1、Designation: E1529 16 An American National StandardStandard Test Methods forDetermining Effects of Large Hydrocarbon Pool Fires onStructural Members and Assemblies1This standard is issued under the fixed designation E1529; the number immediately following the designation indicates the year oforigina
2、l adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon () indicates an editorial change since the last revision or reapproval.INTRODUCTIONThe performance of structural members and assemblies exposed to fi
3、re conditions resulting fromlarge, free-burning (that is, outdoors), fluid-hydrocarbon-fueled pool fires is of concern in the designof hydrocarbon processing industry (HPI) facilities and other facilities subject to these types of fires.In recognition of this unique fire protection problem, it is ge
4、nerally required that critical structuralmembers and assemblies be of fire-resistant construction.Historically, such requirements have been based upon tests conducted in accordance with TestMethods E119, the only available standardized test for fire resistant construction. However, theexposure speci
5、fied in Test Methods E119 does not adequately characterize large hydrocarbon poolfires. Test Methods E119 is used for representation of building fires where the primary fuel is solid innature, and in which there are significant constraints on the movement of air to the fire, and thecombustion produc
6、ts away from the fire (that is, through doors, windows). In contrast, neithercondition is typical of large hydrocarbon pool fires (see Appendix X1 on Commentary).One of the most distinguishing features of the pool fire is the rapid development of hightemperatures and heat fluxes that can subject exp
7、osed structural members and assemblies to a thermalshock much greater than that associated with Test Methods E119. As a result, it is important that fireresistance requirements for HPI assemblies of all types of materials be evaluated and specified inaccordance with a standardized test that is more
8、representative of the anticipated fire conditions. Sucha standard is found in the test methods herein.1. Scope*1.1 The test methods described in this fire-test-responsestandard are used for determining the fire-test response ofcolumns, girders, beams or similar structural members, andfire-containmen
9、t walls, of either homogeneous or compositeconstruction, that are employed in HPI or other facilitiessubject to large hydrocarbon pool fires.1.2 It is the intent that tests conducted in accordance withthese test methods will indicate whether structural members ofassemblies, or fire-containment wall
10、assemblies, will continueto perform their intended function during the period of fireexposure. These tests shall not be construed as having deter-mined suitability for use after fire exposure.1.3 These test methods prescribe a standard fire exposurefor comparing the relative performance of different
11、 structuraland fire-containment wall assemblies under controlled labora-tory conditions. The application of these test results to predictthe performance of actual assemblies when exposed to largepool fires requires a careful engineering evaluation.1.4 These test methods provide for quantitative heat
12、 fluxmeasurements during both the control calibration and theactual test. These heat flux measurements are being made tosupport the development of design fires and the use of firesafety engineering models to predict thermal exposure andmaterial performance in a wide range of fire scenarios.1.5 These
13、 test methods are useful for testing other itemssuch as piping, electrical circuits in conduit, floors or decks,and cable trays. Testing of these types of items requiresdevelopment of appropriate specimen details and end-point orfailure criteria. Such failure criteria and test specimen descrip-tions
14、 are not provided in these test methods.1.6 LimitationsThese test methods do not provide thefollowing:1.6.1 Full information on the performance of assembliesconstructed with components or of dimensions other than thosetested.1These test methods are under the jurisdiction ofASTM Committee E05 on Fire
15、Standards and are the direct responsibility of Subcommittee E05.11 on FireResistance.Current edition approved Nov. 1, 2016. Published December 2016. Originallyapproved in 1993. Last previous edition approved in 2014 as E1529 14a. DOI:10.1520/E1529-16.*A Summary of Changes section appears at the end
16、of this standardCopyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United StatesThis international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for theDeve
17、lopment of International Standards, Guides and Recommendations issued by the World Trade Organiziation Technical Barriers to Trade (TBT) Committee.11.6.2 An evaluation of the degree to which the assemblycontributes to the fire hazard through the generation of smoke,toxic gases, or other products of
