1、Designation: C497 16aC497 17Standard Test Methods forConcrete Pipe, Manhole Sections, or Tile1This standard is issued under the fixed designation C497; the number immediately following the designation indicates the year oforiginal adoption or, in the case of revision, the year of last revision. A nu
2、mber 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 These test methods cover testing of concrete pipe,
3、manhole sections, and tile. The test methods described are used inproduction testing and acceptance testing to evaluate the properties provided for in the specifications.1.2 The test methods appear in the following order:SectionExternal Load Crushing Strength 4Flat Slab Top 5Core Strength 6Absorptio
4、n 7Hydrostatic 8PermeabilityManhole Step910Cylinder Strength 11Gasket Lubricant 12Joint Shear 13Alkalinity 14Gasket Measurements 151.3 The test specimens shall not have been exposed to a temperature below 40F for the 24 h immediately preceding the test.1.4 If any test specimen fails because of mecha
5、nical reasons such as failure of testing equipment or improper specimenpreparation, it shall be discarded and another specimen taken.1.5 Specimens shall be selected in accordance with the specifications for the type of pipe or tile being tested.1.6 A complete metric companion to Test Methods C497 ha
6、s been developedC497M; therefore, no metric equivalents arepresented in these methods.1.7 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibilityof the user of this standard to establish appropriate safety and health practices a
7、nd determine the applicability of regulatorylimitations prior to use.1.8 This international standard was developed in accordance with internationally recognized principles on standardizationestablished in the Decision on Principles for the Development of International Standards, Guides and Recommend
8、ations issuedby the World Trade Organization Technical Barriers to Trade (TBT) Committee.2. Referenced Documents2.1 ASTM Standards:2C31/C31M Practice for Making and Curing Concrete Test Specimens in the FieldC39/C39M Test Method for Compressive Strength of Cylindrical Concrete SpecimensC42/C42M Test
9、 Method for Obtaining and Testing Drilled Cores and Sawed Beams of ConcreteC617 Practice for Capping Cylindrical Concrete SpecimensC670 Practice for Preparing Precision and Bias Statements for Test Methods for Construction MaterialsC822 Terminology Relating to Concrete Pipe and Related Products1 The
10、se test methods are under the jurisdiction of ASTM Committee C13 on Concrete Pipe and are the direct responsibility of Subcommittee C13.09 on Methods of Test.Current edition approved Sept. 1, 2016April 1, 2017. Published September 2016May 2017. Originally approved in 1962. Last previous edition appr
11、oved in 2016 asC497 16.C497 16a. DOI: 10.1520/C0497-16A.10.1520/C0497-17.2 For referencedASTM standards, visit theASTM website, www.astm.org, or contactASTM Customer Service at serviceastm.org. For Annual Book of ASTM Standardsvolume information, refer to the standards Document Summary page on the A
12、STM website.This document is not an ASTM standard and is intended only to provide the user of an ASTM standard an indication of what changes have been made to the previous version. Becauseit may not be technically possible to adequately depict all changes accurately, ASTM recommends that users consu
13、lt prior editions as appropriate. In all cases only the current versionof the standard as published by ASTM is to be considered the official document.Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States1C1231/C1231M Practice for Use of Unb
14、onded Caps in Determination of Compressive Strength of Hardened CylindricalConcrete SpecimensD2240 Test Method for Rubber PropertyDurometer HardnessE4 Practices for Force Verification of Testing Machines3. Terminology3.1 DefinitionsFor definitions of terms relating to concrete pipe, see Terminology
15、C822.4. External Load Crushing Strength Test by the Three-Edge Bearing Test Method4.1 Summary of Test MethodThe test specimen is tested in a machine designed to apply a crushing force upon the specimenin a plane through the vertical axis extending along the length of the specimen.4.2 Significance an
16、d UseThe crushing test shall be either a quality control test performed to establish that the finished,shippable pipe has sufficient strength to withstand the crushing loads stated in the specifications or a proof of design test performedto prove the adequacy of design.4.3 Apparatus:4.3.1 The testin
17、g machine shall be of any type of sufficient capacity and shall be capable of providing the rate of loadingprescribed in 4.5.3.4.3.2 The testing machine shall be substantial and rigid throughout, so that the distribution of the load will not be affectedappreciably by the deformation or yielding of a
