1、Designation: C165 07 (Reapproved 2017)Standard Test Method forMeasuring Compressive Properties of Thermal Insulations1This standard is issued under the fixed designation C165; the number immediately following the designation indicates the year oforiginal adoption or, in the case of revision, the yea
2、r 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.This standard has been approved for use by agencies of the U.S. Department of Defense.1. Scope1.1 This test method covers two
3、 procedures for determiningthe compressive resistance of thermal insulations.1.1.1 Procedure A covers thermal insulations having anapproximate straight-line portion of a load-deformation curve,with or without an identifiable yield point as shown in Figs. 1and 2. Such behavior is typical of most rigi
4、d board orblock-type insulations.1.1.2 Procedure B covers thermal insulations that becomeincreasingly more stiff as load is increased, as shown in Fig. 3.Such behavior is typical of fibrous batt and blanket insulationsthat have been compressed previously to at least the samedeformation by compressio
5、n packaging or mechanical soften-ing.1.2 It is recognized that the classification of materials underProcedures A and B shall not hold in all cases. For example,some batt or blanket materials that have not been compressionpackaged will exhibit behavior more typical of ProcedureAfortheir first loading
6、s.Also, some higher density fibrous insulationboards that have been precompressed will exhibit load-deformation curves more typical of Procedure B. There willalso be thermal insulations with load-deformation curves thatfollow none of the three types shown here; that is, curves withno straight-line p
7、ortion, curves with compaction areas, andcurves that change from negative to positive slope.1.3 This test method does not cover reflective or loose fillinsulations.1.4 The values stated in inch-pound units are to be regardedas the standard. The values given in parentheses are forinformation only.1.5
8、 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, health, and environmental practices and deter-mine the applicability of regulatory limitations prior to use.1.
9、6 This international standard was developed in accor-dance with internationally recognized principles on standard-ization established in the Decision on Principles for theDevelopment of International Standards, Guides and Recom-mendations issued by the World Trade Organization TechnicalBarriers to T
10、rade (TBT) Committee.2. Referenced Documents2.1 ASTM Standards:2C167 Test Methods for Thickness and Density of Blanket orBatt Thermal InsulationsC168 Terminology Relating to Thermal InsulationC240 Test Methods of Testing Cellular Glass InsulationBlockE4 Practices for Force Verification of Testing Ma
11、chinesE177 Practice for Use of the Terms Precision and Bias inASTM Test MethodsE691 Practice for Conducting an Interlaboratory Study toDetermine the Precision of a Test Method3. Terminology3.1 Definitions:3.1.1 Terminology C168 applies to the terms used in thismethod.3.2 Additional terms are defined
12、 as follows:3.3 compressive deformationthe decrease in specimenthickness by a compressive load.3.4 compressive loadthe compressive force carried by thetest specimen at any given moment.3.5 compressive modulus of elasticitythe ratio of thecompressive load per unit of original area to the correspondin
13、gdeformation per unit of original thickness below the propor-tional limit of a material.3.6 compressive resistancethe compressive load per unitof original area at a specified deformation. For those materialswhere the specified deformation is regarded as indicating the1This test method is under the j
14、urisdiction ofASTM Committee C16 on ThermalInsulation and is the direct responsibility of Subcommittee C16.32 on MechanicalProperties.Current edition approved Sept. 1, 2017. Published December 2017. Originallyapproved in 1941. Last previous edition approved in 2012 as C165 07 (2012).DOI: 10.1520/C01
15、65-07R17.2For referenced ASTM standards, visit the 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.Copyright ASTM International, 100 Barr Harbor Drive,
16、 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 theDevelopment of International Standards, Guides and Recommendations issue
