(s)

J 0

e

- st

( 6)

f ( t ) dt

T he Laplace transform can also be used as a moment - generatin g function . T he rth moment of f( t ) , ll r , is then given by

( 6a ) Flow sy stems are nonlinear s yst e m s in sofar a s the Navier- S tokes equa­

tion i s nonlinear . T he fact that re si den ce - ti me dis trib u tion s have the prop ­ erties of a linear system in dic ates t hat they provide an incomplete descrip ­

tion of the flow p roce ss in the reactor . T herefore , they cannot completely describe t he flo w , b u t represent only some importan t p roperties of it . If

one desi gn a tes t h e complete hydrodynamic descrip tion of all t h e fl o w s an d m a s s transfer processes in the reactor as M , then F is a linear property

as sociated with M . W hi le the tran sform ation of M into F i s unique , the op p osite is not tr ue . A s F is an incomplete description o f M , a sin gle F can have an in finite n umber of func tions M as sociated wit h it . In other words , there can b e a large n umber of comp le tely differen t hy drody nam ic

flow sys tems wi th the

same residence- time dis trib u tio n .

I n ten s i t y Function or E scape P ro ba bi l i ty

A residence - time di s t rib ution is a deterministic property of the flow sy stem . I t is sometimes advan t a geous to interpret it probabili stically . One can also look at F ( t ) as the probability that a sin gle molecule will have a residence

69

Residence- and Con tac t- Time Dis t rib u t io n s RE ACTOR I

Q

R E A C T O R II

Q

VOLU M E V1

V O L U M E v2

R T D - F1 ( t )

Q

RTD - F (1) 2

DE N S I T Y F U N C T I O N :

DEN S I!Y F U N C T ION :

f2 ( I )

t1 ( I )

R T D OF TOTA L S Y S T E M : f ( 1 + 2 ) (t )

I

=

0

/tl ( I -T) t2 ( •) d T

OR I N L A P L A C E D O M A I N :

f( l + 2 ) ( s )

=

t1 ( s )

*

t2 ( s )

AV E R A G E R E S I D E N C E T I M E :

=

(a) Ql

R EACTOR I

Ql

R E AC TOR II

Q2

1 1 ( 1 ) , v,

Q

Q2 = Q - Q l

Q -i

1 2 1 1 l , v2

vl

+ v2 Q

F1 ( I )

AV E R A G E R E S I DE N C E T I M E :

T

(b)

Residence - time distribution of two reactors : in p arallel .

FI G U RE 4

(b)

( a ) in series ;

Sh innar

70

T hi s p resents the in formation contained in C onsider a system characteri zed by the re sidence- time den sity f ( t ) . In probability term s , f ( t ) can be interpreted as follow s . If a p article enters the sy stem at time t 0 , the p robability of its leavin g the system within t h e time interval (t to t + d t ) is equal to A particle f ( t ) dt . However , a sli ghtly di fferent proble m may be posed . has already stayed in the sy s tem for a time t ; one wis hes to know the p robability of its leavin g the system within the next time element dt . Let time les s than

t in

the

reactor .

F ( t ) in a more acce ssible w ay .

=

this probability be denoted by A ( t ) dt . T h e func tion A ( t ) may be evaluated as follo w s . T he p robability of a particle leavin g the system between time t an d t + dt e quals f( t ) dt . T his p robability is the product of t wo terms : T he p robability of the particle not leavin g before t , which is 1 F ( t ) , an d the probability of its leavin g between t an d t + dt , as sumin g that it is still in t he system an d has not left before- this was define d as A ( t ) dt . T hus we obtain -

f ( t ) dt

=

[ 1 - F ( t ) ] A ( t ) dt

( 7)

an d by simp le rearran ge ment A ( t ) is derived as A ( t)

=

1

F ( t) F(t) -

-

=

d ln [ 1 - F ( t ) ]

( 8)

dt

A ( t ) i s t he con di tional p robability distribution an d is also known as the in­ t en si t y function or the escape probability . l t must be stress e d that there exists a one - to - one corre spon dence bet ween A ( t ) and f( t ) . In deed , the tran sformation of A ( t ) into f ( t ) is governed by

[{

t

f( t ) = A ( t ) exp

-

A ( t' )

dt

]

( Sa )

Physically , A ( t ) dt is a meas ure o f t h e prob ability of escape for a particle that has s tayed in t h e sy stem for a period t durin g the time in ter­ val t and t + dt . T hus , in th e case of an ideally ( exponentially ) mixed ve s sel , one expects the i nte n s it y function A to b e a constan t , as the c hance of escape d u ri n g any ti me interval dt i s independen t of p revious hi story an d is e qual to dt / 1" . T his is in deed t he case . A l t h ou gh there i s a one­ to - one correspondence bet ween f ( t ) , F ( t ) , an d A ( t ) , information about the prop erties of the residence - time distrib ution and the nature of the flow system is more easily acces sible from A ( t ) . U tili zin g the inten sity function , it is easy to demon strate a previously mentioned p roblem with re sidence - time distrib ution s , namely , that the rela­ T his is illu strated in Fi gure 5 , whic h tion b et ween F an d M is not unique . describes the properties of a n um b e r of theoretical flow models . Thus , for an ideal uniformly s tirred tank , A ( t ) m us t b e a constant ( see Fi g . 5a , curve A ) . However , the converse is not t r u e A A ( t ) that is con stant im­ plies t hat the escape prob ability of a particle i s in depen den t of its p revious history . In other words , t he information as to how lon g a particle has been in the sy stem tells us nothin g about i t s future behavior . T he fact t hat a system has this p roperty does no t p rove or in dic at e that it is an ideally s tirred reac tor . T he latter also implies that the concentration o f .

71

Residence- a n d C o n tact- Time Dis t rib u tions

1 02

I

lc

��-----------------------------------.

I I 1

B � -- -

- - - - - - -

: /

I '

y

A!8l

,J

10

n

' I

°

Ii I I I

10,

;

0.50 ,

A

I

I

2.50

8

(a)

4. 5 0

6 .50

I

I '

i\ c! \a l \

1 -F ( 9 )

I

I

0 1

.

A

.

! \

�------�--�

I

2 0.0

2

e

{b) FI G U R E 5

3

4

( a ) Intensity function for some simple flow mo dels :

A,

s tirred

tank ; B , approach to plu g flow ( estimated by 30 tanks in series ) ; C , ideal

plug flow

(o

function at e

for the models

in

part

(a) .

=

1) .

( b ) C umulative residen c e - time distrib ution

Shin nar

72

all

differen t sp ecies in the reactor is completely uniform at all poin t s , which is not a necessary condition for A ( t ) to be constant . In many reactors , such as p acked beds or baffled fluid- bed reactors , one wi shes to app roach plug flow as c losely as p os sible . In reality , one cannot achieve ideal p lu g flow an d the escape p robability will resemble the one shown in Fi g . 5a , curve B . This con dition will be called near plug flow . Such a flow can be modeled by either a series of s tirred tanks or by a one - dimen sional di ffusion mode l . B oth of these share one property , which is p hy sically very well represented by the escape p robability . For values of t t hat are s m all compared to the average resi dence ti me ( t << T ) , the escape p robability i s close to zero . As t app roaches T the escape probability rises un til it reaches a final constan t value . Physically , that means that for t » T the p rob ability of t he molecule b ein g near the exit if i t is still in the sy stem is hi gh . I n a series of s tirred tanks one can therefore assume that for t » T the particle is probably in the last tank and its escape probability is the probability of escapin g from the last tank ( see Fi g . 6a , curve A ) . It c an be shown ( see Shinnar and N aor , 1 96 7 ) , that in a series of s tirred tanks wi th forward and backward flow between The same the tanks ( Fi g . 7 ) , the escape p robability has a similar form . applies to the one- di men sional di ffusion model ( Fi g . 6a , curve B ) . I n a real p acked b e d the flow is not neces sarily one - dimensional . T here mi ght be a flow maldistribution due to a bad distributor . If there are re­ gion s in w hich the fluid flows faster , then to main tain the same average re­ sidence time , t here must also be re gions of slower flow . T hree such models are gi ven in Fi gure S . I n such a case , i f t » T , the par ticl e i s probably in t he slow re gion and has a lower escape p robability . T he s ame is true if we consider a system in which there are stagnant region s which particles can diffuse in and out of , or if there are adsorption p henomena ( Fi g . Sa , c urve B ) . Whenever any A ( t ) has a maximu m an d then decreases , it implies that the system either has region s of fast an d slo w flows or stagnant re ­ gion s in w hich a particle c an get trapped . C urve C in Fi g . Sa shows that adsorp tion p henomena do not neces sarily lead to decreasin g values of A I f the mass transfer processes are rapid compared to the overall flow velocity , no stagnation will be occur an d the escape probabilities will not b e significantly affected . T he exact value of the inten sity func tion is often les s i mportan t than its form , which p rovides p hy sical insi ght into the nature of the flow . T he critical features of A ( t ) are recogni zable from the form of ln ( l F ) versus t as A ( t ) i s the derivative of - ln ( l F) . This can be seen from Fi gs . 6b an d Sb , w here ln ( l - F ) plotted versus t for the flow models given in Figs . 6a an d Sa . Fi gure 8c illustrates f( t ) for cases with stagnancy . Note that it i s much harder to interpret f ( t ) then ln ( l F) or A ( t ) . •

-

-

-

Age Di s t ri butio n Consider the thought experiment where a timer is attached to all the parti ­ enterin g the system . Instead of collectin g them at the outlet , the whole sys tem i s stopped at some time t o to collect all t he p articles in side the reac tor . One can then con struct a distribution G ( t ) s uc h that G ( t ) measures the fraction o f p articles inside the reactor that entered after to - t . G ( t ) expresses the probability that a particle c hosen at ran dom inside the reactor has an age less t han t . It is also called the age dis t rib u­ tion . G ( t ) is related to F ( t ) by the relation

cles

73

Residence- a n d C o n t ac t- T ime Dis trib utions 3.0

2 .0 Al B ) 1 .0

0.0

0

2

e

(a) 10°

�

4

3

6

5

'

1- F (B )

10 2

L.._____. -----'-

0.0

(b)

0.5

1.0

1.5

e

2 .0

2.5

( a ) I n tensity function for some simple flow models : A , three stirred tanks in serie s ; B , one - dimensional diffusion model . ( b ) C u m ulative residence- time distrib ution for the models in p art ( a ) .

FI G URE 6

74

Shinnar

u,

v,

v

FI G URE 7

Schematic dia gram for a series o f stirred tanks in series with

forward and

g(t) =

bac k wa rd flow between the tanks .

1 - F(t)

E (t )

( 9)

f

w here g ( t ) is t he density func tion of G ( t ) . In a multistage system , one c an examine a sin gle stage Z an d define a local age distrib ution G z with respect to the inlet in the same way as one defines a local residence- time distribution F z ( s ee S hinnar and Naor , 1 9 6 7 ; Zvirin and S hinnar , 1 97 5) . T he same c a n b e done for a local zone i n a re­ actor if the flow i s n ot turbulent and the p roperties of the reactor are steady in this zone . A related fu n c tion is the

again

future

lifetime

the thought experiment where all

distrib ution A ( t ) . Consider mole c u les in side the re act o r are

1 .7 5 1.50 1.25

A<9J

1.00

0 .7 5 0.50 0.25 0.0

(a)

0

2

8

3

4

FI G URE 8 ( a ) Intensity function for three simple flow models described above . { b ) C umulative residence - time dist ribution for the models in part ( a ) . ( c ) Residence- time density function for t he models in part ( a ) •

Residence- a n d C o n tact- T i me Dis t ribu tions 10 °

75

r-��----�

1- F ( 8 )

2 1 00.0

2

3

8

(b)

4

0.6 0.5 0.4 0.3

f (8)

0.2

0. 1 0.0

0

2

8

(c) FI GURE 8

( Con tinued )

3

4

76

Shinnar

Thi s time , at t = t 0 set all t he timers to zero . T hen record t he time t for each molecule as it exits an d construct the dis ­ t ri b u ti on A ( t ) . T hus A ( t ) is t h e probability that a particle which is in t he reactor at time to has exit�d before t 0 + t . One can also define an o t h er related distribution in side the reac tor . C on ­ sider t he thought e x p e ri ment where all t h e particle s inside t he reactor are again provided wi th a timer . At a set ti me t 0 all t he clocks are set to 0 . One can t hen record the clock time s on the p ar tic le s at t he exit and con struct a di s tri b ution A ( t ) . A ( t ) is called the future lifetime distribution . I t can be s ho w n that A (t ) is e qual to G ( t ) ( s e e N oar and Shinnar , 1 9 6 3 ) . Once again , one can define a local future li fetime distribution A z ( t ) . How­ ever , A z ( t ) =1- Gz ( t ) . B oth Az ( t } and G z ( t ) can be measured and are sometimes useful in m o de lin g ( Zvirin and S hinnar , 197 5) , but this is outside the scope of t hi s chap ter . provided with a timer .

=

M u l ti p ha s e S y s tems

All t he definitions giv en until now refer to a sin gle fl ui d . I f a fluid is made up of different components , eac h of them may have a different resi ­ dence - time distrib ution . I n a ho m ogeneou s reac tor , the differences between the residence- ti me di strib ution s are in general n egligib l e . However , in he t e ro gen eou s reactors , t he differences may be quite lar ge , as differen t compounds m ay adsorb differently or distribute t he mselve s differently be­ tween t he p hases in mul ti p h a s e reactor s . Here t he initial hy p�t he tical The system has definition can be very helpful in keepin g thin gs s t raight . to be steady state an d one must be able to tag a particle with a clock such that it retains its identity in passin g t hrou gh the reactor . If the com ­ poun ds reac t , one may have to tag an element that does not change and ob tain a set of residence - time dis t rib ution s Fi ( t } for each s uch element . For each Fi ( t ) the definitions of fi ( t ) and A i ( t ) do not c han ge . T he only relation that does not hold is that 'i , the first moment of f( t ) , is no lon ge r equal to V /Q . T he holdup or average residence time ' i is now different for each el e m e n t and not known a priori . A detailed discus sion of this problem is given in a later section .

T R AC ER E X PE R I M E N T S : M E AS U R EM E N T O F R E S I D E N C E- T I M E D I S T R I B U T I O N S M ethods o f M ea s u rement

S tep C hanges in T racer Concen tra tio n

T he residence - time distrib ution discussed in the p recedin g section can be meas u re d in any s t eady - state sy s te m by use of a s uitable t rac e r . A ssume that at time t = 1 on e starts labelin g all the particles in the fe e d . One then measures the fraction of l ab el ed particles at the exit from the reactor at time t . Any labeled p a r ti c l e that appears at the exit at time t must have entered the reactor after time t = 0 s in ce before that time , no p articles were labeled . Similarly , any unlabeled particle must have entered the re­ 0 since after that time all particles were labele d . actor p ri o r to time t T herefore , the fraction o f labeled particles i s , b y definition , equal t o F ( t ) , which is the p robability of s tayin g in the reactor less than time t an d t h e fraction of unlabeled particles is equal to ( 1 - F ) . For s mall time intervals =

Residence- and

77

C o n t ac t- T i m e Dis trib u t io n s

it is easier to measure F , w hereas for lon g time span s it is more convenient to measure 1 F. I t is not neces sary to label all the particles . A ssume t hat at some in ­ stant in time t :::; 0 , instead of labelin g all the p articles , one s tarts labelin g a con stant fraction C f of the particles in t he feed and then measures the fraction of labeled particles C ( t) at the exit . C learly , -

C ( t ) :::; F ( t ) C

f

Since one is u sually more interested in estimatin g F { t ) , this is usually expressed as

( 10)

In this case , t he fraction of unlabeled particles is no lon ger directly re­ lated to ( 1 F ) , as some unlabeled particles have entered the reactor after time t :::; 0 . I f one waits lon g enou gh , then a s t -+, F ( t ) -+- 1 an d C ( t ) -+- C r . I n practice , equili b ri u m i s reac hed w hen t » T , the ti m e con stant of the sy s ­ te m . A t that point the fraction of labeled particles a t the exit will equal C f , the fraction of labeled particle s at the feed . O nc e the sys tem reaches equilibrium it is u se ful to stop suddenly the flow of labeled partic les (tracer ) . F rom this point on , the fraction of labeled particles at the exit will decrease monotonically . T he fraction of labeled particles , C ( t) at the 0 is then given by exit , measured from the new t -

""

:::;

[1

C (t)

-

F(t) ] C

f

or

1

-

F(t)

C (t)

:::; c;-

This is identical to the case in the precedi n g paragraph except that now it is the labeled particles that have entered t he system prior to time t :::; 0 . A step c han ge i n tracer i s the most acc urate way o f measurin g a residence - time distrib ution . C ( t ) / C r should be meas ured after the tracer is introduced until equi libri um is achieved and then after the tracer is stopped . I f one could measure the average concent ration < C / C r> inside the reactor after a s t ep input at time zero ( av eraged over the total volume at each instant of ti me ) , this yields an e s ti mate of G ( t ) , the age distribu ­ tion o f the system . T hi s c a n be achieved experi mentally b y usi n g a radio­ active tracer and measurin g the total radiation emanatin g from t he reactor .

Pulse

Expe rime n t s

The step input experiments de scrib ed measure F ( t ) an d 1 F(t) . Another tion of a fixed amount m of tracer at of labeled particles C ( t ) at the exit . of the density function f( t ) given by -

in the precedin g section directly more commonly used tool is the injec ­ t 0 an d then measuring the fraction T hi s leads to a direct measurement :::;

Shinnar

78

mf( t )

=

QC (t)

or ( 11)

QC (t) m

f( t )

w here m i s t h e amount o f tracer injected a t t = 0 a n d Q i s the volumetric flow rate . To have reliable estimates of f( t ) , one needs in dependent meas urements of Q and m . The relation

( 1 2)

C ( t ) dt

m

allows a n estimate of t he consistency o f available estimate s . I n t h e absence of acc urate knowled ge of eit her Q or m , one can use Eq . ( 1 2 ) to reformu­ late E q . ( 1 1 ) as

( 13)

C(t)

f( t )

foo

C ( t ) dt

0

T hi s allo w s an esti mate of f ( t ) from a p ulse injec tion in any steady - state system directly from the meas ured fraction C ( t ) . It is the most common w ay in which tracer p ulse experi ments are utilized .

Sin usoi dal Inp u ts

Consi der the case where the frac tion of labeled particles C f at the inlet varied as a func tion of time . I t can be s ho wn that f ( t ) is equal to the linear response function for t he tracer , or C (t)

=

f( t ) * C < t ) r

is

( 14)

where C ( t ) i s t h e outlet concent ration , C f ( t ) i s the inlet concentration , an d * denotes the convolution inte gral . I f one writes Eq . ( 1 4 ) in t he Fourier tran sform , then A

C (jw)

A

=

f(jw )

x

C (j w ) f

( 1 5)

E quation ( 1 5 ) is we ll known from c on t rol theory . One can therefore evalu­ ate f( t ) in t he same way that one evaluates the process transfer function in con troller desi gn . I n t hi s case C f ( t ) i s varied in a sinusoidal form . After waitin g for all transients to die out and for steady state oscillation in the output to be establishe d , the amplitude ratio C ( t ) / C f ( t ) and the p hase angle are found by recordin g i np u t and outp ut data ( see Fi g . 9a ) . T h e frequency of the input si gnal is c han ged and a new ampli t ude ratio and p hase an gle are de­ termined . T hus the complete frequency - re sponse c urve is determined ex­ perimentally by varyin g t he inp ut frequency over the ran ge of in terest . T hese measuremen ts are direct measuremen t s of the Fourier tran sform of

Residence- an d C o n tact- T ime Dis t rib u t io n s

Q(t) q( t )

(a) 101

=

=

Q sin

(w t )

q

(wt + B )

sin

w

8

79

=

=

PHASE ANGLE

�-----

------.

=- - - - - - - - ::..:� 1 0° -::1 ------r.::-:---

------,\...

AR

\

\.

I

. . ' '

'.

\

'

\

1 6 2 ��-rrn�r-.-rrn.mr-oL,rnmm-.-rrl nn�,-TTonm 1� 1 62 ------

S I N G LE C S T R

- ------ --- 5 - C S T R

IN SERIES

s

W T

- PA:a�LE� 7 --� --- S ING L E PFR

C ST R

Q .1

(b)

FIGURE 9

50 %

1

· - -- PA R A L L E L C S T R TRAINS N

7 B� %1 1 1 20%

--

Q•1

4

4

4

( a ) Sinusoidal inp ut - output c urves , w is frequency of inp ut (b ) Frequency response for some simple flow models- amplitude ( c ) Frequency response for the flow models in part ( b ) - p hase lag . ratio . (d) Laplace transform of the density function for the flow models in part signal .

(b) .

80

4 5.0

W T

{c)

4.0 (d) FIG URE 9

( Contin ued )

8.0

--.--

-----.----:-: 1 2�.� 0 1 0. 0

114.0

Residence- and C o n tact- Time Dis tribu t io n s

the

81

ty function :f(jw ) . One can look at f(ju' ) as a vector in polar co­ Th e amplitude ratio defines t he m a gni tud e of the v ec to r for eac h w , and the phase lag defines cj) . I f one can measure both the amplitude ratio and the phase lag over a wide range of fre quen ci e s , one has a good estimate of the Fourier transform of f(t ) . Some typical forms of these functions are given in Fi g . 9b and c . den si

ordinates ( r , cj) ) . r

Measuremen t of the Lap l ace T ransfo rm from

A rb i trary Inp u t s

In

some cases it is hard to perform an accurate step or p ulse exp e ri ment . might not be able to feed the tracer directly to the r e ac tor , or one might have a two-stage system where the inlet concentration to the second stage can b e measured , but the tracer cannot be fed directly to it ( 0ster­ gaard and M ic he l sen , 1 969) . For "all such cases , one can utilize Eq. ( 1 4 ) and obtain the Laplace transform f(s) of t he den sity func tion f(t) by One

C(s)output f( s) :::

( 16)

. put C(s) m

As

C(t) is a m easure d function , C (s ) must be obtained by numerical integra­ This is illustrated in Fjg. l Ob fo r several values of s . Measurement of f( j w) and f( s ) poses a problem . Although in theory it is

tion .

possible

f(t) f(t)

to obtain

=

=

1

2 1Tj

2 11 j 1

a+ o

fa- o J°

- cS

e

by inversion ,

" e st f{s ) dt f( j w )

jwt "

( 17)

d(jw)

depe n d s t ron gly on t he value� of f ( s ) ass -+ 0 or f ( j w ) as which are hard to me as ure . As f ( s ) is hard to invert , either one can try an d fit f( s ) with a reasonable mo d el and t hen invert it , or one can use the measurement of f( s ) to evaluate directly the properties of the residence-time distribution . Some typical forms of f( s ) are shown in Fig. the

re s ul t s

f( t)

w + 0,

9d .

In direct E s t imates o f f( t ) an d F ( t )

Indirect way s of measurin g residence-time distribution are discuss ed later . Thes e are based on t h e effect of residence- time distribution on conversion , especially on product distrib ution in complex reaction s .

Measuremen t of Moments of Residence- Time Dis trib u t ion The

f(t)

t h e residence-time di st ri b u tion can be computed from either F(t) by using Eq. ( 2) or

moments of or

82

0

8 UNIT:

z

�

0: � z ILl (.) z 0 (.) 1/) 1/) ILl _J z

Q

1/) z ILl

� 0

Shin nar

ECLP

6 INLET D E T E CT O R

4

2

0 0.0

(a} 10

0. 5

1 .0

1.5

D I M E N SION L E S S T I M E

2.0

2.5

°

C (s ) C0 (s )

(b)

s

( a ) T racer response o f a radioactive gas tracer i n a n Exxon Donor Solvent coal li q uefic ation reac tor . ( b ) Laplace transform of the re­ sidence- time distribution from part ( a ) ( top o f reactor ) obtained by FI G U RE 1 0

Residence- and C o n tac t- Time D is tribu tions lJ (f)

=

r

r

J

00

t

r- 1

83

( 1 - F ) dt

0

The comments on accuracy made before apply al so here and the step re­ sponse has a si gni ficant advantage . In homogeneous systems , the fir st moment can also often be estimated in depen dently from lJ

1

v = T = -

( 18)

Q

where V i s the volume of the fluid in the reactor . T his is an important check on the acc uracy of the measurement of f( t O . Relation ( 1 8) can only be used in homogeneous system s , as in a system where there is adsorption (or sol ution in another phase) indepen dent knowledge or estimate of the hol d up is difficult . In the case w here , instead of directly meas urin g f ( t ) or F ( t ) , the

Laplace transform f( s ) is me asured , there are two way s to obtain the mo­ ments . When the Laplace transform is obtained from meas urin g the response C 2(t) to an arbitrary input si gnal C 1 ( t ) ( see Fi g . 1 0) , one can get the moment s from the fact that the moments for t wo systems in series are addi­ tive . Recall that f(t) =

fi

( 11)

C ( t)

m

Thus if one now writes

lJ

1 = T1

.

