ASTM E6-2009be1 1875 Standard Terminology Relating to Methods of Mechanical Testing《机械试验方法相关的标准术语》.pdf

1、Designation: E6 09b1Standard Terminology Relating toMethods of Mechanical Testing1This standard is issued under the fixed designation E6; the number immediately following the designation indicates the year of originaladoption or, in the case of revision, the year of last revision.Anumber in parenthe

2、ses indicates the year of last reapproval.Asuperscriptepsilon () indicates an editorial change since the last revision or reapproval.This standard has been approved for use by agencies of the Department of Defense.1NOTEEditorial corrections were made throughout in March 2011.1. Scope1.1 This termino

3、logy covers the principal terms relating tomethods of mechanical testing of solids. The general defini-tions are restricted and interpreted, when necessary, to makethem particularly applicable and practicable for use in stan-dards requiring or relating to mechanical tests. These defini-tions are pub

4、lished to encourage uniformity of terminology inproduct specifications.1.2 Terms relating to fatigue and fracture testing are definedin Terminology E1823.2. Referenced Documents2.1 ASTM Standards:2E8/E8M Test Methods for Tension Testing of MetallicMaterialsE796 Test Method for Ductility Testing of M

5、etallic Foil3E1823 Terminology Relating to Fatigue and Fracture Test-ing2.2 ISO Standard:4ISO/IEC Guide 99:2007 International Vocabulary ofmetrologyBasic and general concepts and terms (VIM)3. Index of Cross-References and Associated Definitions3.1 The terms listed below are associated with terminol

6、ogythat is fundamental or commonly used. The definition for theterm of interest is related to or is given below the definition forthe fundamental term cited.Termangular strain see strainaxial strain see strainbending strain see strainchord modulus see modulus of elasticitydirect verification see ver

7、ificationcompressive stress see stresselastic constants see modulus of elasticity and Poissonsratioelastic modulus see modulus of elasticityengineering strain see strainengineering stress see stressfracture stress see stressindirect verification see verificationlinear (tensile or compressive) strain

8、 see strainmacrostrain see strainmalleability see ductilitymicrostrain see strainmodulus of rigidity see modulus of elasticitynominal stress see stressnormal stress see stressphysical properties see mechanical propertiespin see mandrel (in bend testing)plunger see mandrel (in bend testing)principal

9、stress see stressresidual strain see strainresidual stress see stressRockwell superficialhardness numbersee Rockwell hardness numbersecant modulus see modulus of elasticityshear strain see strainshear stress see stressstatic fatigue strength see creep rupture strengthstrain gauge fatigue life see fa

10、tigue lifestress-rupture strength see creep rupture strengthtangent modulus see modulus of elasticitytensile stress see stresstorsional modulus see modulus of elasticitytorsional stress see stresstransverse strain see straintrue strain see straintrue stress see stressultimate tensile strength (UTS)

11、see tensile strengthyield strength see also upper yield strength and loweryield strength1This terminology is under the jurisdiction of ASTM Committee E28 onMechanical Testing and is the direct responsibility of Subcommittee E28.91 onTerminology except where designated otherwise. A subcommittee desig

12、nation inparentheses following a definition indicates the subcommittee with responsibility forthat definition.Current edition approved May 15, 2009. Published June 2009. Originallyapproved in 1923. Last previous edition approved in 2009 as E6 09a. DOI:10.1520/E0006-09B.2For referenced ASTM standards

13、, 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.3Withdrawn. The last approved version of this historical standard is referencedon www.astm.

14、org.4Available from International Organization for Standardization (ISO), 1 rue deVaremb, Case postale 56, CH-1211, Geneva 20, Switzerland, http:/www.iso.ch.1Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.4. Terminology4.1 Terms and

15、Definitions:accuracy, nthe permissible variation from the correct value.(E28.01)alignment, nthe condition of a testing machine and loadtrain (including the test specimen) that influences the intro-duction of bending moments into a specimen during tensileloading. (E28.04)angle of bend, nthe change in

16、 the angle between the twolegs of the specimen during a bend test, measured beforerelease of the bending forces.DISCUSSIONThe angle of bend is measured before release of thebending force, unless otherwise specified. (E28.02)angle of twist (torsion test), nthe angle of relative rotationmeasured in a

17、plane normal to the torsion specimenslongitudinal axis over the gauge length. (E28.04)bearing area L2, nthe product of the pin diameter andspecimen thickness. (E28.04)bearing force F, na compressive force on an interface.(E28.04)bearing strain, nthe ratio of the bearing deformation of thebearing hol