17、d by the World Trade Organization Technical Barriers to Trade (TBT) Committee.1start of complete failure, the compressive resistance mayproperly be called the compressive strength.3.7 proportional limit in compressionthe greatest com-pressive load that a material is capable of sustaining withoutany
18、deviation from proportionality of load to deformation.3.8 yield point in compressionthe load at the first point onthe load-deformation curve at which an increase in deformationoccurs without an increase in load.4. Significance and Use4.1 In providing Procedures A and B, it is recognized thatdifferen
19、t types of thermal insulation will exhibit significantlydifferent behavior under compressive load. Data must usuallybe obtained from a complete load-deformation curve, and theuseful working range normally corresponds to only a portion ofthe curve. The user is cautioned against use of the product int
20、he range beyond which the product is permanently damaged orproperties are adversely affected.4.2 Load-deformation curves provide useful data for re-search and development, quality control, specification accep-tance or rejection, and for other special purposes. Standardloading rates shall not be used
21、 arbitrarily for all purposes; theeffects of impact, creep, fatigue, and repeated cycling must beconsidered. All load-deformation data shall be reviewed care-fully for applicability prior to acceptance for use in engineeringdesigns differing widely in load, load application rate, andmaterial dimensi
22、ons involved.5. Apparatus5.1 Testing MachineStandard hydraulic or mechanicalcompression testing machine of suitable capacity, and capableof operating at the specified constant rate of motion of themovable head. Verify the accuracy of the testing machine inaccordance with Practices E4.5.2 Loading Sur
23、facesSurfaces shall be at least 1.0 in.(25.4 mm) greater in all directions than the test specimens, andshall be designed to remain plane within 60.003 in./ft (60.25mm/m) under all conditions of load.5.2.1 Procedure AA preferred size is 8.0 in. (203 mm)square. One surface plate, either the upper or l
24、ower, shall bemounted rigidly with its surface perpendicular to the testingmachine axis. The other surface plate shall be self-aligning,suspended by a spherical bearing block as shown in Fig. 4.FIG. 1 Procedure AStraight Line Portion with Definite YieldPointFIG. 2 Procedure AStraight Line Portion bu
25、t no Definite YieldPointFIG. 3 Procedure BIncreasing StiffnessFIG. 4 Spherical Bearing Block for Compressive Strength TestC165 07 (2017)25.2.2 Procedure BA preferred size is 1.0 ft2(0.093 m2)inarea, either 12 in. (305 mm) square or 13.54 in. (344 mm) indiameter. Both plates shall be mounted rigidly
26、so that thesurfaces are parallel to each other and perpendicular to thetesting machine axis.5.3 Load IndicatorLoad-indicating mechanism that willpermit measurements with an accuracy of 61 % of total load.5.4 Deformation IndicatorDeformation-indicatingmechanism that measures crosshead movement, or a
27、simple jigthat will permit direct measurements, with an accuracy of60.1 % of specimen thickness. When crosshead movement isused to measure deformation, use a calibration curve unless ithas been shown that under the conditions of test the crossheadindicator gives an accurate measure of specimen defor
28、mation.5.5 Measuring Instruments:5.5.1 Dial Gage Comparator, with a circular foot having aminimum area of 1.00 in.2(645 mm2) and capable of measur-ing thickness to 60.002 in. (60.05 mm).5.5.2 Steel Rule, capable of measuring to 60.01 in. (0.25mm).5.5.3 Depth Gage, pin-type, as specified in Test Meth
29、odsC167 for Procedure B only.5.6 Drying or Conditioning Equipment (see 6.5):5.6.1 Drying Oven, temperatures to 250F (121C).5.6.2 Desiccator, using dry calcium chloride or silica geldesiccant.5.6.3 Conditioned Space, at temperature of 73.4 6 3.6F(23 6 2C), and relative humidity of 50 6 5%.6. Test Spe
30、cimens6.1 Specimen Size:6.1.1 Procedure A specimens shall preferably be square orcircular with a minimum area of 4 in.2(2580 mm2) and apreferred width or diameter of 6 in. (150 mm). The minimumthickness shall be12 in. (12.7 mm) and the maximum thicknessshall be no greater than the width or diameter.
