1、Designation: F2523 07 (Reapproved 2013)Standard Practice forBlowout Resistance of Room-Temperature VulcanizedElastomers1This standard is issued under the fixed designation F2523; the number immediately following the designation indicates the year oforiginal adoption or, in the case of revision, the
2、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.1. Scope1.1 This practice provides a means to determine the blowoutresistance of a room-temperature vulcanized elastomer s
3、ystem(RTV) using a standard fixture.1.2 The values stated in SI units are to be regarded asstandard. No other units of measurement are included in thisstandard.1.3 This standard does not purport to address all of thesafety concerns, if any, associated with its use. It is theresponsibility of the use
4、r of this standard to establish appro-priate safety and health practices and determine the applica-bility of regulatory limitations prior to use.2. Referenced Documents2.1 ASTM Standards:2D907 Terminology of AdhesivesD1566 Terminology Relating to RubberF2468 Classification for Specifying Silicone Ad
5、hesives andSealants for Transportation Applications2.2 SAE Standard:SAE J1199 Mechanical and Material Requirements for Met-ric Externally Threaded Steel Fasteners33. Terminology3.1 DefinitionsSome terms in this practice are defined inTerminologies D907 and D1566.3.2 Definitions of Terms Specific to
6、This Standard:3.2.1 blowout, ndisruption of the uncured RTV integrityin a joint from system pressurization resulting in sudden loss ofpressure.3.2.2 Tjoint, ninterface created in a sealing surfacewhere three structural components meet.3.2.2.1 DiscussionThis interface may exist as a small gaprequirin
7、g a material such as room-temperature vulcanizedelastomer (RTV) to seal.3.3 Acronyms:3.3.1 RTVroom-temperature vulcanized elastomer4. Summary of Practice4.1 Condensation cures RTVs as a one-component systemcure when exposed to moisture in the ambient air or astwo-component systems when those compone
8、nts are mixedtogether. RTVs are often used to seal joints where three flangesmeet (T joints) such as an automotive engines front cover,engine block, and oil pan. Because of machining and assemblytolerance variations, these T joints may have a slight misalign-ment or gap. We also find gaps in the hal
9、f-round area of the oilpan to block and in the valley between the intake manifold andblock on certain V-engines as a result of manufacturingtolerances. The RTV is used to seal in fluids. In some assemblyline applications, soon after the RTV is applied and the flangesfastened together, the system is
10、subjected to an air decay test ata designated pressure. This test is used to determine an RTVscapability to withstand loss of integrity at this designatedpressure.4.2 When using this practice, one must first determine themaximum gap based on stack tolerances of the system. Atwo-piece round fixture u
11、ses the top portion to mirror thesystem gap (default gap is 1 mm), while the bottom halfprovides the mating flange and the connection for the pressureinput. The gap is machined into the top half of the fixture in a“pie slice” 60 angle. A continuous bead of RTV is applied tothe entire bottom portion
12、of the fixture, the top half is carefullyattached, and the fixture is pressurized to the prescribed limitsand held for a specified time period. If the RTV is not capableof sealing at the pressure applied, a sudden loss of pressure willoccur.1This practice is under the jurisdiction ofASTM Committee F
13、03 on Gaskets andis the direct responsibility of Subcommittee F03.70 on Formed in Place Gaskets.Current edition approved May 1, 2013. Published May 2013. Originallyapproved in 2005. Last previous edition approved in 2007 as F2523 071. DOI:10.1520/F2523-07R13.2For referenced ASTM standards, visit the
14、 ASTM website, www.astm.org, orcontact ASTM Customer Service at serviceastm.org. For Annual Book of ASTMStandards volume information, refer to the standards Document Summary page onthe ASTM website.3Available from Society of Automotive Engineers (SAE), 400 CommonwealthDr., Warrendale, PA 15096-0001.
