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本文(ASTM E837-2008e2 1875 Standard Test Method for Determining Residual Stresses by the Hole-Drilling Strain-Gage Method《用钻孔应变仪法测定残余应力的标准试验方法》.pdf)为本站会员(appealoxygen216)主动上传,麦多课文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知麦多课文库(发送邮件至master@mydoc123.com或直接QQ联系客服),我们立即给予删除!

ASTM E837-2008e2 1875 Standard Test Method for Determining Residual Stresses by the Hole-Drilling Strain-Gage Method《用钻孔应变仪法测定残余应力的标准试验方法》.pdf

1、Designation: E837 082Standard Test Method forDetermining Residual Stresses by the Hole-Drilling Strain-Gage Method1This standard is issued under the fixed designation E837; the number immediately following the designation indicates the year oforiginal adoption or, in the case of revision, the year o

2、f last revision. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon () indicates an editorial change since the last revision or reapproval.1NOTEEq 27 was editorially corrected in July 2009.2NOTEEq 21 was editorially corrected in March 2013.INTRODUCTIONThe hole-drilli

3、ng strain-gage method determines residual stresses near the surface of an isotropiclinear-elastic material. It involves attaching a strain rosette to the surface, drilling a hole at thegeometric center of the rosette, and measuring the resulting relieved strains. The residual stresseswithin the remo

4、ved material are then determined from the measured strains using a series of equations.1. Scope1.1 Residual Stress Determination:1.1.1 This test method specifies a hole-drilling procedurefor determining residual stress profiles near the surface of anisotropic linearly elastic material. The test meth

5、od is applicableto residual stress profile determinations where in-plane stressgradients are small. The stresses may remain approximatelyconstant with depth (“uniform” stresses) or they may varysignificantly with depth (“non-uniform” stresses). The mea-sured workpiece may be “thin” with thickness mu

6、ch less thanthe diameter of the drilled hole or “thick” with thickness muchgreater than the diameter of the drilled hole. Only uniformstress measurements are specified for thin workpieces, whileboth uniform and non-uniform stress measurements are speci-fied for thick workpieces.1.2 Stress Measuremen

7、t Range:1.2.1 The hole-drilling method can identify in-plane re-sidual stresses near the measured surface of the workpiecematerial. The method gives localized measurements that indi-cate the residual stresses within the boundaries of the drilledhole.1.2.2 This test method applies in cases where mate

8、rialbehavior is linear-elastic. In theory, it is possible for localyielding to occur due to the stress concentration around thedrilled hole, for isotropic (equi-biaxial) residual stresses ex-ceeding 50 % of the yield stress, or for shear stresses in anydirection exceeding 25 % of the yield stress. H

9、owever, inpractice it is found that satisfactory results can be achievedproviding the residual stresses do not exceed about 60 % of thematerial yield stress.1.3 Workpiece Damage:1.3.1 The hole-drilling method is often described as “semi-destructive” because the damage that it causes is localized and

10、often does not significantly affect the usefulness of the work-piece. In contrast, most other mechanical methods for measur-ing residual stresses substantially destroy the workpiece. Sincehole drilling does cause some damage, this test method shouldbe applied only in those cases either where the wor

11、kpiece isexpendable, or where the introduction of a small shallow holewill not significantly affect the usefulness of the workpiece.1.4 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 establ

12、ish appro-priate safety and health practices and determine the applica-bility of regulatory limitations prior to use.2. Referenced Documents2.1 ASTM Standards:2E251 Test Methods for Performance Characteristics of Me-tallic Bonded Resistance Strain Gauges1This test method is under the jurisdiction of

13、 ASTM Committee E28 onMechanical Testing and is the direct responsibility of Subcommittee E28.13 onResidual Stress Measurement.Current edition approved July 23, 2009. Published April 2008. Originallyapproved in 1981. Last previous edition approved in 2001 as E837 011. DOI:10.1520/E0837-08E01.2For re

14、ferenced 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, PO Box C700, We

15、st Conshohocken, PA 19428-2959. United States13. Terminology3.1 Symbols:a = calibration constant for isotropic stressesb= calibration constant for shear stressesajk= calibration matrix for isotropic stressesbjk= calibration matrix for shear stressesD = diameter of the gage circle, see Table 1.D0= di

16、ameter of the drilled holeE = Youngs modulusj = number of hole depth steps so fark = sequence number for hole depth stepsP = uniform isotropic (equi-biaxial) stressPk= isotropic stress within hole depth step kp = uniform isotropic (equi-biaxial) strainpk= isotropic strain after hole depth step kQ =

