ASTM B487-1985(2013) Standard Test Method for Measurement of Metal and Oxide Coating Thickness by Microscopical Examination of Cross Section《用横断面显微观察法测定金属及氧化层厚度的标准试验方法》.pdf

《ASTM B487-1985(2013) Standard Test Method for Measurement of Metal and Oxide Coating Thickness by Microscopical Examination of Cross Section《用横断面显微观察法测定金属及氧化层厚度的标准试验方法》.pdf》由会员分享，可在线阅读，更多相关《ASTM B487-1985(2013) Standard Test Method for Measurement of Metal and Oxide Coating Thickness by Microscopical Examination of Cross Section《用横断面显微观察法测定金属及氧化层厚度的标准试验方法》.pdf（4页珍藏版）》请在麦多课文档分享上搜索。

1、Designation: B487 85 (Reapproved 2013)Standard Test Method forMeasurement of Metal and Oxide Coating Thickness byMicroscopical Examination of Cross Section1This standard is issued under the fixed designation B487; the number immediately following the designation indicates the year oforiginal adoptio

2、n or, in the case of revision, the 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.This standard has been approved for use by agencies of the U.S. Department of Defense.1

3、. Scope1.1 This test method covers measurement of the localthickness of metal and oxide coatings by the microscopicalexamination of cross sections using an optical microscope.1.2 Under good conditions, when using an opticalmicroscope, the method is capable of giving an absolutemeasuring accuracy of

4、0.8 m. This will determine the suit-ability of the method for measuring the thickness of thincoatings.1.3 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 and he

5、alth practices and determine the applica-bility of regulatory limitations prior to use. (This is especiallyapplicable to the chemicals cited in Table X2.1.)2. Referenced Documents2.1 ASTM Standards:2E3 Guide for Preparation of Metallographic Specimens3. Summary of Test Method3.1 This test method con

6、sists of cutting out a portion of thetest specimen, mounting it, and preparing the mounted crosssection by suitable techniques of grinding, polishing, andetching. The thickness of the cross section is measured with anoptical microscope.NOTE 1These techniques will be familiar to experienced metallogr

7、a-phers but some guidance is given in Section 5 and in Appendix X1 for lessexperienced operators.4. Significance and Use4.1 Coating thickness is an important factor in the perfor-mance of a coating in service and is usually specified in acoating specification.4.2 This method is suitable for acceptan

8、ce testing.5. Factors Influencing the Measurement Result5.1 Surface RoughnessIf the coating or its substrate has arough surface, one or both of the interfaces bounding thecoating cross section may be too irregular to permit accuratemeasurement. (See X1.4)5.2 Taper of Cross SectionIf the plane of the

9、 cross sectionis not perpendicular to the plane of the coating, the measuredthickness will be greater than the true thickness. For example,an inclination of 10 to the perpendicular will contribute a1.5 % error.5.3 Deformation of the CoatingDetrimental deformationof the coating can be caused by exces

10、sive temperature orpressure during mounting and preparation of cross sections ofsoft coatings or coatings melting at low temperatures, and alsoby excessive abrasion of brittle materials during preparation ofcross sections.5.4 Rounding of Edge of CoatingIf the edge of the coatingcross section is roun

11、ded, that is, if the coating cross section isnot completely flat up to its edges, the true thickness cannot beobserved microscopically. Edge rounding can be caused byimproper mounting, grinding, polishing, or etching. It isusually minimized by overplating the test specimen beforemounting. (See X1.2.

12、)5.5 OverplatingOverplating of the test specimen serves toprotect the coating edges during preparation of cross sectionsand thus to prevent an erroneous measurement. Removal ofcoating material during surface preparation for overplating cancause a low-thickness measurement.5.6 EtchingOptimum etching

13、will produce a clearly de-fined and narrow dark line at the interface of two metals.Excessive etching produces a poorly defined or wide linewhich may result in an erroneous measurement.1This test method is under the jurisdiction ofASTM Committee B08 on Metallicand Inorganic Coatingsand is the direct

14、 responsibility of Subcommittee B08.10 onTest Methods.Current edition approved Dec. 1, 2013. Published December 2013. Originallyapproved in 1968. Last previous edition approved in 2007 as B487 85 (2007).DOI: 10.1520/B0487-85R13.2For referenced ASTM standards, visit the ASTM website, www.astm.org, or

15、contact 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, West Conshohocken, PA 19428-2959. United States15.7 SmearingImprope

16、r polishing may leave one metalsmeared over the other metal so as to obscure the true boundarybetween the two metals. The apparent boundary may be poorlydefined or very irregular instead of straight and well defined.To verify the absence of smearing, the coating thickness shouldbe measured and the p