=

and

w here l..l

Q_

!""

m 0

t C ( t ) dt

( 1 9a )

1 and V 1 ar e the mean an d variance , then ( 1 9b )

00

f( s )

=

f

l

-

st

C ( t ) dt

0

� 00------

J 0

1

- st

C ( t ) dt 0

where C i s the concentration a t the top and c 0 t he con ce n t rati on a t the 1 . 18 and inlet . T he curve can be fitted by [ 1/ ( 1 + T s /N ) ] where T N = 17. ( F rom T army , 1 983 . ) ,

=

S h innar

84

where V 2 an d T 2 are defined analogously to E q . ( 19a) . There is another way to extract the moments from l ( s ) , whic h is e s p e cially important for cases where f( s ) is obtained direct ly , as will be di sc ussed later . One can obtain the moments of f ( t ) directly from f ( s ) as shown in E q . ( 17) . Unfortunately , i t is hard to estimate acc urately the highe r derivatives near s + 0 , but one can us ually get a good estimate for the fi r st derivative by usin g a Taylor expansion , get a reasonable estimate for V an d y , the co­ e ffi ci e nt of variation . I f y is small ( t he flow is close to plug flow ) , V and y can b e estimated by a filterin g mo del such as f( s )

=

--"1'---­ (1

T s /n )

+

( 1 9c )

n

which i s a good approximation for flows that are close t o plug flow . Equa­ tion ( 1 9c ) has the form of transfer function for s tirred tanks in series , b ut here n is used as a fittin g parameter . I f one can fit f ( s ) w i t h Eq . ( 1 9c ) , then y

2

=

1

( 19d)

-

n

varianc e from the Laplace tran sfer for ·cases close to plug flow can be derived as follows . T he measured q�ntitie s in Fi g . 1 0 From t hi s one can derive not only f( s ) b u t also a re C 1 ( t ) and C 2 ( t ) . d f/ ds :

Another way to get the

1

df( s )

f( s )

�

1

A--

=

A

1

( 2 0)

w h er e dC 2(s)

( 20a)

ds

Evaluation of the derivative of f ( s ) t herefore does not require any numerical di f ferentiation , but can be evaluated from the concen tration c urve s by in­ te gration . I f f( s ) can be approximated by E q . ( 1 9c ) ,

1 A

f( s )

df( s ) ds

=

-T (1 + :s )

-1

( 2 0b)

and f(s)

df( s ) /ds

=

s n

-

1 T

Plottin g the left side of Eq . ( 2 0c ) v e rs us s gives a strai ght line , the s lope of which is equal to the coefficient of variation .

( 2 0c )

Resi denc�:r"

an d C o n t a c t- T ime Dis tri b u ti o n s

85

Requi red P ro p e r t i e s of R eac to r s a n d T racers for

Mea s u reme n t s of R e s i dence- T i m e D i s t r i buti o n s

The most fre quen t p roblem t he author has encountered in the practical measurement of residence - time distribution is that not enough though is given to verify tha t C ( t ) /C f is really an esti mate of the resi dence - time distrib ution desired . T here are several i mportan t con ditions that need to be checke d . The c hoice of the tracer is very important . It s hould be acc urately measurable over a wide ran ge of concen tration s . T here are several other properties that also affect its c hoice . Furthermore , there are a number of other conditions t hat have to be fulfilled in order that the tracer experi ­ ments mentioned earlier will lead to a proper estimate of the residence- time distribution . 1.

T he s y s tem m u s t b e a s teady s ta t e and s ta t io n ary in t he s e n s e t h a t

C ( t ) /C f is i n de p e n d e n t of the time a t which t h e trace r is in tro d uc e d i n to the fe e d As most flow s are turb ulent , this is not necessarily true for all

reactors . However , if the len gth - to - diameter ratio is large , the turb ulence effects are averaged out and at the outlet , this condition is satis fied at least to a first ap p roxi mation . T he same applies to systems equipped with mechanical agitators . I n that case the si ze of the large eddies is much s maller t han t he diameter of the reactor an d therefore are often averaged out in depen dent of the len gth- to- diameter ratio . This can be tested in t wo way s . First , t he s tep res ponse m us t be monotonous . A respon se s uch as the one s hown in Fi g . 11 cannot be considered as a residence- time distribu­ tion . The ability to apply this criterion directly i s a significant advanta ge Furthermore , two s uccessive tracer experiments in usi n g the s tep resonse . should gi ve t he same res ult w ithin t he expected exp erimental error . T hi s condition is not just a question of measurement . T he hypothetical experi ­ ment of equippin g each molecule wi t h a clock had exactly the s ame require­ m en t It was ass umed t hat i t di d not matter when the particle entered . .

.

cleo

f

FOR S T E P I N PUT

, _

1 1 R e s p on s e to step inp ut for a system in whic h the response to tracer is a function of the time of injection . In thi s case , C ( t ) /C f does not give the residence- time distrib ution of the system . T his may be due to turbulent mixin g , fluctuation in t he flow rate , or large b ubbles , or other factors . FIGURE

a

86

S hinnar

In K ra m b e c k e t al . ( 1 96 9) the concept of residence - time dis t ribution is ex­ but t his is out si d e the scope of this c hapter . 2. T h e tracer response must be linear in t h e ra nge of t he s tep change . I f t he tracer particles behave e x ac t ly as one of the molecular compounds in t he steady - state system , t hi s condit ion will be fulfilled automatically . I f one can really tag particles i n a s teady - state flow , i t cannot m ake an y dif­ ference how many p artic le s are ta g ged . As lon g as the system is in st e ady s tate , it also does not m atter i f the transport processes are nonlinear . T hi s also applie s t o m ultiphase systems in which one of the compounds is eit her adsorbed on a solid s urface or dissolved in the liq ui d phase . As lon g as t he s y s tem is at s te a d y state in the sence defined in t he first criterion , each compoun d has a re s i de n ce - tim e distrib ution , an d if one finds a real tracer for t hi s compound , its response wi ll be linear , as it cannot However , t he only way to obtain matter how many particles are tagged . tracers wit h s uch p ro pertie s ( at least appro x imate ly ) is to take the real reactant feed and mark it b y exchan gi n g one of its atoms wit h an isotop e . S uch t racers a r e s eldom used and i n most c a s e s o n e uses tracers that are inherently different from t he fluid a t s teady state . There is no thin g w ron g with t hi s method as lon g as one recogni zes its s hortcomin gs an d takes them into account . I f the tracer is different from the steady state fee d , it may u p s et the s t e a d y - stat e condition s , and t here is no a p riori reason for a linear response. I f one w ants to obtain a residence- time distrib ution , one m ust verify ex­ perimentally that t he respon se i s linear . This is ac com pli s he d ' b y two suc­ ces sive tracer exp eri ment s wit h two differen t step magni tud e s which s hould gi ve t he same re spon se . W hat one ob t ain s in this case is a residence- time distribution of the tracer compoun d , w hi ch is not n eces sarily i d en tical with t he residenc e - time di st rib ution of the fluid in t he reactor . Therefore , one m ust add yet another criterion . T he tracer should be similar in b ehav ior to t he fl u i d in the rea c tor . 3. I t is hard to specify t hi s condition in a general way , as it dep en ds strongly on the specific sit uation . I n a homo ge n e o us stirred tank , almost any tracer will do , as diffusion proces ses have n e gli gi b le effects on F a n d there is no potential for adsorption . The tracer is c ar ri e d alon g wit h the liquid . This ap plies to most hom oge n eo u s reactors . I n s uch cases one seldom has to worry about linearity . On t he ot her han d , in a fluidized - b e d reactor , dif­ f u s ion an d adsorption are very important factors , and t he results depen d s tro n gly on t he tracer c hosen . W hic h tracer to choo s e is t herefore a ques ­ tion not only of availability b ut also of what inform ation is s o u ght from the ex p e rimen t . In m ulti p h a se systems it is often ap p ro p ri ate to u s e several t racers , e ac h si m ulatin g a di fferent compoun d , or fluid p ro pe r ty . T his is d i sc us se d in detail later . t e n ded to s y st ems t hat lack this p rop e r t y ,

R e l a ti v e Acc uracy of T racer E x peri m en ts U ti l i z i n g S tep a n d P u l se I n puts

In principle , f( t ) and F ( t ) co n t ai n the same information and e a c h one can be d e ri v e d from the other . I n pr a c tic e , t he experimental errors are di fferent for pulse i n put s and s tep i n p uts . S tep inputs tracer experi ments have s i gni ficant advantages over pulse experiments , p rovide d that they are carried out in both direction s . T hese advantages include :

87

Resi dence- and Contac t - Time Dis t ri b u tions 1.

2.

I mmediate r eco gnition of some unsteady phenomena . T hese are illustrated in Fi g . 1 1 . I n a step experiment a ll one needs i s a kno wl e d ge of C f a n d C ( t ) . As they are meas ured by the same instruments , any bias in measur­ in g C f will also appear in C ( t ) and will ten d to cancel . However , it is important t hat t he step be carried out in both directions , as it is di f fi c ul t to measure C ( t ) / C f accurately i f it is close to unity ( lar ge t for F an d s mall t for 1 - F ) . "

I f one . can do this , a direct estimate of the other han d , in a p ulse expe ri ment C ( t ) of f(t ) . One must derive it utili zin g eit her Eq. ( 1 3) , t he problem of bi a s in measurin g

- F is obtained . On does not give a di r ec t estimate E q . ( 1 1) or ( 13 ) . I f one uses C ( t ) i s eliminate d , but one

F and 1

faces the problem of estimatin g the inte gral . If the residence - time distrib u­ tion is si mple and well b ehaved and has an expon en t ial t ail , a fairly ac cura t e estimate of f ( t ) is easily obtained . Other wise , t he overall form of f( t ) can us ually be derived , but t he relative magnit ude may not be accurate . One way to v e rify the accuracy of the me asurements utilizes Eq . ( 1 2) and com-

pares 1000

C ( t ) dt t o m / Q .

If possible . this s hould always be done , as it

greatly i mp rove s the reli abili t y of the measurement . However , in in dustrial reac tor s it is often impossible or very diffic ult to meas ure either Q or m ac c ura t e ly A step experiment measures F and 1 - F di rec t ly and therefore also allows a direct me asurement of t h e escape prob abili t y . I f one plots ln ( l - F ) versus time , all the in t erestin g feat ures of the escape probability (or intensity function ) will be directly apparent from the plot . On the other hand , to derive the intensity f u n c t io n h ( t ) from f( t ) usin g Eq . ( 7 ) , one must first compute [ 1 - F ( t ) ] by i n t e gr ati o n of f( t ) , w hich introduces in­ acc uracies . I n order T o minimize the error in es t ima ti n g A ( t ) , one should .

use the relation A (t)

C (t)

=

fa> t

The v al ue of 10

00

( 21)

C ( t ) dt

C ( t ) dt is es timated by plotti n g C ( t ) on a lo gari t hm i c plot

and ap p ro xi m at in g the tail by an exponential function . T he ti me constan t o f t h e exponent i s then estimated from t h e tan gent o f l o g C ( t ) for the largest values of t for w hic h the mea s u remen ts are s till reliable . In ge ne r al , the author does not recom mend t he use of frequency- respon se techniques or sin usoidal in p ut s for measurin g residence- time dis tribution s . T he only reas o n they are disc ussed i s that t hey mi ght b e available from control studies an d can t herefore serve as a startin g poin t . The reason for this broad s tatement is that whenever s uch experi ments are feasible , a proper step response in bot h direction s is also feasible , is less time consum­ in g , and pr ovi des far b etter information . I n control desi gn the oppo si t e is true . It is always best to get a direct estimate of t he property of the func1ion re quired for design . I n chemical controller desi gn one needs to know f(jw) and it i s pre ferable to measure it direc t ly , compared to es timatin g it from a step respon se . On t he ot her hand , to evaluate the flow p a t ter n , one

Shinnar

88

needs to know the escape probabi li ty and therefore a direct estimate of

[ 1 - F ( t ) ] i s p refer ab le .

Furthermore , the accuracy and the r an ge of w [( j w ) is neede d is different in t h e two c ases . I n controller desi gn , one needs t he overall form of f(j w ) an d accurate values n ear the phase lag of - 18 00 . Acc urate estimates of f(jw) for very hi gh an d very s mall w are of little i nte re s t in con t ro lle r desi gn , but are im p or t an t in eval u atin g at which

residence - ti me distrib ution .

in p u t that reason ably app ro xi ­ or a pulse cannot be pe rfo rm ed , and one m us t often compro­ mize and utili ze other inputs . A pra c tical example is s ho wn in Fi g . 1 0 . In this sett in g one cannot directly meas ure F ( t ) of f ( t ) b ut c an still m easure an esti mate of t he Laplace tran s form . If o n e has an ap p roxi m ate flow model , one can fit it direc t ly to f( s ) as s hown in Fi g . 9d . This is less accurate than es ti ma ti n g [ 1 - F ( t ) ] by a step or p ulse e x p erime n t . With the latter on e can often get a goo d es ti m ate of the tail of t he function w hich determines the moments . On t he ot he r hand , to obtain reliable estimates of the tails from f( s ) , one n eed s to have acc urate meas urements of f( s ) for values of s w he re s -+- 0 . E s ti matin g t he s e co n d derivative near s -+- 0 from experi ­ t m e n al ly determined f ( s ) is much more difficul t , and therefore estimates of variance are more diffic ult and have to be obtained by first fittin g a two­ parameter model of f( s ) and then es ti m ati n g the variance from t hi s model . T hi s p ro cedu r e involves some mistakes , but if t he variance is s mall , the re­ sul t s are often reasonably accurate [ 0st er gaard and Michels en ( 1 9 6 9) ] . An example i s shown in Fi g . 1 0 . I f one could p lot f( s ) i n a w ay equivalent to an escape probability , i t wo u l d a l low b e tte r in sigh t in to the meanin g of any deviation s of f( s ) from t he simplified flow models u se d to fit the experimen ­ t al res ults . However , the author i s not aware of any met hod t h at would make thi s po s sib le . I t is sometimes p os si b le to use E q . ( 16 ) , In cases w here an e x p e ri m e nt wi t h an

mates a s tep

C(s) f(s)

=

output

C ( s) . t mp u

( 16)

to filter out the effects of meas urement noise , e s p eci ally on t he tai l . It sho uld b e s tressed t h a t t his m ethod i s alway s one of l a s t resort a n d that one alway s loses si gnificant information . In many cases the m o s t important information of t he t racer e x pe ri m e n t is c o n tai n ed in the tail ( t -+- oo ) and t h er e is no way to replace gettin g an ac c u rat e measurement of i t . U s in g E q . ( 1 6 ) merely o b s c u r e s t he fac t that the me as u r em e n t noi s e prevented an acc urate measurement of the t ai l of f ( t ) . The me thod is sometimes useful w hen one knows t ha t the contrib ution of t he tail i s small or when one is interested in b y p a s s p henomena [ which dep en d on t he pr op e rt ie s of f( t ) n ea r zero ] . In all s uc h cases it is importan t to us e an adequate number of values of s in t he ran ge 0 < s < T , where T is the exp e c t ed average residence time . B ut one s hould always be aware of the s hor tc om in gs of this m et ho d .

Residence - and C o n t a c t - Time Dis trib u t ions U S E O F R ES I D E N C E- T I M E D I S T R I B U T I O N S I N R E A C TO R MO D E LI N G A N D T E ST I N G O F I N D U ST R I A L R E A C T O R S

89

Testi n g fo r M a l d i s t r i bu tion i n I n d u s t r i a l Reacto r s Residence - time dis trib ution s a re a n i m p ort an t di a gno s tic tool in e valuatin g the performance of i n d us tria l reactors as we ll as in s ettin g up si mplifie d

flow

T hey c a n be utili zed fo r m o de li n g both homogeneous and T he most i mport a nt a pp lic a tion i s p robably chec kin g for m al distrib ution in flo w s . A la r g e number of industrial reac tors a re de­ In the signed to a pp roxim at e either a s tir r ed tank or a plug- flow reac tor . first case good mixin g i s essential . I n the second case , s uch as a packe d ­ b e d re ac tor , i t is very i m p o rt ant t hat t h e fee d i s w e ll distributed over the c ro ss section and t hat t her e be n o b y p as sin g due to fa ul ty in ternals or de ­ fec tive cataly s t lo a din g . I f a reac to r does no t p erform as p re dic ted , it is importan t to find out w hether t he poor pe r forman ce is due to an in he ren t scaleup prob le m , a faulty cat aly st , or a wron g mechanical d e si gn . A trac e r experi me n t can be a va luab le tool in distin guishin g between t he se pos s ib ili ties . If there are similar reac tors in op er ation which are acces s ib le , one can mode ls .

he t eroge neous reac tors .

con duct a t ra ce r experiment on bot h r e acto r s an d compare t he res ult s .

Oth e rwise , one can c o m p a re the results of the trac er e xp erim ent to those

p redic t e d by an ideali zed mode l .

T hey key q uestion i s how one in t erp ret s any devi ation s between the re sults of t wo r eacto r s 01' bet ween t he actual per for manc e and the mode l . Here t he escape p rob ab ility o r in t en si t y func ­ tion , A ( t ) , i s a u s e fu l tool , a s i t pr ovi de s o n e with immediate in si ght as to

what

or

t he

deviation s m ean .

comp u te A ( t ) .

One does not even always have to actually plot

Wi t h some e xp erienc e on e c an recog ni z e t he i mp o rtant

features of the e sc ape probability from a plot of ln ( 1 - F ) versus t . T her e ­ fore , w hat is really ne eded i s a reliable estimator of ( 1 - F ) whic h ca n usu­ ally be obtained from tracer experi m e n t s . T h e followin g two examples will

illustrate the method .

Imperfect Mixin g and Bypassing in S tirred- Tank Reac tors There are several problems that c an occur in the scaleup of stirred- tank reactor s .

One of t he m is t h a t the mixin g is in s ufficient to en sure that the

enterin g flui d mixes s uffic ien tly r ap i d ly with the contents of the reac tor

[ (Evan gelista et al . , 1 9 6 9b ; S hinnar , 1 9 6 1 ) .

In hetero ge n e ou s stirred- tank

t r an s fe r bet ween the p h a ses , uniformity o f turb ulence , and the other complicatin g fac tor s whic h A l t h ough these p rob ­ are di scussed in S hinnar ( 1 96 1 ) an d T army ( 1 98 3) . lems can be studied u sin g tracer experiment s , they involve methods tha t are outside t he scope of this c hapter . T here is on e p roblem that commonly occurs in the sc ale u p of a s tir red tank reactor and can be effe c ti v ely dealt with u sin g the residenc e - time distrib ution . T his is t he case of a d e si gn where t he escape probability is to remain con stan t and is discussed belo w . When try in g to analy ze w hether the e sc ap e p robability is re al ly constant , consider the type of deviations to be e xp e c ted . One would always expec t some de vi ation a s t + 0 , as there is a minimum fin ite time for t he p ar tic l e reactors there are the additional p roblem s of mass

90

Shinnar

2

�'"'\

A( 8 )

I

\, o

IY"' \

1

\

....._

r'--A �-/...I. 0

J

__

//

I ;, 18

?----------------- - - - - - -- - - -

...... ....... .... -- -c- - - - - - - - - - -...... --::-. -.::::::: .::::: .. -

e

FI G URE 1 2 Inten sity function for i m p er fe ctly mixed stirred- tank reactors : A , short delay between inlet and outlet ( normal cas e ) ; B , delay between inlet and outlet due to insufficient sti r rin g ; C , b yp as s between inlet and outlet ; D , bypass b etwe en inlet an d outlet and stagnant r e gions due to in ­ sufficient s t irri n g .

Howeve r , this time is usually to reach the exit ( s e e Fig . 1 2 , c u rve A) . small comp are d wit h the av e ra ge re s idence tim e T , and if T is large , on e would not notice it . I f the mixin g in te n si t y is too low , this in itial deviation might be quite la r ge , e s p ecially in tall reactors with viscous fluids . In that case one would e xpec t A (t) to look like curve B i n Fi g . 1 2 . This could be re m e died by i n c rea sin g the agitator sp eed or the agitator desi gn . Another com mon type of faulty pe r form ance is shown by c urve C in Fig . 1 2 . It occ urs i f the in l et and outlet pipes are close t o each other and mixin g i n te n si ty is insufficient to distribute the incomin g fluid sufficiently fast over the total reactor . A fraction of the liquid will reach the outlet dir ec tly creatin g a bypas s . For small t on e could then expect A { t ) to be significant­ ly hi gher than the average expected value , as enterin g p a rtic le s have a chance to be in that bypass . I f a particle has s t aye d in the reactor lon ger than it takes to reach the exit via t he bypas s , its c hance to exit is n ow lower t han in the be ginnin g and A ( t ) will exhibit a maximum at low values of t . I f the vessel is really badly mixed , A ( t ) wi ll even have a decreasin g tail ( Fi g . 1 2 , curve D ) . A si gn i fic an t a dv an t a ge of r e p r e s e n tin g the information con tain e d in the residence- time di stribution b y plo t tin g A ( t ) is that one can plot the expected form of A ( t ) without any comp utation s , a s A ( t ) co rr e s p on ds to the p hy sical concept of the sys tem . An actual example taken from an industrial reac tor is shown in Fi g . 1 3 ( Murphree et al . , 1 964) . T he conversion in the re­ actor was m uch lower t han expect ed from the pilot plant res ults . A step in p ut t racer experi m en t was performed an d the result is replotted in Fi g . 1 3a , curve E ( one i mpeller) . Fi gure 1 3b gives ln ( l - F ) a n d Fi g . 1 3c the c o r re sp on di n g curve . T he escape p rob ability is similar to c urve B , in Fi g. 12. I t in dicates i mperfect mixin g . The mixer was modified an d e q uip p ed with t wo impellers and a gain tested by a t racer step inp ut . T he results

Res i de n c e - a n d Con tac t - T ime Di s t rib u tions

91

are also given in Fi g . 1 3 , c urve G , and t he es c ape probabili ty is similar to curve A , in di catin g goo d mi xin g . T he new mixer al s o increased the conver­ sion to that expected from t he pilot plant . T he tra c er result s in Fi g . 1 3 , illu s t r a t e another aspect of the use of re si d en ce - tim e distributions t hat is not e vide n t from t h e escape probability B oth curves refer to a reactor with t he same volume and volu­ as plo t t e d . me tric feed rate , and therefo re the same avera ge re si d en ce time T . O n e can in bot h cases es ti ma te T from !0

oo

(1 -

F) dt u sin g an exponential tail

and c o m pare it to i t s known value . For curve G the estimate i s correc t , whereas c urve E u n de re s tim at e s T by 30%. T he fac t that c urve E under­ estimates T show s that the reactor is not well p erf us e d and has a stron gly stagnant re gion w hic h does not appear in t he plot . I f one could measure F ( t ) acc urately for lon g ti me s , curve E must cross curve G for the t wo in ­ tegrals to b e equal . The true escape probability would look like c u rve D in

Fig . 12 . I f T i s eq ual for the t w o case s , then curves of F ( t ) m u s t cross ea c h other . Therefore , in d epen d ent knowledge of T provi d e s some i m po r t an t checks on the acc urac y of a t rac e r experimen t . A fairly constan t es c a p e p ro b a bility , in depen den t of history , which is characteristic of a w e ll - stir re d tank , occ u r s in quite a num b er of other situ­ ations , such as solids reacted in flui d beds , an d t he test describ ed here appli e s to all these si t uati on s . Packe d -B e d a n d T ri c k l e - B e d R eac to rs

In the desi gn of p ac k e d - b e d and t ric kle - b e d reactors , it i s i mportant to en s ur e t hat the feed is we ll distributed and th a t th e cat aly s t is a rran ge d in s uc h a w ay that t here are no p r e fe r r e d p a t h w ay s wi t h lower pre ssure drop s

F

ON E IMPELLER 0

1 .0

(t l

o.s

o

0. 5

(a )

0 0

o o o

0 0

o o 0 o o o

TWO I M P E LL E R S

a a 0

0

1 .0

°

o o

1.5

o@

a@

2.0

T I ME -

FI GURE 1 3 Residence- time distribution for reactors with i m per fe c t m1xm g . ( a ) Experimental residence - time distrib ution for a s ti rr ed - t ank re actor ( from ) Woo dr o w , 1 97 8 ) . The reactor did not matc h the pi lot plant and gave low conversion . A t rac er experiment showed a s ever e maldi strib ution of the flow . A s eco n d impeller wa s install ed , whic h im p rove d the flow pattern as m e a s u r e d by a residenc e - time d is t rib ut io n a p p roac hi n g an i deally s ti rred tank . T he reactor then matched the pilo t plant . Here the i mp e r fe ct mixin g is not directly recogni zable fro m curve E . I t can only b e recogni zed by c o mp a rin g the estimate of f ( 1 - F ) wi t h the kn own value of T e s tim a t e d from volume divided by flow rate ( see the t e xt ) . T his indicates that in case E t h e reactor is not w e l l p e r fu se d . ( b ) C um ulative re sidenc e - time di s­ t rib u tio n . ( c ) E scape p rob abilit y (in t e n si ty func ti on ) .

92

Shinnar

Gli

B

D 0

0 D

D

D

D

0

0

0 0

0

T W O I MP E LL E R S

D

0

0

0

0

0

0

0

0

D

0

1 - F (I)

0

0 0 0

ONE IMPELLER

o

0

0

TI M E -

(b) 3.0

ON E IMPE LLER

..1\ ( t }

2 .0 1.0

(c)

0 0 0 0 0 0

0

0

o o 0 0

0 0 0 0 0

T W O I M PE LL E R S

D 0 0 0 0 D D 0 0 0 0 0 0 0 0 0 0

0. 5

FI G U RE 1 3 ( Continue d )

1.0

2 .0 1.5 TIME -

Res idence- and Contac t - Time Dis tribu tions

93

which create a bypass . B efore proceedin g with analytical examples , one must first define the concept of bypass and stagnant regions . A well- designed packed bed approaches plug flow and will lead to a A ( t) function s uch as curve B in Fi g. Sa . Most of this is due to the fact that in a randomly packed bed , the path len gth for different molecules is unequal and part of it is due to mixin g in the interstices between the par­ ticles . W henever f( t) is not a delta function , one can in theory represent the pathways of the individual molecules by an organ pipe model such as the one shown in Fig . 14 . As the pathways are of unequal len gth , one can conceive of the shorter one as a bypas s . In general , this is not the prime concern of the diagnos tic test . One is lookin g for m uch stron ger differences caused by maldistribution of flow . One can utilize the residence- time dis­ trib ution in this settin g because the typical flow distribution in a packed bed has a A function similar to that of curve B in Fi g . 5a with no peaks . If the maldistrib ution is stron g enough to cause a peak in the A function , it indicates that one i s dealing with maldistribution in flow and not simply a backmixin g p rocess . There are some exceptions to t he foregoin g s tatement . I f a tracer is adsorbed , it could lead to a peak in 1\ The same applies if there is a stron g diffusional resistance inside the catalyst particle or a mass transfer resistance to the particle . Theoretical examples of such cases are illustrated in Fi g . 1 5 , which shows two examples of a packed bed with a significant chromatographic effect . The residence- time distribution s in Fig . 1 5 are based on the standard equation used in chromatography or ion exchan ge ( S hinnar et al . , 1 97 2 ; Hiester and Vermeulen , 1 9 5 2 ) . T hese c a ses demon ­ strate that to interpret a residence- time distrib ution properly , one needs ei t her a good understandin g of the system or a good data base , such as a tr acer experimen t from a pilot plant or a similar in dustrial reactor . Exam ­ ples are illustrated in Fi g . 1 6 , which shows tracer studies from an indus­ trial tric kle · bed used for hydrotreatin g fuel oil . C u rv e A is from a pilot plant and is similar to curve B in Fi g Sa . C urve B is from an industrial reactor t hat performs well an d shows a small peak in A ( t ) . Curve C is from an industrial reactor that di d not perform well . I t shows a strong peak in A and indicates a strong bypas s . Shinnar ( 1 9 7 8 ) reports that this bypass was correctable b y a change in the design which led to better reactor performance . I f the bypass is really stron g , one would expect f( t ) to be double peaked. This occ urs rather infrequently and a stron g peak in 1\ is a much more sensitive test . For a packed bed one can also check the flow distribution from the Laplace transform . For near- plu g- flow conditions the Laplace transfer {unction should be oJ the for m exp [ - 1: i' ( s ) ] . One can check the form of P ( s ) by plottin g ln [ f( s ) versus s . For one- dimensional diffusion with very large Peclet numbers , •

.