17、uniform 45 shear stressQk= 45 shear stress within hole depth step kq = uniform 45 shear strainqk= 45 shear strain after hole depth step kT = uniform x-y shear stressTk= x-y shear stress within hole depth step kt = x-y shear straintk= x-y shear strain after hole depth step kT = (superscript) matrix t

18、ransposeP= regularization factor for P stressesQ= regularization factor for Q stressesT= regularization factor for T stresses = clockwise angle from the x-axis (gage 1) to themaximum principal stress direction = relieved strain for “uniform” stress casej= relieved strain measured after j hole depth

19、stepshave been drilled = Poissons ratio = angle of strain gage from the x-axismax= maximum (more tensile) principal stressmin= minimum (more compressive) principal stressx= uniform normal x-stress(x)k= normal x-stress within hole depth step ky= uniform normal y-stress(y)k= normal y-stress within hol

20、e depth step kxy= uniform shear xy-stress(xy)k= shear xy-stress within hole depth step k4. Summary of Test Method4.1 Workpiece:4.1.1 Aflat uniform surface area away from edges and otherirregularities is chosen as the test location within the workpieceof interest. Fig. 1 schematically shows the resid

21、ual stressesacting at the test location at which a hole is to be drilled. Thesestresses are assumed to be uniform within the in-plane direc-tions x and y.NOTE 1For reasons of pictorial clarity in Fig. 1, the residual stressesare shown as uniformly acting over the entire in-plane region around thetes

22、t location. In actuality, it is not necessary for the residual stresses to beuniform over such a large region. The surface strains that will be relievedby drilling a hole depend only on the stresses that originally existed at theboundaries of the hole. The stresses beyond the hole boundary do notaff

23、ect the relieved strains, even though the strains are measured beyond thehole boundary. Because of this, the hole-drilling method provides a verylocalized measurement of residual stresses.4.1.2 Fig. 1(a) shows the case where the residual stresses inthe workpiece are uniform in the depth direction. T

24、he in-planestresses are x, yand xythroughout the thickness. Uniformresidual stress measurements can be made using this testmethod with “thin” workpieces whose material thickness issmall compared with the hole and strain gage circle diameters,and with “thick” workpieces whose material thickness is la

25、rgecompared with the hole and strain gage circle diameters.4.1.3 Fig. 1(b) shows the case where the residual stresses inthe workpiece vary in the depth direction. The calculationmethod described in this test method represents the stressprofile as a staircase shape, where the depth steps correspond t

26、othe depth increments used during the hole-drilling measure-ments. Within depth step k, the in-plane stresses are (x)k,(y)kand (xy)k. Non-uniform residual stress measurements can bemade using this test method only with “thick” workpieceswhose material thickness is large compared with the hole andstr

27、ain gage circle diameters.4.2 Strain Gage Rosette:4.2.1 A strain gage rosette with three or more elements ofthe general type schematically illustrated in Fig. 2 is attachedto the workpiece at the location under consideration.4.3 Hole-Drilling:4.3.1 A hole is drilled in a series of steps at the geome

28、triccenter of the strain gage rosette.(a)(b)FIG. 1 Hole Geometry and Residual Stresses, (a) UniformStresses, (b) Non-uniform StressesE837 08224.3.2 The residual stresses in the material surrounding thedrilled hole are partially relieved as the hole is drilled. Theassociated relieved strains are meas

29、ured at a specified sequenceof steps of hole depth using a suitable strain-recording instru-ment.4.4 Residual Stress Calculation Method:4.4.1 The residual stresses originally existing at the holelocation are evaluated from the strains relieved by hole-drillingusing mathematical relations based on li

30、near elasticity theory(1-5).3The relieved strains depend on the residual stresses thatexisted in the material originally within the hole.4.4.2 For the uniform stress case shown in Fig. 1 (a), thesurface strain relief measured after hole-drilling is: 511Eax1y2(1)11Ebx2 y2cos211Eb xysin24.4.3 The cali

31、bration constants a and bindicate the relievedstrains due to unit stresses within the hole depth. They aredimensionless, almost material-independent constants. Slightlydifferent values of these constants apply for a through-thickness hole made in a thin workpiece and for a blind holemade in a thick

32、workpiece. Numerical values of these calibra-tion constants have been determined from finite elementcalculations (4) for standard rosette patterns, and are tabulatedin this test method.4.4.4 For the non-uniform stress case shown in Fig. 1(b), thesurface strain relief measured after completing hole d

33、epth stepj depends on the residual stresses that existed in the materialoriginally contained in all the hole depth steps 1 k j:j511E(k51jajkx1y!/2!k(2)11E(k51jbjkx2 y!/2!kcos211E(k51jbjkxy!ksin24.4.5 The calibration constants ajkand bjkindicate therelieved strains in a hole j steps deep, due to unit

