HVAC AIR DUCT LEAKAGE TEST MANUAL
1ST EDITION-1985
SHEET METAL AND AIR CONDITIONING CONTRACTORS' NATIONAl ASSOCIATION,...
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HVAC AIR DUCT LEAKAGE TEST MANUAL
1ST EDITION-1985
SHEET METAL AND AIR CONDITIONING CONTRACTORS' NATIONAl ASSOCIATION, INe. 4201 Lafayette Center Orive Chantilly, VA 20151-1209
-
------
~~--
••....
TABLE OF CONTENTS
.._--~-_
TABLE OF CONTENTS FOREWORD
iii
FORMER TASK FORCE MEMBERS AND OTHER CONTRIBUTORS
iv
NOTICE TO USERS OF THIS PUBLlCATION
v
TABLE OF CONTENTS
SECTION 1
SECTION 2
SECTION 3
, vii
INTRODUCTION LEAKAGE APPRAISAL BASIS
1.1
OUCT CONSTRUCTION ANO INSTALLATION STANOAROS
1.1
OUCT SEALlNG COMMENTARY
1.4
RESPONSIBILlTIES OESIGNER
2.1
CONTRACTOR
2.1
GENERAL PROCEDURES
-- --_··---=FESTING OVCm,'iEW--:-~:-:-~
3.1
PRECAUTIONS FOR CONTRACTORS SECTION 4
LEAKAGE CLASSIFICATION LEAKAGE CLASSES OtFINEO
SECTION 5
SECTION 6
3.1
4.1
ASSIGNMENT OF LEAKAGE CLASSES
4.1
EXTENT OF LEAKAGE TESTING REQUIREO
4.1
TEST APPARATUS TEST APPARATUS ANO PROCEOURE ONLlNE
5.1
FLOW CALCULATION FOR ORIFICE METERS
5.4
TEST REPORTS INSTRUCTIONS BLANK TEST FORM
6.1 6.2
SAMPLE COMPLETEO TEST FORM
6.3
SAMPLE LEAKAGE ANALYSIS
B.1
SYSTEM LEAKAGE CLASSIFICATION ANALYSIS
B.1
LEAKAGE ANALYSIS
B.1
APPENDIX A
APPENDIX B
HVAC Air Duct Leakage Test Manual·
1st Edition
vii
APPENDIX
APPENDlX
C SUGGESTEO ANALYSIS OF NON-SMACNA CRITERIA SPECIFICATIONS
C.1
SAMPLE PROJECT
0.1
D
APPENDIX
E through
APPENDlX
I
SPECIFICATION
H
FLOW EQUATION FLOWMETER OVERALL
1.1
ACCURACY
1.1
METER LOSS
METER CAPACITY STANDARD
OERIVATION
1.2
FOR TESTED DUCT SIZE
1.2
AIR
1.3
OTHER LEAK TEST METHODS APPENDIX
"
J FLOW COEFFICIENTS
APPENDIX
K through
APPENDIX
N
J.1
M
FLUID METER INSTRUMENTATION
viii
1.3
REFERENCES
HVAC Air Duct leakaop
Tpc:;t M:mual
J.1
• 1c:;t Frlitinn
.-~~I"·~U',,l
TABLES 1-1
Standard Duct Sealing Requirements
3-1
Applicable
4-1 5-1
Assignment of Leakage Classes Orifice Coefficients
5-2
Flow Rate Versus Pressure Differential for Meters
A-1
Leakage as Percent of Flow in System
Leakage Classes
o' ooo. o
o
o.. oo
o. oo.. oo.. o. ooooo.. o
oo
o
oo.. 1.1
o
4.3
ooo.. oo_ o
oo.. o.. o
o
oo.. o.. o o o
E-1
Leakage Factor (F) in CFM/100 SoF Duct
oo
F-1
Amount of Duct to be Leak Tested (SFD)
ooo. o
G-1 H-1
Duct Surface Area in Square Feet per Linear Foot Areas and Circumferences of Circles
K-1
Air Density Correction
M-1
Properties of Manometric
ooo
o oo
o o
4.3 5.1 5.6
o
A.1
o
E.1 F1
o. _
G.1 H.1
Factor, d
K.1
Liquids
M.1
FIGURES 3-1
lIIustration of Testing
3.3
4-1
Duct Leakage Classification
5-1
Leakage Test Meter Apparatus
with Flange Taps
5.2
4.2
5-2
Leakage Test Meter Apparatus
with Vena Contracta Taps
5.3
5-3
Typical Orifice Flow Curves
5.5
B-1 1-1
Duct System Example Ratio of Over-all Pressure Loss to be Metered Differential Versus Diameter Ratio 13 ........•............................................
B.3
J-1
Flow Coefficients K for Square/Edged Orífice Plates and Vena Contracta Taps in Smooth Pipe
J-1
Flow Coefficients K for Square/Edged and Flange Taps in Smooth Pipe
L-1
Gas Expansion
~$.~l;
Test Manual·
J.1
Orific3 Plates _.. oo
Factor, Y, Versus Acoustic Ratio, t.p/kP
HVAC Air Duct Leakage
1.3
1st Edition
o 1
.......••.......•..•...
J.1 _ oL.1
IX
SECTION 1
INTRODUCTION
1.1 This document
identifies certain leakage limits for ducts and outlines procedures for testing ducts for conformity with air leakage limits that are set forth in a desígner's project specification. This document is not an endorsement 01' routine use 01'
duct surface leakage factor can be identified by the lowing relationship.
testíng. Leakage testing IS generalIy an unjustified major expense that is unnecessary when proper methods 01' assembly and sealing are used. Visual inspection for application 01' such proper methods will ordinarily suffice for 01' reasonably tight construction. verification Under any circumstances reasonable allowances for leakage must be adopted because no duct is absolutely airtighl.
where F is a Jeak rale per unil al' duct surface area (typícalIy cfmll 00 s. f.) CL is a constant
P is static pressure (typically in inches water gage) N is an exponent (most typically it is 0.65 but in some cases it is 0.5 to 0.9)
1.2 The sealing provisions contained in the SMACNA
HVAC Duct Construction Standards-Metal and Flexible, 1995 second edition. are reproduced here for convenient understanding of use of prescriptive measures. Consult the SMACNA Fibrous Glass Duct Construction Standards for fibrous glass duct assembly. Closures of joints and seams in fibrous glass ducts rely on taped adhesive systems to make connections, in contrast with metal ducts which use mechanicallocks for connection and use sealants for supplementalleakage
b.
The new SMACNA Leakage Classifications are based on this leakage factor relationship. Whether the designer uses the rates identified or prefers other constants, it is practical to evaluate leakage by this method.
1.4
OUCT CONSTRUCTION ANO INSTALLATION STANOAROS
S 1.0
General Requirements
S 1.1
These construction and installation specifications and illustrations include:
control.
1.3 Duct leakage reduces the air quantities at terminal points unless the total air quantity is adjusted to compensate. Leakage should be considered a transmission loss in duct systems. The farther air is conveyed the greater the loss will be. Key variables that affect the amount of leakage are: a.
1'0]-
Static pressure, not velocity pressure. (The higher the pressure the more leakage wiII occur.) The amount 01' duct (the more duct the more opportunity for leakage there will be).
c.
The openings in the duct surface (the major contributors are joints and seams although access doors. rod penetrations and' fastener penetratíons also contri bu te ).
d.
Workmanship (poor \\orkmanship undermines the best construction standanJs).
It is practical to relate leakage to dUClsurface arca. AIlhough rales 01' loss rer 1'001 01' seam. per diameler 01' hole ar per dimension of crack can be evaluated. dUCl surface area is lhe simplesl parameler by which lo evaluate syslem Ieakage. Furlhermore. research (in Europe and independenlly in lhe Uniled Slates) has led to the conclusion lhal wilhin aceeptable tolerances. a
S 1.2
su
a.
single-prescription
method requirements.
b.
optional altematives,
c.
perfomlance requirements for specific items that are ditlerent in detail from the generalized ilIustrations.
and
These standards are not meant to excl ude any products or methods that can be demonslrated to be equivalent in performance for the application. Substitutíons based on sponsor demonstrated adeqllacy and approval of the regulating allthority are recognized. These requirements presume that the designers ha\'e prcpared contracl drawings showing lhe size and localion 01' dllclwork. including pellllissible fitting configuralions. \Vhere area change. direclion change. divided tlo\\'. or uniled tlO\\' fittings olher Ihan lhose illuslrated her(' are s!1\lwn on lhe contraet drawings. are 11111 of proprielary manunlcture, and ar~ dcfin~d \\Lth friclion loss coellicienls in either lhe S\IACNJ\ lit :IC D/lct SnNII/ Dc-
sign manual or the ASHRAE Fundamentals Handbook chapter on duct design, such fittings shall be t~1bricated with materials. assembly techniques. and sealing provisions given here. Sl4
hardware and accessory items and select them to be consistent with the duct c1assification and services. S 1.8
Unless otherwise specified steel sheet and strip used for duct and connectors shall be G-60 coated galvanized steel of lockfonning grade confonning to ASTM A653 and A924 standards. Minimum yield strength for steel sheet and reinforcements is 30.000 psi (207 kPa).
S L9
Where sealing is required in Table 1-/ or in other tables or illustrations in this manual, it means the following:
EACH DLTT S'{STEM SHALL BE CONSTRUCTED FOR THE SPECIFIC DUCT PRESSURE CLASSIFICATIONS SHOWN ON THE CONTRACT DRAWINGS. WHERE NO PRESSURE CLASSES ARE SPECIFIED BY THE DESIGNER, THE 1" WATER GAGE (250 Pa) PRESSURE CLASS IS THE BASIS OF COMPLIANCE WITH THESE STANDARDS, REGARDLESS OF VELOCITY IN THE DUCT. EXCEPT WHEN THE DUCT IS VARIABLE VOLUME: ALL VARIABLE VOLUME DUCT UPSTREAM
a.
The use of adhesives. gaskets, tape systems, or combinations ofthese to close openings in the surface ofthe ductwork and field- erected plenums and casings through which air leakage would occur or the use of continuous welds.
b.
The prudent selection and application of sealing methods by fabricators and installers, giving due consideration to the designated pressure c1ass, pressure mode (positive or negative), chemical compatibility ofthe closure system, potential movement of mating parts. workmanship, amount and type of handling, cleanliness of surfaces, product shelf life, curing time, and manufacturer-identified exposure limitations.
c.
That these provisions apply to duct connections to equipment and to apparatus but are not for equipment and apparatus.
OF VAV BOXES HAS A 2" WG (500 Pa) BASIS OF COMPLIANCE WHEN THE DESIGNER DOES NOT GIVE A PRESSURE CLASS. Sl.5
No specification or illustration in this manual obliges a contractor to supply any volume control dampers, fire dampers, smoke dampers, or fittings that are not shown on contract drawings.
S 1.6
Where dimensions. sizes, and arrangements ofelements of duct assembly and support systems are not provided in these standards the contractor shall select configurations suitable for the service.
SI.7
The contractor shall follow the application recommendations of the manufacturer of all
1?
LJ\/A_
•.
-
All Transversc andStatic Pressure A/I Transverse joints,joints longitudinal Applicable Transverse joints 2"4" only wgwg(500 and Pa) up (1000 Pa) Sealing Requirements SEAL CLASS 3" \Vg (750 Pa) classConstruction that is upstream Class of the V A V boxes shall meet Seal Class C. and 'lí" wg (125 Pa) construction
Table 1-1 Standard d.
That where distinctions
Duct Sealing Requirements
are made bet\',:een
seams and joints, a seam is defined as joining of t\Vo longitudinally (in the direction of airflow) oriented edges of duct surface material occurring between two joints. Helical (spiral) lock seams are exempt from sealant requirements. AII other duct wall connections are
be underground
below the water table;
9.
be submerged in líquid;
10. withstand continulJus vibration visible to the naked eye; 11. be totally leakfree within an encapsulating vapor barrier; and
deemed to be joints. Joints include but are not Iimited to girthjoints, branch and subbranch intersections, so-called duct collar tap-ins, fitting subsections, louver and air terminal connections to ducts, access door and access panel frames and jambs, and duct, plenum, and casing abutments to building structures e.
8.
12. create c10sure in portions of the building structure used as ducts, such as ceiling plenums, shafts, or pressurized compartments;
Unless otherwise specified by the designer, that sealing requirements do not contain provisions to:
f.
The requírements to seal apply to both positive and negatíve pressure modes of operation
l.
resist chemical attack;
g.
2.
be dielectrically
3.
be waterprooC weatherproof, violet ray resistant;
ExtemalIy insulated ducts located outside of buildings shall be sealed before being insulated, as though they were inside. If air leak sites in ducts located outside ofbuildings are exposed to weather. they shall receive exterior duct sealant. An exterior duct sealant is de-
4.
isolated; or ultra-
withstand temperatures higher 120°F (48°C) or lower than
than 40°F
(4.rc): 5.
contain alomic radiation or scrvc in othcr safely-related
construction:
6.
be clcclrically
groundcd:
7.
maintain leakage inlegrity at prcssures in c.\ccss ofthcir duct c1assitication:
·.s.~_4' HVAC Air Duct Leakage Test Manual·
fined as a sealant that is marketed specificalIy as forming a positive air- and watertight sea!. bonding well to the metal involved, remaining flexible \Vith metal movement, and having a scrvice tcmperature range of -30°F (-34°C) to 175°F (79°C). Ifexposed to direct sunlight, it shall also be ultraviolet ray- and ozone-resistant or shall. after curing, be painted with a compatible coating that provides such resistance. The tenn sealant is not limited to adhesives or mastics but includes tapes and combinations of open-weave fabric or absorbent strips and mastics.