18、ny part.4.3.3 The three-edge-bearing method of loading shall be used. The test specimen shall be supported on a lower bearing of twoparallel longitudinal strips and the load applied through an upper bearing (Figs. 1-4). At the option of the manufacturer, either orboth the lower bearing and the upper
19、 bearing shall extend the full length or any portion of the length of the specimen. Fig. 54.3.4 The lower bearings shall consist of wood or hard rubber strips. Wooden strips shall be straight, have a cross section ofnot less than 2 in. in width and not less than 1 in. nor more than 112 in. in height
20、 and shall have the top inside corners roundedto a radius of 12 in. Hard rubber strips shall have a durometer hardness of not less than 45 nor more than 60. They shall berectangular in cross section, having a width of not less than 2 in., a thickness of not less than 1 in. nor more than 112 in., and
21、 shallhave the top inside corner rounded to a radius of 12 in.4.3.5 The lower bearing strips shall be fastened to a wooden or steel beam or directly to a concrete base, any of which shallprovide sufficient rigidity so that deflection is not greater than 1720 of the specimen length when the maximum l
22、oad is applied. Therigid base shall be at least 6 in. wide. The interior vertical sides of the strips shall be parallel and spaced a distance apart of notmore than 1 in./ft of specimen diameter, but in no case less than 1 in. The bearing faces of the lower strips shall not vary froma straight line v
23、ertically or horizontally by more than 132 in./ft of length under no load.4.3.6 The upper bearing shall be a rigid wood beam with or without an attached hard rubber strip. The wood shall be sound,free of knots, and straight and true from end to end. It shall be fastened to a steel or wood-faced stee
24、l beam of such dimensionsthat deflections under maximum load will not be greater than 1720 of the specimen length. The bearing face of the upper bearingshall not deviate from a straight line by more than 132 in.ft of length. When a hard rubber strip is used on the bearing face it shallhave a duromet
25、er hardness of not less than 45 nor more than 60, and shall have a width of not less than 2 in. and a thickness ofnot less than 1 in. nor more than 112 in. and shall be secured to a wood beam meeting the above requirements.4.3.7 If mutually agreed upon by the manufacturer and the owner prior to the
26、test, before the specimen is placed, a fillet ofplaster of paris not exceeding 1 in. in thickness shall be cast on the surface of the upper and lower bearings. The width of the filletcap, upper or lower, shall be not more than 1 in./ft of the specimen diameter, but in no case less than 1 in.4.3.8 Th
27、e equipment shall be so designed that the load will be distributed about the center of the overall length (L1) of thespecimen (Figs. 1-4). At the option of the manufacturer, the center of the load shall be applied at any point of the overall length(L1) of the specimen. The load shall be applied eith
28、er at a single point or at multiple points dependent on the length of the specimenbeing tested and the rigidity of the test frame.NOTE 1The user of these test methods is advised that multiple points of load appllications to the upper bearing will permit use of lighter beamswithout excessive deflecti
29、on.4.4 CalibrationThe loading device shall be one which shall provide an accuracy of 62 % at the specified test loads. Acalibration curve shall be used. The machines used for performing the three-edge-bearing tests shall be verified in accordance withPractices E4.4.5 Procedure:4.5.1 Place the specim
30、en on the two lower bearing strips in such a manner that the pipe or tile rests firmly and with uniformbearing on each strip.4.5.2 Mark the two ends of the specimen at a point midway between the lower bearing strips and then establish the diametricallyopposite point on each end. Place the upper bear
31、ing so that it is aligned with these marks.4.5.3 For reinforced concrete pipe, any rate of load application up to a maximum of 7500 lbf/linear foot of pipe per minute shallbe used up to 75 % of the specified design strength, at which time the rate of loading shall be reduced to a maximum uniform rat
32、eC497 172of 13 of the specified design strength of the pipe per minute. This rate of loading shall be continuous until the specified acceptancedesign strength is reached. If both the design strength and the ultimate strength are being determined, a specified rate of loadingneed not be maintained aft
33、er the acceptance design strength has been reached. For non-reinforced concrete pipe, any rate of loadapplication up to a maximum of 7500 lbf/linear foot of pipe per minute shall be used up to 75 % of the specified ultimate strength,at which time the rate of loading shall be reduced to the maximum u
34、niform rate of 3000 lbf/linear foot of pipe per minute. At themanufacturers option, the rates of loading in this paragraph shall be any rates that do not exceed the specified maximums.4.5.4 As defined in Terminology C822, the design strength is the maximum load, expressed as a D-load, supported by t