15、Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States15. Significance and Use5.1 This practice may be used to determine the viability ofan RTV sealant to withstand pressure leak testing before cureat maximum gap conditions of a system. This
16、 practice may beused to indicate an RTVs acceptability to undergo an assemblyline leak check without causing a leak path due to materialblow out.6. Apparatus46.1 FixtureAluminum, see Fig. 1.6.1.1 Aluminum casting, forging, or bar stock with 60Brinell hardness, minimum.6.1.2 Surface finish shall be i
17、n the range of 0.7 to 3.2 m Ra.6.1.3 Top half of fixture shall have a machined cutout to thedesired gap depth (1.0 6 0.025 mm default gap), per Fig. 1.The gap and flange width are critical dimensions and should becontrolled to a tight tolerance (62.5 % is recommended). Allother dimensions are allowe
18、d 610 %.6.1.4 Four nut, bolt, and washer sets per SAE J1199 (4.8 hexhead) or equivalent, M10 1.5 50.6.2 Air supply and regulator.6.3 Polyethylene tubing (or equivalent), polytetrafluoroeth-ylene (PTFE) pipe tape, plastic, or brass tube fittings.6.4 Inline pressure gage or equivalent, 0 to 138 kPa,ac
19、curate to 60.7 kPa.6.5 Timing device with 1-s increments.6.6 Measuring device, capable of measuring an adhesivebead height of 2 mm.6.7 Environmentally controlled room (temperature, humid-ity monitoring, and control).7. Reagents and Materials7.1 Cleaning SolventAppropriate cleaning solvent asspecifie
20、d by RTV manufacturer.7.2 Clean, lint-free cloth.8. Conditioning8.1 Sample containers shall be allowed to equilibrate to 21to 25C. Time required may vary depending on the size ofcontainer and previous storage conditions.9. Initial Step9.1 Connect air supply to regulator and to pressure gageusing pol
21、yethylene tubing. Plastic or brass press fit fittings maybe used for the connection points, depending on the adaptorconnection on the three components. Fittings threads shall havepipe sealant applied before installing into fixtures.9.2 Connect tube to bottom fixture with a brass fittingcontaining pi
22、pe sealant applied around threads.9.3 Block off open hole of fixture with a properly securedrubber stopper or compress a soft silicone plaque against thehole. Check for leaks at the various connection points byspraying a dilute liquid soap and water solution5while lookingfor air bubbles.9.4 Test env
23、ironment shall be set at 21 to 25C and 40 610 % relative humidity.10. Procedure10.1 Use either the default gap of 1 mm or choose a fixturewith the desired machined gap.10.2 Make sure all traces of cured or uncured RTV fromprevious test have been removed.10.3 Following the initial setup instructions
24、in Section 9,verify the system is free of leaks.10.4 Method ATime to Blowout at a Specified Pressure:10.4.1 Preset pressure regulator to the applicable test pres-sure.10.4.2 Open exhaust valve to prevent any pretest internalpressure and close inlet ball valve.10.4.3 Apply a continuous 4-mm bead (bas
25、ed on defaultgap, user will have to determine proper bead size for alternategaps) on the flange of the bottom fixture.10.4.4 Apply the top half of the fixture, taking care not tomove the fixture horizontally.10.4.5 Tighten bolts to 1.0 kgm 6 10 %.10.4.6 Close exhaust valve.10.4.7 Immediately after a
26、ssembly (within 2 min of RTVapplication) open ball valve to pressurize the system quickly tothe preset pressure.10.4.8 Start the timer and record the time in seconds atwhich the sudden loss of pressure occurs. If no loss of pressureoccurs after 1 min, report it as “60 s.”10.4.9 Disassemble and clean
27、 the fixture thoroughly, remov-ing all traces of RTV.10.4.10 Repeat Steps 10.4.1 to 10.4.9 a second time.10.4.11 If the second result is within 610 % of the firstresult, report the average blowout time to the nearest second.10.4.12 If the second result is in excess of 610 % of thefirst, repeat until
28、 a consistent value is obtained.10.5 Method BMaximum Blowout Pressure Determina-tion:10.5.1 Method B shall be done at or near maximumapplication/flow rate of the sealant.10.5.2 Open exhaust valve to prevent any pretest internalpressure and close inlet ball valve.10.5.3 Apply a continuous 4-mm bead (
29、based on defaultgap, user will have to determine proper bead size for alternategaps) on the flange of the bottom fixture.10.5.4 Apply the top half of the fixture taking care not tomove the fixture horizontally.10.5.5 Tighten bolts to 1.0 kgm 6 10 %.10.5.6 Close exhaust valve.10.5.7 Screen for approx
30、imate blow out pressure by open-ing the ball valve immediately after assembly (within 2 min of4The sole source of supply of the blowout fixtures in both materials known to thecommittee at this time is Kovil Manufacturing, 925 Sherman Ave., Hamden, CT06514. If you are aware of alternative suppliers,
31、please provide this information toASTM International Headquarters. Your comments will receive careful consider-ation at a meeting of the responsible technical committee,1which you may attend.5Commercially available products exist from a wide variety of distributors.F2523 07 (2013)2RTV application),
32、so as to increase the pressure by 6.9 kPaevery 10 s until blow out occurs. Subsequent iterations todetermine blow out pressure may start 6.9 kPa below thisscreening pressure. If this screen pressure is at or below 20.7kPa, the iterations shall use 3.45 kPa increments in thismethod; otherwise the inc