First Edition
1.3
1.5
DUCT SEALlNG
COMMENTARY
Ducts must be sufficiently airtight to ensure economical and quiet performance of the system. It must be recognized that airtightness in ducts cannot, and need not, be absolute (as it must be in a water piping system). Codes narmally require that ducts be reasonably airtighl. Concems far energy conservation, humidity control, space temperature control, room air movement, ventilation, maintenance, etc., necessitate regulating leakage by prescriptive measures in construction standards. Leakage is largely a function of static pressure and the amount of leakage in a system is significantly related to system size. Adequate airtightness can normally be ensured by a) selecting a static pressure construction class suitable for the operating condition, and b) sealing the ductwork properly.
The designer is responsible for determining the pressure class or c1asses required for duct construction and for evaluating the amount of sealing necessary to achieve system performance objectives. It is recomII1ended that al! duct constructed for the 1" (250 Pa) and W' (125 Pa) pressure class meet Seal Class C. However, because designers sometimes deem leakage in unsealed ducts not to have adverse effeets, the sealing ofal! duets in the 1" (250 Pa) and Yí" (125 Pa) pressure class is not required by this eonstruetion manual. Designers occasionally exempt the following from sealing requirements: small systems, residential oeeupaneies, duets loeated directly in the zones they serve, duets that have short runs from volume control boxes to diffusers, certain retum air ceiling plenum applieations, etc. When Seal Class C is to apply to all 1" (250 Pa) and Yí" (125 Pa) pressure class duet, the designer must require this in the project specification. The designer should review !he HVAC Air DI/e! Leakage Tes! Mal1l/al for estimated and practical leakage allowances.
Seven pressure classes exist (Y2"Wg [125 PaJ, 1" [250 PaJ, 2" [500 PaJ. 3" [750 PaJ. 4" [1000 PaJ, 6" [1500 Pa] and 10" [2500 Pan. Ifthe designer does not designate pressure class for duct construction on the contract drawings. the basis al' compliance \\'ith the SMACNA HVAC DI/cr COIlstrucrioll Stlllldard, is as follows: 2"wg [500 PaJ wg fÓr al! dllCts bet\\"Ccnthe slIpply fan and variable volume control boxes and ¡lIwg [250 PaJ for al! other dllctS ofany application.
Some sealants can ath'ersely atlect the release fllnction ofbreakaway connections to tire dampers: conslllt the dampcr manufacturer fÓr instal!ation restrictions.
1.4
1.5.1
Leakage Tests
There is no need to verify leakage control by field testing when adequate methods of assembly and sealing are used. Leakage tests are an added expense in system installation. It is not recommended that dllct systel1ls constructed to 3" (750 Pa) wg class or 10wer be tested because this is generally not cost effcctive. For duct systel1ls constructed to 4" (l 000 Pa) wg class and higher, the designer must detennine ifany justification for testing exists. If it does, the contract docul1lents must clearly designate the portions of the system(s) to be tested and the appropriate test methods. ASHRAE energy conservation standards series 90 text on leakage control generally requires tests only for pressures in excess of 3" (750 Pa). The H r:4 C A ir DI/e! Leakage Tes! Aful1l/al provides practical and detailed procedures for conducting leakage tests. Apparent differences ofabout delivery and sum of airflo\V nals do not necessarily mean leakage. Potential accuracy should be evaluated.
ten percent between fan measurements at temlipoor sealing and excess of flow measurements
Otherwise, open access doors, unmade conneetions, missing end caps, or other oversights contribute to such discrepancies. When air terminals are at great distances from fans (over 500 feet [l 52m n, more effective sealing is probably required to avoid diminished system performance. Schools, shopping centers, airports, and other buildings may use exposed ductwork. Selecting sealing systems for such ducts may involve more attention to the tinal appearance ofthe duct system than with ducts in concealed spaces. Certain types ofpaint may form reliable seals, particularly for small cracks and holes. F urther research and confimlatíon is needed in thís area. Longstanding industry acceptancc 01' so-ealled 10\\' pressllre duct systems withollt sealants may ha\e lctl sorne eontraetors (and designersl with líttlc ur no expericnce \\ith sealing. The contractor SllOlIld carefllll; sL'ieet cllllstrllction dctails consistent \\íth scaling rel) lIiremcnts. the di rcction 01' the a ir pressllrc. a nd fam iliar sealing methods. The cost ofrestoring systcrns not receí\'ing the reqllired sealing or not bcing properly sealcd C;lll greatly cxceed the modest cos! of a propcr applicatioll. Contractors lIsing slip amI dri\e conncction systerns mllst control conncc(or length and notch tkpth Otl rectangular dllet ends to t~lcilitate scaling.
HVAC Air Duct Leakage Test Manual·
First Edition
~-
-SMA~NA
Failure to do so wil] compromise seal etTectiveness. Round duct joints are nonnally easier to seal than other types. However, with proper attention to joint selection. Vlorkmanship, and sealant application, almost any joint can achieve low leakage. The mere presence al' sealant at a connectíon, however, does not ensure low leakage. Applying sealant in a spiral lockseam can result in pOOl' seam closure and Jcss satisfactory control. No single sealant is the best for all applications. Selecting the most appropriate sealant depends primarily on the basic joint design and on application conditions such as joint position. clearances, direction 01' air pressure in service, ete. The Jisting 01' eertain duet produets by reeognized test laboratories may be based on the use of a partieular joint sealing produet. Sueh a eomponent listing only refleets laboratory test performanee and does not neeessarily mean that the c\osure method ean routinely be sueeessful for the contraetor 01' that it will withstand in-serviee operation of the system on a long-term baSIS.
1.5.2
Liquids
Many manufaeturers produee liquid sealants speeifically for ducts. They have the consisteney of heavy syrup and ean be applied either by brush 01' with a cartridge gun or powered pump. Liquid sealants normally eontain 30 to 60 pereent volatile solvents: therefore, they shrink considerably when drying. They are reeommended tor sJip-type joints where the sealant fills a small spaee between the overlapping picees of metal. Where metal elearanees exeeed)!¡6 ineh ( 1.6 mm), several applieations may be neeessary to fill the voids eaused by shrinkage 01' runout 01' the sealant. These sealants are normally brushed on to round slip joints and pumped into rectangular slip joints.
1.5.3
Mastics
Heavy mastic sealants are more suitable as tíllets. in grooves. 01' between tlanges. Mastics must have excellent adhesion and elasticity. Although not marketed specilically for duct\Vark. high quality curtain wall sealanh have been uscd for this applíeation. Oilbasc caulking ami glazíng compounds ShOllld nO! be llsed.
here to the metal duringjoint assemb!y. The ehoiee 01' open cell 01' closed cell rubber gaskets depends on the amount and frequ~ney ofcompression tic memory.
1.5.5
Tapes
Nothing in this standard is intended to unconditionally prohibit the use of pressure scnsitive tapes. Several such closures are Jisted as components of systems complying with UL Standard 181 tests. There are no industry recognized perfonnanee standards that set forth peel adhesion. shear adhesion, tensi1e strength. temperature limits. aeeelerated aging. ete., which are quality control eharaeteristies speeifically eorrelated with metal duct construetion serviee. However. the Glass Duct COllstruCtiOIl 5101/SMACNA FihroliS dan!s illustrate the elosure of a fibrous duct to metal duct with a tape system. The variety of advertised produets is very broad. Some test results for tapes are published in the product direetories of the Pressure Sensitive Tape Council located in Chicago. IL. The shelf life of tapes may be difficult to identif).'. It may be only six months or one year. Although initial adhesion may appear satisfactory, the aging eharacteristies of these tapes in serviee is questionable. They tend to lose adhesion progressively at edges or from exposures to air pressure. flexure, the drying effects at the holes or eracks being sealed, ete. The tape's adhesi\'p may be ehemically incompatible with the substrate, as is apparently the ease with certain non metal flexible ducts. Application over uncured sealant may ha ve failures related to the release ofvolatile solvents. Sea air may have ditTerent etlects on mbber. acrylic. silicone-based (or other) adhesives. Tapes of a gum-like consistency with one 01' t\\"(l removable waxed liners have become popular 1'01' some applications. They are generally known as the peel and seal variety and have been used betwecn tlangcs and on the exterior 01' ducts. Such tapes are typically 01' thicknesses sC\'eral times that of tapes traditionally known as the pressure sensitive type. Some may have mesh reinfon:ement. Others may have metal 01' nonmetal baekíng \1fl oné surface.
1.5.6 1.5.4
and ..on the elas-
Heat Applied Materials
Gaskets
Durable matcrials sllch as soft elastolllcr blltvl
01'
cx-
trudcd forms of sealants should be used in t1angéd joínts. For case of applicatíon. gaskets ShOllld have adhesi\'c backing 01' otherwise be tacky cnollgh to ad-
llo! mel! and thermally activaled scalants are Icss \\'idely knO\\"Ilhut are used rÓr duct\\ork. Thc hot mclt !ypc ís nOllllally a shop applíeatíon. Thcrmally aetí\ated typcs use heal [O éilher shrink-lít CIOSllrL'Sor 10 cxpand comp\lunds \\ithin joint systems.
~••J"'r.II", H\f~r ~ir nuct Leakaae Tli!stManual· First Edition
1.5
1.5.7
Mastic and Embedded Fabric
There are several eombinations of woven fabries (fibrous glass mesh, gauze, eanvas, ete.) and sealing eompounds (ineluding lagging adhesive) that appear better suited for ereating and maintaining effeetive seals than sealant alone. Glass fabrie and Mastie
more. SMACNA is not able to comprehensively define their eharaeteristies at this time; however, authorities are eneouraged 10 monitor their development progress and consider their use.
1.5.10 Shelf Life
(GFM) used for fibrous glass duet appears to adhere \Vell to galvanized steel.
The shelf life of al! sealant products may be one year or less; often it is only six months. The installer is eautioned to verify that the shelflife has not been exceed-
1.5.8
ed.
Surface Preparation
Surfaees to reeeive sealant should be clean, meaning free from oil, dust, dirt, rust, moisture, iee erystals, and other substanees that inhibit or prevent bonding. Solvent cleaning is an additional cxpense. Surfaee primers are now available, but their additional cost may not result in measurable long-tem1 benefits.
1.5.9
Sealant Strength
No sealant system is recognized as a substitute for mechanical attaehments. Structural grade adhesive systems are being developed to replace spot welded and soldered connections of metals. They have lap shear strengths of 1000 to 5000 psi (6895 to 34475 kPa) or Reprintedfrompages
.h
1.5.11 Safety Considerations Sealant systems may be flammable in the wet, partialIy cured, or eured state. USE LlQUIDS AND MASTICS IN WELL VENTILATED AREAS AND OBSERVE PRINTED PRECAUTIONS OF MANUFACTURERS. The contractor should earefully consider the effects of loss of seal and fire potential when welding on or near sealed connections. NFPA Standard 90A requires adhesives to have a flame spread rating not over 25 and a smoke developed rating not over 50.
1.8 - 1.11 SMACNA HVAC Duct Constnictiol7 Srandards - lnd Ed.. 1995
...",/\("' I\ir
n.."".1 •..••..•1..•.•..•._ •...•T ...........•.• ,,-
---
S31J.1118ISNOdS3~
l NOI!~3S
SECTION 2
,
The duct system designer should: a.
Match the fan to the system pressurc losses.
b.
Designatc the pressure class or classes for constmctíon of cach duct system, as appropriate and cost effective, and clearly identi fy these inlhe contra el dOClIIllenl.
c.
d.
•1
e.
Evaluate the leakage potential for ducts conforming to SMACNA or other standard s and supplement the requirements therein \Vith deletions and additions as may be pmdent and economical, giving due attention to the location ofthe ducts, the type of service, the equipment, dampers and accessories in the system, the tolerances on air balance and the performance objectives. He must account for leakage in equipment such as fans, coils, volume regulating boxes, etc., independently of duct leakage. Prudently specify the amount and manner of leakage testing (iftesting is deemed justified) and clearly indicate the acceptance criteria. Reconcile all significant inconsistencies between his performance specifications and his prescription specifications before releasing contract documents for construction.
f.
Avoid ambiguity created by references to non-specific editions of SMACNA or other documents he has specified.
g.
Have his contract documents reflect a clear scope of work known by hím to conform to applicable codes and regulations, including those addressing energy conservatíon.
RESPONSIBILlTIES h.
Require adequate submittals and recordkeeping to insurc that \York in progress confonl1s to the contract documcnts in a timely manner.
2.2 The ductwork installer should: a.
Comply \Vith the contract documcnts.
b.