34、 stresseswithin hole step k. Fig. 3 shows cross-sections of drilled holesfor an example sequence where a hole is drilled in four depthsteps. Within this sequence, calibration constant represents anintermediate stage where the hole has reached 3 steps deep, andhas a unit stress acting within depth st

35、ep 2. Numerical valuesof the calibration constants have been determined by finite3The boldface numbers in parentheses refer to the list of references at the end ofthis standard.(a)(b)FIG. 2 Schematic Geometry of a Typical Three-Element Clock-wise (CW) Hole-Drilling Rosette, (a) Rosette Layout, (b) D

36、etail ofa Strain GageFIG. 3 Physical Interpretation of Coefficients ajkE837 0823element calculations (4) for standard rosette patterns, and aretabulated in this test method.4.4.6 Measurement of the relieved strains after a series ofhole depth steps provides sufficient information to calculate thestr

37、esses x, yand xywithin each step. From these stresses, thecorresponding principal stresses maxand minand theirorientation can be found.4.4.7 The relieved strains are mostly influenced by thenear-surface residual stresses. Interior stresses have influencesthat diminish with their depth from the surfa

38、ce. Thus, hole-drilling measurements can evaluate only near-surface stresses.Deep interior stresses cannot be identified reliably, see Note 7.4.4.8 In theory, it is possible for local yielding to occur dueto the stress concentration around the drilled hole. Suchyielding can occur with isotropic resi

39、dual stresses exceeding50 % of the yield stress, and for shear stresses exceeding 25 %of the yield stress. However, in practice it is found thatsatisfactory results can be achieved providing the residualstresses do not exceed about 60 % of the material yield stress(6).5. Significance and Use5.1 Summ

40、ary:5.1.1 Residual stresses are present in almost all materials.They may be created during the manufacture or during the lifeof the material. If not recognized and accounted for in thedesign process, residual stresses can be a major factor in thefailure of a material, particularly one subjected to a

41、lternatingservice loads or corrosive environments. Residual stress mayalso be beneficial, for example, the compressive stressesproduced by shot peening. The hole-drilling strain-gage tech-nique is a practical method for determining residual stresses.6. Workpiece Preparation6.1 Requirements:6.1.1 For

42、 a “thin” workpiece, where a through-hole is to beused, the workpiece thickness should not exceed 0.4D for atype A or B rosette, or 0.48D for a type C rosette (see Fig. 4).6.1.2 For a “thick” workpiece, where a hole depth less thanthe workpiece thickness is to be used, the workpiece thicknessshould

43、be at least 1.2D for a type A or B rosette, or 1.44D fora type C rosette (see Fig. 4).6.1.3 A smooth surface is usually necessary for strain gageapplication. However, abrading or grinding that could appre-ciably alter the surface stresses must be avoided. Chemicaletching could be used, thus avoiding

44、 the need for mechanicalabrasion.6.1.4 The surface preparation prior to bonding the straingages shall conform to the recommendations of the manufac-turer of the adhesive used to attach the strain gages.Athoroughcleaning and degreasing is required. In general, surface prepa-ration should be restricte

45、d to those methods that have beendemonstrated to induce no significant residual surface stresses.This is particularly important for workpieces that contain sharpnear-surface stress gradients.7. Strain Gages and Instrumentation7.1 Rosette Geometry:7.1.1 A rosette comprising three single or pairs of s

46、traingage grids shall be used. The numbering scheme for the straingages follows a clockwise (CW) convention (7).NOTE 2The gage numbering scheme used for the rosette illustrated inFig. 2 differs from the counter-clockwise (CCW) convention often usedfor general-purpose strain gage rosettes and for som

47、e other types ofresidual stress rosette. If a strain gage rosette with CCW gage numberingis used, the residual stress calculation procedure described in this testmethod still applies. The only changes are that the numbering of gages 1and 3 are interchanged and that the angle defining the direction o

48、f themost tensile principal stress maxis reversed and is measured counter-clockwise from the new gage 1.NOTE 3It is recommended that the gages be calibrated in accordancewith Test Methods E251.7.1.2 The gages shall be arranged in a circular pattern,equidistant from the center of the rosette.7.1.3 Th

49、e gage axes shall be oriented in each of threedirections, (1) a reference direction, (2) 45 or 135 to thereference direction, and (3) perpendicular to the referencedirection. Direction (2) bisects directions (1) and (3), as shownin Fig. 2.7.1.4 The measurement direction of gage 1 in Fig. 1 isidentified as the x-axis. The y-axis is 90 counterclockwise ofthe x-axis.7.1.5 The center of the gage circle shall be clearly identifi-able.7.2 Standardized Rosettes:7.2.1 Several different standardized r

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