17、olishing, etching, and thickness mea-surement repeated. A significant change in apparent thicknessindicates that smearing was probably present during one of themeasurements.5.8 MagnificationFor any given coating thickness, mea-surement errors generally increase with decreasing magnifica-tion. If pos

18、sible, the magnification should be chosen so that thefield of view is between 1.5 and 3 the coating thickness.5.9 Calibration of Stage Micrometer Any error in calibra-tion of the stage micrometer will be reflected in the measure-ment of the specimen. Errors of several percent are notunrealistic unle

19、ss the scale has been calibrated or has beencertified by a responsible supplier. The distance between twolines of a stage micrometer used for the calibration shall beknown to within 0.2 m or 0.1 %, whichever is the greater. Ifa stage micrometer is not certified for accuracy, it should becalibrated.

20、A generally satisfactory means of calibration is toassume that the stated length of the full scale is correct, tomeasure each subdivision with a filar micrometer, and tocalculate the length of each subdivision by simple proportion.5.10 Calibration of Micrometer Eyepiece :5.10.1 A filar micrometer ey

21、epiece generally provides themost satisfactory means of making the measurement of thespecimen. The measurement will be no more accurate than thecalibration of the eyepiece. As calibration is operatordependent, the eyepiece shall be calibrated by the personmaking the measurement.5.10.2 Repeated calib

22、rations of the micrometer eyepiececan be reasonably expected to have a spread of less than 1 %.5.10.3 Some image-splitting micrometer eyepieces have anonlinearity that introduces an error of up to 1 % for shortmeasurement distances.5.11 AlignmentErrors can be introduced by backlash inthe movement of

23、 the micrometer eyepiece. If the final motionduring alignment of the hairline is always made in the samedirection, this error will be eliminated.5.12 Uniformity of MagnificationBecause the magnifica-tion may not be uniform over the entire field, errors can occurif both the calibration and the measur

24、ement are not made overthe same portion of the field with the measured boundariescentered about the optical axis.5.13 Lens QualityLack of sharpness of the image contrib-utes to the uncertainty of the measurement. Poor quality lensescould preclude accurate measurements. Sometimes imagesharpness can b

25、e improved by using monochromatic light.5.14 Orientation of EyepieceThe movement of the hair-line of the eyepiece for alignment has to be perpendicular to theboundaries of the coating cross section. For example, 10misalignment will contribute a 1.5 % error.5.15 Tube LengthA change in the tube length

26、 of themicroscope causes a change in magnification and if this changeoccurs between the time of calibration and the time ofmeasurement, the measurement will be in error. A change intube length may occur when the eyepiece is repositioned withinthe tube, when the focus of the eyepiece tube is changed,

27、 and,for some microscopes, when the fine focus is adjusted or theinterpupillary distance for binoculars is changed.6. Preparation of Cross Sections6.1 Prepare, mount, polish, and etch the specimen so that:6.1.1 The cross section is perpendicular to the coating;6.1.2 The surface is flat and the entir

28、e width of the coatingimage is simultaneously in focus at the magnification used forthe measurement;6.1.3 All material deformed by cutting or cross sectioning isremoved.6.1.4 The boundaries of the coating cross section are sharplydefined by no more than contrasting appearance or by a narrow,well-def

29、ined line.NOTE 2Further guidance is given in Appendix X1. Some typicaletchants are described in Appendix X2.7. Procedure7.1 Give appropriate attention to the factors listed in Section5 and Appendix X1.7.2 Calibrate the microscope and its measuring device witha certified or calibrated stage micromete

30、r.7.3 Measure the width of the image of the coating crosssection at no less than five points distributed along a length ofthe microsection, and calculate the arithmetic mean of themeasurements (see 8.1.5 and 8.1.6).8. Test Report8.1 The test report shall include the following information:8.1.1 The d

31、ate of test;8.1.2 The number and title of this test method;8.1.3 The identification of the test specimens;8.1.4 The location on the coated item at which the crosssection was made;8.1.5 The measured thickness, in micrometres (millimetresif greater than 1 mm) at each point (7.3), and the length ofsect

32、ion over which the measurements were distributed;8.1.6 The local thickness, that is, the arithmetic mean of themeasured thicknesses;8.1.7 Any deviations from this test method;8.1.8 Any factors that might influence interpretation of thereported results; and8.1.9 The name of the operator and testing l

33、aboratory.9. Precision and Bias9.1 The microscope and associated equipment, its use, itscalibration, and the method of preparation of the cross sectionshall be chosen so as to allow the coating thickness to bedetermined to within 1 m or 10 %, whichever is the greater, ofthe actual coating thickness.