Provide all required preconstnlction ter-installation submittals.
c.
Report discovery of conflicts ties, etc., in a timely manner.
d.
Schedule any required leakage tests in a timely manner, with appropriate notice to authoritieso
e.
Seal duct where and as specified.
f.
Examine the leakage criteria, the specified duct construction classes, and the testing and balancing specifications for consistency!
g.
Select duct constmction options and sealing methods that are appropriate and compatible, giving due consideration to the size of the system.
h.
Control workmanship.
!.
Acquire ture and ods and pecially inherent
J.
Demonstrate that following prescnptlve measures for constmction precludes the need for leak testing .
and af-
and ambigui-
inLfeased understanding of the naamount of leakage and of the methcosts of sealing and leak testing. esthe amount of preparation time in demonstrating a successful test.
S3~na3~O~dlV~3N3~ ENOI.l~3S
SECTION 3
, ~
GENERALPROCEDURES
3.1 Conventional ]eak testing is based on pOSltlve pressure mode analysis. It involves inserting temporary plugs (plates, sheets, balloons, bags, etc.) in openings in a section of duct and connecting a blower and a flowmeter lO the specimen in such a manner that pressurizing the specimen will cause all air escaping from the specimen to pass through the flowmeter.
3.9 Remove temporary blanks and seals. 3.10 Precautions a.
Verify that an adequate and matched electric power source is available for the test apparatus.
b.
Detennine that the capacity of the test apparatus is suitable for the amount of duct to be tested.
c.
Consider acquiring experience with leakage rates in the type of construction used before formaIly conducting field tests. This is especially advisable ifthe contractor has little experience with testing, is attempting to meet allowable rates much lower than normal, is including equipment in the test or is dealing with unfamiliar duct construction.
d.
Isolate equipment (fans, in-line flanged coils, volume regulating boxes, etc.) from tested ductwork. The system designer should ha ve independently accounted for leakage in equipment.
e.
Anticipate difficulty with any test of ductwork that has no prescription for sealing yet is required to meet an allowable leakage level.
f.
Do not overpressurize sure control or pressure behavior is unfamiliar; tus with flow restricted up pressure.
g.
Do not test uncured seals.
h.
Prepare carefuIly when testing in cold weather. Lo\\' temperature influences the effectiveness of sealants and gaskets.
1.
Instruct installers to use special care when assembIíng ducts that will be relatively inaccessible for repair.
J.
Condllct reqllired tests before externa] inslllation is applied and before ducts are conccaled by building enclosures.
k.
Do not overlook doors.
L
Do not leave test apparatlls unattended.
3.2 Select a test pressure not in excess of the pressure class rating of the duct. 3.3 Calculate the allowable or allocated leakage using leakage factors related to the duct surface area. 3.4 Select a limited
section
of duct for which the
estimated leakage will not exceed the capacity of the test apparatus. 3.5 Connect
the blower and flowmeter
section and provide temporary ends of the ductwork.
to the duct
seals at all open
3.6 To prevent overpressurizing ofthe ducts, start the blower with the variable inlet damper closed. Controlling pressure carefully, pressurize the duct section to the required level. 3.7 Read the flowmeter and compare the leakage in cfm per square foot with the allowable rate determined in step 3.3. If it meets the allowable rate proceed to step 3.8. If it does not meet the allowable rate follow steps 3.7a through 3.7c. a.
b.
,
c.
Inspect the pressurized duct (and all connections between the flowmeter and the duct) for all sensible leaks. A smoke bomb test may be used to identify actual leak sources. Ifnecessary apply a soap solution to locate small leaks. Depressurize: repair all audible and other significant leaks. Ifthe first pressurization failed to deveIop the required test pressure level and significant leak sites were not discovered, consider the foIlowing alternatives: Divide the specimen being tested into smaller segments or use larger test apparatus. Allow repaired seals to cure and retest until the leakage rate is acceptable.
3.8 Comnlete
test renorts
ano
ir reollirf'd
oht'lin
J1'fniJ"~
ducts. Provide presrelief iftest apparatus e.g., start test apparaand gradually build
leakage potential
n~¡ni,... h" ;nf~rn"'~nn
r'It.¡•••..••11 •.•••"' •.•••h·
at access
•..••.•••,1
h...,
3.2
n.
Avoid excessíve blanking, consistent with industry practíce, by testing prior to insta] lation of collars for room air terminals.
o.
Take testing seriously; work sequence, work duration and costs can be significantly affected.
)
11'
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,)
)
,
11'
)
-i
>
J
-i
')
:
,¡,
,)
n
J
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n
H
_
1[
llJ
DO NOT OVERPRESSURIZE
WARNING:
CONVENIENT PLACE BLANK OFF AT~
(TYPICAL)
TEMPORARY CAP S
"'
THE DUCT
DUCT TEST PRESSURE MANOMETER
H II
I •• Ir
MANOMETER
TEMPORARY CAPS SEALED SECURELY
ORIFICE DIFFERENTIAL
~í 11 II1
le·
AVOID LEAKS IN DUCTING FROM ORIFICE TO TEST DUCT.
I ',e
NOI.L"~I=lISS"l~ 3~")I"31 P NOI.l~3S
,
SECTION 4
~
4.1 Leakage classification identifies a pennissible leakage rate in cl'm per 100 square feet ol' duct surl'ace according to the relationship Cl = F .;(p)065 as defined in section 1.3.
·w'
F is the leakage rate in cfmJl 00 s.f. of duct surface (It varies with static pressure). Pis the static pressure. Values for (P) 0.65 are given in Appendix E. When P = 1, Cl = F. Cl is the leakage c1ass and is a constant. 4.2 Leakage classifications 3, 6, 12, 24 and 48 are shown in Figure 1 for pressures up to 10" wg They are associated with duct type, seal c1asses, and construction pressure cIasses in Table 4-1. Table 4-1 is the basis of evaluating duct confonning to the SMACNA duct construction standards unless a specifier gives other limits. 4.3 If, at the specified test pressure, the leakage factor (F), by test, is lower than or equal to that associated with the specified leakagt; class, the duct is in compliance. Alternatively, ifthe leakage constant (Cd detennined fram tests is lower than or equal to the speeified leakage class, the duet is in compliance. 4.4 Assignment of leakage cIasses involves careful consideration of system size, duct location, sealing and construction class. Arbitrary assignment of an al!owable % of leakage in disregard of these factors can indicate unobtainable results. A Y2% alIowance, for example, on a 3900 cfm system with 1300 s.f. of duct or on a 39,000 cfm system with 13,000 s.f. of duct would mean an unrealistic leakage factor of 1.5 cl'mllOO s.f. in each case. Similarly, arbitrary assignment of 10" wg c1ass construction for a system operating at 1" wg in order to get leak class
,
LEAKAGE CLASSIFICATION 3 rectangular duct would not be cost efTective. Assigning a leakage c1ass3 to a 1" wg rectangular duct system may address an achievable result but the associated difficulty and costs wiII be excessive. Table 4-1 represents the leakage expected using Seal Classes A, B, and C as indicated on duct construction of the types typically selected for each pressure class. Conceivably Seal Class B or A could be applied at construction pressure c1asses lower than indicated in Table 4-1. However, unless joint type, seam type, duct wal! thickness and specific sealing method were already colIectively prequalified by tests (or by an aeceptable expenenee record at a higher pressure) leakage rate is less predictable. The benefits of setting alIowable leakage rates lower than shown in Table 4-1 should be carefully weighed against the costs of achieving them. 4.5 A sample leakage cIassification analysis is given in Appendix B. 4.6 No leakage tests are required by the SMACNA duct construction standards or by this leakage test manual. When the designer has only required leakage tests to be condueted in accordance with the SMACNA HVAC Air Duct Leakage Test Manual for verification that the leakage cIassifieations in Table 1 have been met (and has given no other criteria and scope), he is deemed to have not fulfilled the responsibilities outlined in section 2.1 for praviding a clear scope of work. When duct construction pressure cJasses are not identi fied in the contraet drawings and the amount of leakage testing is not set forth in the contract documents, any implied obligation ofthe instalIer to fulfil! the responsibilities under section 2.2 in regard to leakage are deemed to be waived by defective specification.
100
90 80 70 60 50
40
u: 30 Oen
O
O
..-
Ci
c..
20
~ u..
U
Ctl
O) •...
LL
o
O .lIl: Q) LL ....J Ctl
Q)
10 86759 4
3. ~,.
~~'
pO.55
0.1
0.2
0.3
OA
0.5 06 0.7
091.0
2.0
3.0
4.0
50 6.0
7.0
90
Pressure in Inches 01 Water
SEETABLE
4-1 FOR ASSOCIATED
~==APPENDIX
DUCT CONSTRUCTION
CLASS
E FOR TABULAR FORM OF FIGURE 4-1
FIGURE 4-1 DUCT LEAKAGE CLASSIFICATION
4.2
~
~--'-~----'
I
.d
OUCT CLASS METAL JOINTS, SEAMS
B 6 PENETRATIONS ]2 JOINTS A ONLY 243" 3]2 TRANSVERSE JOINTS TRANSVERSE ANO ALL ANO SEAMS Cwg 4".6",10" wg )1;, ", ]", 2"WALL wg
Table 4-1 Applicable Leakage Classes NOTES:
].
..,
3.
4.
Leakage classes in Table 4-1 apply when the designer does not designate other Iimits and has specified Sea] Class C for)l;,1I and 1" wg See text on sealing in the HVAC-DCS manual.
Unsealed rectangular Leakage Class 48.
metal duct may follo\V
Fibrous glass duct may folIow Leakage Class 6 (at 2" wg or less). Unsealed flexible duct leakage average is estimated 10 be Class 30. Sealed nonmetal flexible duct is an average ofClass
5.
6.
12.
7.
Leakage C]ass (Cd is defined as being the leakage rate (cfmlIOO s.f.) divided by pO.65 where P is the static pressure (in wg). When P is numerically equal to 1" the leakage rate is CL. See Figure 4-1.
8.
The duct pressure c1assification is not the fan sta tic pressure nor the external static pressure (on an HVAC unit) unless the system designer has made such an assignment is his contract documents. Unless construction class is otherwise specified it means a static prcssure c1assification in the SMACNA HVAC-DCS. Those classifications pertain to maximum operating pressure in the duct as follows: 0.5" wg maximum 0.6" to 2" wg maximum
See SMACNA HIAC Duct Systems Design
1.1" to 2" wg maximum
Manual Table 5-1 for longitudinal age rates.
2. 1" to 3" wg maximum
Although for lower conform pressure. results.
seam leak-
Seal Class A or B might be assigned pressures. the leakage c1ass may not to those associated with the higher Otherconstruction details influence
3.1" to 4" wg maximlll11 4.1" to 6" wg l11aximum 6.1" to 10" wg maXil1111111
snJ.Vl:IVddV J.S3J.
s NOI.L:>3S
--
,
SECTION 5
TEST APPARATUS
5.1 Test apparatus shal1 consist of an airflow measuring device, flow producing unit, pressure indicating devices and accessories necessary to connect the metering systcm to the test specimen. 5.2 Thc contractor conducting tests shall arrange for or provide al1 temporary services, al! test apparatus, all temporary scals and all qualified personnel necessary to conduct the specified testing.
5.8 Taps for st3tic pressure indication across orifices shall be made with Y\6" to Ya diameter hoJes 11
drilled neatly in the meter tu be wal!. The interior ofthe tube shall be smooth and free of projections at the dril!ed holes. 5.9 Pressure differential sensing instruments shall be readabJe to 0.05" scale division for now rates below 10 cfm or belO\v 0.5" wg di fterential. For higher flow scale divisions of 0.1" are appropriate. U-tube manometers should not be used for readings Iess than J of water. 11
5.3 Test apparatus shal1 be accurate \vithin plus or minus 7.5% at the indicated flow rate and test pressure and shall ha ve calibration data or a certificate signifying manufacture ofthe meter in conformance with the ASME Requirements for F1uid Meters. ASME qualified orifice meters do not require calibration. 5.4 Unless otherwise specified, test apparatus shall be used asoutlined in this section, as described in Section 3 and as recommended for good practice.
5.10 Liquid for manometers shall have a specific gravity of I (as water) unless the scale is calibrated to read in inches of water contingent on use of a liquid of another specific gravity, in which case the associated gage fluid must be used. 5. J 1 The duct test pressure shall be sensed only from an opening in the duct. 5.12 The illustration
5.5 Typical construction and use of orifice meters is indicated in Figures 5-1 and 5-2. TypicaI orífice selections are shown in Figure 5-3. 5.6 The use offlow nozzles, venturi meters, laminar flow meters, rotameters, Pitot tube meters or other meters having equivalent accuracy and suitability is not prohibited by the references herein to orifice meters. 5.7 The
recommended
mlnlmum
thicknesses
larger diameters. Steel or stainless steel plate material is preferable. Plates shall be flat and have holes with square edges (90°) that are free of burrs. Orifice openings shall be centered in the meter tube. Plates shal1 be perpendicular to the tlow path and shall be free of leaks at points of attachment.