FI G U R E 1 4

Alternative flow model for a packed bed .

94

f(s)

Shin nar

-

exp ( Pe / 2 ) [ 1

( 1 + 4 -r s / P e )

1/2

( 22)

]

Equation ( 2 2 ) is approxi mate on ly for hi gh values o f P e ( Pe > 2 0 ) . On e can ( 2 2 ) by plottin g ln [ 1 /f( s ) ] - 1 vers us -r s {ln [ 1 / f ( s ) ] } - 2

check the fit to E q .

·-

which s hould give a s t rai ght line with s lope -rs and i n te rc e p t 1 / Pe ( 0s ter gaard and Mi c he l s en , 1 9 6 9 ) . However , plottin g ln [ f ( s ) ] ve r s us s might be s u ffi ci e n t an d should also be close to a strai ght line with s l op e - 1 n e a r s + 0 . I f in this plot the slope near zero is less than -r or there are 1 / Pe] ,

s t r on g c han ges in t he slope ( see Fi g .

9 ) , it in dic ates a s tron g deviation It is extremely diffic ult to dis ­ tin gui s h sole ly by mean s of a tracer exp eriment bet ween maldistribution s ca u s e d by a ba d di strib utor and those c aused either by di ffu sio n proces ses in side the particle or by adsorption p roc e s s e s ( see Fi gs . an d 2 6 ) . For­ t un ately , in an industrial case , one often has a reference case from another we ll - p er formin g reactor which can be used for compari son . One s hould , fro m a well- dis trib uted plu g - flow reac tor .

15

2 .0 ,...-----,

1 .6

f {I)

1-\ I \

I I I I

1 .2

\

I I I I I

0.8

\ \ \ \

\

I

0.4

\ \ \

).. = 1

\ ).. \

= 10

\

\

'

...... ""!- _ ��--...... 0.0 L____L____,.L_____J____-===-3.0 2.0 1 .0 0.0

(a} FI G U R E 1 5

( a ) Resi dence - time distrib ution of a chromato grap hic

( F rom S hi n n a r

f

=

et al . ,

e->-• [o(t -

( b ) C u mul a tive

-r)

1 9 7 2 ; H i e st e r and V e r me u l e n +

; e - A. ( t - -r ) / r�

t

1� ,

, 1952 . )

I � >. � l( t r

re sidenc e - time distrib ution for the column

( c ) E scape p robability

( inten si ty

in

c olu m n :

•>)]• = 0. 5 part ( a ) .

func tion ) for the colu mn in part ( a ) .

r

=

1

95

Residence- and Contact - Time Dis trib u t ions

' 1-F ( t )

'

'

'

'\

'

'

'\

\

\>.

\

=

10

\

\

\

\

(b) 6

r-------� _ .... ...... / ,..,

4

A(t)

2

I

I

I

I

I

I I

I

I

I

/�

/ =

/

/

//

10

>.

v

=

1

0 L-----L-----�--�--� 0.0

1.0

(c) FI GURE 1 5

( C ontin ued )

3.0

\

S hinnar

96 3

z 0

� 2

1-

P I LOT P LANT

:J l.L. >1-

(/) z w 1z H

INDUSTRIAL R E A CTOR ( C )

0

0

10

FI GURE 16

et al . ,

20

TIME

( min )

T racer experiments in a

30

40

trickle -bed

1 978 . )

reactor .

( From Shinnar

however , be careful when usin g pilot p lant re sults as a comparison unless

the pilot plan t has the same linear velocity .

A ch an ge in linear velocity

c han ges the m ass transfer coefficient s an d t herefore also the residence­ time di strib u tio n in a packed bed .

trickle bed .

It also c han ges t he flow re gi me in a Often this can be predicted by fluid dynamic condition s .

U se of RT D i n Reactor Mode l i n g

T racer experi men ts a n d resi dence - time distribution s are just one of many One seldom starts in a vacuum tools in s tudyin g flow systems in reactors . and us ually has other information about the r e actor In principle , one As F ( t ) meas ures a linear p roperty wan ts to un ders tan d its fluid dynamic s . of a n onlin e a r system , the information obtainable from it is alway s incom­ p lete , although it can be quite importan t . I f a reactor model is available , one c an compute the expected res ults of a tracer expe ri me n t and comp are it with the actual experimental resul t s . I f one w ants only t o con firm t he model or meas ure its parameters , doint it via a re si d ence - time distrib ution is an unneces sarily comp licated te c hnique However , the use of residence- time distrib ution can be of benefit in two important ways . Firstly , one n ever exp ec t s models to be completely accurate , so t h a t re­ sults which deviate sli ghtly from t he prediction s of t he model are not sur­ U sin g I\ ( t ) gi ve s a p hysical i n si ght a s to t h e meanin g o f the de­ p ri sin g . S econ d , h ( t ) gi ve s in formation in a form th at i s a t leas t partially viation s . .

.

One still has a p hysical model o f s t e a dy st a te and tracer be­ havior b ut does not need any a p ri o ri assumption s as the the exact flow model . I nterp retin g the res ults in such a way forces one to consider what model free .

-

Residence- and Contact-Time Dis t rib u t ions

97

other explanations or alternative flow models may be consistent wit h the observed data . T his type of approach is very important in any reactor desi gn p roblem ( Overcashier et al . , 1 959) . As a n example , one might cite some o f the early tracer experiments in fluid beds , w hic h are represented in Fig . 1 7 . A low fluid b ed has a tracer response quite similar to a stirred tank , b ut representin g it in the A ( t ) domain im mediately indicates that one i s dealin g with a bypass p roblem , which was s ubsequen tly confirmed in other ways . It is often useful to have a knowledge of the p roperties of residence ­ time distrib utions o f different flow models . These are shown i n T able 1 . One must always remember that transport processes are nonlinear and cannot be described adequately by simplified models . F ( t ) is a linear property of such a model and the only time one can use it to p redict re­ actor performance is in first- order reactions in homogeneous system s , a problem that is not often encountered by the reaction en gin eer . However , simplified models are a very valuable tool . I n S hinnar ( 1 978) the term learning models was introduced to distin guish them from models used in actual desi gn predictions . T hey provide an un derstandin g of how the tran s ­ port processes might affect the chemical reactions an d give some guidance for de si gnin g the scaleup . Fortunately , many reaction s are not very sen ­ sitive to scaleup . N evertheless , it is important to be able to recogni ze those cases where significant scaleup problem s may be expec ted . There is one important case where models derived from t racer experiment s are di­ rectly useful in reactor desi gn . In many reactor p roblems , a plug - flow re­ actor is t he op timal configuration or if not optimal , is the only design that is safe for scaleup . As real reactors are seldom true plu g- flow reactors , one wants to know how closely the desi gn approaches plug- flow and how the deviations could affect reactor performance . Here one utilizes the fact that if deviations from plu g flow are small , one s hould get a reasonable estimate about their impact from any model that has a similar residence- time distrib ution . T his is equivalent to an asy mp totic expansion around a solu­ tion retainin g only the first -order term s . In such a case , one could use either a model based on one- dimen sional diffusion or a stirred tank followed by plug flow or a series of stirred tanks . The latter is preferred as it is easier to compute , and t he additional complexity of a diffusion model is not justified for cases where the real phy sical transport processes are not molecular diffusion . It is also more similar in its form to act ual measure tracer responses , as compared to a sin gle stirred tank followed by a plug­ flow reactor .

It is common to derive t hese simplified asymptotic models by demandin g the variance of the residence- time distribution of the model is equal to that of the actual measured residence- time distribution . The variance is then expressed as an equivalent P eclet number by the relation Pe : 2/y 2 , where is t he coefficient of variation as defined earlier . For a series of stirred tanks the equivalent P eclet number is approximately 2n . It will be shown later that such models give similar kinetic performance as long as the deviation from plug flow is small . These rela tio n s make sense for Peclet numbers larger than 10 ( pre­ fe rab ly 20) . For reactors in whic h the P eclet numb er is s maller , simplified models based on one- dimensional diffusion or series of stirred tanks make no p hysic a l sense ( unless , of course , one is really dealin g with three stirred tanks hooked up in series ) . that

y2

98

Shinnar

1 .0

0. 8

0.6

�

0. 4

"

1 - F (BJ

""

"

0. 2

0.1

"

�

"

e

(a )

"

"

3

2

0.0

"

4

2.0 1 .5

A
1 .0 0.5

0.0

(b)

0.0

0.5

1.0

1 .5

e

2.0

2.5

3. 0

3.5

FI GURE 1 7 ( a ) Experimental cumulative residence - time distribution for a fluidized bed . ( b ) Experimental inten sity func tion for a fluidi zed bed . Solid line : flow of gas in fluidi zed-bed reactor ; dashed line : completely mixed reactor ( for comparison ) .

99

Residence- a n d C o n tac t - Time D is trib u tion s TAB LE 1

P rope r ties

o f Some T heor e ti c al Residence- Time Distributions

I deally mixe d vessel Density :

f(t)

= .!T e

C umulative di st ri b uti on :

1

F (t )

-

-t / T

=

e

-t h

Expected value :

= 1

Coe ffic ien t of va ria tion :

y

Laplace trans for m :

L(f ,s) = E(e

I ntensity func tion :

f

1\ ( t )

-st

)

1-

-

-

-

1 +

TS

1

= ­ T

I deally mixed vessels in serie s ( T is the parameter o f eac h sin gle vessel ) n - 1 - t /T e 1) ! T (n

D e n si t y :

f( t )

C u m ulative distrib ution :

1 - F(t)

(t / T )

-

=

e

E (t) f

Coefficien t of variation :

y

Laplace trans for m :

L (f , s) - E(e

Intensity function :

1\

Special values :

f

=

(t)

A ( 0)

i

i!

i=O

Expected value :

=

( t} T )

� 1 L.J

-t /T

nT

1

,;n

--

=

=

- st

1

-

) -

1

+

TS

n- 1 /( n - 1) ! (t /T) ,.. n - 1 )i 1 . , 1. T L. i=O ( t I T

0

1

fl ( oo ) = T

}

(n > 1)

Two nonidentical ideally mixed ve ssels in serie s ( T and T 2 are the 1 parameters of the t w o ves sels )

D en si t y :

f( t )

=

'1

1

-t / T

'2

(e

1

e

-t /T

2)

S hinnar

1 00 TABLE

1

( C on tin ue d )

Cum ulative distrib ution :

1 - F ( t)

=

1 _ ;:.._ ..:;

_

1

1

Expected value :

Coefficient of variation :

2

T1 Laplace tran sform :

In ten si ty func tion :

Special values :

L( f , s )

1\ ( t )

1\ ( 0)

E(e

=

11 2

- st

T

+

) =

2 2

�---7-:-.,...-----:(1

1 1 1s ) ( 1

+

-1

+

1 2s )

-t /1 t/ 2 1 e __--,-___e'----:--

-t/1 1

=

J\ ( oo )

2T

+

-t/1

- 1 e '/,

2

0

=

min (;1 ' ) 1

=

T2

Plug - flow ve s se l Den si ty :

f( t )

C um ulative distrib utuon

1

=

unit Dirac function

F(t)

=

Expected value

f

t �

1 1

= 0

Coefficien t of variation :

y

Laplace trans form :

L ( f , s)

I ntensi ty func tion :

1\ ( t ) =

T wo

t <

{�

=

E (e

{�

- st

)

t :f t =

=

e

- sT

1 1

-

parallel , n oniden tical , i d ea l ly mixed ve ssels [ fraction II passes through T 1 ; frac tion ( 1 II) p a s s e s t hrou gh second vessel wit h parameter T 2 1 one ve ssel wi t h p arameter

D e n sity :

f(t)

1 - II

+ --- e

T

2

-t / 1 2

1 01

Reside nce- and Con tac t- Time Dis trib u ti o n s TAB LE 1

( Contin ued )

C um ulative distrib ution :

1 - F(t)

lie

=

-t/T

1

( 1 - II ) e

+

-t/T

2

Expected value :

Coefficient of variatio n :

Laplace tran sfor m :

I n ten sity function :

y

f

=

L(f , s) = E(e

A (t)

-st

( II / T ) e 1

II

..,..1-s --

) =

+

-t/T

l

A

( 0)

+

1 - II 1 + T s 2 - t/ T

+

( 1 - II h 2 ) e

-t/ T

2

= ------,--------:---

-t/T

II e

Special values :

T1

II

= -

+

1

-

1

II

+ ( 1 - II ) e

2

---

'

2

T w o parallel vessels , one ideally mi xe d , one plug flow [ fraction II passes through plug flow v e ss e l with pa r a me t e r T 1 ; frac tion ( 1 - II ) passes

t hro u gh i deally mixe d vessel with parameter < 2 1

Density :

f(t)

=

1 -

f( t ) = II

Cu m ul ative di s t rib ut ion :

II

---

1 - F(t)

'

2

x

=

{

- th e

Coefficient of variation :

T

1)

unit Dirac function ( t

II + e

e Expected value :

( t :f.

2

-tJ,

-t/ T

2

( 1 - II )

2 ( 1 - II )

=

T ) 1 t <

t ;
'1 '1

1 02

TABLE 1

Shinnar

( C ontinued )

L ap l ac e t ran s form :

L( f , s )

I n te n sity

A (t)

fu nc ti on :

=

E(e

=

S pecial value :

A ( O)

)

=

ITe

-t !c (1

A ( t)

- st

-

IT ) e

2

- s -r

1

+

(1

-

IT ) -:-= 1 +'--' s

1

2

+ IT

1

=

-

=

---

1

-

rr

E s ti mation of Model Pa rameters f rom R e s i dence- T i me D i st r i buti o n A s di scusse d in the p receding section , to esti mate the kinetic impact of s mall de v i ations from p l u g flow , one e stimates an equivalent P eclet number from the coefficient of variation of the residence - time distrib ution , One can direc tly use either f( t ) or F ( t ) [ s e e E qs . ( 1 ) to ( 3 ) ] . In the litera­ ture , re sidence - time distributions are often used to estimate simultaneously several param eters of a complex mocel . The author doe s not recommend this . Resi dence - ti me distributions a r e hard to measure accurately and are quite constrained . In a homo geneous flow , the first moment is fixed by V /Q . T he limit s of experimental accur acy seldom allow one to measure more than t wo additional momen t s . Often only one additional moment , namely the variance , is all one can reasonably expect to obtain . Therefore , one can ­ not estimate more t han one or two param eters from such experiments . Fur­ thermore , the models them selves are not accurate , and estimating multiple param eters for approximate models from a si n gl e exp eriment i s a doubtful procedure at best ( Overcashier et al . , 1 9 5 9) ,

U s e of T racer E x pe ri ments i n Col d- Flow Mod e l s and D e si g n of R ea c to r I n te rna l s T racer experi ments and residence- time distrib ution s are becomin g a widely tool in this area . In principle , t here is very little difference in the approach from t hat w hich was disc ussed in the p reviou s sections . One w an t s to make sure that one of the limitin g models , such as a stirred tank or plug flow , is app roxi mated as closely as possibl e . Q uite often one uses multiple tracers ( which will be discussed later ) , b ut the p rinciples remain the same . The followin g two exam ples may help illu strate this point , Baf­ fles , especially horizontal baffles , allow one to modify the complex flow in a fluid bed such that it approaches plug flow quite closely . Properly de­ signed baffl es achieve this by breakin g up the bubbles and stagin g the bed ,

used

1 03

Residence- a n d C o n tact- Time Dis trib u t io n s

reducing solid mixing bet w een top and bottom and th e reby also reducin g recirculation of gas either adsorbed on the catalyst or entrained in the dense p ha s e inside p ar ti cle clusters . An example of this effect and its me as u re m ent by a tracer expe riment is gi ven in Fig . 1 8 [ for details , see Ov er ca s hie r et al , , 1 9 59] . Fi gure 1 9 gives an example of the study of gas dis t ribu tor s in fluid beds. In Fi g . 19 some of th e f( t ) plots ar e double peaked , w hich clearly indicates a maldistribution . Here both f(t) and the e sc ape probability A ( t) clearly indicate that the desi gn of the dis t rib uto r is unsatisfactory and leads to a maldistrib ution in t h e overall reactor , w hich can be corrected by a proper design . This example ill u st r a te s the importance of a p rop e r base case in comparing al t ern ativ e s Fluid beds , especially short fluid beds , have maldistributions of flow caused by the formation of larger bubbles . These are due to inherent hy drody n ami c ins tabilities and c a nno t be pre­ vented by the desi gn of the distributor . In the cases shown in Fi g. 1 9 , some o f t he distributor d e si gn s give maldistributions which are much more p r on ou n ced c om pa r e d to the best achievable case , which is a p oro u s plate . R e siden ce ti me distributions cannot distinguish between t h es e two ph enomen a and should always be considered only an additional , al bei t important dia gn os tic tool . .

-

­

BAFFLED

UNRAF F L E D

2

(a )

(8 )

4

FIGU RE 1 8 ( a ) E xp e ri mental residence - time distribution for gas fl ow in a fluidi zed - be d reactor ( gas velocity = 1 . 6 ft / s ec ) - inten si ty function . ( From Overca shier et al . , 1 9 5 9 . ) ( b ) Cumulative residence- time distrib ution for the flow in part ( a ) .

1 . 0 ,...---..;;;;::-----,

o.e

0.6

0.4

0.2 1·F( 8 )

0. 1

0.0 8

0.0 6 0.04

0.0 2

0.01

0

2

9

( b)

3

4

( Continue d )

FI G U RE 18

f (t)

s s no z z l e p l a t e s an dw i c h g a s d i s t r i b u t o r

poro u s p l a te

c

Umf

_ u_

Umf u

=

=

1 .7

2 .0

F I G U R E 1 9 Residence- time distribution measured wi th di ffe re n t gas distribu­ tors in a fluid bed , as a fun c tion of fluidi zation indexes u / u ( From Woodrow , 1 9 7 8 . )

mf

"

1 05

Res idence- and Con tac t - T ime D is tri b u tions Mea s u remen t of Flow R a tes a nd R ea c tor

Volume o r Hol dup

In hydrology and physiology , tracer exp eriments are wide ly used to measure

flow rates and volumes [ Wein stein and Du dukovi c ( 197 5) ] . In reacti on en ­ gin eerin g it is possible in most cases to measure flow rat e s directly . Excep ­ tion s are reactors with internal circulation caused by density an d pressure differences , where t racer experiments are sometimes useful to measure flow It is not a very ac c urate method and should b e used rates u si n g E q . ( 2 ) . only as a last resort . In homogeneous reactors , the volume or h ol d up is almost always know n . One can then compare t h e volume es ti mate from t he residence- time di stribu­ tion with the known volume . To do thi s , one has to esti mate the contribu­

tion of the tail o f either F ( t ) or f ( t ) to the first moment . If the volume estimated from the first moment i s si gnificantly smaller than the know n volume , the ves s el is not w ell p er fu sed and has stron gly stagnant region s . An example o f this was shown i n Fi g . 1 3 . In multi phase systems the rela­ tive volume and holdup of solid liquid and gas are sometimes hard to measure , and he re tracer experiments can be valuable , despi te the s ho r tcomi n gs men ­ tioned above . An example of t hi s use is p resented later .

U S E O F R E S I D E N C E- T I M E D I ST R I B U T I O N S I N T H E

D ES I G N O F H OMO G E N EO U S R E A C T O R S

One advantage of u sin g t h e concept o f a residence- time distribution i n eval ­

uating tracer ex p e ri men t s has already b een discussed , namely , the p hysi cal insi ght in to the p roperties of t he system t hat is gained from the u s e of the escape probability II ( t ) . Just as important are the direct conceptual in­ sight s , w hich. can h e l p in un d er s tandin g reac tor desi gn problem s . T racer experiments are very useful i n organi zin g and evaluating alter­ native reactor de si gn s , a s well as in desi gni n g and evaluating pilot plant experi ment s . T hi s requires m ore than simple al go ri th mi c u s e s of the di s ­ tribution in w hic h o n e tries t o comp ute performance directly from a resi dence­ time distribution . However , the conceptual framework w hich offers quide­ lines for scaleup and scale- down p roblem s is generally worth the effo rt . T he results in this chapter can be derive d ri gorously only for homogeneous re a c tor s , w hich are a s m all fraction of the cases met by the de si gn en gi neer . However , the gui deli nes for reac t or design derived from the m ( i n contrast to desi gn al gorithm s ) apply to het ero geneou s reactors , as lon g as one un der­ stan ds the basic principles . The differences are di scu ssed in a later section . Fi rst-O rder I sotherm a l Reac tions

Consider the case of a first- order i s ot her m al reaction system . set of co mpounds A j ( j

T here is a

1, 2, , n ) which can undergo composi tion c han ges such that the rate of formation of a compoun d A j is given by n

r(A.) ]

- L

-

i=1

=

( - k1]. . A ].

.

+

]1

k..A.) 1

•

.

( 23)

In other words , all reaction s between t wo compounds A an d B can be ex ­ pressed by a set of reaction s

Shinnar

1 06

( 2 4) w here K A B i s t h e equilibrium con stant of t h e reaction A <::::;> B . I f one s tarts wit h an inlet c o m po site C j o , th e ou tle t c o m p osition of a plu g - flo w reactor is given ( Wei an d P rate r , 1962) by the equation n-1

C . (t) J

=

a. .

JO

'E

+

r=l

a. .

Jr

( 25)

exp ( - l. t ) r

where Cj is the co n c e n t ratio n

of

componen t j

ex p r e s s e d as a mole fraction

tt o and tl r an d A. r a r e the (n - 1) nonzero eigenvalues of the s y s te m . j j are c o n s t a n t s that depend on the initial and e quili b ri u m composition of the system , an d t is the residence time in the ho mo gen eou s isothermal plug- flow r e acto r ( or the r eac ti on tim e in a homogeneous b at c h r ea c to r ) . E quation ( 23) an d i t s solution [ Eq . ( 2 5) ] are co m p let ely equivalent to a Consider a pro b le m in probability theory describin g stochastic s y st ems . lar ge set of particle s , w hich can ch a n ge their state in a discrete w ay . E ach particle is a s s oci a ted with a state Aj . The p ro b a bilit y of a sin gle p a r ti c le b ei n g in a s pe ci fic state A i i s Pj . I f the number of p a rtic l e s in the se t i s very lar ge , the p robability of a p a rt iqle to be in Aj i s exactly equiva­ lent to the mole fraction s of partic le s Aj in the sy stem , w hich in a first ­ or d e r system i s p ro p o r tio n a l t o t h e co n c en tr at io n Cj . One can therefo r e look at Cj ei ther as a concent ration or as the p robability of a sin gl e particle ( o r molec ule ) t o be in s t a te j . T h e mathematical proof is gi ven in Shinnar et al . ( 1 97 3 ) . T h e reader unfamiliar with probability theory can i n terp ret E q . ( 2 5) as follow s . The concentration C jo of the p a rti c les entering the r ea cto r expresses , for a si n gle particle , the probabilit y of bein g in state j . T h e reactor changes this p rob ability into C j ( t ) . Each p a rti c le behaves here independently from its nei ghb o r and can u n dergo chan ges completely independent of an y other molecule in the reactor . This is t h e p hysical meani n g of a fi r st - or der reaction syste m . Once thi s is understood , some important results in re actio n engineering become clear wit hout further mathematical derivation . Consider a homo­ gen eo u s isothermal reac t o r w hich has a s t ea dy - st at e flow that can be charac­ te ri z ed by a residence - time di st rib u ti on f( t ) . T he inlet con c en tr ation is One can now p er fo r m t he follo win g t ho u ght experiment . An observer C jo stan ds at the outlet of t he reactor an d collects a ll the particles and sort s ·

t he m int o bi n s acc o r di n g to t h eir residence time . To d o s o , o n e has to divide t he residence time into intervals ll t . If ll t is small , all particles in t he bin , t to t + 6. t , e s s entiall y have the same re sidence time , t , in the As each molecule in t he bin behaves in dependently of i t s nei ghbors , sy s te m . the concentration in t he bin would be the same as at the outlet of a homo­ gen eous i sother mal plu g- flow re ac tor with residence time t . n- 1

J

p.(t)

=

C . (t) l

=

JO

c:t .

+

L

= r 1

a. .

Jr

( 26)

exp ( - A. t ) r

T he average concentration at the outlet of the reactor < c .> can b e obtained

by avera gi n g ov e r all th e

bins :

1

107

Residence - a n d C o n t ac t - Time Dis trib u tions

= l

j'0 f( t ) 0

[ a.

+

JO

�1

r= l

exp ( - A. t ) r

a. .