18、combustion.1.6.3 Simulation of fire behavior of joints or connectionsbetween structural elements such as beam-to-column connec-tions.1.6.4 Measurement of flame spread over the surface of thetest assembly.1.6.5 Procedures for measuring the test performance ofother structural shapes (such as vessel sk
19、irts), equipment (suchas electrical cables, motor-operated valves, etc.), or itemssubject to large hydrocarbon pool fires, other than thosedescribed in 1.1.1.6.6 The erosive effect that the velocities or turbulence, orboth, generated in large pool fires has on some fire protectionmaterials.1.6.7 Ful
20、l information on the performance of assemblies attimes less than 5 min because the rise time called out in Section5 is longer than that of a real fire.1.7 These test methods do not preclude the use of a real fireor any other method of evaluating the performance of structuralmembers and assemblies in
21、 simulated fire conditions. Any testmethod that is demonstrated to comply with Section 5 isacceptable.1.8 The values stated in inch-pound units are to be regardedas standard. The values given in parentheses are mathematicalconversions to SI units that are provided for information onlyand are not con
22、sidered standard.1.9 This standard is used to measure and describe theresponse of materials, products, or assemblies to heat andflame under controlled conditions, but does not by itselfincorporate all factors required for fire hazard or fire riskassessment of the materials, products, or assemblies u
23、nderactual fire conditions.1.10 This standard does not purport to address all of thesafety concerns, if any, associated with its use. It is theresponsibility of the user of this standard to establish appro-priate safety and health practices and determine the applica-bility of regulatory limitations
24、prior to use.1.11 The text of this standard references notes and footnoteswhich provide explanatory information. These notes and foot-notes (excluding those in tables and figures) shall not beconsidered as requirements of the standard.2. Referenced Documents2.1 ASTM Standards:2B117 Practice for Oper
25、ating Salt Spray (Fog) ApparatusD822 Practice for Filtered Open-Flame Carbon-Arc Expo-sures of Paint and Related CoatingsE119 Test Methods for Fire Tests of Building Constructionand MaterialsE176 Terminology of Fire StandardsE457 Test Method for Measuring Heat-Transfer Rate Usinga Thermal Capacitanc
26、e (Slug) CalorimeterE459 Test Method for Measuring Heat Transfer Rate Usinga Thin-Skin CalorimeterE511 Test Method for Measuring Heat Flux Using a Copper-Constantan Circular Foil, Heat-Flux TransducerE814 Test Method for Fire Tests of Penetration FirestopSystemsE2683 Test Method for Measuring Heat F
27、lux Using Flush-Mounted Insert Temperature-Gradient Gages2.2 Code of Federal Regulations:346 CFR 164.007 Structural Insulations2.3 IMO Documents:4IMO A7542.4 ISO Standard:5ISO 834-1 Fire Resistance Tests Elements of BuildingConstruction Part 1: General Requirements2.5 ISO/IEC Standards:617011 Confor
28、mity assessmentGeneral Requirements foraccreditation bodies accrediting conformity assessmentbodies17025 General requirements for the competence of testingand calibration laboratories3. Terminology3.1 DefinitionsRefer to Terminology E176 for definitionsof terms used in these test methods.3.2 Definit
29、ions of Terms Specific to This Standard:3.2.1 total cold wall heat fluxthe heat flux that would betransferred to an object whose temperature is 70F (21C).4. Summary of Test Methods4.1 A standard fire exposure of controlled extent and sever-ity is specified.The test setup will provide an average tota
30、l coldwall heat flux on all exposed surfaces of the test specimen of50 000 Btu/ft2h 6 2500 Btu/ft2h (158 kW/m26 8kW/m2).The heat flux shall be attained within the first 5 min of testexposure and maintained for the duration of the test. Thetemperature of the environment that generates the heat flux o
31、fprocedures in 6.2 shall be at least 1500F (815C) after the first3 min of the test and shall be between 1850F (1010C) and2150F (1180C) at all times after the first 5 min of the test.Performance is defined as the time period during whichstructural members or assemblies will continue to perform theiri
32、ntended function when subjected to fire exposure. The resultsare reported in terms of time increments such as12 h,34 h, 1h, 112 h, etc.2For referenced ASTM standards, visit the ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual Book of ASTMStandards volume inf
33、ormation, refer to the standards Document Summary page onthe ASTM website.3Available from Standardization Documents Order Desk, Bldg. 4 Section D, 700Robbins Ave., Philadelphia, PA 19111-5094, Attn: NPODS.4Available from the International Maritime Organization (IMO), EnvironmentalStandards Division
34、(CG-5224), U.S. Coast Guard Headquarters, 2100 Second StreetSW, Washington, DC 20593; http:/www.uscg.mil/environmental_standards/5Available from American National Standards Institute (ANSI), 25 W. 43rd St.,4th Floor, New York, NY 10036, http:/www.ansi.org.6Available from International Organization f