•
0.50 0.36 0.60 0.70 0.490 0.52 0.623 0.600 0.608 0.699 0.88 0.73 0.63 0.82 O.()C)O OAO 0.250 0.160 0.650 0.30
use of it on the
5.13 Instruments must be adjusted before pressure is applied.
to zero reading
5.14 Airflow across a sharp edge orifice with standard air density of .075 Ib/ft3 is calculated from
_Equation 5-1 Q = 2L8K(D2r /¿jp
for
ori fice plates in tubes of various diameters are Y\6" to 6" diameter, 3/32" to 12" diameter and Ya" for
D:>/D1
of the flowmeter on test blower
discharge does not precIude suction side.
Where Q = air volume. cfm K = coefficient
of airflo\V from Table 5-1 or
Appendix J 0= orifice diameter, inches (02) OP= Pressure drop across orifice. inches wg
/
BLOWER WITH INLET OAMPER. BYPASS OAMPER OR VARIABLE SPEEO CONTROL
TESTE O OUCT
l- 401+ MIN. 201+ 401--1 J
I
1
----
01
OUCT TEST PRESSURE MANOMETER
_
'"
\
Xs" HOLE
lF
lI"
0.0.
------
G
/
FLOW STRAIGHTENER VANESORPERFORATEO PLATE ORIFICE PRESSURE OIFFERENTIAL MANOMETER
INCLlNEO MANOMETER (REQUIREO FOR ORIFICE OIFFERENTIAL BELOW 1" WG)
TUBE
1~" LONG
STATIC PRESSURE TAP ATORIFICE
NOTE: MANOMETERS MUST BE LEVELEO ANO ADJUSTEO TO ZERO BEFORE UNE PRESSURE IS IMPOSEO.
1
01
FLOW
! 1" LOCATION USE
3132"
OR
Ya 11
1"
OF FLANGE
(PIPE) TAPS
STEEL SQUARE EOGE ORIFICE PLATE
FIGURE 5-1 LEAKAGE TEST METER APPARATUS-FLANGE
5.2
TAPS
.
/
BLOWER WITH INLET OAMPER, BYPASS OAMPER OR VARIABLE SPEEO CONTROL
TESTEO OUCT
/
- 4Qt 20¡-/- 40,MIN.
1
~-........
O,
CB
\ OUCT TEST PRESSURE MANOMETER
FLOW STRAIGHTENER VANES OR PERFORATEO
-------
\
x," HOLE
'r: U"
STATIC PRESSURE ATORIFICE
N
ORIFICE PRESSURE OIFFERENTIAL MANOMETER
PLATE
INCUNEO MANOMETER (REQUIREO FOR ORIFICE OIFFERENTIAL BELOW 1" WG)
l\" 0.0. TUBE 1 ¡;;" LONG
TAP NOTE: MANOMETERS MUST BE LEVELEO ANO AOJUSTEO TO ZERO BEFORE UNE PRESSURE IS IMPOSEO. D2 0.3 0.7 0.6 0.8 0.4 0.5 f
FLOW
O2
O,
0.2
O, J
/-x-i /=.-0,~1 LOCATION OF VENA CONTRACTA TAPS USE
3h2"
OR
Ya"
X
0.36 D, 0.66 0.60 0.45 D, 0.74 0.53 0.71
STEEL SQUARE EDGE ORIFICE PLATE
FIGURE 5-2 LEAKAGE TEST METER APPARATUSVENA CONTRACTA TAPS
The ralio
01' orifice
diameler O2 lo meter lube interior
diameler 01 is known as lhe Bela (1)). or diameler r~llio. It is nonnally selecledin lhe range 01'0.710 0.3. The orifice-lo-lube area ralio (.'\2/A,) i::; an indication 01' lhe conlraclion of tlow. Kp in Table 5-1 is the overall prc::;::;ureloss lhal occurs from conlraL'ling ami cxpanJing lhe 110\\. Thus. lhe oritice cause::; a Kp x i'lP loss that atreclS blo\\'er capacily. 5.15
Select a tlmvmetcrsuilablc dllCl to be tesled: a.
b.
tClr1he Icakage inlhe
Using the target leakagc rale (cfmlOO s.r) for the desired amount 01' tcsted duct tind lhe cfm rcqllired. Al this cfin the blo\\-er \ViII ha\'c to produce a pressure approximatel.y cqual to the Slll11ofthe dUCl test pressure and lhe oritice ditlÚential pressure. Add 0.5" wg ir 02iO¡ is less than 0.5. This assumes that there are no extraordinary pressure losses in the lest meter and duct connecting it to lhe lest specimen. Selcct the meler trom Figure 5-3 or use Table and Equation 1 10 size a meter that \Vi11 have a tlo\\' curve of the desired range and
slill be wilhin the capacily 01' the blower. Characlerislics 01' lypical ori tices are shown in Table 5-2. 5.16 Precaulions
10
be followed for test apparallls:
a.
Start the bltmer wilh blocked suclion or discharg:c 10 a\oid o\'erprcssurizing: duclwork.
b.
Use clean manometers.
c.
Heal manometers cold \Veather.
d.
11'
manometer
to avoid ti'eezing tluid in
tlllid is blo\Vn out: retill wilh
the appropriate tluid: tor convenience add a drop ofwaler soluble dye to \Vater-tilled manometers. e.
Level position sensilive instnnnents them to zero scale reading.
and set
f.
Read liquid le\'els by viewing them horizonlally.
g.
Record instruments
5-1
5.4 ~------~~~~~~~~~~~~~~~
HVAC Air Duct Leaka~e Test Manual·
First
used for testing.
Fc-litinn
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1.0"
2.0"
3.0" 4.0"
6.0"
Orifice Differential
FIGURE 5-3 TYPICAL ORIFICE FLOW CURVES
• ---o., __,_ ..__ , •. __
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10.0" wg
,,';~~
='.10 -~;(J lA" -1/"7 .:;..;": l} ,"' l,l}fl -L,ll -lXll ...• in. .32.70 XII :;¡" w~ 1}--l9 lA" 51029 "'¡O;.(I -1.00 10).9 10-1.7 lfJó.1 JÓS.X 17.~.; 15X.7 .: 1'1:\ -+--i_._ 31 70;-:' .../.7.6 2X.9 .11.0 -l..J.S J6.6 lP-f¡.; -l9.f1 -:-;-;1 -::(1 ,'\1)(1 91"': l)91) ---10 In.:;: I..j..~ l¡q:-; ~5.2 h""i :'-U 11.9 5:-.': ¡.-J5 76.2 :-io ':;2\} 5~ 76.h 77.0 :y5 -1.20 ¡.6 ...•. 00 .." '!.00 6.~It 3-1 x"~ 7~ XIl.7 'ti ." 1---12.0 2-JA -W.tJ 166.0 100.0 37.5 ,3.1 :-':.-f0 2.11.1 J075) t(J2."~ 26;'.7 IIIIA 107,1 209.9 261.1 17 :.':Xfl.S ló'-.~ ISO.: 110.1.) 116.1 2--l:-;.2 25---1.7 1-J7.x .276.---1 1;-.;3.0 2x:-'} 110.2 11 15n.O IOX.6 116.X 100.9 176.1 2~l'.X 2---1h.5 jIS~.J ¡'1t,2 2'::J.lJ Iq"'¡IJ 1;.;; Il)I.<J ---IMdl .,0.7 0191 "'¡--+S.2 ---Ió;'\.y -l¡ OX3.1 Úl}l). (~2~.6 .~IU 2~.7 21}.2 Y2.X 5~"¡.3 ó-lqh 679.1.) -I-lK .15.5 -'08 .116 71:->.2 5l0.X 29 -1.2' (l""7()(1 7:'-.':33.0 -1---1.0 34.2 35.-1 ':Y.6 -lh ---IS.3 ..•2.5 1l¡79 111<)-l5.5 :. 7-H) ¡llnl ]Ilq¡ 11251!..' I1 llll'} 1121 1100 '-';,(J t}u! "h::'. :-\~--l 3-JI.ó xTi :\I..¡ s:'i-l -l00. X4(1 l)~--l 997 36X.0 <'2.X 90.ó (}I.:.': 1';0\.1 t;1.0 64.0 1t)t).6 6(',":' 6,.1 5-:-/1 h:'.l IfJlJ.6 5:-'.;0\ 6"'JJ h.'.h 66.1 70.lJ 72.2 61./1 6:'.h 7LX 75.3 79.1 x...: h-.f..h 7s.1 :9.9 ":'<1 71.'¡ 2"7.:-; 2X.O 2s.2 [0.00 1.7 26.5 27.'XI.I -l,:,11 ;-;óo 1.50 --1.6/1 .'\.9{t 9.111 1I.f'll1 lJ.;(J -I.-ltl lf.20 ...¡q/l ·UlI ó.---IlI t. 6.1)0 5.(}11 7.00 .'\.XO 7.20 ;0.;.1\0 J.II ).60 {j.~ .l.~ ..'; 1.46 I.-H) loX :1.--l1l 1.66 1.72 ,.;0 ...• :(1 ..' -'6.1 1I ~tl 70.1 -U.;¡u -JII.I 111:' 5{).lJ 7X.X -l6.lJ 01.7 óM.9 109.2 19.5 2:-;.) 132.9 25115 10--J.2 X3.2 S.IO ~.9()" 2.625" 26---1.2 271.1) 2X'::~ 2x3.h 2ó5.~ 111.) 2515 256.-l 2.'2.x 2,." 103.1 lO:'.:' 1f]!ll.J.-l 12<,).7 2fo;\.~ ":7(J.:J 127.S 120.:125.8 27..J\} ~o2."'¡ 210,--+ 212 112A 1/7.5 11 ~3(\ 1:' 12---1A 2---l--l.lJ 129.1 J26; IÓJ.S 1.21.0 139.0 21(1 22-.0 23--l.ó 150.n 171.3 ':(lfl.~ 1119 11-1.6 '::'::0.0 .: 22':;:t, 229.2 11<J.6 2.~S.1 1:':'.0 2---1IA .":rl-l.-l 2~ 06.'.1 ---lXS.'7 --177.5 --+N'.2 30.6 -+l}·L::' 502.-1 óOh.4 -l9.7 6:->9.[ .J1.'f, -l"'q:'0.9 .¡7"'.: 505.0 617.9 21).S -126.:.~(LI .'-l.'':.\) -':'.0 ~2.ó -lS5.Q ---1-1.)1.5 35.2 25.1 26.--l 5--J.:\.tI 5tJ5.i t\."tl -'3.M 32.2 .. -I211.1 32.0 33.2510.0 1017 51X.2 5ÓO.S 03.3 53.3 52.~---+ 30.5 .'-tJ) --;')) 1tI0J HIlO 1.1.2 393 lO;";.':; 3x.--J. 772 1067 11I:3 !SI/.! :-;22 95ó 11.-:;':"; 11'2 Xt}2 2.~.:-\ lJ21 9..1.2 970 S.'K V) 213.0 96.' 3L!.J ¡';()I.J lJ2S 67.6 2X4.S _~-l5.5 39h.l} 374.3 3~2.9 270.0 275.0 -'60.7 375.7 320.9 ó6.~ 65.1 ."X6.4 lJ6.; 2---1X.X ~(I.(I .n2.1 .N.'.--+ Y5.5 1);'\.lJ lJ3.7 :\6.2 161.27~.7 (•...• 72A 11.)2.0 hl.~ 6X.1 75.8 ó9.() 76.9 S2.2 ~-I.2 79.1 6<J5 59 7~.<j 177.6 60.1 7J..1 7.1.6 7X.O 71.3 óh.ó 7.~.ó 75./ 5.i".1 74.0 78.3 X.2 2(dl 9.'\.3 70.--1 27.0 26.3 26.;-; 27.5 1:'5 ..liu IX h4 950 ó.20 x23.3 X.J/j 25.X lJ.--lO 7.XO s.OO lJ.30 ti50 5.30 ).)0 h.IO n.SO 7.70 7.90 6.{I(J h.hO 5./0 ~.llfl 5.20 721.2 2-1.1 :\.;1) 18.~ 1.11 1.2(1 120 .." 13.00 ..' 2.~{1 '-3h IA2 1.00 1.:':-1 .3 2.00 2.t)f1 .'.10 1.5-l O 1.60 1.70 1.76 J.XP ."'P}{l I.X6 I.MO 1.9~ O '-SS 1.8M ..¡ I.XO 1.7:-: 1.52 .20 .10 O ..~ ...": ~-! 2S(1.:' 2!lU--l 2-f.7 119.2 9.9 IIX.9 -'6.5 .J9<J.7 "¡l)h.<J .5L~.(} .1.1.6 3'5.7 11136 361.0 977 7.60 5.-111 l~l.7---i L62 11.50 .X.2. .5ó 1"'¡.2.S .16..1 2~ 1.6 2X:'. 132Jl 2.5---1.3 1.22 :·<~t>.2 572.tl 3375 23.6 2Ir,'\.:' 115A -l572 h:'l}.l} :.-:;'(\.6 515.6 "'¡.'h.ll 507.7 I02J 2~í).6 298.9 316.7 -'07.9 :NO.O 2llJA -'03.~ IX5.2 2.2A 20.6 7.00 X.50 25.5 18.5 3.2/1 3.511 2u~(J 2.625" .277.;-; 127.1 12:\.1 2.../.3.2 253.1 25-=-.1} 136 .:: 2.615" -l:'í -tIlU 3---1-A --+1",1' 3.1.0 35.0 )5.9 lOS:' ~25.ó 325 294.3 2-U.2 2M.9 3.135 349..4 357.2 j1:'2.3 2XO,O 1~15 ~7.2 X9.1 91.~ ÓS.5 ~O.2 XX.I 20.9 22.1 S.2 21.R ~;.Y 25.0 7.10 ~.90" 20.2 215 2"'1..7 ....2 1.3 "..1(1 I.2X :'.-lO 250 2.hO 1..'2 2.XO 1.6X 1.90 :-UlI 1.% lA" ..2 128A 206.5 329.3 81.2 353.3 ·l-;;;--+.3 237,:' 254.6 23.0 1.92 1.9ó 1.2.3.X in_ \ole J
.:;.:;. ;o.;tJl.) f..t ..