31、NOTE 1See Test Methods C240 for preparation of cellular glass testspecimens.6.1.2 Procedure B specimens shall preferably be square orcircular with a minimum width or diameter of 6.0 in. (153mm). The minimum thickness shall be 1.0 in. (25.4 mm) andthe maximum thickness shall be no greater than the wi
32、dth ordiameter.NOTE 2For some materials, the specimen thickness has considerableeffect on the deformation at yield, the compressive resistance, and thecompressive modulus. Therefore, use the same thickness for comparisonswith other test specimens. The thinner the specimen, the higher thecompressive
33、resistance and the lower the deformation at yield.6.2 The number of specimens to be tested and the samplingplan shall conform to materials specifications where appli-cable. In the absence of such specifications the minimumnumber of specimens shall be at least four, chosen at random torepresent the l
34、ot.6.3 The specimens shall be cut from larger blocks orirregular shapes in such a manner as to preserve as many of theoriginal surfaces as possible. The bearing faces of the testspecimens shall be plane, parallel to each other, and perpen-dicular to the sides. Where the original surfaces of the bloc
35、k aresubstantially plane and parallel, no special preparation of thesurfaces will usually be necessary. In preparing specimensfrom pieces of irregular shape, any means that will produce aspecimen with plane and parallel faces without weakening thestructure of the specimen shall be used.6.4 The speci
36、mens shall be prepared so that the direction ofloading will be the same as that on the insulation in service. Ifthe direction of loading in service is unknown and the materialis suspected of being anisotropic, different sets of test speci-mens shall be prepared with compression axes parallel to thed
37、ifferent directions of loading that might occur.6.5 The specimens shall be dried and conditioned prior totest, following applicable specifications for the material. If thematerial is affected adversely by oven temperatures, the speci-mens shall be conditioned for not less than 40 h at 73.4 6 1.8F(23
38、 6 1C), and 50 6 5 % relative humidity before testing. Inthe absence of definitive drying specifications, the specimensshall be dried in an oven at 215 to 250F (102 to 121C) toconstant mass and held in a desiccator to cool to roomtemperature before testing. Where circumstances or require-ments precl
39、ude compliance with these conditioningprocedures, exceptions agreed upon between the manufacturerand the purchaser shall be specifically listed in the test report.7. Procedures7.1 Procedure A:7.1.1 Measure the specimen dimensions within 61 %. Eachdimension shall be the average of at least two measur
40、ementstaken on each specimen face. Use the steel rule and the dialgage comparator as appropriate.7.1.2 Place the specimen between the loading surfaces ofthe testing machine, taking care that the centerline of thespecimen coincides with the centerline of the testing machineso that the load will be un
41、iformly distributed. The self-aligningsurface shall be approximately parallel to the fixed plate. Keepthe spherical bearing seat well lubricated to ensure freemovement.7.1.3 Adjust the crosshead speed to the value specified forthe material being tested. This shall not exceed the range from0.01 to 0.
42、5 in./min (0.25 to 12.7 mm/min) for each 1 in. (25.4mm) of specimen thickness. In the absence of suchspecification, the speed shall be 0.05 in./min (1.27 mm/min) foreach 1 in. of specimen thickness.NOTE 3The speed of crosshead travel will have considerable effect onthe compressive resistance value.
43、In general, higher crosshead speedsusually result in higher compressive resistance values. Take this intoaccount in selecting crosshead speed other than standard when comparingdifferent types of thermal insulation.7.1.4 To reduce the time for the loading head to contact thetest specimen, the crosshe
44、ad shall be moved at a rapid untilcontact with the specimen is made. This will cause a slightpreload to be applied to the specimen. Change the loadingspeed to the required value once contact is made. This preloadshall not be more than 2% of the load at the final deformation.NOTE 4If this test method
45、 is used in specifications or by specifiers toC165 07 (2017)3characterize the compressive resistance of a material, any preload valueused must be specified.7.1.5 Compress the specimen to the desired deformation.Record the loads and deformations at points that will ad-equately describe a load-deforma
46、tion curve.7.2 Procedure B:7.2.1 Measure the specimen face dimensions within 61%using the steel rule. Each dimension shall be the average of atleast two measurements taken on each specimen face.7.2.2 Measure the specimen thickness to 61 %. Use thepin-type depth gage and follow Test Methods C167 if t
47、hematerial is pin-penetrable. If it is not, use the dial gagecomparator. Average three measurements.7.2.3 Place the specimen between the loading surfaces ofthe testing machine, taking care that the centerlines of thespecimen and the testing machine coincide.7.2.4 Adjust the crosshead speed to a maxi
48、mum of 5 in./min(125 mm/min), but follow material specifications if a differentspeed is specified (see Note 3 above).7.2.5 Compress the specimen to the desired deformation ofeither 10 or 25 % of the thickness measured in 7.2.2 or of thenominal thickness if so specified. To reduce variability insampl
49、e sets with densities greater than 3 lbs/ft3(48 kg/m3), theinitial deformation point on the load curve must be chosen at afixed preload. Preload values shall be less than 2 % of the loadat 10 % deformation.NOTE 5If this test method is used in specifications or by specifiers tocharacterize the compressive resistance of a material, any preload value tobe used must be specified.8. Calculations8.1 Procedure A:8.1.1 Construct a load-deformation curve.8.1.2 Using a straightedge, carefully extend to the zero loadline the steepest straight portion of the load-