35、or Standardization (ISO), ISOCentral Secretariat, BIBC II, Chemin de Blandonnet 8, CP 401, 1214 Vernier,Geneva, Switzerland, http:/www.iso.org.E1529 1624.1.1 These test methods require quantitative measurementsof thermal exposure during both furnace calibration and actualtesting.4.1.2 These test met
36、hods are cited as the “Standard LargeHydrocarbon Pool Fire Tests.”5. Significance and Use5.1 These test methods are intended to provide a basis forevaluating the time period during which a beam, girder,column, or similar structural assembly, or a nonbearing wall,will continue to perform its intended
37、 function when subjectedto a controlled, standardized fire exposure.5.1.1 In particular, the selected standard exposure conditionsimulates the condition of total continuous engulfment of amember or assembly in the luminous flame (fire plume) area ofa large free-burning-fluid-hydrocarbon pool fire. T
38、he standardfire exposure is basically defined in terms of the total fluxincident on the test specimen together with appropriate tem-perature conditions. Quantitative measurements of the thermalexposure (total heat flux) are required during both furnacecalibration and actual testing.5.1.2 It is recog
39、nized that the thermodynamic properties offree-burning, hydrocarbon fluid pool fires have not beencompletely characterized and are variable depending on thesize of the fire, the fuel, environmental factors (such as windconditions), the physical relationship of the structural memberto the exposing fi
40、re, and other factors.As a result, the exposurespecified in these test methods is not necessarily representativeof all the conditions that exist in large hydrocarbon pool fires.The specified standard exposure is based upon the bestavailable information and testing technology. It provides abasis for
41、comparing the relative performance of differentassemblies under controlled conditions.5.1.3 Any variation to construction or conditions (that is,size, method of assembly, and materials) from that of the testedassembly is capable of substantially changing the performancecharacteristics of the assembl
42、y.5.2 Separate procedures are specified for testing columnspecimens with and without an applied superimposed load.5.2.1 The procedures for testing loaded columns stipulatethat the load shall be applied axially. The applied load is to bethe maximum load condition allowed under nationally recog-nized
43、structural design criteria unless limited design criteria arespecified and a corresponding reduced load applied.5.2.2 The procedure for testing unloaded steel columnspecimens includes temperature limits. These limits are in-tended to define the temperature above which a steel columnwith an axially a
44、pplied design allowable load would failstructurally.5.2.3 The procedure for unloaded specimens also providesfor the testing of other than steel columns provided thatappropriate acceptance criteria have been established.5.3 Separate procedures are also specified for testing beamassemblies with and wi
45、thout an applied superimposed load.5.3.1 The procedure for testing loaded specimens stipulatesthat the beam shall be simply supported. Application ofrestraint against longitudinal thermal expansion depends on theintended use, as specified by the customer. The applied load isintended to be the allowa
46、ble design load permitted for the beamas determined in accordance with accepted engineering prac-tice.5.3.2 The procedure for testing unloaded beams includestemperature limits for steel. These limits are to define thetemperature above which a simply supported, unrestrainedbeam would fail structurall
47、y if subjected to the allowabledesign load. The procedure for unloaded specimens alsoprovides for the testing of other than steel and reinforcedconcrete beams provided that appropriate acceptance criteriahave been established.5.3.3 It is recognized that beam assemblies that are testedwithout load wi
48、ll not deflect to the same extent as an identicalassembly tested with load. As a result, tests conducted inaccordance with the unloaded beam procedure are not intendedto reflect the effects of crack formation, dislodgement ofapplied fire protection materials, and other factors that areinfluenced by
49、the deflection of the assembly.5.4 A separate procedure is specified for testing the fire-containment capability of a wall/bulkhead/partition, etc. Ac-ceptance criteria include temperature rise of nonfire exposedsurface, plus the ability of the wall to prohibit passage offlames or hot gases, or both.5.5 In most cases, the structural assemblies that will beevaluated in accordance with these test methods will be locatedoutdoors and subjected to varying weather conditions that arecapable of adversely affecting the fire endurance of theassembly. A program of acce