~
.:;;;ó2A 26.2 óJ.l 22.X .~2.1 .'!JI :;-l.ó 1 X.7 OX.X ..;7.0 63.X 29..~ OJJ .'~2 -15.2 );'.7 5X.:' 54.; 52.1 -t1.3 50.5 5ó.:-; OrificeSize
Orifin' llP llPSizt' Orifi<-·•.•SiJ:t'
)7.1
Table 5-2 Orifice Flow Rate (SCFM) Versus Pressure Differential (In. of Water) Ba,ed on T' Díall1eler Tube "'¡lh Flange (pipl" Tal" thl' rabie gi\·l'S ctl11 ti,) tht..' llcarcst 0.1_ tc~t rerort,:, shplIlJ list nllIllocrs denoló aír "1 'I"nd~"d eLlnJílioll' llj"70 F and 11.07' lb cf dc'lbIl\.
AhhlHlgh
SCF\l
RcrrinlCtl frolll I"dffs/rio!
5.6
1t·llli/u/iol!
hy the .:\mericlIl
(·on
t"'t.'ft.'JlL·C
rplltHied
pf (j{l\·(Tnnh.'lltd
tll {he th..·~!n.'stcfm.
:\cclIraL"Y tp {he IlearL'sl (l.! ¡s: nnt illlrJied.
Ilygienists:.
HVAC Air Duct leakaqe Test Manual • Fir~t Frlitinn
S.l~Od31::1.lS3.l
9 NOI1.~3S
SECTION 6
TEST REPORTS
6.1 When leakage tests are required, preparation lhese should include the folIowing: requirements
1'or
should not exceed the allowable. even though the amount in one or more segments may some\\hat exceed the cfm alIowable indieated 1'or eaeh
lor
segment. In such case, to compensate, another segment would have to be tighterthan required.lf the duct is not in compliance rekr to seetion 3.7 01' the general procedures. 6.4 A suggested test summary report !
a.
Review ofthe speeifícation testing.
b.
Understanding
c.
Review ofthe general procedures outlined in seetion 3.
d.
Familiarity with the leakage analysis in section 5.
e.
Test scheduling.
of the aeceptanee
criteria.
c1assifícation
6.5 Procedure for completing f.
a reporl.
Test apparatus acquisition. a.
Log the project data.
b.
Enter the fan cfm (Q), the tesl pressure (PT), and the leakage c1ass (CL> specitied by the designer.
c.
Enter an identification [or each duct segment to be tested. Compute and enter the eorresponding area of duct surfan; arca excluding any equipment connected in-line.
d.
Look up the alIowable Ieakage factor (F) from Figure 4-1 or Appendix E. Enter this number on the report for each test segment. (This value can also be computed as F =- Cl x pO.65).
e.
Calculate the allowable leakage for each test segment by multiplying thc surface arca by the leakage factor, then dividing by 100.
f. 6.3 Verilication of compliance consists 01' testing sections of duct at the specified pressure level, finding the leakage in cfm and comparing this \\'ith the alIowable amount associated with the
Conduct and record the field tests. Iflhe sum of the cfm measured is less than or equal lo the sum of the allowable Icakage lhe lesl is passed. Record the date(s). pn:sence of witnesses and fiow meter char;lclcristics.
leakage c1ass. When several separate segments \\"ithin the same system and pressure class are tested for eOl11pliance. the aggregate leakage
6.6 Test reports shall be submitted as rClfuired by the project doeuments.
g.
h.
Delivery of notices to concerned witnesses. Preliminary
parties and
data entry on report fornls.
6.2 When the designer has adequately analyzed the systems and clearly specifíed the test parameters the reporting procedure is relatively simple. As discussed in previous sections the following requirements should be c1early specified: Test Pressure (equivalent to the duct construction sure c1ass is suggested).
pres-
Leakage Class (c1ass selected from Table 4.1). Amount of system to be tested ( 10%, 20%, 50%, all). 1f the test pressure or leakage c1ass has not been provided. see Appendix e and section 2.
and systcll1 idcntifiealion
\
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_
PROJECT NO.
****
_
f'IELD TEST DATA RECORD
DUCT CONSTRUCTION
PRESSURE
SPECIFIED TEST PRESSURE (Pt)
LEAKAGE CLASS
AIR DUCT LEAKAGE TEST SUMMARY
***** **** **** ***** **** FACTOR PERFORMED DATA DATE DIAMETERACROSS BY CFM ORIFICE PRESSURE" DUCT TUBE BY CFM CFMII 00 ['Te WITNESSED ACTUAL ORIFICE ARlóA INDI:SIClNW.G. !T' (TEST SECTION)
_
_
FAN CFM (O)
~n
AIR SYSTEM
PROJECT NAME
CLASS (Pcl-------
_
PAGE
OF
"
TOTAl.
TESTED) RISERS
J
PROJECT NO, __
3432
-ª-
FIELD TEST DATA RECORD200
DUCT CONSTRUCTION
PRESSURE
SPECIFIED TEST PRESSURE (Pt)
LEAKAGE CLASS
AIR DUCT LEAKAGE TEST SUMMARV
**** ********* •• ******** ••• DESIGN DATA FACTOR BY ORIFICE DIAMETERACROSS ACTUAL DUCT CFM PRESSURE •• w.G. AREAIN WITNESSED TUBE BY FT2 CFM/IOO FT2 PERFORMED 9.639 ORIFICE 60.6 7" 7" 9.ó 9.654 1.4 -ISO :!.2<J(} 4ó 35 4/0 "CFM 220 840 J(TEST RL 4./<),85 63.13.85 4.16.85 3.2 3.5 1.8 3.7.85 7" 1.4" A AI3T UNG UNG BT 48 81 71 9.6 1.1" DATE 2.625" JRL 9óOO SECTION) 5ÓO
24,000
HVAC-2
AIR SYSTEM
FAN CFM (Q)
Wall Street Towers
PROJECT NAME
CLASS (Pcl
-º..:.:-
PAGE
~
OF
,
S3~laN3dd"
--
APPENDIX A FANCFM 2 1.6 12 4 3l.3 2.4 12 ]5 24 19 7.7 6.1 2.4 5.1 2.4 3010 4.7 12 4.1 22 12 0.8 2.5 0.6 0.9 2.0 0.4 0.5 25 LO 16 61.2 LO 3.1 15 9.6 38 156.1 13 4.8 6.0 3.0 8.0 1.2 0.8 3.1 34.7 3.0 4.0 7.4 7.5 6.3 9.82.6 6.1 6.11.5 8.21.9 1.9 2.0 1.5 3.7 6 4.9 7.7 6.4 3.1 9.4 3.8 3.8 1.3 1.0 2.6 1.9 3.2 1.6 4.8 1.9 0.6 3.8 9.6 5.9 PRORATED* PERS.F. ]4.9 12 0.8 3.1 1.5
STATIC PRESSURE
S
Table A-1
*TYPICALLY
DUCT
Leakage as Percent of Flow in System
%~/:l1:.AREA
% OF FLOW = LEAKAGE
(IN WG)
WILL BE 2 TO 5 CFM!SQUARE
FOOT
FACTOR (IN CFMIlOO AT THE PRESSURE)
DIVIDED BY
FAN CFM = CFMA x ~ SI. .SURFACE 100SI. CFM¡
CLASS 48 IS AVERAGE UNSEALED RESULTS FOR SEALED OUCTS.
RECTANGULAR
OUCT CLASS 24 ANO LOWER ARE ANTlCJP.;\TED
APPENDIX B.l
B
SAMPLE
LEAKAGE
ANAL YSIS
Since the system size and the impracticality of attempting to reach unrealistically low levels ofleakage are such prominent considerations, the evaluation 01 leakage by lhe pereenlage melhod should be a seCO/1dary. eO/1sideralion. However, it is recognized that a percent of fan cfm or a percent of flow in a section of a system that passes through unconditioned space (considered as a heat loss or a heat gain) can be a useful parameter in energy conservation analysis. Leakage as a percent of flow entering one selected section of duct is not an adequate appraisal of the system performance. Five percent ofthe system flow is quite a different criteria than allowing 5% in each 100 ft of a 500 ft continuous mn of duct It should also be remembered that actual leakage will tend to be less than that appraised for the maximum pressure, because the average pressure under operating conditions will be less.
Leakage as a percent offlow has been related to leakage c1ass and pressure in Appendix A. As Appendix A is studied, the significance of seal classes A, B, and C as applicable to duct pressure classes (see Table 4-1) must be understood. An example ofthe application of leakage c1asses to a duct system is provided to aid a realistic approach to the use of seal class, leakage c1ass and percentage method analysis. While other parameters such as cubíc contents (of duct interior) or lineal feet ofjoint might be used for leakage evaluation they are less practical and should not be used unless the square footage analysis has already been made.
8.2
SYSTEM LEAKAGE ANALYSIS
LEAKAGE
B.3 a.
ANALYSIS
Unsealed duet at ;/;>" static pressure. At ;/;>" s.p. on Class 48 curve in Figure 4-1, 30 cfmllOO s.f. is read. 30 x 2074 ft2 100
= 622 cfm
622 cfm is 7.8% of 8000 cfm fan capacity. Alternative
Calculation
(as in Appendix A)
8000 cfm 2074 ft2
= 3.9 to 1 ratío
Allowable
leakage factor 30 X 3.9
1 = 7.7%
NOTE: The diflerence (7. 7 vs. 7. 8) occurs because 3.9 is roundedlrom 3.857. b.
Unsealed duct (;/;>" s.p. c1ass) operating at 0.3" s.p. If the system actually operates with 0.3" average static pressure and is unsealed, 22 cfm/l 00 s.r. leakage is read from the Class 48 curve 00 Figure 4-1 at 0.3" pressure. This is 456 cfrn or 5.7%.
c.
Leakage Class 24 Requiremeot, Pressure)
Ch" Static
From Figure 4-1, 16 cfm/IOO s.f. is read.
1~~ x 2074 x 322 cfm, which is 4.1 % of fan cfm.
CLASSIFICATION
Alternative
method:
16 x 3\
SYSTEM DATA d. Leakage Evaluation for Supply Duct in Figure 8-1, page 8-4 of the SMACNA HVA C Duel Design Manual
Leakage Class 12 Requirement, Pressure) From Figure 4-1,7.5/100
=
4.1 (;/;>"
Static
x 2074 = 156 cfm
or 1.94% gOOOctin fan /;>"
wg duct construction
c1ass
e.
Allowable
leakage of 5%
320 Lf. ofduct
2.074 ti~ duct
i.9 cfm/s.r.
is average
8000 cfm l.e., 2074 s.r.
=
distribution
83. )7)
If 5°'0 is allowed (i.e., 400 cfm) this is :~~ or 19.3 ctin/I 00 s.f. allowable; . F 19.3 Leakage class If Cl. = p0l15 = 0.64 = 30 The plan on page 8-5 ofthe duct design manllal shows an access door, two volume dampers and a flexible connection (vibration isolation tvoe): leakaQ'e allow-
L ®
-
> ®O® ® t
~
6000 cfm'" O VD 500 12 cfm x 18 x 44 x 18' 0.13" w.c. 30' 20'
®
lL
2 @ 16 8000cfm x 8 Gr 20' 500 cfm ea.
~
<:,
36 x 18
D~
L
MV 1
o
0_E
VD~E V14X12 ~14X12
3i
~§ 14 x 12 @~~,,\0' '"
/ 'ªO
E
ti
§
U$n/ ~/
1
/
gl~
45 ~D
o
Enlly Tap 20'
.~lLiL~
36 x 16 Gr. 2000cfm
-
2000 cfm
0.08" w.c.
2 @ 16x 8 Gr. 500 cfm ea. 500 cfm 12 8 W·13"W'C. 20' @ x
2 @ 48
x
18 Grílles
3000 clm ea. 0.08" w.C.
~ 30 x 24
<0 • indicates duct liner used; sizes are interior dimensions.
24
®
FIGURE 8-1 DUCT SYSTEM EXAMPLE
• l' lA ,....