Jr

]

dt

( 27)

which is equal to

10

c.

n- 1

+

:E

a.

r=l

Jr

"'

f( A. ) r

( 28)

where f( A. r ) is t h e L apl ac e transform o f f ( t ) wi t h A. r sub stituted for the t rans for m variable ( s ) . E q u a tio n ( 2 8) is equivalent to the outlet of a hypothetical reactor described in Fi g . 2 0a , w hi c h con si sts of a set of paral ­ lel tubular fl o w reactors with different residence times t . T he fr ac ti on of fluid e nt e rin g a tube with a r e si d e n c e time b e t w e en t an d t + A t i s f { t ) A t . In practice , a real reactor wo uld h ar dly look like Fi g . 2 0a , but t h e re is one case that is equivalen t . C onsi der t he case w here th e reactor feed consists of separate dro p l e t s encap sulated by im p e rm e abl e membranes which have a residence - time distrib ution F ( t) in the reactor {it i s equi valent to the re ­ actor in Fi g . 2 0a ) . The in divi du al droplet s in suspension polymeri zation In a mixed reactor this is t r ue only in the li mi ti n g case behav e t hi s way . called se gr e ga t e d flow . In a firs t- order system , by definition , each mole­ cule can be considered s uch a sep arate dro p le t . T he well- known case of an ideally stirre d tank will illustrate E q . ( 2 7 ) . Consider the irreversible reaction A ->- B . In the case of a plug- flow re­ actor , C A ( t ) C A 0 e- k t and for a sti r re d - t an k reactor , a mass balance will giv e =

l

-

I �--------��--�, ------� ------------

------�1

L-

-

(a)

(b) Alternative flow models for Zwieterin g method of bou nding the conversion for a re action of nth or d e r : ( a) segregated flow ; ( b ) maximum mixedness . F I G URE 2 0

1 08

Shinnar

0

( 2 9)

or

For a stirred tank , f ( t ) i s here ( l l l ) e

E q . ( 27 ) ,

- tiT

and t herefore acc o rdin g to

( 30) In the mass balance [ Eq . ( 2 6) ] , i t was assumed that the concentration in the stirred tank i s uniform at any point in t he tank . For a linear system , a much w eaker assumption is s ufficien t namely that for residence - time dis­ Residenc4 tribution is exponen tial or that the escape probability is constant . time di s t ri bu ti o n s are linear p rope rty of the nonlinear model of the trans­ port p roc e s s in the reactor , and first- order reactions depend only on this linear p ropert y of the flow . In reality very few reaction s are truly linear , but it is a sufficiently good app roximation for m any system s . Many react io n s are also p seudolinear in the sam e sense that w hile the reac tio n rates contain nonlinear terms such as a Langmuir expres sion , they can be w ritten in a form ,

,

·

( 31) where Ki j is a mat ri x of linear reaction rate coefficients an d <j) ( Cjo ) is a non­ linear function of inlet con c en t ratio n an d pressure that can be taken out in front of the reaction rate m atrix . Although this is seldom completely cor­ For all those syste m s residence- time rec t it is often a good approximation . distributions are an imp o r t ant modelin g tool . ,

Dev i a tion of the R e s i dence- T i me D i s t r i b u ti on from K i netic E x periments

If one has a complex reac ­ One can also use E q . ( 2 8) in t h e reverse way . tion system in which the ei genvalues A r chan ge over a si gnificantly wide ran ge , we can use it to recon struct f( s) . A s sume th at the values of A r hav e been measured from a batch e x p e ri men t or a plu g flow reactor , and one now has experimental values for all the concentrations C j at t he outlet o f an industrial reactor . One can then compute the v alue s of A r and use them to e s ti m a t e f( A r ) for the in dustrial reactor . One then has sev �ral values of t he Laplace tran sform f( s) from which a reconstruction of f( s ) can be attemp ted . I f the A r are wi dely spaced , the reconstruction i s quite goo d . T hi s approach will b e discussed in more detail later when we deal with contact - time distrib ution in hetero geneous reactors . -

...

109

Residence - a n d Con ta c t - Time Dis tri b u tions Opti m a l R eactor C oncepts fo r Fi r s t- O rde r R eact ion s

Iso thermal Reac to rs T h e conce p t s derived in the p recedin g s ection lead to some important con ­ Sp ecifically , t hey clu sions with regard to choosi n g a reac tor confi gura ti on . provide gUi delines for cases in w h i c h a plug- flow reactor is th e preferred choice and for cases in w hich other reactor confi guration s will be p refera b l e . The p rincip l e that a first - order reaction system is c om pl e t ely equivalent to the case w here sin gle m ol ecu le s under go c han ge s from one state to othe r states , with defined probabilities , si m p li fie s many desi gn p ro b lems . Many op timal p ro b l e m s that are v ery difficult to deal wit h analy tically become in­ tuitively clear if one understan d s the fo regoin g p rin ci p le and applies it approp riat e l y . In the p recedi n g section it was s how n t hat in th e case of a fi r s t - order isothermal reaction system of arb i t rary complexity , the h y p o t he tical reactor in Fi g . 2 0a w ill give identical re sul t s t o a ny reac t o r havi n g the same residence- time dis tribution . T he outlet concentration is therefore t h e average o b t ain e d from several plug- flow reactors with di ffe r en t residence O nce o n e re co gni zes t hat all one needs t o d o is ave ra ge over a num ­ time s . ber of p l u g - flo w re acto rs , o p ti mi zation is si m p le . C o nsider , for example , the case w here < C j ( t ) > for a specific v alue of t has a de sirable o p ti m um minimum or m axi m u m concentration of < C j> · Th e n assume that one has found a re ac to r wi t h a re si denc e - time di strib ution f ( t ) that gives an o p ti m u m

yield of Cj · In this reactor t he o u t l et concentration < c > is si m p l y the j average of all t h e different plu g - flow r ea ct ors . There i s a simp le al geb raic theorem that say s t hat in any s e t of n u mb er s with average X , there i s at least one member of the set e q u al or large r than X and a.t least one member equal o r smaller t han X . I f f( t) is a plug flo w , one has only a sin gle plug­ flow rea cto r wit h t = E f ( t ) = T an d which has a u ni q u e C j < Cj > . B ut if f( t ) is not a p l u g flow , o ne has in Fi g . 2 0a diffe ren t tubes with different outlet concentration . One o f these reactors has an o u tle t concentration equal or l a r ge r than t he average concentration < C j > and in one of these re ­ actors C j is s m al l er ( o r l ar ge r ) than < c j > . T herefore , depending on whether one wishe s to maxi mi ze or mini mi ze < C j > , on e can alw ays fin d a tubular reac tor in Fi g . 2 0 wi t h a uni form resi den ce ti me w hich is as good or better than the reactor wi t h the a rbi t rary residence time f( t ) . T hi s is a si mp le proof that for first - order systems a p lu g - fl o w reactor is optimal i n the sense t h at o n e c a n d e si gn a plug- flow reactor wi t h a yi el d or selectively as high or hi gh er than any i sothermal reactor with ar bi t r ary residence- time distribution . It results in a very sim p le b ut powerful con c e p tual tool fo r reactor desi gn . I n all cases w here t he s y s te m is such t hat one can o b t ain the outlet co n c e ntrati on si mply b y av e r agin g over the bin s of differen t re­ sidence times , t hen , for any reaction system which has the p rop erty that there is an o p ti m um yield of one co mpoun d , a p l u g - flow reactor is t he best choice . I f , fo r other reasons a simple plug- flow reactor is no t fe asible or desirable , one w an t s a desi gn in w hi c h the resi dence - time di stribution ap ­ proaches plug flow as cl o s ely as possible . For example , F ( t ) for a series of s tirr e d tanks approaches plug flow if the number of stirred tanks is reasonably lar ge . One can j u dge t h e re q ui r e d number of tanks si mpl y by =

110

Shinnar

the allowable deviation from plug flow .

S ta ge d systems in general h av e a

similar property and one can use the s a m e approach to estimate the number of stages re quired . For av e r a gi n g to apply , the reaction does not have to be s t ri ctl y first order . A ll one re qui re s is that t he reaction behavior of a mo le cu le is not affected by t he nature of i t s ne i g hb o r s , as di s cu s s ed in the p r e c e di n g sec­ tion . O therwis e , one needs to know not only how lon g a mo l ec u l e has been in t he system , but al s o who its nei ghbors were . If the outcome i s s t ron gly affected by the nature of its n ei ghbors , a residence- time di s t ri b ution can­ not p rovi de an answer for the o ut co m e . N or can one show that plug flow is op timum , although one can still get some g ui de li n e s w hich will be di scus s e in a la t e r s e c tion . In a si mi l a r way , if one looks at t he conversion of a first - order simple re ac ti o n A <=> B wit h reaction ra t e

( 32) it is given by

a - a

eq

=

(a

0

- a

eq

)e

- ( k +k ) t l 2

( 3 2a)

A gain , the outlet concentration of a reactor wit h resi dence - time distrib ution f( t ) is obtained by av e r a gin g over the bins , - (kl k 2 ) t over f ( t ) . It is easy to see + w hich really me an s averagi n g e t hat a p l u g - fl o w reactor with the same average residence time t will h av e a low er a - ae an d hence hi gher co nv e r si o n t han a reactor in w hich the bin s have di f eren t t . ( Had the function been concav e , the opposite would For hi gh co n v e ri so n in a fir s t - o r d e r isothermal system , a hav e been true . ) plu g- flow reactor will h av e t he lowest res i d en c e time . A gain , o n e can evalu­ ate the permissible d e vi a tio n by some very si mp l e models ( such as a s e ri e s of s ti r r e d tanks ) an d jud ge the desi gn by measurin g the deviation from p l u g flow via a tracer ex p e ri m e n t . For small deviations the co effi ci en t of v a ri at ion y 2 of f( t ) is a good criterion . In the li tera t u re the P e clet number is oft e n used in stead and is app roximately equal to 2 f y 2 . M ore accurately , it is given by the expression ( see Shinnar a n d N aor , 1 9 6 7 ) .

T his is a convex function of t .

�

y

2

=

2[e

- Pe

- ( 1 - Pe) ] 2 Pe

( 33)

w hich for large Pe ap proaches

y

2

2 Pe

( Pe

+

00

)

( 3 3a)

B ut o n e should be careful not to use P eclet numbers smaller th a n 1 0 , be­ cause in m o s t c ases this is meanin gless , as t h e residence - time distribution will not fit a o n e - dimensional diffusion mo d el . I n fact that the re sults are not s e n s it i ve to the form of the deviation from plug flow is illustrated i n Fi g . 2 1 , w h e r e two cases are plot t e d . T he

111

Residenc e - and C o n tact- Time Dis t rib u tions 100

"I 9 0

. .q .... 0 z 0 Ul a:

� 80

'- I D E A L STIRRED

z 0 0

70

(a)

A ....'!.. a 1.0

2 .0

3.0

�

:I

X .q ::E

K

5.0

6.0

k

k

A _).. B � C

0.7

::t

4.0

-'---'---'--- ·_l __!.__L___L_--L._-.J

O. B

0 .q ..... CD

TA NK

0.6 0. 5 0.4

0.3 0. 2 0.1

0.0

(b)

IDEAL STIR R E D TA N K 1.0

2 .0

� kl k

3.0

4.0

5.0

( a ) Conv er si on o f a first- order irreversible reaction for differ­ residence - time distributions . ( b ) Selectivity of a con s ec u ti ve first ­ order reaction for different residence- time distributuons . 1 . Mixed flow ; 2 , five C STRs in series ; 3 , one- dimen sional flow , Pe = 8 . 87 ; 4 , 1 0 C STRs in series ; 5, one- dimensional flow , Pe = 20; 6 , plug flow . FIGURE 2 1

ent

Shinnar

112

first illustrates an irreversible fi rst - order reaction at hi gh conversion , and For the second s how s the selectivity of a consecutive fir s t - order reaction . both case s , the limitin g cases of plu g flow an d a stirred tank are given and two models with equal Peclet number are given . O n e is a network of equal stirred tanks in series an d the other is a one- dimensional di ffusion system with a Peclet n umber chosen such t hat y 2 is equal for both cases . For y 2 = 0. 1 , the re sults are so close that it is impossible to plot the difference . For y 2 = 0 . 2 ( Peclet number 8 . 9 or 5 s tirred tanks in serie s ) the difference is already recogni z able b ut still s mall . One should not mi sinterp ret this statem ent . The results are alw ays sensitive only to the variance of f( t ) . In this case only models for which f( t ) has a reasonable similar form were compared . For such cases all models with eq ual y 2 will give si milar results , For computation it is therefore ad­ provided that y 2 is sufficiently small . vantageou s to use simpler models based on stirred tanks instead of diffusion , esp ecially since none of the models rep resent s the actual physics accurately . N o n iso thermal R eac tors

T he arguments in t he precedin g section can be easily extended to a noniso­ thermal reactor , p rovided that t he temperature profile is i mpose d from the outsi de and i s independent of the reactions . For example , consider an a rbitr a ry network of stirred tanks , each of which is homo geneous and has a uniform temp rature imposed from the outsi de , altho u gh eac h reactor may have a different temperature . The reactors are interconnected in an A gain , arbitrary manner . T here could be s everal inlets and outlets.. each enterin g molecule is equipped with a clock , but this time a more com ­ plex clock i s c hosen that not only records t h e time spent i n a specific t ank , but also records each s tep in a specific tank in the order in which it occurs . ) If one looks at each clock , one finds a set of ti mes < t t . t 2 , t s , t l , t 2 , i dentifyin g each successive stay in tank i until it leaves the syste m . One again collects t hem into bins , but this time one insi s ts that not only the total residence time t is constant in each bin , but that all molecules in a bin have an i dentical clock history . T hus in each b i n not only are t he separate stays in each tank of equal len gth , but they occur in the same sequence . In each stirred tan k the reaction s are first order wit h fixed reaction rate , determin e d by t he temperature of the tank . This means that if one know s the state of a molecule ( or the concentration of each compound ) enterin g the tank and the len gth o f stay i n the tank , the p robability dis­ tribution at the time it leav e s the tank is known or can b e computed . T hi s means that if one knows t he whole history of a molecule in a bin , one kno w s the p robability of it bei n g in each one of the permissible states , w hich in reaction term s means that one kno w s the concentration of the dif­ For t hose w ho are somew hat uncom fortable ferent co mpounds in the bin . with p robability theory , thi s concept can be t ranslated a s follow s . Follow a blob of molecules that has an equal history . As t hey travel through each tank , the concentration of the b lo b changes in each tank in the same way it would in a plug- flow reactor wit h the same temperature and residence time . T here is now only a cascade of plug- flow reactors with different resi dence times and temperatures ( or reaction rates ) . Each bin represents a unique sectional plu g- flow reactor o f this type ( see Fi g . 2 2 ) . It was shown pre­ vio usly t hat each stirred tank can be presented in such a w ay that mole c ule s with residence time t can be lumped to get her and treated as i f they would be in a p lu g - flo w reactor of t he same residence time t . The avera ge outlet .

.

•

Residence- a n d

FIG U R E 2 2

113

C o n t ac t - T im e Dis tri b u tions

E qui v a l en t representation of a

particle

S ec t io n ally uniform plug- flow reactor . each section ; ti residence ti me of each s ec tio n

mal reactor .

,

history in a noni so the r

­

T i , t emperat ure of

.

is now the average of all those sectional plug- flow reactors clear that if one is all ow e d to average them , one can always fin d a single bin (or a plug- flow reaction with a s p e cial temperature and tim e sequence ) , which yi e l d s a result as good or better than t he network of stirred tanks . This p roof i s not limited to n e t wo r ks of stirred t an k s One can take any arbit ra ry flow and represent it by such a n etwork if one makes the stirred tanks small en ough This i s therefore t r u e for any arbitrary flow

concentration

and it is

.

.

system provided that : 1.

2.

T he re ac tion rates are locally first order in concentration . The temperature profile i s independent o f the reactions and i mpos ed from the ou tsi d e .

If co n di tion 2 is not fulfilled , as for example in an adiabatic reactor , one can no longer average . T he temperature of a tank will depend on its con ­ centration , and therefore the r e ac ti o n rates affecting a sin gle molecule will depen d on the n at u r e of t he other molecules in the tank , which violate one Howeve r , as many r e a c ti ons are approximately first condition for a v er a gi n g order , ave r a gi n g p rovides a s i mp le guideline for reactor desi gn . E ven more important , it lets one understan d and reco gni ze the e x c ep ti o n s to the rule , in the cases w here plug- flow reactors are not optimal . T hese inglude , for example , all cases in w hich it is d e sir abl e to maximize the contact between produc t s and reactants . .

Bounding

M e t ho ds for N o nlinear

Reac tions

For a fi r st or d e r system , knowled ge of the r e si d e n ce tim e distribution co m pletely determine s t he pro d uc t co m p o s ition in a premixed i sothe r m al homo­ For nonlinear re ac tio ns this is not e nou gh as one n ee d s geneou s reactor . to know n ot only the history of a molecule , but al so the property and s tat e However , for a certain class of of the molecules in i t s close neighborhood . nonlinear r e ac ti o ns wehre the reaction rate is of the type -

-

­

,

rA

=

- kan

( 3 4)

Zwi et erin g ( 1 9 5 9) has show n t hat o n e can get ri gorous bounds on t he pos­ sible conversions directly from f ( t ) . C on side r again a s tirr e d tank w it h the simple irreversible re action A + B but t hi s time let the re ac tio n rate be second order. If the tank is ideally sti rr e d , a mas s bal anc e will give ,

- QC

Z

- VkC

2 A

=

0

( 3 5)

114

S h i n nar

and

( 3 6)

One can also namely , that

look

at the other extreme i de ali zed case

mentioned

stay together ( w hich Zwieteri n g term s se gre gated flow ) .

equivalent to the re actio n c on centratio n will be

in Fi g .

13.

T hi s case i s

I n each tub ular reactor the outlet

1

=

an d t h e

before ,

the enterin g flui d enters as separate encapsulated drop s that

( 37)

average

outlet concen tration will b e

>

S exp (

th e average

simply

over f( t ) ,

or


A

=

C

AO

S ) Ei ( a >

a

Ei i s t he exponential inte gral . ferent results . However , if k C A O t small ( see Fi g . 2 3 ) .

00

1

=

kC

w here

t

AO

not

T h e reason for the difference is that

1

=f

-

very large ,

for a

e

0

that the two

N ote is

E.

-u

u

0 /u

lead t o difference

cases the

( 38)

dif­ is

s e c o n d o r der reaction the

p robability of a molecule of substance A r eac tin g depends on its p robability

molecule of A . In the segregated case , t his is larger than in t he mixed case , a s in the latter t h e enterin g molecule is immediately exposed to p roducts t hat reduce C A in its surround ­ in gs . K nowle d ge of the resi denc e - time di strib ution alone is here insufficient to comp ute C A , as one needs to know w hat happened not only to the mole cule but to its neighbors . H o we ve r , for this simple cas e of secon d - order reaction , Zwietering was able to show that ideal mixing a n d s e gregated flow of

bein g close to another

probability

­

condition s are extremes and that all other possible mixin g sit uations for

f ( t ) is the

w hic h

C

A

For n

r

A

(ideal

=

=

s am e will res ult

mixi n g )

> C

A

in an

( s e gregated

outl et concentration such that

( 3 9)

flow )

1 / 2 or - kC

A

1/2

( 40 )

the limits become

2

( � ) (� � kt

2

C

AO

2

kt

2

2

C

AO

( 41)

115

Residence- and Con tac t - T ime Dis t ri b u tions

0.8

0.4 0.2 0.0

0

2

4

3

5

-

-

F I G U R E 23 C o nversio n of a sec on d o r der irreversible reaction ( A B) in a sti rre d tank as a function of time for segregated an d completely mixed flo w .

an d

C

[ (� )

l ( s e gre ga ted flow ) = C Ao A

+

kt

2

2

C

2

-

( 42)

AO

Note that C A for t he i deal stirred tank is l e s s than C A for se gregated flow . Here the presence of molecules of A reduces the r eact ion r a t e a n d mi x in g However , one has to be v e ry careful wit h products improves conver sion . with such arguments w hen applie d to reaction s of fr ac tional order . T h ey arise nor m ally from Langmuir- ty p e re ac tion r ate expres sions . Expressin g them as a fractional order is correct only over a lim it ed ran ge of con c entra ­ tion s . T here is a high probability t hat in in t e gr ati n g the results for Eq . ( 40) , one m ay go o u tside the ran ge w here this is applicable , an d t herefore T he one must verify that the final result is not se n siti ve to this mistake . results for a n on line a r reaction t herefore dep end not only on f ( t ) but on a mo re complete descrip tion of the mixin g phenomena which Zwieterin g t e rms

micromixin g .

Swieterin g has also s hown that these results can b e extended t o any arbitrary re si dence - time di stribution as lon g as the r e ac ti o n is a si mple re­ In that case C A I C A o will al way s be bounded by two ex ­ tre me cases : the case of segre ga ted flow given in Fi g . 2 0a and another Where ­ case defined as maxi mum mixedne s s , w hic h i s illu strated in Fi g . 20b . as in Fi g . 2 0a ea c h tubular re ac t or is s epa r a t e in Fi g . 2 0b , t here i s inter ­ mixing betw een them and the feed inl e t s are arranged such that t he expected action of order n .

,

S h in nar

116

future life is constant for all molecules in a given cross section . P h ysi c al ly , one could reali ze t he a r r an gem en t of F i g . 2 0b b y d e si gnin g a pl u g flow r e­ actor in w hich additional feed is i ntr o d u ce d at different poi nt s along the t ub e . For a r ea c tio n of order n the two limi t s or bounds on conversion are se g r e ga t e d flow and maximum mixedness . For the case of segre gated flow , 00

J

[1

+

( n - 1)RJ

111

-

n

f ( t ) dt

( 43)

0

- kt R = -�1-n

C

AO

For the case of m aximum mix ed n e ss , < C A > / C A O h a s to be o b t ai n e d by solv ­

i n g the differential equation

( 4 4) w here A is an i nt e gr a ti o n variable and A ( A ) is the escape p robability a s de ­ fined by E q . ( 8 ) . E q ua ti on ( 44) can be int e grated numerically , although for certai n valu e s of n and certain values of 1\ ( :>.. ) it has analytical solutions . Here one sees another useful p roperty of the escape p robability and why one w a nt s to m e a s ur e the re sidence- time distribution in such a w ay that A ( t) can be comp uted reliably . For reactors close to plug- flow reactors , the bounds are very close and one does not have to worry about micro ­ mixi n g w hi ch i s im p ortant mainly in stirred- tank reactors . S t ri c tl y speakin g , the results of E q . ( 43) apply only to si mple reaction of o r der n , in homogeneous ideally stirred reactors , w hich is a rather rare desi gn p roblem . However , the concepts of boun di n g t he outlet co m position of a reactor is an e ssential tool of reaction engineerin g . I t i s really a fo rm of p e rfor min g a s e n siti vi t y analysis on a de si gn . Consider the example o f a A priori one knowns that this is an i deali zed model t ha t can­ sti rre d tank . H o wever , o n e c a n approach i t in t he sense that the not b e fully reali z e d . time a droplet of feed spends in the reactor before it becomes t ot all y mixed i s very s mall com p ared to the tot al residence time ( Ev an geli s t a et al . , 1 9 69b ; S hinnar , 1 9 6 1 ) . O ne also kno w s t hat durin g scaleup t he residence time s t a y s constant , w hereas the mi xi n g ti me always i nc re a se s ( Evan gelista et al . , 1 96 9a , b ; Shinnar , 1 9 6 1 ; W ei n s t ei n and Dudkovic , 1 97 5) . For a se co n d - o r d e r sin gle reaction , Z wieterin g' s results show that one p robab ly does not need to worry about this , a s the completely mixed case is t he worst ( least de ­ T here are many ot her cases for which this i s not true . One si rable ) cas e . wants to know how important s uch deviation s from complete mixin g are . To answer t hi s , the two limitin g cases for any arbitrary reac ti o n system are d e ter m i n e d . If the reactions are complex an d nonlinear , t he se two limiting cases ( s e gr e g at ed flow and complete mixing ) will not give rigorous bounds b u t will indicate i f t he system is sensitive to mixin g and w hat p enalties are i n c ur re d for in com p l e t e mixin g . In scaleup , one cannot achieve se gregated flow , so the case of complete mixi n g must be s ati s fac tor y or the desi gn must be chan ged . If the s y s t e m i s sen sitive t o mixin g , one can estimate t he per­ missible mixin g tim e by u si n g models for incomplete mixin g that si m ul at e

Res idence- and C o n t ac t - Time Distrib u tio n s

117

small deviation s from in co m p le t e mi xin g ( E v an geli s t a et al . , 1 9 6 9a , b ; B elevi

et al . ,

1981 ) .

I f , in a sti rr ed - t an k reactor , s e gr e ga t e d flow leads to improved re sult s ,

a plug- flow reactor will n orm ally be even better . If one r e qui r e s the stir­ rin g , one can a ppro ach plug flow by putting several such s ti rr ed tanks in se ries . E xperiments that de m ons t r a t e the s e n si tivit y to d e vi ation s in mixin g can al so be performe d in a pilot p l an t . For ex amp le , one can desi gn a

pilot plan t similar to the one shown in Fi g . 2 4

des pi t e the fact that the T here hav e been a number o f models propo se d that look at m icromixin g for more comp lex flow co n di t ion s over a w i d e r ran ge of mic ro mixi n g [ see , e . g . , Weinstein and Adler ( 1 9 67 ) ; N g a n d Rippin ( 1 96 5 ) ] , T he s e models , which are reviewed in detail in N auman ( 1 98 1 ) , are more in t he nature of l e arnin g model s than de si gn models , an d are th e r e fo re outsi de t he scope of this ch a p t er . Si milar c o nsi d er atio n s app ly to p ack e d - bed and fluid- bed reactors . For nonlinear r eac ti o n s the only safe w ay to sc al e them up is to approac h plug flow as clo s ely a s p o s si b l e . A gain , one wants to know how closely plug flow m u s t be appro ac hed and w hat the p e n al t y is for s mall deviations . One can again p e r form e x p e rim e nt s w hic h ex p e rim en t all y check the sensitivity of the reaction system to d e v i ati ons from plu g flow an d desi gn the reactor accordingly . H e re re si dence- time di s t ri b u tio n s are directly u seful , since for small de v i atio n s from plu g flow , one can estimate the deviation fro m A si mple model will p l u g flow fro m the tr ace r response by m ea s uri n g y 2 . gi ve reasonably reliable bounds as to the possible impact of such small de­ viation s , even i f t he reactions are hi ghly nonlinear . If the sen sitivi t y i s large , o n e s hould take a safety coefficient with re s p e c t to t he allowable co ­ efficient of v ari a t ion . T hi s is i l lu st r a t e d in Fi g . 2 5 , w here the effect of small dev ia tio ns fr o m p l u g flow on s e v eral reactions are comp ared . One i s simply the irreversible r e act io n A + B of se co nd ord e r , and t h e other is a nonlinear ca s e very sen sitive to mixin g . In both cases th e re sult s a re in­ distin gui s hable , and for y 2 = 0 . 2 ( five stirred tanks in series , or a Pecl e t number of 1 0 ) the results are r ea so nab ly close . In both cases we also giv e the limiti n g cases of p l u g flow an d a stirred tank to indicate the sensitivity to back mixi n g . T he comments made with re ga r d to Fi g . 2 2 apply here final reactor i s c omp l etel y mixe d .