18、e, in the direction of the applied force, to the pindiameter. (E28.04)bearing strength FL2, nthe maximum bearing stresswhich a material is capable of sustaining. (E28.04)bearing stress FL2, nthe force per unit of bearing area.(E28.04)bearing yield strength FL2, nthe bearing stress at whicha material

19、 exhibits a specified limiting deviation from theproportionality of bearing stress to bearing strain. (E28.04)bend test, na test for ductility performed by bending orfolding a specimen, usually by steadily applied forces but insome instances by blows. The bending may be interrupted toexamine the ben

20、t surface for cracks.DISCUSSIONThe ductility is usually judged by whether or not thespecimen cracks under the specified conditions of the test.DISCUSSIONThere are four general types of bend tests according tothe manner in which the forces are applied to the specimen to make thebend. These are as fol

21、lows:1. Free Bend2. Guided Bend3. Semi-Guided Bend4. Wrap-Around BendDISCUSSIONThe specimen has a substantially uniform cross-sectionand a length several times as great as the largest dimension of thecross-section. (E28.02)bias, statistical, na constant or systematic error in testresults. (E28.04)bi

22、axial stretching, va mode of sheet metal forming in whichpositive strains are observed in all directions at a givenlocation. (E28.02)breaking forceF, nthe force at which fracture occurs.DISCUSSIONWhen used in connection with tension tests of thinmaterials or materials of small diameter for which it

23、is often difficult todistinguish between the breaking force and the maximum forcedeveloped, the latter is considered to be the breaking force.(E28.04)Brinell hardness number, HB , nresult from indentationhardness test in which a number proportional to the quotientobtained by dividing the test force

24、by the curved surface areaof the indentation which is assumed to be sphereical and ofthe diameter of the ball.HBW 5 0.10232F/pDD D2 d2!1/2(1)where:F = test force, N,D = diameter of ball, mm, andd = mean diameter of the indentation, mm.DISCUSSIONIn former standards, a steel ball was allowed forhardne

25、ss values below 450. In cases where a steel ball was used theBrinell hardness was denoted by HB or HBS.DISCUSSIONThe symbol HBW is preceded by the hardness valuewhen the test is carried out under the following conditions:Ball diameter 10 mmForce 3000 kgfDuration of loading 10 to 15 sWhen other condi

26、tions are used, the hardness value and symbol aresupplemented by numbers indicating the test conditions in the follow-ing order: diameter of ball, force, and duration of loading. (E28.06)Brinell hardness test, ntest in which an indenter (tungstencarbide ball) is forced into the surface of a test pie

27、ce and thediameter of the indentation left in the surface after removalof the test force is measured.DISCUSSIONThe tungsten carbide ball may be used for materialswith Brinell hardness not exceeding 650. (E28.06)calibration, na process that establishes, under specificconditions, the relationship betw

28、een values indicated by ameasuring system and the corresponding values indicated byone or more standards.DISCUSSIONThis definition is intended to meet the principles of thedefinition of calibration provided by the ISO/IEC Guide 99:2007International Vocabulary of Basic and General Terms in Metrology(

29、VIM). (E28.91)calibration factor, nthe factor by which a change inextensometer reading must be multiplied to obtain theequivalent strain.DISCUSSIONFor any extensometer, the calibration factor is equal tothe ratio of change in length to the product of the gauge length and thechange in extensometer re

30、ading. For direct-reading extensometers thecalibration factor is unity. (E28.01)compressive strength FL2, nthe maximum compressivestress that a material is capable of sustaining. Compressivestrength is calculated by dividing the maximum force duringa compression test by the original cross-sectional

31、area of thespecimen.DISCUSSIONIn the case of a material which fails in compression bya shattering fracture, the compressive strength has a very definite value.In the case of materials which do not fail in compression by a shatteringfracture, the value obtained for compressive strength is an arbitrar

32、yvalue depending upon the degree of distortion which is regarded asindicating complete failure of the material. (E28.04)compressometer, na specialized extensometer used forsensing negative or compressive strain. (E28.01)E6 09b12constraint, nany restriction to the deformation of a body.(E28.11)creep,

33、 nthe time-dependent strain that occurs after theapplication of a force which is thereafter maintained con-stant.DISCUSSIONCreep tests are usually made at constant force andtemperature. For tests on plastics, the initial strain however definedis included; for tests on metals, the initial strain is n