,
20' x 18
/
'10'14 14xx 12 12 ,,\0'
§f;1~
11
~IEVD~
IJ
APPENDIX
e
SUGGESTED ANALYSIS WHEN DESIGNER IS NOT USING THE SMACNA CRITERIA, DOES NOT PROVIDE LEAKAGE CLASS OR TEST PRESSURE AND ONLY REQUIRES TESTING TO MEET A PERCENTAGE AS ALLOWABLE LEAKAGE.
At this point the contractor may find it informa tive to relate the contract requiremcnts to thc leakage suggested in Table 4.1. This can be done as follows:
C¡
F x 100 po 65
A. lEAKAGE RATE DETERMINATION
When a leakage class is specified it is relatively simple to find the allowable leakage for a given test segment. However, when a total allowable leakage is expressed as a percent oftotal fiow, it is somewhat more cumbersome to prorate the allowable leakage to any single test segment. A suggested method is as follows:
l.
Calculate the total amount of allowable leakage by multiplying the percent allowable by the total fiow ofthe fan.
2.
Calculate the area ofthe entire duct system in square feet.
3.
Divide the allowable leakage obtained in (1) by the total area obtained in (2) to obtain a prorated leakage rate (F). Enter this number on the report for each test segment.
4.
Calculate the allowable leakage for each test segment by multiplying its surface area by the leakage factor obtained in (3).
In this formula (F) is the leakage rate obtained in paragraph (3) above, and P is the test pressure.
Compare the numerical value ofthe leakage class obtained through this calculation with the suggested leakage classes for the type of duct construction and extent of sealing used. Ifthe calculated value is below the value suggested in Table 4-1 the contractors should anticipate some difficulty in obtaining satisfactory test results. The greater the difference is, the greater the difficulty will be. Resolve the issue under sections 2.I(e) and 2.2(c) ofthe leakage test manual.
B. TEST PRESSURE DETERMINATION
The duct will be constructed for some pressure class (or classes). It is not practical to include duct from two different construction classes in the same leakage test segment. Ducts should not be leak tested at pressures greater than the construction class.
APPENDIX 0.1 NOTlCE
D
SAMPLE PROJECT SPECIFICATION
l.
Contractor shalJ, at the beginning ofthe work construcL erect and leak test a representative sample ofthe duct construction to be used at the __ pressure cIass. The sample specimen shall inc\ude at least five transverse joints, typical seams, an access door and at least t\Votypical branch connections plus an elbow.
2.
The leakage amount shall not exceed the allotted amount for the pressure class or the allotted amount for that portion of the system, whichever is applicable.
TO DESIGNERS:
WHEN TESTS ARE DEEMED NECESSARY, A TEST OF A REPRESENTATIVI;: SAMPLE OF THE DUCT IS RECOMMENDED. IF SAMPLE IS DEFECTIVE, THE CONTRACTOR SHOULD REPAIR OR MODIFY THE CONSTRUCTION. IF RESULTS OF SAMPLE TEST ARE GOOD, CONTRACTOR CAN BE PERMITTED TO PROCEED WITHOUT FURTHER TESTING VISUAL INSPECTION AND EXAMINATION OF OPERATING CONDITIONS SHOULD SUFFICE TO JUSTIFY FAITH IN METHODS USED.
DUCT
CLASS 12 63LEAKAGE
CONSTRUCTION
CLASS 6" 4" wg 3" lO" wg
NOTE: See section 4 of the SMA CNA Leakage Test j\1anualfor normal classification. 3.
Leakage test procedures shalI folIow the outlines and c\assifications in the SMACNA HVAC Duct Leakage Test Manual.
4.
Ifspecimen fails tomeet alIotted leakage level, the contractor shalI modify to bring it into compliance and shalI retest it until acceptable leakage is demonstrated.
5.
Tests and necessary repair shall be completed prior to concealment of ducts.
APPENDIX
E
12 2.7 4.2 1.73.-+ 17.2 2.1 2.2 2.4 P=I When 23.2 21.2 5.4 6.7 2.7 24 30.80 13.5 11.0 14.3 12 11.222.4 610.6 5.6 7.8 9.4 0.90 2.8 1.4 62448 5.5 6.613.2 7.6 9.5 8.6 10.7 1l.0 3.8 3.3 5.2 4.8 4.3 34.4 6.7 1.3 0.05 0.10 0.20 0.40 0.50 8.-+ 1.5 0.60 0.7 0.4 1.9 l.l 1.7 25.0 11.6 12.5 7.0 24.5 27.1 21.7 108.5 13.6 16.0 18.2 12.2 17.1 14.8 49.0 2.5 43.4 54.2 59.0 4.0 4.5 3.0 5.4 8.6 9.1 7.4 28.5 8.0 9.0 29.5 CLASS 118.1 10.9 98.0 86.8 5.5 5.0 6.1 8.0 15.631.2 18.837.7 lOA 44.8 62.4 48 41.5 20.8 2.0 3.9 0.30 4.7 3CLASS 15.3 2l.9 30.6 26.4 0.9 0.70 2.6 26.8 10.0 13.4 19.2 6.0 9.6 ]6.8 19.0 38.1 CLASS 75.4 CLASS CL F= CL(P)065 p" eL =F -CLASS pO.65
_
Table E-1
LEAKAGE CLASS (CL> UNSEALED
F
Leakage Factor (F) in CFM/100 S.F. Duct
These factor may also be read from Figure 4-] . See Table 4-1 for sea! class and pressure class.
--APPENDIX
F
LEAKAGE 50 150 400 300 500 250 5625 00 833 417 833 200 100 250 200 333 666 167 ]25 100 167333 4]7833 500 750 667 833 208 83 100200 300 600 50 2.500 USO 250 600 800 400 500 800 12.500 7.500 2.000 5,000 5.000 10,000 2,500 7,500 20.000 40,000 13,333 5,000 5,000 6,250 ],667 500 1,000 2,500 3,333 4,000 20,000 32400 5,000 ,333 8~333 15,000 30,000 1,250 3,750 1,333 1,250 2,083 1,500 25,000 10,000 3,000 4,167 1,667 10,000 6,667 6,000 ,000 1,666 6,666 15,000 10,000 ,500 1,000 ],000 2,000 1,500 2,500 1,000 2,667 1,200 1,000 1,000 1,250 2,500 4,000 1,600 3,000 2,000 1,333 3,333 8,000 CFM/IOO SFO
25
LEA K TEST RIG FLOW CAPACITY
IN CFM
Table F-l Amount of Duct to be Leak Tested (SFD) SFD IS DUCT SURFACE AREA IN SQUARE FEET NOTE: The statie pressurefor the test mU8i develop within the efm range ofthe test rig; ifit does not the leakage in the amount of dl!t;ueSletHS (prooably) greater than the estimated amOlmt.
,,,
;It
1"
l"
311
tU
211
)"
8"
6"
4"
2"
O"
8"
•
I
:.-
¡
I
28'; - 30" 5.33 ..':67.-.600.
"1
DUCT
i
I
_1467U~i~~t:~.~:;;-::~ r 6.00 6.33 6.67 7.00 ::: 7.33 :: 7.67
8.00
,
I
¡-
'
-.1
!
.
I
. --- ¡.
U
t
----
--
'1
....
,-
- .
..
_l .. __
.L_.
"". _
J·_+-rJ
-.--.----j- -
..
- .-
._u_
-.,.,,-_.-~._-
18.00 L2?:~~1
..
----.---
----
... -.-.- ..
11.00 1200 ::: :::
o
----
••
n
·-··----1
,
.
,
I
I
. 2 .00 i 30.00 I 32.00
8
- -1""
¡-..--..-..--
i
I
¡
I I
~~~.·~·~fr.
i
,"u. __.•__ ..·--···..
22.00 .~~~~O. 25.00:7.00 j 29.00 24.00 26.00 28,00 I 30.00
~~~~~::~
...-,,--
16':O'.'O*OO,:i~OO:
-_==~j==[]=I==rl:r3200I~.::]
- ••
_.__n·
_,-,",O
16.00 17.00 18,00 19.00 20,00 "_I' 22,00 24,00 26.00 ..... I ••
------
13.00 140':
I
~i:~ -:¡~;~~ ;:~::~~:~ ~~!
t
10.00 12.00' 11.00 -73.00 12.00 14.00 13.00 -;5."00" 14.00 "1(;.00"';-7,'00 15.00 16.00 ';8~O--·20.ool22~·(;O17.00 19.00 I 21.00123.00 '24-.00' 14.00 15.00 16.00 17.00 18.00 19.00 21.00123,00 -25,00-
--==~_:-~o ------ .---__
__ ".. -
. =.•• -- .. =.• ' -- .
-.-.\
¡__ ._._ .. --
1:
G')
><
ze
m
"'O "'O
»
:~i~ ~~a~::~11~j:1
!~_:~~. ~~.~~1~:0~
Table G-1 Duct Surface Area in Square Feet per linear Foot
-1= : ..•.t· .= .••. -
I
I . -- -".'
,
-;-·····r"-----!·----------
i..... IfU'-I'
I
~'~~n_13~~~._~~~~__1.~...0~..
::: :.:: .:~:::. ..~. 13.00 :::: ::::. 8.00 .::: 9.00 10.00 11.00 ~12.00 14.00 15.00 17.00 19.00l21.00
7.00
._: +__~..... . '.:i3-8~i IJ_J~_.t_t~~ __ 8:00-':6~ :: ·;;00;;;:00 :: :::
DI(~~~;~~N
.
...
. 4.00: 4.3314.6~.¡._5:~0.1.~:3.~ _~~~~ __~:~~ ~~~3 6.67
.. ' 1700 96"L1~~'--i 11500 i 19001
8~3 8.67 ..'~3~~':33. 9.67 10.67 11.67 ,,33j,:33+'3::o1,533 12.67113.67 15.67 1'733 ¡ 17.67 l.19:'.3: ! 19.67 i
36" 7.00 4~~~_48'~1~~t.~~.jn.6.~"_I!,,2'~._t~41: 8.00 900 11000 1'100 11200 1'300
(WIDTH)
2.67.. 300 3.33, 3.33, 3.67 3:6714:00..4:331.4.671=()()...!~3 4.00 I 4.33l 4.671 5.00 5.33 5.67. .'.67 6.00 600 6.33 6.33 6.67 ~33 7.67
8" .. , 10" 2.33 2.67: . 1~U.;.~4". 3.00: 3.331 3.67 j
..l:~_~~~1 ~~E~~'-'.2,,6" 400 1-43314671;00
DUCT DIMENSION
--
I
------- --.-- ____ ___.. -----_-~~---- ---_.----------~------------~--~-~._---------_._-~_--_ , -0.-_-. 804.248 283.529 Inches 314.16 13.09 12.5664 3.1416 2375.83 2290.22 0.5236 163.36 0.0491 0.0218 0.0873 1.047 14.14 1475 54 53 52 3959.19 2922.47 2733.97 2827.43 2.182 56 69 70 71 I Ft 0.7854 4417.86 3019.07 4656.63 4536.46 0.00545 3.142 74 75 77 51 7699.69 5410.61 5281.02 6082.12 7853.98 157.08 307.88 100 12.04 12.30 6.681 97 12.51 13.64 98 99 86 87 84 3525.65 3421.19 4901.67 1.227 1.396 1.767 64 78 68 67 6503.88 1385.44 1520.53 1452.20 1320.25 292.17 24.61 11.26 24.35 24.87 9.168 47.17 9.621 45.17 94 95 10.08 11.04 93 91 5.241 81 80 19.6350 7.0686 2123.72 2206.18 0.7854 172.79 166.50 169.65 0.1364 14.40 1.309 13.61 13.88 9.425 55 16.50 15.32 38.4845 63.6173 50.2655 95.0332 78.5398 3848.45 3739.28 346.361 2642.08 2463.01 2551.76 62.832 65.973 233.05 188.50 175.93 191.64 28.274 25.133 21.991 31.416 18.850 1.571 2.880 15.45 2.618 14.66 14.92 4.974 2.356 0.5454 15.71 0.3491 2.094 0.6600 1.833 20.29 26.73 27.49 17.72 1.969 18.99 19.63 17.10 57 61 59 60 58 4300.84 132.732 4071.50 452.389 4185.39 490.874 530.929 2042.82 113.097 3117.25 0.2618 75.398 72.257 160.22 194.78 40.841 37.699 0.7854 0.9218 3.142 13.35 6.545 2.640 28.27 29.87 2.885 3.409 3.976 3.687 14.19 72 73 62 63 76 5808.80 5944.68 7542.96 5674.50 855.299 7238.23 6221.14 6361.73 7389.81 5541.77 907.920 1075.21 1885.74 1017.88 1963.50 1134.11 180956 1661.90 1194.59 1734.94 1256.54 109.956 122.522 113.097 106.814 116.239 103.673 147.65 144.51 270.18 153.94 304.73 301.59 267.04 125.66 282.74 31102 276.46 Ft 25.92 12.83 23.04 23.30 22.51 22.78 12.57 25.66 13.09 26.18 21.99 25.39 21.73 22.25 21.47 25.13 23.56 10.47 9.948 8.639 7.876 8.378 7.467 8.727 7.069 41.28 54.54 5346 39.41 42.24 44.18 40.34 52.38 12.05 6.305 50.27 5.585 10.21 11.54 90 96 89 82 88 83 85 226.980 254.469 201.062 3631.68 3318.31 3216.99 4778.36 153.938 176.715 56.549 53.407 47.124 50.265 91.106 207.35 4.189 4.451 7.592 4.712 7.330 17.28 3.665 17.54 17.02 1.069 4.587 34.04 22.34 4.276 1.576 65 79 66 6939.78 6792.91 7088.78 6647.61 1590.43 295.31 298.45 289.03 285.88 10.99 10.73 23.82 11.52 11.78 24.09 48.19 49.22 4616 10.56 92 5026.55 5153.00 706.859 754.768 254.47 94.248 21.21 4.909 15.708 12.566 15.90 314.159 219.91 216.67 185.35 179.07 182.21 34.558 5.236 15.97 15.18 5.498 0.4418 0.2673 0.1964 18.06 18.33 25.97 18.35 Diamctcr 415.476 572.555 380.133 84.823 81.681 226.19 235.62 78.540 238.76 69.115 232.48 197.92 5.760 16.49 16.23 3.403 6.283 6.021 7.069 6.807 19.37 19.11 18.85 19.63 21.65 32.34 31.50 20.97 29.07 30.68 942.113 119.381 100.531 150.80 260.75 257.61 273.32 263.89 279.60 9.686 8.901 9.163 8.296 43.20 51.32 37.57 36.67 5.940 615.752 660.520 43.982 87.965 248.19 210.49 204.20 201.06 245.04 20.42 3.927 17.80 16.76 24.48 23.76 23.04 33.18 25.22 141.37 138.23 97.389 135.09 251.33 131.95 128.81 7.854 20.94 8.116 35.78 34.91 59.690 18.69 229.34 241.90 20.16 19.90 Circumfcrcncc 38.48 213.63 20.68 In 2.405 Sq I 28.2743 Sq In o_o
..