FIGURE 24

Si m ula ti o n of finite mi xi n g in a p i lo t p la n t .

118

Shinnar

equally w ell .

T he results are not unique functions of y 2 .

How ever , for

s m all deviations from plug flow , t he results are not model sensitive as lon g

as the residence - time distri butions are rea sonably similar . For simulation p urposes , a model based on stirred tanks is therefore preferable , as it is T he fact that y 2 alone i s not s ufficient t o charac­ much easier to compute . teri ze the system unless y 2 i s very s m all is illustrate d in Fi g . 2 5c w here two ot her models with y 2 0 . 1 are compared to a serie s of stirred tanks . For a reaction sen sitive to mixin g , such as t he one show n in Fi g . 2 5b , the differences are very lar ge and a m uch smaller y 2 is necessary for them to become ne gli gible . Such reaction s t he refo r e require extra care in scaleup and a close app roach to plug flow ( or a stirred t an k ) . =

80

70 <[

60

LL.

0 z 0

u; 0:: ILl >

� 50 u

40

30

3.0

2.0

1.0

4.0

(a) F I G U RE 2 5 ( a ) C onversion of a second - order irreversible reaction for dif­ ferent flow models . ( b ) C o m p a ri so n of p roduct yield in a consecutiv e non­ Reaction A + B + C fir s t order ; linear reaction for different flow models .

reaction A + C + D second orde r . Inlet concentration of A , 1 . 0 ( di m ensio n ­ less unit s ) . 1 , Mixed flow ; 2 , five C S T R s i n series ; 3 , one- dime nsional flow , Pe 8. 8 7 ; 4 , 1 0 C S TRs in series ; 5 , one- dimensional flow , Pe = 2 0 ; ( c ) Same as in p art ( b ) for different flow models : 6 , p l u g flow . =

(I )

VPF

+ =

[=:J

+

Ll..J

0. 69 V , V ST

=

+

(II )

0. 31.

1 0 stirred tanks in serie s ( I I I )

....

l.LJ

....

c:=J+

119

Residence - a n d C o ntac t- Time Dis t ribu tions 0. 0 5

0

A .!. e.!.c A + C 0"1

0.04

w w u.

z c(

D

0.0 3

w ..J

0 ::iE 0

......

0.02

0 u.

0 ::iE

0.01

/

;y

/:/_ .

0. 0 0

...... -

- -��

-- - �

-·

1 .0

2.0

3.0

4.0

L-----'-----'----.I..... ---'---___.___.J

(b) 0.04

-

/ �Pl.� ./

II) w ..J

--

- '"4

TIME -

----- -------�

A 2. e ....!. c A +

c ..QJ.. o

0.0:3

0 IL 0 Ul w ..J 0

::!: 0. 0 2

0.01

0.00

(c)

1 .0

2.0

F I G U RE 2 5 ( Continued)

3.0

T I ME -

4.0

120

S h in nar

T here is another area in which the concep t of a residence - time distribu­ tion is useful in o r ganizi n g ones thinkin g and experimentation . T h inking in terms of residence times and joint p robabilitie s is helpful i n de ci di n g what reactor types t o choose . For all linear and p s e u do lin e a r system s , iso­ thermal as well as nonisothermal , plu g- flow reactors are alw ay s p re fer able . The case w here bac kmi xin g or a stirred tank has a po si ti ve influence is Ex­ w hen there are complex interaction s betw een p roducts and reactants . amples a r e autocatalytic reaction s , autothermic reac tions ( hea t c a n be con ­ sidered a prod uct ) , or reactions of the types A + B

+

C

A + C + D If D is d e si r abl e , a mixed reactor is p r e fe r abl e , as can b e seen from Fi g .

2 5 . I f D is undesirable , a plu g- flow r eacto r is p re ferable . of thi s reaction di scussed in R enick et al . ( 1 9 8 2 ) : Methanol

+

olefines

+

aromatics

A r om a tic s + m e t hanol + durene

+

An example

p araffin s

I f D ur en e form ation i s to be avoi de d , the reactor should b e as close as possi bl e to plug flow . T hi s re s ult can be derived wit hout reference to residenc e - time distribu tion , but thinki n g in term s of resi dence time p ro vides a useful fram e w ork . T here are a num b er of ca s e s in w hich the desirable confi gur ati on i s neither p l u g flo w nor a sti rr e d tank . Combustion is an example . B ut here one can often b reak dow n the optimal or desi r e d flow sys t e m into confi gura­ tions composed of w el l - d efi ne d flow s . I f , o n the other hand , the flow i s complex , residence- time distributions may pr ovi de dia gnostic test s , b ut one can neither model nor scale such cases sol e ly on t h e basis of residence- time distributions . It s hould be emphasi z e d that at the p resent state of knowled ge , t here is no w ay that one can reliably scale up a reactor if the reactor is sen s itiv e to the form of f ( t ) and the r e ac tor does not approach one of the well ­ defined i deal cases . ·

H E T E R O G E N EO U S R E A C T O R S A N D

M U LT l P H A S E S Y S T E M S

Prope rties o f T racer E x peri m e n t s i n M u l ti p hase S y s tem s

Residenc e - time distrib utions p r ovi d e a powe rful method for the a n al ysi s of ho mo g e ne o us i sothermal reactors . Unfortunately , very few real reactors used are t r uly ho mo ge n eous . Those few that are seldom p rovide se riou s difficultie s in desi gn or scaleup . The majority of t he re act ors used are heterogeneous , eit her gas - solid , gas - liqui d , or triple phase . Catalytic re ­ actors are almost alway s heterogeneous , even in homo geneous catalysis , w he re most of ind ustriral reactors deal with gas - liquid reactions . If t h e use of re si den c e - tim e distrib utions was restricted to homo ge n eo u s Luckily , m o s t of t he reactors , t heir usefulness woul d b e rather limited . concepts derived in the pr evio us sections can with some care , be applied to hetero geneous reactors . One must , ho wever , be careful to take i nt o account the hetero geneous nature of the system . T his rules out many of

1 21

Residence- a n d C o n tact- Time D is t ri b u tions

the algorithmic uses of residence - tim e di st rib utions . One cannot simply m easure a residence- time di stribution and predict the performance of a com­ Even t he concept of a residence- time di s t rib u ti on is not sim ­ plex reactor . ple any more , as different reactants m a y have totally different residenc e ­ time di stribution s . I n a hetero geneous reaction one cannot measure reaction rates and re sidence - time distributions i ndependent ly and reliably predict re­ actor performance even for first - order system s . B ut the main uses focu sed on in the precedin g section remain .

1.

T he intensity function is still a useful tool to dia gno s e maldistribu ­ tions in t he flow and provide clues to the nature of the flows in Of special importance is t h at it allows one to check how t he system . closely a desi gn approaches plug flow (or an ideally stirred tank ) It is also usefu l in cold- flow models , w here it c an be used to test the efficiency of flow distrib utions or baffle s . T he examples given earlier were fro m hetero geneous reactor s Residence- time distributions still provide a powerful conceptual tool for desi gn and scaleup . A lthou gh often one cannot get accurate p rediction s , one can derive a better un d erstandin g of the scaleup p roblem . Resi denc e - time distrib utions i n multiphase systems allow m easurement of t he hol dup o f each phase . .

.

2.

3.

T here are some imp o rtant differences between tracer exp eri m en t s in homo ­ geneous and he t ero ge n eou s sy stem s . It is i mportant to understan d these differences not only in evaluating tracer experiments , but also because they are related to desi gn and scaleup . In a hetero geneous system , di fferent compounds m ay have stron gly different resi dence - time distribution s . In a homo geneous reactor t he difference in residence- time distrib utions between different compounds i s , i n most cases , ne gli gible . T his is especially so if T he only exceptions are slow laminar flow s , the mixing process is turbulent . w here mo lecu l ar diffusion will be important . T hu s in most homo geneous re­ actors the nature of t he t racer compounds is of small importance . On the other hand , in heterogeneous system s , there can b e lar ge differences be­ tween the response of different tracers , and therefore between the respon s e o f a tracer and that of a reactant . Even different compounds in t he feed or different products may have different residence- time distribution s . An example o f this is shown in Fi g . 2 6 ( see also O rth and S c h ii ge rl , 1 9 7 2 ) . Fi gure 2 6 i l l u st rates data taken from a pack e d - b e d Fi scher- T ropsch reactor in which CO an d H 2 were reac te d over a Ni c ataly s t . T he reactor w as operated at s t eady state and a step in p u t of CO containin g 1 3 c w as intro­ T he helium concentration w as duced to gether wi th a step input of helium . T he re sponse o f kept very small so as not to di sturb the steady state . the 1 3 c in t he C O is plug flow with a lo n ger residence time , which show s that the CO is adsorbed but t hat the interchan ge of the adsorbed CO with the CO in t he gas p hase is very fast . On the other han d , both the C H 4 and C 3 H 6 p roduct b ehave like a stirred tank i n series with a p lu g flow . This indicated not only stron g adsorp tion but that , in this case , the inter­ change b etw een the adsorbed phase and the gas p hase for t he pro d uc t i s T he re slow and has a characteristic time similar to t he residence time . sult s could also have been the reverse ( slow i n t erchan ge of the reactant and fast interchange of the p roduct ) . In a reactin g system the concept of a residence- time distribution itself b ecomes rather c om ple x to define .

1 22

Shinnar

,/H e

1.0

I I , I I r I r r I

0.5

0

r I I I I I

0

/

100

200

30 0

400 I ,

sec

FI G U RE 2 6 Response of a packed- bed Fi scher-Tropsch reactor , fed with an d H 2 , to a step input of 1 3 C O and H e . Reactor kept at steady state . ( From Biloen et al . , 1 98 3 . ) CO

One can always define it with respect to specific elements such as C in Fi g . 2 6 ( o r molecular combination s that d o not chan ge such a s benzene rings ) , but the only way to measure this would be by means of proper isotope markers . In Fi g . 2 6 the tracer response is given separately for 1 3 C O and 13c H 4 . From the ori ginal data one could have measured a tracer response for 1 3c , which would give a residenc e - time distribution for carbon atoms . I t i s a proper residence - time di stribution , containin g valuable information , but its interpretation is more difficult . It is not only a function of the flow pattern but also a function of conversion ( or catalyst reactivity ). To measure maldistribution in flow , a nonreactive tracer is often p referable . T he average residence time of a sin gle tracer is not necessarily equal to total reactor volume divided by the flow rate . I t is therefore hard to estimate independently the average residence time , which due to adsorption or similar phenomena , can vary by a factor of 5 or more betw een different tracers . Furthermore , not all tracers give linear responses . This makes the choice of a proper tracer much more critical than in a homo­ geneous system . Residence - time distributions are by definition linear func­ tion s . At steady state all compounds in a reactor have a measurable resi ­ dence-time distribution re gardless of the nonlinearity of t he flow , nonlinear adsorp tion phenomena , and so on . If one can properly mark a compound ( e . g . , usin g an i sotope ) , the tracer experiment will result in a residence ­ time distribution . B ut if one introduces a tracer that is not present in the system , it could behave in a nonlinear way , and the result could be very dependent on the amount of tracer introduced . Furthermore , one does not always want a tracer that behaves similar to the reactant . For example , in some cases w here one is studying reactor internals in a packed bed , non­ adsorbing tracers are preferable , as they are more sensitive to a maldistribu­ tion in the flow . This can be seen from Fi g . 2 6 . A heli um tracer would have given a much better indication of a maldistribution in gas flow than using 1 3 c o and measuring the total amount of 1 3 c leavin g . The proper choice of t racers is discussed in more detail in the next section . Residence- time distributions cannot be used directly to predict outlet composition even for linear reaction systems . Reaction rates in catalytic reactors are measured and reported on the basis of either reactor volume ,

1 23

Residence- a n d C o n tact- Time Distrib u tions catalyst volume , or catalyst w ei gh t . same time scale as t he re si de n c e ti me tem t hi s re la ti o n s hip i s not v ali d ( due solubilitie s , etc . ) , and the di ffe re n c e

In a h o mo ge n e o u s system this has the

distribution . In a hetero geneous sys­ to adsorption , ab s orp tion , different in time sc ale can be a fac tor of 5 or more . T he r at i o is di ffe r e n t for different reactants . Consi der , for exam­ ple , a p a cke d b e d reactor . T he estimat e s of ki ne tics are based in most cases on overall re si d e n c e time s of m ole reactant}lb catalyst p e r hour . T he real residence - time di st ri b u ti o n of the gas i s in most cases unknown b e c aus e t h e ho l d up of t he gas depends on adsorption . If one could really tag a re ­ actant one would not nec e s s a ril y get p l u g flow in a tubular laboratory re ­ actor ( see Fi g . 2 6 ) . However , t h e ki n e ti c d a t a u n d e r l yi n g t h e s cal e u p assumed plug flow in t h e lab reactor . T he rate ex p re ss ion s are really not molecular kinetic e x p r e s s i o n s d e s c ri bi n g real molecular events but r ep r es ent overall re l a ti o n s allow i n g one to scale up a lab reactor to an industrial packed b e d . T his ap proa c h works very well even if the reactant is stron gly adsorb ­ ing and t he reactions are h i gh ly nonlinear . The fact that for a hi gh l y ad so rbi n g reactant t he real residence time of a molecule is , in reality , far from plug flow , a n d different for all react ant s , does not affect the u seful ­ ness of s u c h overall kinetic relations for steady - st ate desi gn . I t m ay how ­ ever , s t ro n gl y affect t h e d y n a m i c behavior of the reactor and one has to be ca r e fu l w hen u sin g r at e e x p re ssio n s o b t ai n e d fro m s t ea d y s tat e e x p eri men ts to de scribe the dy n am ic b ehavior o f a reactor ( S hinnar , 1 97 8 ; B i loe n et al . , 1 98 3) . T his al so p revents one from u si n g such methods as t he boundary methods of Z w i e t e ri n g unless once a gain o n e i s d eali n g with s m all p e rt u r ba ­ tions . In c a t al y ti c reactors , reactivity can c ha n ge wi t h p o si tio n even i n i so ­ t her m al rea c to r s I n so me c at al y t ic re ac ti on s e s p e ci ally at hi gh t em p e r a­ tures , reaction s occur in the g a s p h as e as well as at the ca t al yti c s urface . T here is t h e re fo re no unique co r re latio n between residence time and t he state of t he molec ul e , w hich i s a p roblem already en co u n t ere d in t he case of the nonisot herm al reactor . While a residence- tim e di strib ution c an gi ve i m port an t information about t he flow , one w o u l d need ad ditional information to p r e di c t t h e o u t l et co m pos i t i on , even if the reactor is i so t h er m al and first ord er T he co n ce p t of a re si d e n c e t i me distribution is s till hel p fu l in the sense outlined in t h e b e gi n ni n g , as lon g as on e is careful to reco gni ze the di ffe r­ ences . This wi l l be di s cu sse d in detail at t h e end of t he s ection . Firs t , some techniques t hat a re e s p e ci ally applicable to h et e ro ge n eo u s reactors will be discusse d , n a m e ly m u lti ple tracer e x p eri m e n t s and contact- time distributions . -

-

,

-

,

.

,

.

-

,

M u l t i p l e T racer E x pe r i ments A s in hetero geneous s y s t em s , different compounds may have di ffe r en t re­

sidenc e times . I n de p e n d ent knowled ge of the re si d e n ce - ti m e di stribution of sev er al tracer compounds gives a b e tt e r description of the system . I f the feed cont ains different compounds , one may wish to use m ar k e rs for e ac h of t he m to study t h e system . One can also learn a consi derable amount about the s y st e m by u si n g a n u m b e r of different t r ac ers even if t h e y are completely di ffe re n t from the re ac t a nt flui d ( Shinnar et al . , 1 97 2 ; N auman , H o w e v e r , one is really measurin g the 1 9 8 1 ; Ort h and S c hli g er l 1972) . residence- time di s t ri b u tio n of the s p e ci fic tracer , which is not neces sarily ,

,

Shinnar

1 24

representative of the system .

If several t racers of stron gly varyin g

p rop er ties are utili zed , the residence- time distributions

of t he comp ounds in the system can be bracket e d . One should note , how e ver , t hat even i f one uses a n i sotope of a reactant , o n e still cannot call thi s a resi d ence - tim e distrib ution of t he system , as in a hete ro geneou s system different reactants may have totally di fferent residence - time distributions . One does not alw ay s want a trac er that behaves like the reactant flui d . Consider , for e xamp le , a p acke d - bed reactor . To measure maldistributions of the gas flow , one w ant s a tracer that does not di ffu se into the cataly st and d o e s not get adsorbed . I n this case the t ransport pr o cesses i n si de the cat al ys t parti cl e s an d a d so rp t ion p rocesses are irrelevant fo r scaleup or reactor performance in the s e n se that one deals with s c ale u p of a p i lot plant The main p ro b lem o n e n eeds to co n s i der with i dentical cat alyst p a rticl e s . is t hat mass t ran s p o r t processes to and from the particle to no t chan ge as the linear velocity in the large reactor increases . T racer experiments are not sensitive enough to check this p rop e r t y , but t here are other m etho ds to e n s u re t hi s . The main use o f a tracer experi men t is to test that t here are no maldistributions in the overall flow . An exam pl e of t hi s was shown i n Fi g . 1 6 . I n a packed bed , i f the re are maldistributions , one can use the result of a t racer exp eriment with a no n ad sorbing tracer to e s ti m at e their impact on c o n v e rsion and p ro d uct distribution . In t rickle beds one must worry about both liqui d and gas distribution , and would there for e w ant two t racers , one for each p hase . In all these c a ses , A ( t ) is the most sensitive way to c heck for a mal dist ri b u tion , but in a trickle b�d one m u s t Stron g d evi a ti o n s from pl u g flow can occur due to fluid dy n ami c be careful . effects an d o n e t here fo re needs a goo d reference case ( Mi l ls and Dudukovic , 1981) . In fl ui d - bed reactors the situation is more complex . If th e solid p hase is not s t atio na ry b ut is fed an d removed from the bed ( as in the treatment of solids in an F C C cracke r ) , one may w ant to use a solid tracer to check if the solid has the desired residence- time di st ri b utio n . In a sin gle stage one pro b ab l y want s complete mixin g of the soli d s or a constant A ( t ) , w h e rea s in a m ul tis t a ge bed and for t reatment of solids , one w ant s the residenc e - time di st rib ution for the s oli d to corr es pon d to a s e ries of stirred tanks , or to ap p ro ach plug flow . I n some t ric kl e beds , part of th e feed ev ap or ates . In t his case , to study the flow p r o p erl y , it is recommended that b ot h an evaporatin g and nonevapo rating fracti o n of t he liq uid be tagged . An e x am p le of such a multiple t racer experiment is shown in Fi g . 27 , which illustrates r e s ul t s ob ­ tained in a hydro t re at e r for fuel oi l ( Snow , 1 9 8 3 ) . T h r e e tracers a re used . T h e C 1 6 compound rep resents The C g co mp o un d enters in the gas phase . a comp ound that under t he conditions of t his h y dr ot reat er i s p resent in both T racer phases , whereas the C 3 2 c o m po u n d stays m ai n l y in the li qu i d phase . Re­ results are gi ve n for two react o r s op erat i n g under similar conditions . actor A co ntai n s a 1 / 8 - in . e x t r u d at e hyd ro t r e atin g cataly s t , w hereas react o r B op e rat e s with a 1 / 1 6- in . e x t r uda t e . Reactor B s how ed a better perform ­ ance at hi gh conversion , allo wi n g a 5 0 % hi ghe r through p u t at 99 % c o nver sio n . T he results gi v e a good i ll us t r a tion of t he advanta ge of u sin g proper multiple tracers . T he most i nte re s ti n g information in Fi g . 2 7 is not the for m of the individual t racer respon se but the relative p o si tio n of the i n divi d u al tracer responses . In a t rickle bed , o n e would expect that t he residence tim e of t he l qi ui d is larger t han t hat o f t he gas . The results bear t hi s out , as the average residence time of th e C 32 response is larger in b o t h reactors then in th e C 8 tracer . In r e act or B the C 32 tracer appears 3 min a fte r the C g t race r . However , looking at Fig . 2 7a one notices imme d iat ely

125

Residence- a n d C o n tact - T ime Dis t rib u tions . 1 6 .------

-- - -- · -

Unit A

f(!)

.1 2

I I I •

"'

lj /�

.0 8

I '

�

.04

I•

0 0

4

8

12

20

16

. 3 2 .-------,

f(t)

Uni t B

.24 .1 6

.08

0 0

(a)

4

8

12

16

20

F I G URE 27 Multiple tracer experime n t s i n t w o industrial fuel oil hydro­ treaters . ( Private communication with A . I . S now , Arco Petroleum C o . , 1 9 8 3 . ) T hree compounds tagged w i t h 1 3 c introduced simultaneously in feed

(pulse exp eriment ) and measured at reactor outlet . ( a ) R esidenc e - time density function ; ( b ) inten sity function ( escape probability ) of unit A ; ( c )

intensity function ( escape probability ) o f unit B ; ( d ) cumulative residence­ time distribution ( unit A ) ; ( e ) cumulative residen ce - time distribution ( unit

B).

1 26

Shinnar

0. 3 0

U nit A

ACtl

0 .1 5

0.00 6

0

12

18

(b) ACt>

Unit B

0.60

0. 3 0

./· - -- ------�.!2_

tl

�--­

_ __

.l.._ _J._____JI... .l.._ ...- --1---...J o.o o L-�i_____.J.___!__ _L_...._....

(c )

0

FIG URE 27

6

( Continued )

12

18

Res idence- and C o n t ac t - T ime Dis t ri b u tions

10°

1- F

127

r---��----� Unit A

(d )

10 3 �--L_ 0

6

(e) FI G U R E 2 7

12

18

L___L___L___L___ L---L---L---L-�

__

( Continued )

128

S h i n nar

that the c 32 t rac e r in reactor A ap p ea r s about 1 mi n before the C s t rac e r . This s how s a si gni fican t difference between the two reactors an d s how s th at so m e t hi n g is w ro n g with reactor A w hich explains its lower p e r fo rm a n c e . If one ex ami n es in detail at t he e sc ap e p r ob a bility ( Fi g . 27c and d) , one also notes that the C 3 2 re s po ns e shows a s tron g maldistribution in reactor A and good liquid di stribution in re ac to r B . I nterestin gly , react or B has a m al di s t rib utio n in the gas flow ( C s ) which is n o t evi dent in reactor A . B u t it is ap p ar en t ly not si gni fi c an t eno u g h to cause p rob l e m s . T hese tracer results contain some very i n t eres t in g information about what h ap pe ns i nside the se re ac t o r s , an d h avi n g sim ultaneous information from both a liquid and gas t racer gre atly adds to t heir value . However , the i n t e rp re t ati on of these resul t s is in no w ay uni q ue , as the mal di stribu­ tion of t he C 3 2 re s p o n s e in reactor A co ul d be due to s e v e r al causes . It co ul d be c a u s e d b y a mechanical p robl e m re s u l ti n g in a nonuniform liquid di s t ri b u tio n , or b y inherent flow problems , or by the di ffere n t catalyst si ze . Some reactor m od eli n g could indicate w hi c h of these e x p l an at ion s i s mo re likely . It is i m p o rt an t to note that in such a m ul ti phase system , there is n o w ay to deduce from a single t racer experiment if a. maldistrib ution s uch as the C 3 2 response in reactor A ( Fi g . 2 7 ) is caused by n bad di s t ri b u tor or by b y pa s s p henomena inherent in the flow regime of t hi s s p e ci fi c r ea c t o r or by ph e no m en a inside the catalyst particle . T rickle beds , by their n at u re , do not sc al e equally well in different flow r e gim e s , which are d ete rmi n e d by various flow p ar a me t e r s , such as gas v e lo ci t y and density , liquid p roper­ t i e s , a nd liqui d - to - ga s ratio . This problem w a s alr e a d y e n co un t e re d in the disc u s sion of the fluid bed , and it is i m p o r t an t to reali ze this . However , often on e has two reactors o p e rat i n g under similar con di tions and , in s uc h a case , a difference in tracer re s po n s e cle ar l y indicates a mechanical problem . I n s t u dyin g t he gas flow in a fluid bed , one faces a p roblem not en ­ co untered in pa c k e d beds . If the r e a c t an t is a d s o r be d , it will move wit h t he s oli d . I n an i so t he r m al or adiabatic packed bed , i f a pilo t plant and a large p l an t have the same residence- time di st ri b ut ion for a non ad so r bi n g t racer , one would expect them to behave si mi la rl y . I n a fl uid bed one can ­ no t make t h e same as s u m p tio n , a s the mixi n g p rocesses o f t h e solid and the a d so r b e d reactant with it are di ffe re n t for t he t w o c as e s . T h e only ti m e that one can r eli a b l y scale a fluid b e d an d p r edi c t i ts p er for m an c e from a pi lot p l ant i s w here in bo t h cases the g a s flow approaches p l u g flow as closely as pos sible . One way to a c hi ev e this is by u si n g baf­ fle s in t he fluid bed . B affles here have a double purpose . T hey prevent by p as s in g of gas d ue to lar ge b ubbles by breakin g up the b ub bl e s , and re­ duce solid circulation , t hereby also r e d u c i n g the b ac k mixi n g of gas by moment of reactants adsorbed on the c a t aly st . In cases where one w ants to test w h et h e r t he flo w distributor op erates w ell , a no n a d s o rbi n g t racer is a more sensitive tool ( see Fi g . 19) . When there are b a ffl e s in a fluid bed , the problem becomes more complex . A good case can b e ma d e t ha t an ad s o r bi n g t racer is more s ensi ti ve , as it shows if a d s o r b e d tracer is recycled by the catalyst to the bottom of the T herefore , i f a baffled fluid bed ap p r oa ch e s plug fl o w wit h a r ea c to r . strongly a d so r bi n g rracer , it giv e s one better confidence in the d e si gn . However , one has to b e careful to c h ec k t hat the t r a ce r be ha v e s li n e a rly . To check t hi s , one alw ay s needs co m p a r ativ e result s from a p ack e d- b e d

1 29

Residence- and C o n tac t - Time Dis t ri b u tions

SF 6 has been reported to hav e desirable properties , and its ad­ reactor . sorption can be chan ged in a cold- flow model over a wide ran ge , as the adsorption equilibrium i s a function of the w ater content of t he air . If a properly baffled desi gn gives a residence- time distribution with a hi gh Peclet number ( low coefficient of variation ) for both a nonadsorbing and an adsorbin g tracer , thi s improves the confi dence in the scalability of the desi gn .