34、 Under good conditions, whenusing an optical microscope, the method is capable of giving anabsolute measuring accuracy of 0.8 m and for thicknessesgreater than 25 m a reasonable error is of the order of 5 % orbetter.B487 85 (2013)2APPENDIXES(Nonmandatory Information)X1. GUIDANCE ON THE PREPARATION A

35、ND MEASUREMENT OF CROSS SECTIONSX1.1 IntroductionThe preparation of test specimens andmeasurement of coating thickness are greatly dependent onindividual techniques and there is a variety of suitable tech-niques available. It is not reasonable to specify only one set oftechniques, and it is impracti

36、cal to include all suitable tech-niques. The techniques described in this appendix are intendedas guidance for metallographers not experienced in measure-ments of coating thickness. For additional guidance see Meth-ods E3.X1.2 Mounting:X1.2.1 To prevent rounding of the edge of the cross section,the

37、free surface of the coating should be supported so that thereis no space between the coating and its support. This is usuallyachieved by overplating the specimen with a coating at least10-m thick of a metal of similar hardness to the coating. Forhard, brittle coatings (for example oxide or chromium

38、coat-ings) tightly wrapping the specimen in soft aluminum foilbefore mounting has proved successful.X1.2.2 If the coating is soft, overplating with a metal whichis softer will make polishing more difficult, because the softermetal tends to be polished away more rapidly.X1.2.3 Overplating of zinc or

39、cadmium coatings with cop-per may cause difficulty because of the tendency, duringsubsequent etching, of dissolved copper to deposit on thecoatings. It is better to overplate zinc with cadmium and viceversa.X1.3 Grinding and Polishing:X1.3.1 It is essential to keep the cross-section surface of themo

40、unt perpendicular to the coating. This is facilitated byincorporating additional pieces of a similar metal in the plasticmounting, near the outer edges, by periodically changing thedirection of grinding (rotating through 90) and by keeping thegrinding time and pressure to a minimum. If, before grind

41、ing,reference marks are inscribed on the side of the mount, anyinclination from horizontal is easily measurable.X1.3.2 Grind the mounted test specimens on suitable abra-sive paper, using an acceptable lubricant, such as water ormineral spirits, and apply minimum pressure to avoid bevellingof the sur

42、face. Initial grinding should employ 100 or 180 gradeabrasive to reveal the true specimen profile and to removedeformed metal. Subsequently, use Grades 240, 320, 500, and600 without exceeding grinding times of 30 to 40 s on eachpaper; alter the direction of scratches by 90 for each change ofpaper. A

43、 final polish of 2 to 3 min on a rotating wheel chargedwith 4 to 8-m diamond paste particles and lubricated withmineral spirits should suffice to remove scratches for finalexamination. If an especially high degree of surface finish isrequired, a further treatment, using diamond paste of approxi-mate

44、ly 1-m particles, may be employed.X1.3.3 If very soft materials are being prepared, abrasiveparticles may become embedded during grinding. This may beminimized by totally immersing abrasive papers in a lubricantduring grinding or by using a copious flow of lubricant. Ifabrasive particles do become e

45、mbedded, they may be removedby applying a short, light hand polish with metal polish aftergrinding and before diamond finishing or by one or morecycles of alternate etching and polishing.X1.4 EtchingEtching is usually advisable to promotecontrast between the metal layers, to remove traces of smeared

46、metal, and to develop a fine line at the boundary of the coating.Some typical etchants are given in Appendix X2.X1.5 Measurement:X1.5.1 The measuring device may be a filar micrometer ora micrometer eyepiece. The latter has a lower precision. Animage-splitting eyepiece is advantageous for thin coatin

47、gs onrough substrate surfaces. Measurement of the image projectedon to a ground-glass plate is usually less satisfactory because ofthe lack of sharpness of the image and poor legibility of theruler when the projected image is visible.X1.5.2 The measuring device should be calibrated at leastonce befo

48、re and once after a measurement, unless repeatedexperience indicates otherwise.X1.5.3 When making calibration and coatingmeasurements, both should be made by the same operator, thestage micrometer and the coating should be centered in thefield, and each measurement at a point should be made at least

49、twice and averaged.X1.5.4 For critical and referee measurements, all steps forthe preparation of cross sections and measurement of coatingthickness, from grinding with 600 grade or coarser abrasive, upto and including the determination, should be performed atleast twice. With good techniques and equipment, and smoothcoating and substrate surfaces, repeatability within 2 % or 0.5m, whichever is the greater, is reasonable.X1.5.5 Some microscopes are subject to a spontaneousmovement of the stage relative to the objective, possibly due tononuniform therm