____
un_o
____________
Circumfcrcnce Area
- --
"
------_
.. ----
--
APPENDIX H
Table H-1 Areas and Circumferences of Circles Thc' surt;lcc arca (rcr Iincar IllO!l "f lla¡ ,,,al duc¡ can Ix calculatcd
fnllll .;.I-ID . 2 L. "hcrc
l. is ¡hc lla¡ span and [) is ¡hc dq1lh. Thc ,aluc 3.I-ID
APPENDIX 1.1
I
COMMENTARY
FLOW EOUATION
ON FLOW CALCULATION
DERIVATION
where
º
K
º
D 6P=
º
The basic tlow equation is = A V for whieh is in cfm, A is in ft2 and V is in fpm. Veloeity pressure head Iz = ~ and veloeity V = ,i2glz where gis the gravitational factor of 32.17 Iblft-sec/sec. To use basic formula in inches of water gage pressure it is neeessary to multiply the velocity head in feet by 12 inift and by
....
plb/ft3
the ratlO of alr denslty to water densJty 62.3 Ib/ft 3' To use velocity in fpm divide by 3600 s2/m2.
Thus,
Iz
d=
1.2
pressure drop aeross orifiee, "wg density factor from Appendix K
FLOWMETER
ACCURACY
a1r:
ve
12
2(32.17)
P
x 3600 x 62.3
R
V = 1096.7 jh/p
When p
air volume. cfm eoeffieient of air tlow orifiee diameter. inehes
The coefficient K is affeeted by the Reynolds number, a dimensionless value expressing flow eonditions in a duct. Appendix J relates Reynolds number, Beta ratio, and K. The following equation gives a simplified method of ealculating Reynolds number for standard
Where and
FOR ORIFICE METERS
= 0.075, V = 4005 jh
Fluid flow texts indieate that for temperatures below 5000 F thermal expansion effects in the orifice meter need not be accounted for. AIso, for the normal range pressures in HVAC system testing, the effects of air compressibility are negligible. A eombined coeffieientK is used forvarious effeets dueto approaeh, eontraetion. discharge and pressure tap loeations.
Standard airtlow across a sharp edge orifiee p = 0.075 Ib/ft3 is ealculated from
with
Q = KAV =
=
K¡ ~~1096.7
1
= Reynolds number = Orifiee diameter, inehes V = Veloeity of air through orifice, fpm
The coefficient K is read from Appendix J for the type of meter taps used. lt varies more below R values of 105 than for higher values. Some texts sueh as F an Engineering, eopyrighted by Buffalo Forge Co., use K eoefficients for Reynolds number of 106 (with pipe diame ter as the reference) as reasonably accurate for normal flow in 1Y2" to 16" diameter pipes, whether flange or vena contracta taps are used. Fisher and Pvrter Company reports in their Flowmeler Orífice Sizing Handbook that ASME publieations and other research indicate that regardless of pipe size and standard orifice tap locations, only ± 1% error is likely over a beta range of 0.12 to 0.72 if the equation for K is
For densities other than standard, the following equation ean be used as a good approximation:
Equation
I
/lP
+
= 0.5930 + 0.413-1
(0.0015//3
+
O.OI2{34) j1O;¡O
jO~;5
21.8KDc ,L1P
/' T/'r'I. ..•
8.4DV
R D
Xc
Equation
=
2
The terms with fJ in this equation are relatively smal! and the praetice of using K = 0.60 is fairly common. Flow approaching the orifice must be unifonn to maintain accuraey. Straightening vanes or other tlo\\' straightening means must be used upstream. However. ASME and other texts point out that the basic oritíce tlow eoeffieients need moditícation for the effeets of gas expansion ifthe pressure drop aeross more than a few percent of the absolute stream ofthe orifiee. Appendix K may be uate the etTpC')sof a pas pxnlln<:inn fllrtnr
the oritice is pressure upused to evalY in !prm, nf
to meters indicated in Table 5-2 ofthis manual do not
at constant pressure to constant volume (k = 1.4 for air) and orifice pressure drap. The Y factor would reduce the apparent flow by becoming a multiplier in the formula Q = KcYA V The Y factor should be considered when determining the beta ratio to be used in a meter that is to be highly accurate.
require calibration. Otherwise, the nominal values for K that are given in Table 5-1 are deemed suitable for flow measurement under field conditions. Table 5-1 is lIsable for vena contracta taps at aIl De/DI ratios and for flange taps when De/DI is 0.50 or less. Vena contracta taps or flange taps are acceptable for Figure 5-3 except that Q = 372 /P (with K = 0.711) may have 10% error with flange taps when Reynolds number is less than 105
Manometer scales are caJibrated for fluids of specific density. Fluids with density corresponding to scale calibration must be used. Recalíbration is not necessary. Densities ofvarious manometer fluids are given in Appendix M.
1.3
The accuracy ofthe K coefficients in Figure 5-1 can be compared with those varying with Reynolds number in the following manner.
OVERAll
METER lOSS
Where test apparatus fan capacity is marginal overall pressure loss through the orifice meter may contribllte to difficulty in obtaining the required test pressure level in the duct. The overallloss in relation to the diame-
With 100 cfm in a 2.625" diameter orifice
is indicated in Table 5-1 and in Figure l.
ter ratio
f3
1.4
METER CAPACITV FOR TESTED DUCT SIZE
Q
R = 8.4DV = 8.4D A Or
R
= 8.4(2.625) ~ !9~_~= 5.87
X 104
A test meter must ha ve a fan that can produce the target cfm at a static pressure that is a combination ofthe duct test pressure plus other "system" losses. The required capacity of a leakage test meter should be examined in relation to the duct leakage classification chart. The orifice relates cfm to pressure according to Q = X pO'. Leakage class is a plot of Q = x pfI.65. However, the orifice capacity needs to relate only to one pressure level on the leakage c1ass curve, the test pressure. An orifice conforming to
If ~: = 0.375, Figure I gi\·es K = 0.61 and Figure 2 givesK= 0.615.
e e
Observe that 0.623 from Table 5-1 is 102% of 0.61. With 30 cfm in a 1" diameter orifice,
R = 8.4(1)~ ~~~._ = 4.6
If
geI =
X
10 /LlPwill. forexample, have the capacity to register only 24 cfm at 6" orifice differential. Ifthe test is at 6 static pressure for Leakage Class 3 compliance, i.e., 9.6 cfm per 100 s.f, with 6" orifice differential and 6" duct test pressure, the meter could only indicate 24 cfm. However. the blower for the test apparatus would have lo produce 24 cfin al/O" 10 /2" slalic. Observe that with a jJ ratio ofO.29, as in a 3" tube with 'la" orifice, the meter loss is 88% of the orifice differential.
10"
0.33, Figure 1 gi\es K= 0.605 and Figure 2
gives K = 0.61.
Table 5-1 (interpolated) 9~U;;(jonf 0.61.
gÍ\CS
K
= 0.6024 which
Assllming that the duct leaked at Class 3 and the test apparatus cnuld gcnerate thestatic pressure to indicatc 24 cfm. 250 square feet of duct (24/9.6 x 100 = 250) could be tcsted at one time. A Iarger meter, for exalllpIe. Q = 26LlP. could test 666 s.r of duct (64/9.6 x
IS
Varinus
100) with 6" .1P lfthe 10 "LlP meter \Vere used to test Class 24 duct at I Y2" static and it could not develop morc than abollt 10" orifice drop while maintaining 1 Y2" in thc tcstcd duct: the 32 cfm metered could only
standard Pitot tube amI states that orifices confonning
handlc 32/31 x 100 or 103 s. f of duct(unless
,,..,
U\ I 1\ '"
A·
_
~..I.'
__
L
t~e leak-
-
--
JlO
~ •..-' 1.00 .70 .~ O w ~ .90 ~ ~ .ti)
!
!¡
1
1
~t'
~
..
. .(0
~ w
.JO
> O
I
! r--...
I.<--rp
~
¡
I ~
I
!I¡i
II"-.. ~
.20 10 o O
10
.:10
.XI
.40 OIA~ETER
.ti)
.50
00
.:'0
Q(1
RAno. ti
FIGURE 1-1 RATIO OF OVER-ALL PRESSURE LOSS TO METERED DIFFERENTIAL VERSUS DIAMETER RATIO fJ Reprinled ji-am Handboak
So. IOB900. FIOlnneler Orifice Si::ing. Fischer and Porla
age rate 5-3 with pressure variable
was below the allowable). Comparing Figure Figure 4-1 can facilitate testing. Excess fan can be controlled with inlet dampers, bypass, speed motors or other means.
1.5
STANDARD AIR
Air density varies with barometric pressure, temperature, and the amount of moisture present. Moist air is less dense than dry air at a given temperature. At a barometric pressure 01'29.92 in. Hg and 70° F dryair has a density ofO.07495Ib/ft3. At 60° F dry air is 0.764 Ib1t13. Federal agency documents define "standard atmosphere"; at sea level standard temperature is 59° F with 29.921 in. Hg barometric pressure. Industry documents define "standard air" in different ways. ASHRAE uses a standard \alue ofO.075 lb ofdry airpercubic 1'oot for 60° F at saturation and for 69° F dry at 14.7 psia. The ASHRAE Fundamentals Handbook chapkr on duct design states that no corrections to their duct friction chart are needed for ±30° F from 70° F. elevations to 1500 ft amI duct pressurcs from +20" wg to -20" wg These limits result in only ±5'~o variation. Comparable limits should be acceptable for ficld tests. Other variations can be observcd in Appendix K.
eo .. "'ilh permission
al, published by ACGIH, defines three equivalent methods of calculating ACFM. The SCFM basis is 0.075 Ib/ft3 at 70° F at sea leve!.
a.
b.
c.
ACFM = SCFM x 46~3~ T whereTisactual dry bulb air temperature in °F, moisture is negligible and pressure is less than = 20" wg.
ACFM = SCFM x O.~75 where d is alr density taken from psychrometric charts.
A CF M
= lb per mino of dry air x humid vol-
ume ft3 per mino per pound 01'dry air.
These naluations arc rarcly applied on commercial projects but are common in the industrial sector. For cxample. outdoor air at 95" db and 75° wb has a humid air \'olumc of 14.3 ft3/lb ofdry air. The density is 0.07 Ibift3. By formula b) abO\e an actual tlow measurcment of 100 cfm would mean a standard airtlow of
93.3 din. Those who test air handling systems \\ill occasionally be concemcd with the dcsignations ACFM and SCFM. The "A" refers to "actual": the "S" rcters to standard
For additional
information
on tlowmeters
see rcfer-
1.6
OTHER LEAK TEST METHODS
Various methods of leak testing are used for shafts, bui Iding compartIl1ents. door cracks, \\'indo\\'s. curta in wa]ls. critica] ducts in safety related criteria zones in nuclear power plants and other circumstances. ASME/ ANSI Standard NS 10, Testingo(NuclearAir-C1eaning Svstems, covers requirements for field testing of engineered safety feature systems and high efficiency air c1eaning systems. Bubble, spray DOP, liquid penetranL pressure decay rate and other methods are found in N5 1O. Several levels of tightness for ducts in contaminatíon zones and other applications are addressed ín N5 1O and also in ASME/ ANSI Standard N509, Nuclear POH'er Plan! Air-Cleaning Units and Components. Provisíons in both of these documents are reviewed in the ERDA 76-21. Nuclear Air C1eaning Handbook, available from the U.S. Department of Commerce NTIS.