Un derstandi n g the effec t of adsorption on the residence - time distribu­ tion i s he lp f ul i n an ot he r w ay . I t explains why di ffe r en t reactions may have different sensitivity to scaleup in the same fl ui d bed . To understand this concept , one must first consider the evaluation of tracer experiments wit h adsorptive t racers in a more ri gorous way . T he approach u sed i s de­ sc ri b e d in detail in Shinnar et al . ( 197 2 ) . Consider a pack ed b e d or a chromato graphic column in w hic h a t racer can be adsorbed inside a porous p a rtic le . One can now perform a t racer experiment with a nonadsorbing tracer w hich can also diffuse into t he porous particles an d has t he same co ­ effi ci en t of diffusion inside the particles . For simplicity a p ulse tracer ex ­ periment will be used . T he density function of the nonadsorbing tracer i s desi gnated fo and that of the adsorbin g tracer f . Also a s s u me that the a adsorption equilibrium is linear and the amo unt of t racer adsorbed at equilibrium per unit volume of C o gas phase is dc 0 , w here Co is the con ­ centration in the gas phase . Consider the case where ideal plug- flow con­ ditiond exist . T hen fo( t ) for t h e nonadsorbin g tracer is a delta function at t T. One can then measure fa ( t ) for different value s of T an d define a f unc t i on IJ.In ( t ) =

•

ljJ ( t ) a

=

f ( t - -c ) a

( 4 5a )

w hic h gi v e s the so jo u rn - ti m e distribution of the adsorbi n g t racer in the adsorbed state . The simplest case is if the tracer adsorb s in a way that the ra t e of adsorption and de sorp tion is very fas t . In this case ljJ ( t ) a

=

o

(en)

( 4 5b )

and for th e general case w here a is a cons tant , that gives the ratio of t h e residence time in the adsorbed p h a s e to that in t he contin uous p hase . ( 4 5c )

fini t e rat es , E q ( 4 5c ) will not hold . t he b e d has uniform prop erties and the flow in the gas phase is plug flow , lji ( t ) must b e a unique function of T in the continuou s ph a se . a One can f u r th er show that for vario us values of -c If ad sorp tion and desorp tion have

However , if

ljJ ( t / -c 1 a

+

• 2>

t

=

f

0

ljJ

ap

c e / , 1 ) \ji

ap

( ( 1 - e] / ;: ) d e 2

( 4 6a )

w here 1/Ja. p ( t / 1" 1 ) i s the function tfu p ( t ) given that T for the continuous phase is '1 · T he sub script p was added to in dicate that the flow in the continuou s phase is plu g flow . I f E q . ( 46) holds , one can al so show that the Laplace t ran sfer of IJ.Ia ( t ) must have the form ( S hin n ar et al . , 1 9 7 2 )

1 30

Shinnar

�ap and

(�)

e

=

- T P (s)

( 4 6b )

therefore ( 46c )

p ( s ) there fo re c haracterizes the adsorption process or in a more general w ay the transport processes in an outer p hase not reachable for the tracer use for f0 • In E q . ( 4 5c ) it was as s um ed that p ( s ) = as . If one as sumes a finite ra t e of adsorption an d desorption , then in the example given p ( s ) becomes P ( s)

a.s

A

=

7 1-+-=:-(a-:-: /}_,...,.)s

( 47a)

w here A i s a normali zed exchange coefficient . For understanding the gen ­ eral concepts , one does not need more complex form s of p ( s ) . The re a de r should consult Shinnar et al . ( 19 7 2 ) for more details . If p ( s ) is given by E q . ( 47a) , then 1jJ A

ap

- e - CXTS / [ l+ ( CX/-A ) S )

( s)

( 47b )

_

is a well- known function used in chromato graphy . To d erive it , one must not only assume that fo( t ) is a plu g flow , but al so assume t ha t the catalyst bed has uniform properties and t hat t he c a t aly s t is s t ation ary T hi s mea n s that any molecule that got a d sorbe d returned to the same place it left . In the limitin g case w here A -+ oo [ E q . ( 4 5c ) ] , t he last assumption is not needed. H ow e v e r the assump tion of uniformity i s s till n ece ss ary If the bed is uniform in its properties and each particle returns to the same place in the gas phase , Eq . ( 46) can be generalized to the case where fo ( t ) is not plug flow . For any such c a se with arbitrary fo ( t) , which

.

,

$a C t )

t

ap

t

f (t)

a

and

$a ( s )

f 0 ( T ) 1J!

f0

=

f0

=

=

where p ( s )

f ( -r ) lji 0 ap

-t -r

(

d -r

t --' ,

( 48a)

)

( 48b )

d -r

r0 ( p ( s ) )

has

.

( 4 9a )

been substituted for the variable s in

f( s ) .

Si milarly ,

( 49b ) Note that in

the

previous simplified

case ,

1 31

Residenc e - a n d C o n tac t - T ime Dis t rib u tions

( 4 9c )

T he re s ults o f

Eq.

( 49c ) are experimentally testable , as one can me as u re

a s / ( 1 + as / A.) in a p acked- bed reactor under conditions approaching p l u g

Howe v er , t here are stron g re stri c tions on its applicability . E qu ation ( 49) also allow s computation of �a ( s ) an d therefore of 1/J ( t ) from measure­ a ments of fa ( t ) and f 0 ( t ) in o t h er cases w here the adsorbed particle returns to t he same place . T he only other case w here this direct c o mp utatio n is po ssi b le is w hen t here is n o correlation between the total residence time of a particle in the adsorb e d p hase and i t s residence time in t he ga s p h a s e . In this case flow .

( 50 ) w here * i s agai n t he convolution i n t e gral . Unfortunately , thi s i s a rather unre ali s tic case for a catalytic reactor . In real cases w hen can Eq . ( 49) b e use d ? One case is a packed bed with back diffusion . The other i s a stirred tank reactor in which bot h the continuous and gas p hase are mixed ( such as in a B erty reactor ) . I n that case all molecules in t he continuous phase have equivalent location an d the r e fore E q . ( 4 9 ) ho l ds . There are additional i m portan t i mplic a tion s that can be deduced from E qs . ( 48) and ( 4 9) . Consider the special case of a pa c k ed - b ed reactor in w hich the flow

o . Further assume that flow or r0 ( s ) = e all reactants and products have the same rate of ad sorption and d es o rp ti on and also the same adsorption equilibrium . T herefore , lJla ( t } is con stant for all compounds . Finally , assume t hat a firs t - order complex reaction oc cu r s In t hat case on e can w ri t e an equivalent of Eq . in the adsor�ed phase . ( 28) fo r the product distribution :

in the internal p h a s e

< c .> J

=

a.0 + J

n- 1

'E

r=1

-• s

is p l u g

1/J ( t.. ) ,..

a.

Jr

a

( 51 )

r

which for a packed - bed reactor can be w ritten

=

10

a.

n- 1 +

'E

( 5 1a )

r=l

In standard kinetic p r ac tic e one neglects adsorption processes an d simply assumes that t h e rea c to r is plug flow and o n e writes an equivalent of Eq . ( 2 6 ) :

P . < t > = c < t>

J

where /.. �

1

.

=

a. 0 + J

n- 1

E

* - T t.. r p

( 52)

r= l

are ei genvalues based on p henomenolo gical r at e constants . T is p time constant that has t h e di m en sions of time but does not refer to any real measurable time . It is exp ressed in lb fee d /lb catalyst per ho u r (or lb mo l feed /lb cataly st per hour ) . N ote t ha t

a

Sh.innar

1 32 1:

0

p( A ) r

=

1:

A*

( 5 3)

p r

Equation ( 5 3 ) implies t hat it is alw ays possible to describe a first -order re ­ action occurring in t he adsorbed phase of a cat alyst by assumin g t h at t he reactor is a plu g- flow reactor . T he reaction rates will not relate to any real reaction rates at the catalyst surface , but this is not import ant in phenomenolo gical rate equations in reactor desi gn . Norm ally , tha kineticist is interested in eliminati n g from transport resistances that deal with transport to and from t he catalyst particles and di ffusion in the m acropores , as w ell as b ack di ffusion in the reactor . T hi s can be achieved by as suming that the cat alyst p articles are sm all enou gh and t hat the microreactor used is lon g enou gh [ Silverstein and S hinnar , 1 97 5 ) . I n thi s special case , one c an t hen estim ate t he conversion of an iso ­ therm al packed - bed reactor i n w hich fo ( t ) deviate s from plug flow ( either due to di ffusional resistances or due to m aldi strib utions) , by meas uring f0 ( t ) with an inert tracer and then comp uti n g the effect of the deviation from p lu g flow j ust as one di d in a homo geneous reactor . T hi s is the re ­ sult of derivin g E q . ( 5 3 ) from Eq . ( 5 1 ) . One must , how ever , note that fo( t ) has a different time scale t han E q . ( 5 3 ) . One m ust therefore non ­ dimensionali ze f0 ( t ) and scale it such that the new first moment is the same as that u sed in comp uti n g T hi s is p articularly important , as kineticists often use di fferent definitions for ' P in comp uti n g Equation ( 4 9) to ( 53) also imply that for a first -order reaction , one can predict t he behavior of a p acked bed by getti n g kinetic measllrements in a completely mixed reactor such as a B erty reactor , and vice vers a . One cannot , how ever , predict t he outcome of any reactor for which E q . ( 4 9) does not hold , such as a fluid bed in which t he catalyst move s . If t he movement of the catalyst is slow comp ared to t he adsorption - desorption processes of all reactants , one can get approximate predictions . For exam ­ ple , if the fluid bed is st a ged by vertical baffles , it approaches a series of stirred t anks or , for practical purposes , the react ants return to the same place . T he outcome c an then be predicted using a packe d - bed reactor ( or another fluid bed close to plug flow ) as a model . T he relationship between E q s . ( 5 1 ) and ( 5 2 ) w as derive d for the case w here 1Jia ( t ) is equal for all react ants . T his is not a very likely case but w as used for didactic reasons . How ever , the principle that one can pre ­ dict t he outcome o f a first -order reaction in a reactor for w hich E q . ( 4 9) holds by me asurin g fo ( t ) and the overall kinetics in a packed - bed reactor is valid for arbitrary soj ourn -time distributions in t he adsorbed p hase , even when t hey are different for each compound . T he concept therefore has To prove t he validity of t he more general much bro ader applicability . principle , one can use an argument similar to t he one used earlier when w e discussed op tim al reactor concepts for nonisothermal reactors . For any first - order reaction one can derive a phenomenolo gical equation such as Eq . ( 5 2 ) . Kinetici sts define a first -order reaction by thi s condition as they do not measure real reaction rates in the adsorbed phas e . Consider such a case in w hich 1/Ja. ( t ) is different for all compoun ds . T he average sojourn - time di stribution of the molecule s will now depend on their st ate and therefore on the reactivity of the cat alyst . T hi s is included in :>.. * . Once again , t he hypothetical observer stands at t he outlet o f a plu g- flow reactor and collects the molecule s . T he molecules are now sorted into bins . T he molecules in each bin have a unique so journ time e in the continuous

:>.. ;

:>.. ; .

:>..; .

Residence- a n d C o n t ac t - Time Dis trib u t io ns

phase . I n each bi n , gi ven B one can comp ute P j ( B) , t he probability o f bein g in s t ate j given B. As the number of molecule s is large , p · ( B) i s eq ual t o Cj ( B) . Averagin g over all t h e histories yields < p or or the outlet c o n c en t r at ion . Note that if t he conditions leadin g to Eq . ( 49) hold [ nam ely , t he catalyst has uniform p rop e rti es and a molecule alw ays

?

1 33

�Ci>

re ­ turns to the s ame place in the space of fo ( t ) ] , t hen is a unique func ­ tion of the r esidenc e time t of the molecule in the no nad sorbed phase . I f one looks at molecules with different sojourn times i n t he no nadsor b e d phase , their pro b ability of being in state j should be the s ame as that of a molecule passi n g a plu g - flow reactor with resi dence time t in the nonadsorbed phase . The previous ar guments should t herefore hold re gardless of the fact that all compounds h ave different adsorption desorption behavior as long as the system is li ne ar and fulfills t he basic assumptions . T he p revious discussion leads to the di s co n c e rti n g conclusion that in order to predict the behavior o f a first - order reaction , one doe s not w ant a true residence -time distribution . A more accurate measure will be given T hus the choice of tracer by a no n ado s rb i n g tracer that measures fo( t ) . can be cruci al in p r e dic tin g the outcome even of a first - order r e act i on . There are c ases w here t he "true" residence - time distribution will not cor ­ rectly predict t he outcome of even a first -order re ac tio n . T hi s has i m ­ portant i m p lic ation s for t he scaleup o f first -order reactions . It was shown that t here i s a fun d a ment al similarity between a mixed reactor and a plug­ flow reactor and t h at one can alw ays scale up from one to t he other re gard ­ less o f how the reactants behuve i n the adsorbed p has e . However , one cannot apply the kinetic data obt ained from eit her one to predict the outcome in a fluid - bed reactor . Thi s has important implications for t he scaleup o f first -order reactions , as it indicate s a fun d ament al similarity between a mixed reactor and a plu g - flow reactor in terms of arbi t r ary behavior in the adsorbed phase . An important exception is the limitin g case of a fluid bed which is rea son ab ly uniform and approximates plug flow . T his will occur when either ,\ is very la r ge or the mixi n g of the soli d is slow compared to t he tim e icale of l· ( t mixing > 1 /l_) . Ot he rwis e , 1/la ( t ) would depend on bot h l and solid mixin g . Unbaffled fluid beds in the b ubb li n g ran ge are not very uni form and are o ften modeled by a two - p hase model . Here , E q . ( 49) does not apply even if A i s lar ge . One can , however , use an ad so r bi n g tracer with a large value o f A to test how close the bed appro aches the desired condition , namely , that the bed has no bypass o f gas that does not contact the solid and ap proaches plug flow . Adsorbing tracers are an effective

tool to test w hether t he system approaches plug flow or not . In a packed- bed reactor one can measure .\ . In fact , if one uses tracers with low er values of A and still gets a-good approximation to plug flow , one can then get an es ti m ate of the solid backmixin g . To esti m ate its imp act on the reaction , one would have to bound A fo r all the re ac t ant s and products , which can in p rinciple be done by usin g tracer methods similar to those used in Fi g . 26. There is one essential point to remember in testi n g for maldistribution of flow or for the e ffectivenes s of internals in fluid beds and trickle beds . This is the need for a goo d comp arison case of a w ell - per for min g reactor . If the residence -time distribution obtained by a tracer experiment deviates stron gly from p lu g flow , it does not necessarily indicate a maldi stribution of flow due to b ad desi gn . It could be a fluid dynamic instability p henom e ­ non which is common in fluid b e d s and which can also occur i n lar ge

1 34

Shinnar

trickle - bed re actor s .

In

trickle - bed

rea ct or s it can be due to di ffusion and

adsorption p henomena in t he liquid p hase . cannot di sti n gui s h

between

I nput output tracer experiment s

t he two cases .

W hat t hey can do is p rovide com ­

p ari sons bet w een two reactors and give clue s t o t he

tive

w hich is

m e asure s s uch as baffles ,

effectiveness

o f correc ­

a very valuab le tool p roperly used .

Mea s u rement of H o l d u p i n M u l t i phase S y s t e m s I n m ultiphase

If

systems

the sep arate holdup o f each p h a s e m ay be unknow n .

t he system i s si m p ly soli d gas or liq uid gas , t he holdup o f t he solid or

li q ui d m i ght be obt ained by a pressure difference . T he holdup of the gas is more di ffi cult to measure , as it m ay dissolve in t he liquid or adsorb on a solid . H e re tracer experiment s can be very help ful . One has to be careful wit h the choice of t he tr acer . For a solid tracer it is im po rt an t to find p articles that do not sep arate and have the same si ze distribution and den ­ sity as t he solid s t u died . For best results t he solid s hould be impre gn ate d with t he tracer when possible . I f t he liquid doe s not adsorb or evaporate almost an y tracer will do , b ut i f it does , it i s best to tag the liquid or p art of it . C hoice of a proper tracer from t he gas phase presen t s similar prob ­ lem s . I f t he gas adsor b s or is soluble in t he liquid , one needs a tracer wit h similar p ropert ies or preferably an isotop e of the real compound . T hi s When a suit able tracer is sometimes the only direct w ay to measure holdup . is available , two further requirements m ust be met .

1.

Accurate measurement of

total feed

rate

for the

flow

of the p hase

me asure d

Accurate measurement of the amount of tracer introduced

2.

In a

p u l se experiment

!0

Q C ( t ) is equal to

gral

oo

better than

one can use !0

t he holdup obt aine d

if the

the

always

amount of

care fully

tracer

check t hat the inte ­

introduced

wit h

an

acc ur acy

95%. In this case , one s hould never use Eq . ( 1 3) . T he first will then give an estim ate of t he holdup . In a step experi -

moment o f f( t ) ment

one should

tracer is

oo

is

( 1 - F)

dt

to

e stimate the holdup .

T he e s timate o f

includes adsorp tion p henomena . T herefore , of the real flow , compoun d , one has to be

one that

not an isotope

very c are ful in i t s interpretation . T he example given in Fi g .

It

i s based

on

dat a

supplied

1 0 c an

1 98 1 ) from a study of the E xxon Donor men t s here

were

problems . by E xxon ( Mills an d D udukovic , Solvent Reactor . T he tracer experi ­

serve to illustrate the se

t o the author

performed t o me asure holdup o f t he t hree p hase s .

T he

system . T he reactin g gas is a mixture o f hydro gen and hydroc arbons , and t he li qui d is a mixture of dis solved coal liquids and recycled solvent . T he solid p hase i s ash and coal particle s . The tracer used to measure gas holdup was an isotope o f ar gon w hic h dis ­ solves in the coal liquid , and it is t hi s experiment t hat is shown in Fi g . 10 . The solu bility of the tracer at the reactor temperature an d pre s s ure can be me asured and , at equilibrium , the mole fraction of ar gon in the gas is five time s t he m ole fraction of ar go n in t he liqui d . In Fig . 10 t he Laplace transform of t he residence- time distribution com ­ puted from the tracer response was plotte d . T he first moment can be ob ­ t ained from it by estimatin g the tan gent of f( s ) as s + 0 . T his i s sy stem illustrated is a three - p hase

1 35

Residence- and C o n tact - Time Dis t ribu tions A

e as the flow is close to plug flow and therefore ln[ f( s) ] s line ( see Fig . l O b ) , the slope of whic h is to the first moment . The variance has to be es tim at ed from the second derivative near zero . This is not easy , but if the coefficient of variation is sm all , one can do it by model fit t i n g usin g relatively easy h re versus ( s ) i almost a straight equal ,

=

where

1 (1

+

T S /n )

( 1 9c )

n

This pp a several problems the fact cer sol What y the of the tracer , estimate l m r r e ce t lar there no that esti­ and the gas holdup . Fortunately , in this the es i t ev r reasons . Either gas-liquid mass r s or t the s small , to the has only very small im in the range of accurate measurements because it s The coefficient then in this is ap ec t then error the st the example ve , the mass e c e t could and this alternative could ruled It therefore a o e that mass transfer fast , hic that the the liquid phase the phase . the liquid h l u the of a o is No that if have to be difficult to e i at volume of the phase the reactor .

n in here is a c urve - fittin g p arameter . a ro ch was discussed earlier . are caused by that the gas tra is uble in the liquid . one reall wants to know is not holdup but an of t he gas vo u e in the eacto If t he co ­ ffi i n of variation y is ge is w ay one can reliably particular case , y is small mate t m a e could be obtained . The sm all y could be due to s e al the t an fe r coe fficient is small i is If m as transfer coefficient is adsorp i n in very lar ge . liquid phase a p ac t on C 2 ( t ) , m ain ly affects C 2 ( t ) for t + co ( or + 0) . of variation is reality lar ge , but not p r ia e d when comp uted from the measured form o f f( s ) . One can get a lar ge 2 in e imate of ll and y . In gi n trans­ fer co ffi i n be measured indep endently be out . is re s n abl to assume the is w h allows one to assume gas adsorbed in is in equilibrium with gas I f one knows o d p and the solubility of gas , a condition for the e ffects b s rp t ion can no reliable way to be made . te y 2 was not very sm all , there make any such correction . and it would s t m e t he gas in

There

.

,

C O N T A C T -T I M E D I S T R I B U T I O N S

has in t n a sojourn-type in active phase ob­ by s tracer as d t s ds r tracer of i then , for u flow , can n y in the adsorbed phase

The term con tac t - t ime dis trib u tio n been used he literature in two O e is distribution t he which is tained u ing a sli ghtly adsorbin g well as a non a sorbin g inert tracer . I f one de si gn a e f( t ) of the a o bin g as fa ( t ) and the n na d sorb n g tracer as fo ( t ) , pure pl g one define de si t function of a sojourn - time distribution

ways .

o the as

w here < o is the first momen t of f0 ( t ) . This distribution was discussed in the prec e din g section , w here it w as shown t hat the function lj!a ( t ) can be measured not only for plug flow but also for a limited number of other cases . However , alt h ou gh this distribution is useful for reactor modelin g and for dia gn osing maldistributions , it is not directly useful for e sti matin g the behavior of a first -order reaction . The kinetic relations assume p lug flow in a packe d bed , whereas tracer experiments with a proper isotope tracer will not necessarily give plug flow

1 36

S ht n nar

( see Fig . 2 6 ) . A c lo se examin ation of Fi g . 2 6 not use the real residence- time distrib ution o f dict the behavior of a he te ro ge n eo u s reactor .

w il l demonstrate that one can­ the r e ac t a n t s t o re li ab ly pre ­ In Fi g . 2 6 t he overall flow is plu g flow . However , the re sidence time of the 1 3 c tr ac er is not plug flow an d has a lar ge coe fficient o f v ari ation For ot h er reactants the dif­ fe re n c e could even be l ar ge r If one applies t he kin e tic rel ation s w hic h are b as e d on t h e assumption of p l u g flo w to a model b ase d on the act ual re si d en ce - t im e distribution , o n e would obtain very erroneous results . More me ani n gful results can be obtained by u si n g the data from t he h e li u m tracer . T he helium tracer has a re side nc e - t i m e distribution similar to fo ( t ) .

.

true overall residence-time distribution of any of the actual reactor is a fluid bed , one can no lon ge r rely on the re sults from a helium t r ac er , nor can one rely on the t ru e residence ­ time distribution . However , if the true residence- time distribution for both the fluid bed and t h e packed be d are available an d t he y are very close to each other , one could deduce t hat the re ac tio n should scale up safely . In b u t dis similar to t he

If

re ac t an t s .

t he

other cases , one cannot directly apply the in formation . A m o re useful definition of contact - time distrib ution is b a s e d on t he re ­ lation bet w een the product di s t ri b u t ion of first-order reac tio n s and t h e E arlier it w a s shown that knowl­ residence-time dis t ri b u ti o n of the s y s t e m edge of the p ro du ct distrib ution defines the Laplace tr an s for m o f the residence-time distribution density function [ Eq . ( 2 8 ) ] . F or a fi r s t or der irreversible re ac tion A -+ B with a re act io n rate r ( A ) = - ka , the outlet con c ent r ation in a hom o gen eo u s s y s te m all

.

-

"

a

-

a

==

( 5 4)

f( k )

f "

f{ k ) is t he Laplace tran s form of f( t ) w ith the reaction rate k sub stituted for s . For a first -order re act ion o cc ur rin g in a he t e ro ge n eo us re ­ actor , one can use Eq . ( 28) to d e fin e the di s t rib u tion l!_ by w here

JP

==

a. 0 J

n-1 +

I;

r==1

a.

( 55 )

$c >.. r >

J r-

equivalent of Eq . ( 2 8 ) . This distrib ution , o ri gi n ally pro po s e d et al . , 1 96 2 ) an d Glasser ( Glasser et al . , 1 9 7 3 ) , is not a real distribution of sojourn times b ut has the s ame dimensions and p rop e r ties . Re gar d le ss of the rea� s oj o urn ti me distrib ution , A. r is defined and m e as ure d by a s s u m in g that .!J:( A.r ) is plug flow for a p acked - bed r e ac t or . For a complex first - order reaction o cc ur ri n g in a p ac k e d be d reactor , one can determine A. r for each r . I f the reaction then occurs in a different reactor s u ch as a fluid bed , one c an obtain me asurements of C j · The i n ­ for m at i on from Cj an d the Ar fro m t he packe d - bed reactor giv�s estimates for several values o f j:( A r ) . T o ob t ain the complete fun ctio n j:( >.. r > , one would h ave to use cu r ve - fittin g functions . H owever , in p rac tic e this is o fte n not ne e d e d , as sufficient information is available from the linear v al ue s of _i{ A. r ) In this case , A r c orre s p ond s to the L ap l ace transform variable o f 1/J ( t ) even t h o u gh 1/J ( t ) is an artificial constraint defined by Eq . ( 5 5 ) with no physical me ani n g: Another w ay of m e asurin g iOr ) is t o vary k in Eq . ( 5 4) . In a cat aly t ic reactor , this can be d on e by eit h e r changing the te m p e r at ur e of the r eac to r or the re ac tivi ty of the c at aly s t . One can then use an equivalent of Eq . ( 5 4) which is an

by Orcutt ( O rc utt

­

-

-

"

•

137

Residenc e - and C o n t ac t - T ime Dis t rib u t ions

( 5 6) to define �.