35、he pipebefore a crack having a width of 0.01 in. occurs throughout a continuous length of 1 ft or more measured parallel to the longitudinalaxis of pipe barrel. The crack is 0.01 in. in width when the point of the measuring gage will, without forcing, penetrate 116 in. at3 in. maximum intervals, thr
36、oughout the specified distance of 1 ft. Measure the width of the crack by means of a gage made fromNOTE 1The figures illustrate a method of applying the load to the pipe.FIG. 1 Three-Edge-Bearing Test, Circular PipeC497 173a leaf 0.01 in. in thickness (as in a set of standard machinist gages), groun
37、d to a point of 116 in. in width with corners roundedand with a taper of 14 in.in. as shown in Fig. 6.NOTE 1The figure illustrates a method of applying the load to the pipe.FIG. 2 Three-Edge-Bearing Test, Arch PipeNOTE 1The figure illustrates a method of applying the load to the pipe.FIG. 3 Three-Ed
38、ge-Bearing Test, Horizontal Elliptical PipeNOTE 1The figure illustrates a method of applying the load to the pipe.FIG. 4 Three-Edge-Bearing Test, Vertical Elliptical PipeC497 174NOTE 2As used in this specification, the 0.01-in. crack is a test criterion for pipe under load in three-edge bearing test
39、 and is not intended as anindication of overstressed or failed pipe under installed conditions.4.5.5 As defined in Terminology C822, the ultimate strength is the maximum load supported by the pipe.NOTE 3Ultimate strength of concrete pipe in the buried condition is dependent on varying soil bedding f
40、actors and varying failure modes and shallhave no relationship to the ultimate strength as defined under three-edge bearing conditions.4.6 ConditioningThe moisture requirements of 1.3 are not required, at the option of the manufacturer.4.7 Calculations:4.7.1 Strength test results shall be calculated
41、 in terms of pounds per linear foot. The length used in calculating the strengthvalues shall be that indicated by the manufactured length (L) in Figs. 1-4. For pipe with a bell, the manufactured length (L) is thelength from the spigot/tongue end face to the bell/groove inside shoulder. For straight
42、wall pipe, no bell, the manufactured length(L) is the same as for pipe with a bell or the alternate of the length from the spigot/tongue outside shoulder to the socket/grooveend face. For plain end or cut pipe, no bell or spigot, the manufactured length (L) is the same as the overall length (L1). Fo
43、r pipehaving a spigot on one end with the opposite end being plain, the manufactured length (L) shall be the distance from the plain endto the center of the joint. For pipe having a bell on one end with the opposite end being plain, the manufactured length (L) shallbe the distance from the plain end
44、 to the bell inside shoulder. See Terminology C822 for definitions of manufactured length (L)and overall length (L1).4.7.2 The ultimate strength in pounds per linear foot shall be calculated by dividing the maximum test load applied to the pipeby the manufactured length (L).4.7.3 The D-load strength
45、 in pounds per linear foot per foot of inside diameter or horizontal span shall be either the 0.01-in.crack D-load strength or the ultimate D-load strength. The 0.01-in. crack D-load shall be calculated by dividing the test loadrequired to produce the 0.01-in. crack by the manufactured length (L) an
46、d by the pipe inside diameter or horizontal span. Theultimate D-load strength shall be calculated by dividing the ultimate test load applied to the pipe by the manufactured length, (L),and by the pipe inside diameter or horizontal span.4.8 Precision and BiasThe user of these test methods is advised
47、that the true value for the strength of a concrete pipe cannotbe determined because the specimen is tested to destruction and exact duplicate specimen cannot be obtained. Therefore, nocalculations of precision and bias are presently capable of being performed. Specifications that include this test m
48、ethod for thevarious types of concrete pipe should include a provision for additional tests of one or more specimens.5. Flat Slab Top Test Method5.1 Summary of Test MethodA load is applied to the flat slab top and the supporting capacity of the flat slab top is measured.5.2 Significance and UseThe t
49、est method is a proof of design test performed to prove the adequacy of the design.5.3 ConditioningThe moisture requirements of 1.3 are not required, at the option of the manufacturer.5.4 ProcedurePlace the section that has been designated to receive the flat slab top on a firm, even surface. Assemble the flatslab top to this section. If a frame or riser has been designed to be fitted to the access portion of the flat slab top, assemble it tothe slab top. Apply the test load to the riser or frame as assembled to the flat slab top. If no ac