Tracer gas methods have been used frequently by researchers investigating the leakage in houses and commercial building compartments. NBS has used the method and numerous ASHRAE transactions report this method and fan pressurization methods. Transaction H 1-8S-03 No. 21ists many ofthe references. ASHRAE Fundamenta/s Handbook Chapter 2S, on ventilation and infiltration, reports leakage rates for various building elements. Key standards for such tests are:
ASTM E283, Rate orA ir Leakage Through Exterior IVindows. Curtain IVal/s, and Doors
ASTM E74 L Measuring Dilution Method
A ir Leakage hy the Tracel
ASTM E779 .. \feasuring Air Leakage h¡' rhe Fan Pressurization Aferhod
ASTM E783. Fie/d Measuremel1r of Air Leakage Through Insralled Exterior Wil1doH'Sami Doors
Measurement techniques, field studies, and the significance ofinfiltration are comprehensively reviewed in ASTM STP 719-1980, Bui/ding Air Change Rate and lnfil!ration Aleasurements.
Typical leakage rates for walls and floors of commercial buildings are reported in Design ofSmoke Control Sys!ems for Buildings, available from ASHRAE. This document has an extensive bibliography on stairwelL shaft, and building leakage. At the present it appears that insufficient knowledge exists about the leakage rates in ceilings, interior partitions and corridor construction to document rates for design purposes.
Damper leakage is lab tested by AMCA Standard SOO. Several c1assifications of damper leakage are published in UL Standard 555S, Leakage Rated D':lInpers for Use in Smoke Control Systems. Higher integrity cIassifications of damper leakage are in ANSI N509.
Tests of HVAC systems and building compartments for smoke control performance may involve flow direction study, air change rate and leakage evaluation by means other than orifice meters.
APPENDIX J 1.1
FLOW COEFFICIENTS
;J
f:
'
T
,-~ . ,, r '.... 7-
~
;
I!
1:
jlir----+-~:'; ,- i ~ fr.. t
:
~ 066
.' ~
f
j."
!
i
.~
I
l'
I111
'1
¡!
1:
-
060¡'-
¡
í 1 i
,.'
..
!
1
,
¡
¡ j: !
i
~
)
¡
,
¡!'
-t
I ¡¡
l'
¡ 1, ¡ i
I
I
¡"
f•
~ l.
¡
!
I
tt.
ll! ti ~Iin~ i
1
1
I i
i
1,
¡
I ¡I
¡..+i; t m . 1 I T
i
'11
1
i
i '1' i1 !
¡ I !J'
r-T' 1
¡. ¡1I
. ..---.-, , .I
¡
t-
l'"0601,!
,
1
I
j
, ;
111 ~;
I!
1/1
¡
TTiil
i
"
11
!¡
1
f
2
)
jo~o I
i ,
." .
'
;
Q
,
nr~1 r ~.' '.:;Tfl W¡i~ !
,,1
;c~
j
•• I
¡ DH '-¡o~~rr;
í ~ ~
1 :-1 . r I', i .•..• -+ .. i 1,:, •. ¡ i l., ¡ ,II.O}O 111" _1 _L.1 U.LL ....
'.
¡
J
¡ , '
i 1 L.l.J.ll, ! ¡l' 0~8i __._..l __ 'I ....1 z
~.!O¡ '010'1,'
'. "'-..
~
i , I ! 11: 1 .•...• ; tIJ ! ' -' ¡i '! j, ,1
T
,¡
, H-' - ;.-065 t·
, , ---C·f·-t· . ! ;.
'.
~"I'I"'I"
..
--r
=trtr:. '., : , :J:ttñ .•.. ,." '~:¡i¡ ~." :.'_1.;. ,
lC4
:
I
t -.-.
-.
;'~ ¡
t
:;. "
--~
I
¡"
r
J &2
' ! ¡ \ ¡i t1,'---t-' ' !
-,¡l'"r-'--'"
"!
,t
~l
o
,',
l.
r,
:~ 064
i
1
:) !,) 7--'-
068
-'. -'-',
.
~
106
.1'1'1 ~o
2
1 '
}
:
~
10'
E y ,.,Ol OS NVU8( R. "~ni
.'ti
FIGURE J-1 FLOW COEFFICIENTS K FOR SQUARElEDGED ORIFICE PLATES AND VENA CONTRACTA TAPS IN SMOOTH PIPE
0.fl~
,
O.Be,
r
¡iI : ¡. . ,¡'
,11"f, .
1
f
¡.
•.••.
.... ,
.
-
I I
"
...
.
----
;. .•...
J
,
¡ ¡
t-
•. O"'~·
"
~
u ... ••• W
ou o~
? .•..••. .' ,.
. , n~:~oo, I
~ 6~
t
t
T
r
~
O.b~
t
t
t
!í
0&0
,
.:. € ':. ~
1
-
-~~ ~~;-:Ii e'"
" 1<[ Y1';0,
.. ,
es ",u"8t 1/. - ;p;:
O. ~~
o ~o
1
:
¡'o
40 'o ~o
¡
-
106
10 .
FIGURE J-2 FLOW COEFFICIENTS K FOR SQUARE-EDGED
APPENDIX
K
1.01 I.IJ 0.82 0.27 0.29 1.09 0.97 1.13 1.05 0.44 1.22 4000 7000 2000 6000 1000 0.'12 OA5 1.15 0.99 0.81 1.03 1.07 075 0.91 25.S4 24.90 28.86 23.98 29.92 407.5 OA5 0.92 0.79 0.79 0.65 0.95 0.73 0.85 0.92 1.02 20.58 056 351.7 074 0.75 0.89 0.77 0.96 0.77 0.72 0.60 0.51 0.56 0.37 0.56 OA3 0.49 0.58 0.54 0.62 0.'10 0.53 0.52 0.:\3 0.27 0.31 0.36 0.29 10.000 0.32 0.30 0.25 0.29 0.37 0.28 0.28 0.30 0.35 0.31 0.39 OA7 0.93 XOOO 0.34 0.37 280.1 0.'17 0.'10 OAI 0.34 087 31-1.3 0.44 0.39 0.'15 OA3 0.90 291.1 0.46 1.26 1.17 OAO 0.'13 OA4 326A 0.'12 00_400 5000 Levcl 0.53 0.55 0.57 0.60 085 078 22.22 26.82 0.36 23.09 27.82 0.48 378.6 392.S 069 0.88 095 0.76 0.99 0.50 0.52 0.54 33S.9 0.86 1.00 0.78 0.72 0.67 0.83 0.87 0.84 0.80 0.69 0.69 0.71 0.60 0.74 0.64 0.64 0.70 0.62 0.70 0.65 0.67 0.36 0.49 0.47 0.65 0.55 0.51 3000 0.41 0.46 0.35 OA8 9000 0.'14 0.53 0.26 0.33 0.49 OA6 0.39 302.1 0.38 0.33 0.35 0.85 070 1.06 0.82 0.88 21.39 365.0 0.71 0.93 0.65 0.80 0.81 0.66 0.57 0.56 0.58 0.52 0.50 0.43 0.42 0.39 0.38 0.68 0.62 0.75 (fl)
Sea
Table K-1 Air Density Correction ~eprinled from Industrial
Ventilation. by the American
Conference
ofGovernmenlal
Industrial
Factor, d Hygienisls.
wilh permission.
APPENDIX L
0.96
0.98 0.92 1.00 eex(f)ene(f)e...:nn"1'\~ 0.94 W (9 "O oo'\roo.. LL o..
13=0.7
>-
~ ~ 13=0.1 r-. 1" I J.- _ I '-".~ I~ '\~ f"
"
13=0.6-1--
i 0.5 13=
~
0.90 0.00
0.05
0.10
Acoustic Ratio
0.15 L1
0.20
p
kP1
FIGURE L-1
Reprinted
from Handbook
GAS EXPANSION FACTOR, ~ VERSUS ACOUSTIC RATIO, iJPIKP1
No. 108900. Flol\"}J1eler Orifice Si=ing. Físcher and Poner, eo., wíth permíssion.
rica
""O
Is:
""O
1978. From ISA Recommended
Liquids
Practice RP2, I---Manometer
·100
»of Manometric - -Properties -m- ----
·24-42 -4 Coeflicienl 01'Thcrmul Expunsion nllll-intllllll. 300+ ,170 -31 O,3-50°C 427 17.5 .J.12 .--0'·(,0 ~o KI, 40 202 2 10 176 +(U\ K(.,I .10 20 100 1/') 230 /\l'l'l vlenl' ICIl'IIhn>11\ idc 2,l)('420/4 173 70 554320 64 !nw absllrbs 1,2C1O 20/4 absorbs \VlIlcr 6K7 12 (,K 111I1lllI'lI.\ .187 644 O (,(,0 241 3 140 il142 40 20120 ,1,IKO 1.11).1.25 non-inlllll11, 212 KY) 32 (((, Vapor ,100+ 20 non-inll:II1\. -201\\ (,7') 101 -.18 250 1.1.570 IOKO (,00 IIhso,hs 95R 532 75+ 34,7 2.()Kl) 20/4 354 (,38 (,8 O,(l9 1,1155 20/4 ·UO150+ 77H 30,\5,2 2HI 5056K 30-100 Point 1,024-30 ID7 340 165 106 367 74,7 0,85 IIbsorbs O,<)OllJ O,K7lJ4 KL'rosinc. 41 no /\1'1111 (,0"1: I).K200 (,O/(,(l 17.1 55 2070 115 6H 1(1) 1,000 1,1)5(,20/4 203 181,K (J.()OI2 O,K.l.1O (,(l/(,O Action Pressure with 10-4 7(,lJ Fhlsh Point 0.71).1'1 I'oinl lIt 68°F 1, I-Dihr\\l1111ctllallc, C,II~BI', per dcg F)( n-BuI)'1 Plithlllllle, ('Vapor I(,H"O~ 1.0477 R.mgc \\-l)ihl'llnlllhcn/l'lll', {'(,II.¡IJr, Ml'I'CIII'Y' Bcnzenc (Bcnwl 1,C(,H(, 106 Ilcgligiblc 1II'I'ligihll' Ill'gligihil' /\Ic\\lwl Cilyc\\l c1cgF 433 negligiblc Cilyccrillc (C'I)'CL'rllll. C,IlsO, Boiling ncgligihle pcr dcg C)( Ellison Gagc Oil IIbsorbs sligl1lly Elhvlcnc CiIY'Clll¡GI)'Cllll, dcg (',11(,0 IIhsorbs F slowly BUlyl Cellosolvc C(¡H ncgligiblc I~O, ncgligiblc dcg F,ILl) dcg Wutcr F >< Elhyll\kohol. ('a,h·II\\1. C'(¡H\~(), Mclting Specific Elbcr) ,\10n\\l:111Iy Elherl
-z Tables
-76
e
APPENDIX N.1
l.
N
FLUlD METER REFERENCES
INSTRUMENTATION
ASHRAE Fundamenrals Handbook Chapter on Measurements and Instruments
11. Fon Engineering. Buffalo Forge eo.
12. Fischer & Porter Company Handbook IOB9000, Flo\\meter Or{fice Si::ing, 1978
No
13. Industrial Ventilation, ACGIH. Chapter 9, Moni2.
toring and Testing of Ventilation Systems.
ASME, Fluid Aleters. Their TheOf}'and Applica-
tion 14.
3.
4.
Volume 1, Leak Testing, American Society for Nondestructive Testing and American Society for Metals.
ASME Power Test Code PTC 19.5
ASME MFC-3M (Part 1, Orifices) Measurement
of Fluid Flmv in Pipes.
5.
Nondestructive Testing Handbook, 2nd ed., 1982
ACGIH, American dustrial Hygienists,
1984
PrincipIes and Practices of Flowmeter Engineering, L.K. Spink, Foxboro, Co.
6.
ANSI/ API 2530, Orífice Metering of Natural Gas (AGA Report #3)
7.
Flow Measurement Engineering Handbook,
R. W.
Conference of Govemmental Lansing, Mi
AGA, American Gas Association,
ANSI, American York, NY
National
Arlington,
Standards
VA
Institute,
APCA, Air PolIution Control Association,
In-
New
Pittsburgh,
PA
MilIer, McGraw HilI (1982) API, American 8.
Plates for Flow Measurement (For ANSI BI6 flanges)
9.
Petroleum
Institute, Washington,
DC
ISA-RP 3.2 Flange MOlmted Sharp Edged Orífice
The Measurement ofGas Flo\\', January '83 Journal of the Air PolIution Control Association
10. ASHRAE
ASHRAE, American Society of Heating, Refrigerating and Air-Conditioning Engineers, Atlanta, GA
ASME, American New York, NY
Society of Mechanical
Engineers,
Standard 41.5, Standard Measurement
Guide-Engineering Data
.4naZl·sis of E\perimental
See building element leak test references and instrumentation
in Appendix
I.
".