I t h a s the same me anin g as the definition in Eq . ( 5 5) with k re­ placing B ut it may n o t have the identical numerical form . Chan ging temperature or reactivity m ay change the complex t ran sport proce ss as well a s the ad sorption and de sorption rate s in side t h e cataly st p article s . Therefore , the values of < k ) obtained in this w ay will not be identical to t hose obtained usin g W < A r ) as de fined in Eq . ( 55) . However , the form will be similar . As ume that one measures ( k ) or �( "- r > in a p acked bed and then re­ peats the s e experiments in a fluidized be d keepin g the sp ace velocity constant , and measures the conversion for each ( k ) . T he highest conversion possible at eac h ( k ) is the same as in a plu g - flow reactor . I f , for any ( k ) , the con ­ version is higher [ or f(k) smaller] , it follows that either the reaction is not first order , or the reactor is not isotherm al , or t he initial small packed -bed reactor w as diffusion controlled . If the conversions for all values of ( k ) are equal to that of the packed bed , the fluid is essentially described by a p l u g flow . If not , the conversion at each point is a m e asure of the w ay the fluid bed deviates from the packed bed . If a /ao for the two cases is plotted vs . ( k ) , one can interpret the curves as plots of ( k ) for the two reactors . (k) for the p acked b e d is by definition plu g flow . Much c an be learned from the nature o f the plot . In Fi g 2 8 an experim ent al contact -time distribution for a relatively short bu bb ling fluid bed is ve n and compared with a plu g- flow re­

t..;.

i

s

_t

_t

.

_i

gi

actor and a stirred t ank . Note that $ ( k ) of the fluid bed is lar ger than $(k ) o f the packed - bed reactor ( plu g- flow case ) for all values o f ( k ) . A t lar e values of ( k ) , < k ) , for t he fluid bed , is very flat and , within exp P.rime n tal accuracy , almost p arallel . This indicates that part of the material es sentially bypasses the reactor . In fact , a s im p le bypass model

g

i

i< k )

=

a exp ( - k T) + b

( 5 7)

fits the experimental result s quit e well . Fi gu re 28 also gives tank . Note that it fit s t he experimental data les s well . (k)

_t

$( k ) for a stirred is larger than that

1.0 .B

.6

t( k )

.4

.2 5

10

15

20

k

25

E x peri m e nt al cont act - time distribution for a flui d - bed ( Orcu tt

FIGURE 2 8

et al . , 1 9 6 2 ) . Comp arison with variou s models ; - - - - - , stirred - t ank plu g- flow re actor allowin g reactor ; - - - - - plu g - flow reactor ; for bypass and stagn ancy ( experimental) . ( F rom Glasser et al . , 1 9 7 3 . ) �(k) is measured here by conver sion of ozone in fluid be d over an iron catalyst .

k

is varied by dilatin g the catalyst with inert s .

1 38

Shin nar

of a s tirre d tank for sm all and l a r g e values of ( k ) . For intermediate range i< k ) is smaller than for a stirred t ank , w hi ch is typic al o f s o m e byp as s p h eno m en a . The $(k ) for the fluid bed shown i n F i g . 2 7 has anoth e r int er es t in g proper ty th at is common to most fluid beds . The s lo p e of $(k ) n e ar k -+ 0 is small e r than for a plug- flow reactor . ( The only w ay to k now this is to measure the reaction in a packed bed with the same cat aly s t under isothermal conditions . ) This indicates that not only does the bed h ave a bypass in the bubble phase , but that part of the c at aly s t p h as e is not w ell contacted . In the author's ex­ p e ri en c e properly baffled (or turbulent) fluid b e d s do no t s ho w any by p as s in the gas p h as e but will s h a re the p ro b l e m that the dense catalyst phase is not perfused . Such baffled beds be h ave like ne ar - p lug - flow reactors with a s m all e r e ffect ive cat aly s t volume ( about 50 to 70% of real c at alyst holdup) . ( A possible e x p lan at io n i s give n in Krambeck et al . ( 1 967) . ] I f one c o ul d re a lly m e a s ure t he slope of ji ( k ) for very small ( k ) , it would app roach T as k + 0. T his i s the s a me p ro b le m t h at w as i llu s t r at ed in Fig . 13 w hen m e a s urin g the tail of F(t) . I f a region of t he reactor i s n o t well perfused , T will be underestimated . If an i n d e p e n d e nt estim ate of T is available , underestimatin g T usin g t h i s technique is evidence that the reactor is n ot well p e r fu se d . For the case shown in Fig . 1 3 , one could estimate T from the volume of the reac t or and the fe ed rate . In the c a se of � ( k ) , the on ly way to e s ti m a t e the first moment is by usi n g a packed­ bed reactor for comparison . Note t hat $( k ) here yie lds some v al u ab le in ­ formation directly ap p lic able to reactor de si gn . One can compare the infor m ation obtained from Fi g . 27 with that obtained by tracer exp erim en t s in similar fluid beds ( see Fi g . 1 7 ) . Fi gure 17 for a similar be d also clearly in dica t e s R by p ass phenomenon . T he e scap e probability A ( t ) m eas u re d from the tr ac er response of a nonadsorbing tracer show s a c le ar m aximum , indic at ­ in g a b y p a s s or stagnancy . The method shown in Fi g . 17 has one significant a d v an t a ge . It a l lo w s one to p lot A ( t ) w hic h gives dire c t p hysical in s i gh t into the nature of the transport p roc e s s . T here is as yet no e q ui v alen t way to extract e qui valen t information directly fro m in s pe cti on of $ ( k ) . I f f( t ) is measu r ed , compu t a­ tion of f( s) or f'( k ) i s s t r ai gh t fo r w ar d an d relatively e asy . T he op p o si t e is not true . i:< k ) i s hard to in ver t accurately , a n d therefore it Js h ard to obtain an acc ur ate estimate of the escape p ro b a b ility A ( t) from ljl( k ) . There are way s of invertin g � ( k ) eit he r by n u m e ric al inverSion or by fittin g it wit h a theoretical mo del :- but bot h methods are inacc urate . Ho w ­ ever , i:
1 39

Residence- and C o n tac t - T ime Dis trib u t ions hand , lJia < t > is

u niq u ely measurable only in

t he s e cases where the ab sorbed

in other word s , wh e r e ad s o rp t ion c han ge t he residence - time distribution in the continuous p h ase

tracer p articles return to the sam e pl ace , does

not

.

i&_( k ) provid es a useful alternative . Unfortunately , �( k ) s u ffe rs from t he same problem as lJia ( t ) . T h at is , although it is u s e fu l in mo d e lin g , it cannot b e used for scaleup , as the � ( k ) d e p e n ds on a d so rp tion behavior and would be di ffere n t for different fU'st - o rd e r reaction s . One must t herefore be careful w he n ap p lyin g $ ( k ) t o ac t u al s c aleup problem s . I t will , i n a c ol d flo w model , give good in dica­ tion s o f bypas s p he n om e n a . T here i s , ho w e v e r , no guar an t e e t h at t he As t hi s condition is oft e n not met ,

real re acj ant will h ave model . lji ( k ) is u s e ful trial reactor s .

one and

If

an

the same

behavior as reactions used in t he cold flow

in stu dyin g m aldistrib utions of flow in act ual indus ­

do e s no t pe r for m up to expect ations , � ( k ) by chan gin g the t e m p erat ure t he n c o m p are the effect of c h an gi n g in the

in d ustrial reactor

c an o ften obtain sever al va l u e s t h e r eb y

(k) .

One can

industrial reactor to

of

(k)

pi lo t plant re s ult s or similar indu strial reactors .

From

one can then infer � ( k ) and possible re a son s for the poor p er fo rm anc e . This is a power ful di a gno s t i c tool , complementin g or s u b s ti t u ti n g for tracer studie s in indu stri al reactor s . One can get similar re sult s even if the re­ ac tion is n on li n e ar and complex in volvin g several co m p o u n d s . One starts with the a s s u m pt ion of a plu g- flow re acto r , estimates a s e t o f rate const ant s , and t he n obtains e xpre ssio n s comp letely eq uivalent to E q s . ( 1 6 ) and ( 20) . this

In this c ase , unlike the homogeneo u s c a se , one

comp ute t he outlet composition .

cannot use f( t ) or lji ( t ) to -

o u tlet com p o si tion can still be used to e sti m at e $(k) , as � ( k ) is an operator t r an s for min g the results of a plug flow re ac t o r into our r e ac to r . Note t h at r eli ab le d e si gn requires that $ ( k ) be close to p lu g flo w . An especially i nt er e s tin g case is one of consecutive re ac tion s with equal

reaction r at e s .

T he

Consider , for example , t h e

ca se

The solution of this c ase is gi ve n in Table 2 . I f the values of the r e ­ ac tion rates are equal , one gets an e s ti m ate n o t only of � ( k) b u t also of the hi gh e r derivatives of _i ( k ) or ( dn� ( k) /dkn ) k =k . i Even if the v alue s

of

( k ) are di ffe re n t ,

the values

of

C j give a goo d approximation of the are small . If esti mat es of the

derivative s as lon g a s the differences derivatives are availab le ,

expansion around ( k ) re actio n in

sec u ti ve

a

$(k)

can be recon structed from a

( see G la s s e t et

cold flow model .

al . ,

1 97 3) .

However , if

reaction , one c an comp are t he

It is

h ar d

T ay l o r

to

series

u se such a

an industrial reactor has a con ­ distribution to that of a

p ro d u c t

If signi fic an t deviations are foun d , this allo w s so me nature of t he flow . A good b as e case , preferab ly an isot herm al packe d - be d reac t o r , is es s e n ti al as well as a well-per formin g re ­ actor of a similar type . One doe s not al w ay s w an t to rec o n s t r u c t $ ( k ) ( alt h ou gh this is pos sible ) . T he nature and m a gnitu d e of t he deviations give some i mme di at e qualitative infor m ation ab o u t t he n at u r e an d m a gnit ud e of the deviation from plu g flo w , which c an b e i n t e r p r e t e d by looki n g at some sim p le flow models an d st y din g t heir effect on p ro d uct dis tri b ution . packe d - bed

conc l usio n s

r e ac to r .

as

to the

gi ve n in Table 3 . In t h e se examples , the overall resi dence time T is kept c on s t a n t for all c ases . The re ac t io n rat e k i s varied for each flow model so as to keep the outlet concentration of A ( A /Ao ) con­ stant . T hi s is don e to make t he e x amp le more consistent with act ual practic e . In m any c a se s , c atalyst activity c han ges and is c o m p e n s ate d for

An examp le is

1 40

Shinnar

TAB LE 2 Dep en denc e of t he Product Distribution of a Fir s t - Order Consecutive Reaction on the Residence - Time or Contact - Time

Distribution8

Reaction :

Reactor with residence ­ time distrib ution f(t)

Plu g- flow reactor

A " A f(k 1 ) 0

-

)!_ A = k1 0

2

E ._1

1-

_Q_ = k k A 1 2 0

D

TI

e

'J-1' 2

- k, T

( k. - k . )

j :# 1

L

. _1 3 1- '

B A0

1

J

TI

J- '

j:# i

- =

1

-k.T

e 1 ( k . - k. )

'- 1 3

J

=

1

1

2

E

._1

1-

c

- =

A0

k k

1 2

f( k ) 1 ( k . - k. )

--::-:-=--,-

II

j =1 ' 2

J

j:#i

3

E ._1

1-

1

f(k ) 1 __.:;_ "

TI

j=1 ' 3

__

]

(k. .

j :# i

-

k.)

__

1

1-A-B -C

=1-A-B -C k.

]

a

k

For contac t - time di stribution , sub stitute

=

3

1

( k ) for

-

E

i= l

f(k ) 1

IT

j=1 , 3 j :# i

k.

k. - k . ]

1

f( k ) .

by changing the re ac to r temperature . In practice one would therefore comp are the results of the industrial reactor to th e pilot plant at constant I A o . One does the same if the conversion is reduced du e to a 'naldistribution i n the flow . H ere the c o n c e nt ration of variou s products of a consecutive re ­ action , w hich are a function of t he residence-time di s t rib ut ion , can clearly show if the reduced conversion is due to a change in catalyst acti v ity or due to a m aldistribution in flow ( provided , of course , that one can confirm in the p ilot plant that catalyst reactivity does not strongly affect selectivity ) . The results for the case of co n s ec u tive reactions A -+ .... C -+ D w he r e all reac­ tion rates are equal are given in T able 3. The results in t hi s example are very sensitive to the residence-time and contact - time distributions .

A

B

1 41

Residence- and Con t ac t - T ime Dis t ribu tions

k 1 = k 2 = k3 = k Plu g - flow reactor e

-kT

Reactor with residence time distribution f( t )

AAo B

Ao

=

=

2

2

T �

k

e

Ao c

-kT

1 - A - B - C

1 -

f( k1) A

f( k ) = -k 1 ddk

=

I k=k

1

k 21 d 2f( k) 2! dk 2 k=k 1 1 - A - B - C

( if=O ( k.� ) i] e -k -r 1'

A P P L I C A T I O N S O F CO N T A C T - A N D R ES I D E N C E - T I M E

D I ST R I B U T I O N S T O T H E D E S I G N O F H E T E R OG E N E O U S R E AC T O R S

Earlier , rigorous concepts as to how residence - time distributions affect the

conversion and contact - time distribution in i sothermal homo geneous reactor s were discus se d . U n fortunately , very few reactions are truly homogeneous and fewer are isotherm al . In the previou s sections it was shown that t he se principles cannot be applied to hetero geneous reactors in strai ght forward way . However , the m ain applic ations are still valid if one is care ful to recogni ze t he special fe atures o f residence -time distributions in hetero geneous

...... ""' ""

TABLE 3 Depen dence of the Product Distribution of a First - Order Consecutive Reaction on Residence- Time ( Contact - Time) Distribution :

Numerical Example k

k

1

k

3

2 A --- B --e -D k

Flow model

1

= k

2

= k

3

= k

Average residence time ( h )

K

( h- 1 )

A JA

0

B /B O

C tC

0

D !D

0

1.

Plug flow

1. 0

1.0

0 . 368

0 . 368

0 . 1 84

0. 08

2.

Ten stirred tanks in series

1. 0

1 . 05

0 . 36 8

0 . 35

0. 183

0 . 099

1.0

1 . 06 8

0 . 368

0. 336

0 . 1 92

0 . 104

4.

1. 0

1 . 36

0. 368

0. 236

0 . 1 91

0 . 205

5.

1.0

4. 03

0. 368

0. 33

0 . 147

0 . 156

3.

1.0

2: CJ) ;:s ;:s Q ....

143

Residence - and Contact- Time Dis tri b u tions

reactors . I n this section t he concepts presented earlier w i ll be extended to the more general case o f hetero geneous reactors . I n the pre sent state o f knowle d ge , ri gorous al gorit h mic use o f residence ­ time distributions to predict product distrib ution in heterogeneous reactors is very re st ric t e d , even for first -order reactions . T here is no real goo d algo rithmic equivalent of Zwieterin g' s method . Fortunately , t he c oncept of boundin g the outlet composition is still valid . U tili zin g different models , one can still evaluate w hether t he reaction performan c e is sensitive to the act ual flo w model . T he resi den c e - time and contact - time distributions can then be used to place c onstraints on the range of flow models that one should consider . If the re ac t or is close to plug flow , one c an evaluate bounds by me asurin g the deviation from plu g flow by m e an s of a tracer experiment . T hi s works well only if t he devia­ tion from plug flow is small . The c on c ep t u al uses of residence - time distributions given earlier are still valid . Plu g- flow reactor s or staged reactors approachin g plug flow are optimal for all first - order reaction s and for all reactions in which contact between product s and reactants should be minimi zed . In fact , the example mentioned earlier was from c atalytic heterogeneo us reactors ( B e le vi et al . , 198 1 ) . Also noteworthy is t he con c ep tual use of t he contact - time distribu­ tion � ( k ) in react or design and scaleup . Recall that ( k ) was really an oper ator that showe d quantitatively the w ay the trans po rt process in the reactor modi fy the p roduct distribution as comp ared to a p acked - be d reactor . Its time scale was the reaction rate used to pre dict the results of a pac ked ­ bed reactor , w hich is simply the overall reaction rate p e r unit volume or per unit wei ght of catalyst . It therefore has the same time scale as the in ­ verse of the space velocity . In a packed-bed reactor with a good flow distribution , it is possible to keep both ( k ) and fo ( t ) , the residence-time distrib ution in t he gas p hase , constant . H owever , durin g sc ale up , t hi s is no t automatically guaranteed . fo ( t ) will norm ally stay con stant and close to the plug flow if the microre ­ · actor or p�ot plant is su ffici e nt ly lon g [ Silverstein and s hinnar , 1 97 5 ) . However , lj! ( k ) will stay constant only if there is no mass transfer resistance between t he gas p hase and the catalyst parti c le . Otherwise , increasin g re­ actor len gth will chan ge the mass tran s fer coefficient , which will chan ge ( t ) and t herefore (k) . Another interestin g con c ep t u a l conclu sion can be derived from the con­ cept of a contact - time distribution . I t can be seen from Eqs . ( 4 8 ) to ( 50) that , for certain classes of systems , tPa ( t ) and a ( s ) can be uniquely d e ­ rived from two s e t s of information .

�

i

i

_i

�

1. 2.

T he residence - time distri b ution fo ( t ) in the continuous p hase T he residence -time distribution fa ( t ) of an adsorbin g tracer in a plu g - flow reac tor

Consider a first - order reaction that occurs in the adsorbed phase .

As

each of the different reactants has a di fferent adsorption behavior ( its adsorptive e q ui li b ri um may be different , as well as the rate at w hi c h it

adsorbs or desorbs ) , e ac h species has a different i ( t ) or (s) . To proper ­ ly model the system , one would need an exact tracer (isotope) for each re ­ actant . However , for t he special case described , one could predict lji ( t ) or fo r each of the spec i es , given t he tracer results from a plu g- flow reactor and fo ( t ) , which is common to all species . I f one follow s a molecule

_i

_i(s)

Shinnar

1 44

un der goin g a first -order reaction , one c an concep tually measure for each molecule a total s oj o u r n time i n the adsorbed p hase . To comp ute its residence - time distribution , one must also know the reaction rates in order to determine how much time it s p e n d s in e ac h of the various states it can assume . T his is si mi l ar to t he concept u sed earlier to deal with fi rst - order reactions in n o ni sot h e rmal homo geneous system T he above is equivalent to c han gi n g t he n at ure of p( s ) in E q . ( 4 9a ) . Al t ho u gh one can n ot make this computation without detailed knowledge of a d sor p tion kinetics , one can use the concept to derive an im p or t an cri­ terion in reaction engineerin g : n am e ly , that for all case s for which Eqs . ( 4 8 ) to ( 50) ap p l y , one can u se the p se udokinetics o b t ain ed from a packe d ­ bed reac to r and ap p ly it to all case s , u sin g fo( t ) to comp ute the result s . T his allows one to d eal w i t h di s p ersion and recyclin g in p ac k e d beds . I t also show s that for a fi r s t - or der reaction , t h e result o f a stirre d - t ank catalytic reactor is direct ly scalable to a pac k e d - b e d reactor , and vice vers a , as a stirred tank is o n e of t he few cases wit h movin g c at al y s t for which Eq . ( 48) app li e s . T his s c a li n g i s po s silb e despite the fact that one is re ally m e as u ri n g a p s e udokin eti c first - order reaction rate b as e d on space ve lo ci ty and not the ac t ual kinetics based on r e al re sid ence t i mes . T his con c ept can be extended q u ali t at i ve l y to s ec on d - or d e r r e ac t i ons in a catalytic reactor . I n reactors o f thi s type , mic r o m i xi n g is no t impor ­ tant . However , it is o ft e n important to know w hether t he p ro d uc t distribu­ ti on can b e p re di c t e d reasonalby from fo ( t ) . For cases w here Eq . ( 48) applies , the Berty re ac t or p rovides a simple test . If a s ti rr e d - t ank cat aly ­ ti c r e ac tor y i e lds kinetic r el ation s that p redict well the behavior of a packed - bed reactor , t hen nonlinear interactions between products and react ants are not i m p or t ant an d fo ( t ) can be used to p r e di ct the effect of dispersion in scaleup . The comp arison above is often i mp or tant in the d e si gn of complex re ­ It is t herefore important to understan d the p ri n cip le s by w hich actor s . E q s . ( 4 8 ) an d ( 4 9 ) w e r e derived . T he m ain assum p t i on s were : •

1. 2.

The system is sp atially uniform . A n adsorbed p a rtic le (or a p artic le diffu sin g i n t o a c at aly s t particle ) always r e tur n s to the s ame place [ or to a place equivalent to it in terms of fo( t ) 1 .

T he se assump tions are not alw ays valid . N everthele s s , t her e are many cases where one w an t s to predict the p er for m an ce of a hete rogeneous re ­ actor w hich i s not a p acke d bed from eit her a s mall p acke d - b ed reactor or a p ilot plant . This applies to fluid beds as well as tran s p ort reactors such as a riser cracke r . I f o n e comp ares s u c h a reactor t o a p ac k e d bed , it is im p o s sible to keep b ot h fo ( t ) an d i_ 0(k) con s t an t . For example , the first I f t h e reaction occurs moment of f o ( t ) will be m u c h larger for the riser . only at the solid surface of this c atalyst , this s hould not matter . B ut in m any comp lex reaction systems c at alytic surface reactions compete and inter­ act with gas - p hase reactions . T he cat alyst or solid may also act a s an in ­ hibitor for the g as - p hase reactions . In som e catalytic reactions , intermedi ­ ates forme d at t he surface will either diffuse through the gas phase or re ­ ac t in the gas p hase . One s hould therefore be careful in such cases , and evaluate the po s si b le impact of c h an ges in fo ( t ) relative to l/Ja ( t ) . Ri gorously , it is n ot enou gh that f o ( t ) and ljia ( t ) stay constant . T he distribution of sin gle stays in eit her p h a s e should also s t ay constant . I f

Residence- an d

Contac t - Time Distributions

1 45

one cannot assume this to be true , one can experimentally test t he sen ­ sitivity of t he reaction s t o variation s in fo ( t ) , k eepi n g 1/!a ( t ) const ant . T his technique is a simple and power ful conceptual tool for or gani zing one ' s t hinkin g about the pit falls of a given scaleup problem . C onsider , for ex­ am p le , a catalytic fluid - bed cracker in which the crackin g really oc c u r s in the dilute phase riser . A t low t e m perat u re s , gas - p hase reactions are slow

and the res u l t s correlate very well with t ho se obtained in a dense - p hase bed at the same space ve loci ty . At hi gher temperatures , the gas -phase re ­ actions become si gni ficant and the correlation is poorer . As t he se gas ­ phase reactions are un d e si rab le , it is imp or t an t to reduce t he average residence time o f fo ( t ) , keeping the space velocity const an t . Anot her import ant example is t he c ase of a dens e - p h ase catalytic fluid bed . E q u ation s ( 48) and ( 49) do not apply ri gorously in a fluid bed for two r eas on s : 1. 2.

The gas phase is nonuniform , as part of the gas i s in bubbles and part in a dense phase around the catalyst . T he T he solid circulation and ad sorbe d reactants circulate w ith it . sojourn - time distribution at e ac h reactant depends on t he rate at which it adsorbs and desorb s from t he cataly s t .

One can , however , design a fluid bed s uch that Eq . ( 4 8) ap p ro xi mate l y For example , one can see to it that fo ( t ) ap pr o ac h es plu g flow . One can al so use an adsorbi n g t rac er with fast e x ch an ge an d desi gn the re ­ actor suc h that fa ( t ) app ro aches plug flow . That would occur on ly if all gas particles are adsorbed and desorbed many ti mes . T hi s then ap p roac hes the condition of spatial uni for mi ty despite the pressure of bubbles . One can achie ve this either by w o r kin g in the tur bulent fluidi zation regime or by usin g properly desi gne d baffles . Designin g the tu rb u lent flow regime only help s condition 1 . The second condition c an b e approached only by b a ffli ng or stagin g t he be d . One can al w ay s approach plug flo w by a s u f­ ficient num ber of sta ges . I f the catalyst circulation between the st ages is slow comp ar e d to the rate o f a ds orp tion and desorption of reactants , one ap p ro ach e s condition 2 , na m e ly , that each molecule always returns to a place su c h that its r e side n c e time in t he continuous p has e is not c h an ged . These ar gu ments allow one to underst and on t h eo r etical grounds the B affl es give added confidence to t he scale­ importance of ba ffl es in scaleup . up even if the fluidi zation is t urb ule n t and a t rac e r experiment shows that T his is so b ec au se solid mixing one ap p ro ac h e s plug flow wit hou t baffle s . in a fluid bed alw ays incre ases d urin g scaleup even when t he pilot plant is reasonably l ar ge . It is i m port an t t hat t he b affles really reduce solid mixin g and divide the solid cat aly st phase into stage s . Vertical b a ffles , w hich are often used , do not achieve this goal and t h e refor e do not provide the needed safety net for scaleup which can be ac hieve d u si n g ho ri zon tal b a ffles . We will conclude with on e final e x ampl e . R e c entl y , fl ash hydro ge natio n of coal , in w hich coal i s devolatili zed and p art i ally gasi fi e d in t he p res e nce of hydrogen at hi gh pressure , has received consi d erable attention . A simplified kin etic scheme of the reaction is ap p li e s .