34、ot included.(E28.04)creep recovery, nthe time-dependent decrease in strain in asolid, following the removal of force.DISCUSSIONRecovery is usually determined at constant tempera-ture.DISCUSSIONIn tests of plastics, the initial recovery is generallyincluded; for metals, it is not. Thermal expansion i

35、s excluded.(E28.04)creep rupture strength FL2, nthe stress causing fracturein a creep test at a given time, in a specified constantenvironment.DISCUSSIONThis is sometimes referred to as the stress-rupturestrength or, in glass technology, the static fatigue strength.(E28.04)creep strength FL2, nthe s

36、tress that causes a given creepin a creep test at a given time in a specified constantenvironment. (E28.04)deep drawing, va metal sheet forming operation in whichstrains on the sheet surface are positive in the direction of thepunch travel and negative at 90 to that direction.(E28.02)deflectometer,

37、na specialized extensometer used for sensingof extension or motion, usually without reference to aspecific gauge length. (E28.01)Demeri split-ring test, na test the measures the springbackbehavior of sheet metal by comparing the diameter of a ringextracted from the wall of a flat bottom cup to the d

38、iameterof the same ring, split to release residual stresses.(E28.02)discontinuous yielding, na hesitation or fluctuation of forceobserved at the onset of plastic deformation, due to localizedyielding.DISCUSSIONThe stress-strain curve need not appear to be discon-tinuous. (E28.04)discontinuous yieldi

39、ng stress, nthe peak stress at theinitiation of the first measurable serration on the curve ofstress-versus strain. (E28.04)ductility, nthe ability of a material to deform plasticallybefore fracturing.DISCUSSIONDuctility is usually evaluated by measuring (1) theelongation or reduction of area from a

40、 tension test, (2) the depth of cupfrom a cupping test, (3) the radius or angle of bend from the bend test,or (4) the fatigue ductility from the fatigue ductility test (see TestMethod E796).DISCUSSIONMalleability is the ability to deform plastically underrepetitive compressive forces. (E28.02)dynami

41、c mechanical measurement, na technique in whicheither the modulus or damping, or both, of a substance underoscillatory applied force or displacement is measured as afunction of temperature, frequency, or time, or a combina-tion thereof. (E28.04)eccentricity, nthe distance between the line of action

42、of theapplied force and the axis of symmetry of the specimen in aplane perpendicular to the longitudinal axis of the specimen.(E28.04)edge distance L, nthe distance from the edge of a bearingspecimen to the center of the hole in the direction of appliedforce. (E28.04)edge distance ratio, nthe ratio

43、of the edge distance to thepin diameter. (E28.04)elastic calibration device, na device used in verifying theforce readings of a testing machine consisting of an elasticmember(s) to which forces may be applied, combined with amechanism or device for indicating the magnitude (or aquantity proportional

44、 to the magnitude) of deformation ofthe member under an applied force. (E28.01)elastic force measuring device, na device or system con-sisting of an elastic member combined with a device forindicating the magnitude (or a quantity proportional to themagnitude) of deformation of the member under an ap

45、pliedforce. (E28.01)elastic limit FL2, nthe greatest stress which a material iscapable of sustaining without any permanent strain remain-ing upon complete release of the stress.DISCUSSIONDue to practical considerations in determining theelastic limit, measurements of strain using a small force, rath

46、er thanzero force, are usually taken as the initial and final reference.elongation, El, nthe increase in gauge length of a bodysubjected to a tension force, referenced to a gauge length onthe body. Usually elongation is expressed as a percentage ofthe original gauge length.DISCUSSIONThe increase in

47、gauge length may be determined eitherat or after fracture, as specified for the material under test.DISCUSSIONThe term elongation, when applied to metals, generallymeans measurement after fracture; when applied to plastics andelastomers, measurement at fracture. Such interpretation is usuallyapplica

48、ble to values of elongation reported in the literature when nofurther qualification is given.DISCUSSIONIn reporting values of elongation, the gauge length shallbe stated.DISCUSSIONElongation is affected by specimen geometry (area andshape of cross section, parallel length, parallelism, fillet radii,

49、 etc.),preparation (degree to which surfaces within the reduced section aresmooth and free of cold work), and test procedure (alignment and testspeed, for example). (E28.04)error, nfor a measurement or reading, the amount it deviatesfrom a known or reference value represented by a measure-ment standard. Mathematically, the error is calculated bysubtracting the accepted value from the measurement orreading. (See also percent error.) (E28.91)extensometer, na device for sensi