33、rements shall be 6.9 kPa.NOTE 1Torque sequence shall be “crisscross” pattern.FIG. 1 Aluminum Blowout FixturesF2523 07 (2013)310.5.8 Immediately after assembly (within 2 min of RTVapplication), open the ball valve and start incrementally in-creasing the pressure every 5 s until the initial pressure o
34、f thescreening pressure minus 6.89 kPa is reached.10.5.9 Start the timer. If no loss of pressure occurs after 1min, incrementally increase the pressure and start the timer.Repeat this process until failure occurs and record this value.10.5.10 Disassemble and clean the fixture thoroughly, re-moving a
35、ll traces of RTV.10.5.11 Repeat the steps in 10.5.1 through 10.5.10, using thevalue obtained in 10.5.9. If this again results in a failure, cleanthe fixture and repeat the process using the value obtained in10.5.9 minus 6.9 kPa.10.5.12 If failure occurs, repeat the process of cleaning andapplying fr
36、esh RTV and testing, each time reducing thepressure until a “pass” occurs, then record this pressure.10.5.13 Repeat the test a second time at this pressure toverify a “pass.” Report this value as the maximum blowoutpressure.11. Potential Failure Modes of Test Procedure11.1 Inconsistent results in th
37、e procedure may be due toseveral reasons and shall be reviewed. Some of these may be:11.1.1 Inconsistent RTV bead applied. RTV should beapplied in an amount sufficient to fill the gap when the fixtureis assembled and bolts torqued. Insufficient RTV will result invoids within the fixture gap. These v
38、oids will result inpremature failure when running Method A, and possible lowerpressure values when running Method B. Excessive RTVapplied in the fixture gap will result in an internal and externaldam of RTV that will resist movement of air by the appliedpressure. This can result in artificially high
39、 time to blow out(Method A) and resistance to blow out pressure (Method B).11.1.2 Misplacement of bead. RTV bead biased toward theinside or outside can result in non-fill of the fixture gap,resulting in lower time to blow out (Method A) and resis-tistance to blow out pressure (Method B). Addition of
40、 RTV tocompensate for this offset of the bead placement can result inan excessive amount of RTV, and is further discussed in 11.1.1.11.1.3 Air entrapment in RTV bead. Entrapment of air orother contaminants that create voids in the RTV can createresults similar to insufficient RTV application, and is
41、 furtherdiscussed in 11.1.1.11.1.4 Improper gap. The induced gap should be machinedprecisely to the agreed dimension within the tolerance limitstated in 6.1.3 (1 mm is the default gap). Failure to properly setgap will result in correlation issues between laboratories. Useof fixtures with improperly
42、low gaps can result in artificiallyhigh results. Use of fixtures with improperly high gaps canresult in artificially low results.11.1.5 Improper torque sequence or setting. Improper se-quence can result in inconsistent gap fill or shifting of RTVbead, or both, thus providing inconsistent and impreci
43、seresults. Low bolt torque can result in shimming of fixturecreating a slightly larger than desired gap, and artificially lowdata.11.1.6 Contamination by improperly cleaned fixture. Im-properly cleaned flanges in the non-gap areas can causeshimming of the fixture which may result in artificially low
44、data. Improperly cleaned flanges in the gap area can result ineither artificially high or low data, depending on how thecontaminant acts on the fresh RTV bead during fixture assem-bly. Contaminants such as partially cured RTV encapsulated bythe bead can cause air entrapment and voids which may resul
45、tin artificially low data. Partially cured RTV carried on theinside edge of the fresh bead can act as a barrier to airmovement through the bead resulting in artificially high data.11.1.7 Faulty pressure regulator or pressure measurementdevice, or both. Faulty equipment will provide unreliable andun-
46、correlatable data with other laboratories.11.1.8 Air leaks within the system, some of which can varyvia fixture handling and movement. Air leaks prior to thepressure regulator system may cause variations of availablepressure between the source and the regulator.This could causeerratic data if the so
47、urce setting is close to the pressure beingapplied by the regulator to the fixture. Air leaks between theregulator and the fixture will result in artificially high data.11.1.9 Low-viscosity RTVs evaluated with large gaps mayresult in lower between lab correlation.12. Report12.1 Report shall consist
48、of:12.1.1 Material classification per Classification F2468,12.1.2 Fixture type used in the evaluation,12.1.3 Fixture gap used in the evaluation,12.1.4 Laboratory test environment (temperature and rela-tive humidity) and location,12.1.5 Material supplier and product code,12.1.6 Application rate(s) ev
49、aluated,12.1.7 Method used, and12.1.8 Average blowout time in seconds for MethodAalongwith test pressure and maximum blowout resistance pressurefor Method B.13. Precision and Accuracy613.1 Statements are included for Method B, Blow OutPressure Determination only.13.1.1 RepeatabilityTwo test results obtained within onelaboratory shall be judged not equivalent if they differ by morethan the “r” value for that material; “r” is the intervalrepresenting the critical difference between two test results forthe same material, obtained by the same operator using t