Coal

H2 H2 H2 - heavy liq ui ds - B T X -- - methane ( 1)

( 2)

( 3)

1 46

Shinnar

are also c at aly zed by the con sec utive reaction , plug flo w of t he gas is req uire d for good selectivity , and it is also important to control the re sid en ce time in a narrow optimal ran ge . Kinetic an d the rmo dy n am ic con si de r atio n s r equi r e t he reactor to be as isot herm al as po s si b l e It has and the e asi est w ay to achieve this is by backmixin g of solids . the re for e been su ggested that flui d - bed reactor s or risers with hi gh solid circulation would have si gni fic an t advantages for s uc h a de si gn . However , all pre sent experimental data were obt ained in c urrent dilute phase reactors in which t he solid / gas ratio is an order of m agnitude low er t h an would pre ­ vail in a riser with solid recirculation . T here is no w ay to estimate reliably from data in a d il ut e p ha se cocurrent reactor w hat would happen in riser w it h hi gher concentration of solids . O ne cannot keep residence time and con t ac t time constant sim ultaneously . For any de si gn estimates one would need data fro m a system in w hic h both con ta c t time and residence time are similar to t he desired desi gn . Or one would need evidence th at one of these t wo has no i m p ac t on the re act io n T hese simp le examples should be sufficient to illustrate the varied ap­ p lica ti on s of contact - and resi dence - time di stributions to the desi gn of hete ro geneo us reactor . They provide guideline s for d e ali n g with th e diffi­ c ult proble m s of re ac t or scaleup i n complex reactors . Steps

2

and 3 can occur

coal ash as

w e ll as

by

in

t he

t he gas p h as e an d

char .

A s t hi s

is

a

­ ,

-

.

N O T AT I O N

a J

A.

A(t)

concentration of compound A name of co mp o un d j inside the reactor fraction of artic le s inside t h e reactor that will le ave it be fore time t concentration of compound A in prod uct st re am fut ure life distrib ution of p article

p

C C

A Af

concentration of product f in feed stream

a

s trea m

C(t)

concentration of t r c er in exit

C (t) f

concentration of tracer in feed stream

E f f( s )

F(t)

expected value of t

n

n or J0"" t f( t ) dt

Laplace transform of f( t ) re si den c e - ti me distrib ution :

raction o f p artic le

f

enterin g at time

zero that leave t he reactor before time t

f( t )

g( t )

G ( t) k

kij

i i fr ac ti o n o f c s exitin g between t and t l1 t = f( t ) L1 t den sit y function of G (t) internal age distrib ution : fraction of p artic le s which are in t he reactor at a gi ven time of ob se rvation that have been inside the reactor less t han time t kinetic rate c on s t ant den s ty function o f re s d e n ce time distribution : p ar ti l e

rate constant of reaction A

+

i

,... A

j

147

Residence - and Contac t - Time Dis trib u t ions K

equilib rium constant of reaction A

+

Aj

i amount of tracer introduced in pulse experiment

ij

m

pi

probability of molecule or particle to be in state j

Q

volumetric flow r ate

t

time

Peclet n umber

Pe

V

volume of reactor variance of density function f( t )

G reek Lett e r s

constants in Eq . ( 2 5 )

�r

{V;

y = A

coefficient of variation of f( t )

­

T

ei genvalue s of firs t - order kinetic systems [ see Eq . ( 2 5) ]

r

escape prob ability o r inten sity function of residenc e - time distrib ution r E C t ) = rth moment of f( t ) r

A (t) ll T

r

=

average residence time in homo geneous reactor

=

V /Q

Laplace tran sform o f contact - time distribution sojourn - time distribution density function o f stay in the adsorbed p hase [ see Eq . ( 4 6 ) ] R E FE R E N C ES

Belevi , H . , J . R . Bourne , and P . Rys , C hemi c al selectivities dis guised by mass diffusion , Helv . C him . Acta , 64 , 1 6 1 8 ( 1 98 1 ) . Biloen , P . J . N . Helle , F . G . A . van der Berg , and W . M . H . S achfler , I sotopic transients in Fischer T rop sch reactions , J . C atal . , ( 1 9 8 3 , in press ) . D anckwerts , P . V . , C ontinuous flow systems , C hern . En g . S ci . , 2 , 1 ( 1953) . Evan gelista , J . J . , S . K at z , and R . S hinnar , T he effect of imperfect mix­ ing on stirred combustion reactor s , 1 2th Symp . ( Int . ) Combust . , Combu stion I nstitute , Pittsburg , P a . , ( 1 96 9a ) , p . 90 1 . Evan gelista , J . J . , R . Shinnar , and S . K at z , Scale - up criteria for stirred tank reactors , A I C hE J. , 1 5( 6 ) , 8 4 3 ( 1 96 9b ) . Froment , G . F . and K . B . Bischoff , C hemical Reac tor A nalysis and Design , Wiley , New York , ( 1 97 9) . Gilliland , E . R . and E . A . Mason , Gas mixin g in beds of fluidi zed solids , Ind . En g . C hern . , 4 4 , 2 1 8 ( 1 95 2 ) . Glasser , D . , S . K at z , and R . S hinnar , T he measurement and interpretation of cont act time distributions for catalytic reactor characteri zation , I n d . Eng. C hern . Fundam . , 1 2 , 1 6 5 ( 1 9 7 3 ) . ,

1 48

Shinnar

Hiester , N . K an d T . V erme ulen , S at u ration p e r fo r m ance of ion -e xchan ge and a d so r p ti o n columns , C hern . En g . P ro g . , 4 8 , 505 ( 1 9 5 2 ) . Himmelblau , B . M . an d K . B . B ischoff , Process A nalysis and Sim u latio n , Wiley , N e w Y ork ( 1 96 8 ) . K rambeck , F . J. , S . K at z , an d R . Shinnar , Stochastic models for fluidized beds , C hern . E n g . Sci . , 2 4 , 1 4 97 ( 1 9 6 7 ) .

S hinnar , Interpretation of tracer experi ­ me n t s in sys te m s with fl uc t u a ti n g throughput , I n d . En g . C hern . Fundam . 8 , 4 3 1 ( 1 969) . Le hman , J . and K . Sch ii gerl , I n ve s ti g atio n of gas mixin g and gas di strib u­ tor pe r for m an c e in fluidi zed beds , C hern . Eng. J . , 1 5 , 91 ( 1 97 8) . L e ve n s p ie l , 0 . , and K . B . B i sc ho ff , Patterns of flow in chemical process vessels , Adv . C h ern . Eng . , 4, 95 ( 1 963) . Mills , P . L . , an d M . P . D u d u kovic , Evaluation o f Liquid - solid con t ac t i n g in t ri c k le b e d reactors by tr ac e r methods , AIChE J . , 2 7 , 8 9 3 ( 1 9 8 1 ) . M u rp hree E . V . , J . V oo rhies , Jr . , and F . X . Mayer , A pp lic atio n of cont ac t i n g studies to the an aly s is o f reac to r per form anc e , I nd . Eng. C hern . Process Des . Dev . , 3 , 3 8 1 ( 1 96 4 ) . N aor , P . and R . S hin n ar , Repr e sent atio n and evaluation of resi denc e time distrib ution s , I n d . En g . C hern . F un d am . , 2 , 2 7 8 ( 1 96 3 ) ; N aor , P . , R . S hinnar , and S . Kat z , I n dete r min ac y in the estimation of flowrate and transport functions from tracer e xp e ri m en t s in closed circ u l ati on , Int . J . En g . S ci . , 1 0 , 1 1 5 3 ( 1 9 7 2 ) . Naum an , E . B . , R e s i dence time distrib utions an d micromixing , C hern . E n g . C ommun . , 8 ( 5 3 ) ( 1 9 8 1 ) Nauman , E . B . a nd B . A . Buffham , Mixing in Co n t i n uo u s Flow Systems , Wile y , New Y or k ( 1 98 3 ) . N g , D . Y . C . , an d D . W . T . Ri p pi n The e ffe c t o f incomp lete mixin g on conversion in hom o ge n eo u s reactions , Proc . 3rd Eur . Symp . C hern . R eac t . En g . , P e r ga m on Pres s , Oxford ( 1 96 5 ) , pp . 1 6 1 - 16 5 . Orcutt , J . C . , J . F . D avi d s o n and R . L . Pi gfor d , Reaction time dis t rib u ­ tion s in fluidi zed c ata ly tic reactors , A I C hE C hern . Eng. Pro g . S ym p . S e r . , 38 , 1 ( 1 96 2 ) . Orth , P . an d K . S c h ii ger l Distribution of re sidence times and cont act times in p acked bed re ac t or s : influence of t he c hemical reaction , C hern . E n g . S ci . , 2 7 , 4 97 ( 1 9 7 2 ) . Overcas hier , R . H . , D . B . T odd , and R . B . O lne y Some effects of baf­ fles on a fl ui di ze d system , A I C hE J. , 5, 5 4 ( 1 95 9) . 0 s t er gaar d , K . an d M . L . Mi c he lse n On the use of the i m p e r fe c t tracer p ulse method for determination of ho l d - up and axial m ixi n g , C an . J . C he rn . E n g . , 4 7 , 10 7 ( 1 96 9) . Pennick , J . E . W . Lee , a n d J . Maziuk , D e ve lo p m e n t of t he methanol to gasoline ( M T G ) P ro c e ss , 7th I nt . Meet . R eac t . E n g , Boston ( 1 982) . Petho , A . and R . D . N o b l e , eds . , Residence Time Dis trib u tio n T h eo ry i n C hemical E n gineeri n g , V e r l a g C h e m ie W ei n h eim , W e s t Germany ( 1 98 2 ) . S ei n fe l d , J . an d L . L ap i d u s Process Modeling, Es t imatio n , and Iden t ifica­ tio n , Prentice - H all , E n glewood C liffs , N . J . ( 1 9 7 4 ) . Shinnar , R . , On t he behavior of liquid di sp e rsi on s in mi xi n g vessels , J . Fluid Dyn . , 1 0 , Pt . 2 , 2 5 9 ( 1 9 6 1 ) . S hinnar , R . and P . Naor , R esi d en ce time di s t ri b utio n s in systems with i n t er nal reflu x , C he rn . E n g . S ci . , 22 , 1 3 6 9 ( 1 9 6 7 ) . Shinnar , R . , P . N aor , an d S . K at z , I nterpretation and e v al ua tio n of multi ­ ple tracer exp e ri men t s , C hern . E n g . S ci . , 2 7 , 16 27 ( 1 97 2 ) . Krambec k , F . J . , S . Kat z , an d R .

-

,

.

,

,

,

,

,

,

.

,

,

149

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Glasser , a n d S . K at z , First order kinetics in c o n tinuous

C h e rn . En g . S c i 28, 6 1 7 ( 1 973) . S hinn ar , R . , Tr a c e r ex pe rim e nts in re ac t or desi gn , 2nd C on f . Physico ­ c he m . H y d ro d y n . , Oxford ( 1 9 7 7 ) . S hinn ar , R . P ro c e ss cont rol rese arc h : an evaluation of present st a t us and research needs , A C S Symp . Ser . , 72 , 1 ( 1 97 8 ) . Si lve rst ei n , J . , and R . S hinn ar , D e si gn of fixed bed cat alytic microreactors , Ind . En g . C hern . Proce s s D e s . Dev . , 1 4 , 1 2 7 ( 1 9 7 5 ) . Snow , A . I . , p riv ate comm unication , A R C O Petrole um C o . ( M ay 1 98 3 ) . T army , B . , private communication , Tracer experiments performed on the reac tor s ,

.

,

Exxon ED S Pilot Plant (March 1 98 3 ) . J . an d C . D . P r a te r S tructure an d analysis of complex chemical re ­ act io ns , Adv . C atal . , 1 3 , ( 1 96 2 ) . Wein stein , H . and R . J . A dler , Mi c ro m i xi n g e ffects in continuous chemical reac to r s C hern . E n g . Sci . , 22 , 65 ( 1 96 7 ) . Wein stein , H . an d M . P . Dudukovic , Tracer methods in the c i rc u l at io n in Topics in T ransport P he n om e n a R . Gutfin ger , ed . , H e mis p he r e , New York ( 1 9 7 5 ) . Woodrow , P . T . , U se o f intensity function rep r e s e ntatio n of residence time variability to understand and impro ve p er for m anc e of industrial reactors , ACS Symp . S e r . , 6 5 , 57 1 ( 1 9 7 8 ) . Z virin , Y . an d R . Shinnar , Int . J . Multip hase Flow . , 2( 5 / 6 ) , 4 9 5 ( 1 97 5 ) . Z wieterin g , T . N . , The d e gr e e of mixin g in cont i n uo u s flow systems , C h e rn . E n g . S ci 1 1 , 1 ( 1 95 9 ) . Wei ,

,

,

,

,

.

,

3

Catalytic Surfaces and Catalyst Characterization Methods W . N I C H O LAS D E LG ASS

E D U A R D O E . WO L F

Purdue U nivers i ty ,

Wes t Lafay e t te ,

Univers i t y o f No t re Dam e ,

No t re Dame ,

In diana In diana

I N T RO D U C T I O N

C atalysi s i s a complex p henomenon i n which a multit ude o f i nt er e st in g

A review of the prin c i p l e s an d factors involve d in variables intervene . determinin g c a taly ti c ac t i vity is b e y o n d the scope of t h i s chapter . We have

focused on the characteri zation of cat aly t ic propert ies to enhance our un­ Emphasis is given to t he modern s u rface a n aly si s tec hniques , which can p ro vi de new in sights for interp ret ­ ing catalyt ic phenomena . Such methods , whic h were often first applied to st u dy model surface s , are n ow b ei n g use d to analy ze the more complex sur­ faces foun d . on t ec hnical heterogeneous catalysts . T wo ty pes of c harac t e ri zation techniques are di scuss e d in this chapter : ( a ) p hy sical charac teriza­ tion , and (b ) physicochemic al c haracterization . T h e first type refers to total surface are a and p ore size distribution . Total area is re l evan t in de­ ter m inin g the contact between t h e catalytic a gent and reac t an ts . P oro s i ty is si gni fican t in c on t r o l li n g the tran sport of the c atalytic a gen t in to the support durin g catalyst p r ep ar ation as well as t he transport of r eac t ants and p r o duc t s between t he b ulk fluid p hase and the active sites durin g re ­ acti on Since surface area and pore vol u me are r elat e d a b alance b etween these two variables is a key factor in cataly st de s i gn . The B ET a d s orp ti on method to me a sure total surface area a n d metho ds to m e a s u re pore s i ze dis ­ trib ution are disc u s se d in t he follow in g two section s . O t h er imp o rtan t variables t hat cha r ac t e ri z e a su pp or te d cataly st are the area of the a c tiv e cataly tic component ( i . e . , metal area in t he case of a s up po r te d metal catalyst ) and the c ry s t alli t e size distribution of t he active Many reac tion s are sensi t ive to the crystallite size , and t hey are p hase . termed s t ruc t u re -sen s i tive or deman d i n g reac tions . Va ri o us factors are in ­ volved in this structure sen siti v i ty The occu r re nce of a partic ular crystal phase , the ratio of edge to corner sites , the st r uctur e of the surface , and th e s tab ility of o v e rl ay e r s can all depend on c ry s t alli te si ze . A di s t in ct iv e chemical feature of c ryst all it e s in t he size re gion 0 . 5 to 5 nm is the low c oor dination n umber of the s urface atoms . Later s ec tion s de sc rib e sel ec tiv e de r s tan din g o f the underlyin g processes .

­

,

.

,

.

1 51

1 52

Delgass and Wo lf

chemisorption of gases as a method to measure total metal area an d x - ray diffraction an d tran s mission electron mic roscopy as methods to determine avera ge crys tallite si ze and size distrib ution . Although the methods mentioned previously have been known for many years , their development for chemic al analy sis of surfaces is more recent . As know ledge of the principles of op eration , capabilities , an d limitations of surfac e analysis methods expands , the in terpretation of catalytic p henomena will become accordin gly more sop hi sticated . Ultimately , thi s new knowledge of surface chemical behavior will support the search for and desi gn of new catalysts . Knowled ge of the composition of a surface is a prerequisite for understan din g its c hemistry . X - ray p hotoelectron spectroscopy ( X P S ) , Au ger electron spectroscopy ( A E S ) , an d ion scatterin g spectroscopy ( I S S ) p rovide quantitative analysis o f surfaces o r thin surface layers . This in ­ formation can reveal surface en richmen t in alloy s , the surface concentration of promoters in multicomponent supported c atalyst s , and the composition of the s urface of mixed oxides . These methods can also detect imp urities and poison s an d , in general , follow c han ges in the cataly s t surface after expo­ sure to the reaction environ ment . Oxidation state an d p hase iden tification come most readily from XPS an d , for selec ted elements , from t he Mossbauer effect . T he c urren t frontier in surface analysis is the meas urement of local s urface composition an d structure by application of ( a ) extended x -ray ab sorption of fine struc ture ( E X AF S ) , an d (b ) secon dary ion mas s spectros­ copy ( S IM S ) . We disc uss the se analy tic al tools and magnetic resonance in relation to the determination of surface composition an d structure . T he distrib ution of a catalytic material , or a poison within ·a support , can be a key variable in c atalyst performance . Slight chan ges in p rocedure durin g cataly st preparation may in troduce significant c han ges in t he distri­ b u tion of cataly tic materials inside the pellets . We disc us s the use of elec ­ tron microprobes and electron microscopes equipped with analytical capabili­ ties to assess the distrib ution of materials in side p ellets . To complete the chemical c haracteri zation of a surface , one must examine its interac tion with adsorbin g an d reac tin g gases . We discuss methods by whic h the effec ts of gas - solid contac t on the composition an d chemistry of the soli d surface can be examined . T he influence of the surface on the adsorbed molec ules is usually probed with vibrational spec troscopy ( I R or Raman ) an d can be investigated with a magnetic resonance ( N M R or E S R ) . Another measure of gas - surface interac tion is the stren gth of the adsorbate bon d . Sabatier suggested lon g a go that this bon d must be stron g enou gh to perturb the molec ule b u t not so stron g as to form an un reac tive s urface compoun d . T emperature- p rogramme d desorption and reaction methods for studyin g surface bon ding are discusse d , alon g with vibrational spec troscopic tec hnique s for examinin g the adsorbate molecules themselve s . T hese adsor ­ bate studies can serve either as a direct probe of the reaction it self or as an additional mean s of chemical c harac terization of the catalytic surface . T he tec hniques revie wed in this c hapter are those best developed and most commonly applie d or most promisin g at this time . T he presentation emphasi zes the es sential conc epts an d features of eac h technique and major application s in cataly sis . We have attempted to avoid excessive use of jargon to keep the disc ussion s un derstan dable to the non specialist . Refer ­ ences to more detailed descriptions are given in each section . We note , finally , that thoro u gh characteri zation of catalysts often requires use of combination s of techniques chosen to give complementary information , and

1 53

Cataly tic S urfaces

that characteri zation o f the catalyst surface encompasses only half of the information neces s ary to fu lly un derstand a catalytic system . T he other half is the evaluation of t he element ary kinetic steps of the reaction w hich are the m anifestations of the influence of the c ataly s t surface on the react ­

in g molecules .

TO T A L S U R FA C E A R E A :

BET METHOD

There are several technique s t o e sti m at e the tot al surface area an d pore size distribution of porous m aterials . Various review article s concerning such measuremen t s have been published ( E m met t , 195 4 ; Innes , 1 968) . The B E T method is , however , the most com mon t e ch niq u e employed today for such measurements ; conse q uent ly , it is the only t e chnique di scussed here . The reader is directed elsewhere in reference to other techniques ( I nn e s , 1 96 8) . BE T A dsorp tio n

Many physical adsorption isotherms exhibit S shapes which are inconsistent with the Lan gmuir i sot herm b ased on monolayer adsorption - de sorption e quilibri u m . B runaue r , Em mett , and Teller ( 1 93 8) p roposed an explanation base d on the assump tion that m ulti l ayer adsorption could occ ur . T he B E T

model also pos tulates s ur fa ce h omo gen ei ty and no intermolecular interaction The most common form of the B E T a ds ortp ion isotherm also assumes that an infinite n umber o f multilayers can be ad­ sorbed . T he resu l tin g lineari zed B E T i sotherm has the form

between adsorbed s p e ci e s .

V d (P a s

p

O

·

- P)

=

1

V C m

+

c - 1 V C m

p P 0

( 1)

where Vads is the volume at STP occupied by molecules adsorbed at a pres­ sure , P , Vm is the volume corre spon din g to monolayer coverage , C i s a constant , and P o is t he saturation vapor pressure of t he adsorbate over a plane surface . A plot of P / V ads ( P o - P ) versus P /P o is a s t r ai gh t line with slope S = ( C - 1) /Vm C and i n t erc ep t I = 1 /V m C . Knowin g S and I p e rmits c alc ulation of V m and t here fore the number of gas molecules ad­ sorbed in a mono l ayer , w hich , when m ultiplied by the cross- section al area of the ad sorb ate , give s the total surface are a o f the solid . T he followin g cross - sectional areas (in square angstroms per mole cule ) give reasonably self-consistent total are as : N2 16. 2 , 02 1 4 . 1 , Ar = 1 3 . 8 , Kr 19. 4 ( Adamson , 1 97 6) . N 2 is the p re ferre d adsorbate , but Ar and Kr are also commonly used . =

=

=

T he most common e xperimental con fi guration s used to measure B E T iso­ therms ( Innes , 1 96 8 ; E vere t t and Otterwill , 1 97 0 ) are ( a ) the classic al

volumetric static app aratus used by E m m e t t , in w hich pressure associated with increm en t al volumes of gas is measured ; ( b ) a recirc ul ati n g batch flow system with helium dilutent ; and ( c ) a pulse chrom atographic dyn amic

flow system .

Several commercial s y s te m s b ase d on s t atic or d y n amic techniques are available ( Everett and Ott er will , 1 97 0 ) . T he expe ri m e nt al obje c ti ve in every These case is to determine V ads as a func tio n of the adsorb ate pressure . values are then sub stituted into Eq . ( 1 ) so that the intercept and the

1 54

Delgass and Wo lf

slope of the lineari zed BET isotherm c an be determined . T he re gion of best fit for the isotherm is in the P /P o r an ge 0. 0 5 to 0. 3 . C ontinuous an d autom atic systems have also been de si gned and differ from batch systems in that the gas is added continuously to the system at a very low rate instead of in lar ge increment s . Contin uous a d dit ion per­ m i t s automation , w hich , when coupled with microcomp uters , provides di rec t c alculation of surface area an d pore si ze distribution . M ajor factor s in all B E T measurements are p roper de gassin g of the samp le and e q uili bration . O t her t e c hni q ues used for c alc ul ation of total surface area , such as gravi­ metric techniques , se le c tive a d so r p t ion from liquids , and small - an gle x - ray scatterin g , are briefly summarized by I nnes ( 1 96 8 ) . PO R E S l Z E A N D D I S T R I B U T I O N

T he distribution o f pore si zes i s one o f the i m p o rt an t characteristics o f s up ­ ported c atalysts since i t i s related to the value of the effective transport coefficients , and consequently it can affect activity , selectivity , and rates of de activation . C at alyst pellet s have a comple x p ore structure which pre ­ sents a wide distribution of si zes . Pores b et ween 10 and 1 0 0 A are re­ ferred to a s mtcropores , those between 1 0 0 0 A and 10 �m are called mac ro ­ pores , and those of intermediate size are c alled mesopores . T he micropores are us ua lly characteristic of the s upport p o ros i t y , whereas macropores can ori ginate in the interp ar ticle s p ac e crea t e d d urin g formation of the pellets . A m ateri al e x hi bi t in g both micropores and macropores is described as having a bimodal pore di s t ri b u t io n . Detailed disc us sions of pore structure and its determin ation have been presented in various textbooks and mo no grap h s ( E verett and O t terwill , 1 97 0 ; Gregg an d S i n gh , 1 96 7 ; Parfitt and Sin gh , 1 976) .

A first - order approximation or estimate of the ave r a ge p o re si ze can be pe r fo rm ed by ass umin g that all pores are nonintersectin g c ylin de r s of uniform len gth L an d radius rp ; t he n

Pore s u r fac e Pore volume

=

s

v

p

=

2

r

( 2)

p

or

2V

r

p

___E. s

w here V p is t he t ot a l pore volume and S the total surface area . For materials with a distribution of pore si zes , it is necessary to kno w

the pore volume at various pore si zes . The derivative of the pore volume curve wit h respect to the radius give s the pore si ze distribution . T he two m os t common tec hniques used to determine pore volumes are the BJH method ( B ar re t t et al . , 1 9 5 1 ) , base d on t he use of either a d so rption iso­ therms or porosimetry . Pore Size Dis tribu tion from Phy s ical A ds o r'p t i o n Isother'ms

If a physical adsorption isotherm is e x t e nd e d to the re gion in which P /Po about 1 , a rapid increase of V occurs due to condens ation of the ads

is

1 55

C a taly tic S urfaces

ad s o rb at e o n ! he pore walls . Conversely , a de c r e a s e in pressure res ults in e vap o ration of the adsorbed o r condensed liquid . Kelvin derived t he followin g relation between the vapor pressure reduction over a liquid con ­ tained in a c y lind rical c api llar y and the radius r : =

where P o

2V o

rRT

cos ¢

( 3)

the sat u r ation pressure , a t he surface tension o f t he liq ui d , simplicity ass um ed to be 0° ) , and V the molar volume of the liquid . T he K elvin equatio n c an be u s e d in pri n ciple to calculate r fo r any c orresp on din g value of P /P o . However , sever al com ­ plic at ions arise : ( a ) a hysteresis loop is often observed i n ad sorp t ion isotherms ; ( b ) the pores are not cylindric al and have v aryin g radii ; an d ( c ) an adsorbate film of varyin g t hickne s s decreases the e ffec tive Kelvin radius . A disc u ssion o f the various theories that have been p ro p o s e d to account for the factors cited above is given by G r e g g a n d S i n gh ( 1 967 ) . A detailed c alculation p rocedure , known as the B J H me t ho d , has been reported by B arrett , Joyn er , and H alenda ( 1 95 1 ) . The m e t hod c on sists o f step w i s e c alculation s based on t he dat a obtained from the de s orp tio n branch of the is other m abo ut the re gion where P /P o :::: 1 . T he c alc ula tio n s yield a cum ulati ve pore volume versus po re radius whic h is then differentiated with respect to the radius to obtain t he pore si ze distribution . is