ASTM A977 A977M-2007 Standard Test Method for Magnetic Properties of High-Coercivity Permanent Magnet Materials Using Hysteresigraphs《使用磁滞曲线记录仪测试高矫顽磁力永磁材料磁性的标准试验方法》.pdf

1、Designation: A 977/A 977M 07Standard Test Method forMagnetic Properties of High-Coercivity Permanent MagnetMaterials Using Hysteresigraphs1This standard is issued under the fixed designationA 977/A 977M; the number immediately following the designation indicates the yearof original adoption or, in t

2、he case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval.A superscript epsilon (e) indicates an editorial change since the last revision or reapproval.1. Scope1.1 This test method covers how to determine the magneticcharacteristics of magnetically

3、 hard materials (permanent mag-nets), particularly their initial magnetization, demagnetization,and recoil curves, and such quantities as the residual induction,coercive field strength, knee field, energy product, and recoilpermeability. This test method is suitable for all materialsprocessed into b

4、ulk magnets by any common fabricationtechnique (casting, sintering, rolling, molding, and so forth),but not for thin films or for magnets that are very small or ofunusual shape. Uniformity of composition, structure, andproperties throughout the magnet volume is necessary to obtainrepeatable results.

5、 Particular attention is paid to the problemsposed by modern materials combining very high coercivitywith high saturation induction, such as the rare-earth magnets,for which older test methods (see Test Method A 341) areunsuitable. An applicable international standard is IEC Publi-cation 60404-5.1.2

6、 The magnetic system (circuit) in a device or machinegenerally comprises flux-conducting and nonmagnetic struc-tural members with air gaps in addition to the permanentmagnet. The system behavior depends on properties andgeometry of all these components and on the operatingtemperature. This test meth

7、od describes only how to measurethe properties of the permanent magnet material. The basic testmethod incorporates the magnetic specimen in a magneticcircuit with a closed flux path. Test methods using ring samplesor frames composed entirely of the magnetic material to becharacterized, as commonly u

8、sed for magnetically soft mate-rials, are not applicable to permanent magnets.1.3 This test method shall be used in conjunction withPractice A 34/A 34M.1.4 The values and equations stated in customary (cgs-emuor inch-pound) or SI units are to be regarded separately asstandard. Within this test metho

9、d, SI units are shown inbrackets except for the sections concerning calculations wherethere are separate sections for the respective unit systems. Thevalues stated in each system may not be exact equivalents;therefore, each system shall be used independently of the other.Combining values from the tw

10、o systems may result in noncon-formance with this test method.1.5 The names and symbols of magnetic quantities used inthis test method, summarized in Table 1, are those generallyaccepted by the industry.1.6 This test method is useful for magnet materials havingHcivalues between about 100 Oe and 35 k

11、Oe 8 kA/m and 2.8MA/m, and Brvalues in the approximate range from 500 G to20 kG 50 mT to 2 T. High-coercivity rare-earth magnet testspecimens may require much higher magnetizing fields thaniron-core electromagnets can produce. Such samples must bepremagnetized externally and transferred into the mea

12、suringyoke. Typical values of the magnetizing fields, Hmag, requiredfor saturating magnet materials are shown in Table A2.1.1.7 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 appr

13、o-priate safety and health practices and determine the applica-bility of regulatory limitations prior to use.2. Referenced Documents2.1 ASTM Standards:2A 34/A 34M Practice for Sampling and Procurement Test-ing of Magnetic MaterialsA 340 Terminology of Symbols and Definitions Relating toMagnetic Test

14、ingA 341/A 341M Test Method for Direct Current MagneticProperties of Materials Using D-C Permeameters and theBallistic Test MethodsE 177 Practice for Use of the Terms Precision and Bias inASTM Test Methods2.2 Magnetic Materials Procedure Association Standard:31This test method is under the jurisdict

15、ion of ASTM Committee A06 onMagnetic Properties and is the direct responsibility of SubcommitteeA06.01 on TestMethods.Current edition approved Nov. 1, 2007. Published December 2007. Originallyapproved in 1997. Last previous edition approved in 2002 as A 977/A 977M02.2For referenced ASTM standards, v

16、isit 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.3Available from Magnetic Materials Producers Association, 8 S. Michigan Ave.,Suite 1000, Chica

17、go, IL 60603.1Copyright ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.MMPA No. 010000 Standard Specifications for Perma-nent Magnet Materials2.3 International Electrotechnical Commission Document:4Publication 60404-5 Magnetic Materials Part 5

18、: PermanentMagnet (Magnetically Hard) Materials Methods ofMeasurement of Magnetic Properties3. Terminology3.1 Basic magnetic units are defined in Terminology A 340and MMPA No. 010000. Additional definitions with symbolsand units are given in Table 1 and Figs. 1-3 of this test method.4. Significance

19、and Use4.1 This test method is suitable for magnet specification,acceptance, service evaluation, quality control in magnetproduction, research and development, and design.4.2 When a test specimen is cut or fabricated from a largermagnet, the magnetic properties measured on it are notnecessarily exac

20、tly those of the original sample, even if thematerial is in the same condition. In such instances, the testresults must be viewed in context of part performance history.4.3 Tests performed in general conformity to this testmethod and even on the same specimen, but using different testsystems, may no

21、t yield identical results. The main source ofdiscrepancies are variations between the different test systemsin the geometry of the region surrounding the sample, such as,size and shape of the electromagnet pole caps (see Annex A1and Appendix X1), air gaps at the specimen end faces, andespecially the

22、 size and location of the measuring devices for Hand B or for their corresponding flux values (Hall-effectprobes, inductive sensing coils). Also important is the methodof B calibration, for example, a volt-second calibration of thefluxmeter alone versus an overall system calibration using aphysical

23、reference sample. The method of B and H sensingshould be indicated in test reports (see Section 9).5. Measuring Methods and Apparatus5.1 Measuring Flux and Induction (Flux Density):5.1.1 In the preferred B-measuring method, the total flux ismeasured with a sensing coil (search coil) that surrounds t

24、hetest specimen and is wound as closely as possible to thespecimen surface. Its winding length should be no more than athird of the specimen length, preferably less than one fifth, andmust be centered on the specimen. The leads shall be twistedtightly.As the flux changes in response to sweeping the

25、appliedfield, H, the total flux is measured by taking the time integralof the voltage induced in this coil. This measurement is takenwith a fluxmeter. Modern hysteresigraphs use electronic inte-grating fluxmeters that allow convenient continuous integra-tion and direct graphic recording of magnetiza

26、tion curves. Ifthe signal is large enough, high-speed voltage sampling at thecoil and digital integration is also possible.5.1.2 The magnetic induction B is determined by dividingthe total flux by the area-turns product NA of the B-sensingcoil. For permanent magnets in general, and especially forhig

27、h-coercivity materials, an air-flux correction is required (see5.1.5).5.1.3 The total error of measuring B shall be not greater than62%.5.1.4 The change of magnetic induction, D B = B2 B1,inthe time interval between the times t1and t2is given as follows:D B 5 108/AN!*t1t2edtcustomary units! (1)D B 5

28、 1/AN!* t1t2edtSI units! (2)where:B = magnetic induction, G T;A = cross-sectional area of the test specimen,cm2m2;N = number of turns on the B-sensing coil;e = voltage induced in the coil, V;t = time, s; and*t1t2edt= voltage integral = flux, V-s Weber.5.1.5 The change in the magnetic induction shall

29、 be cor-rected to take into account the air flux outside the test specimenthat is linked by the sensing coil. The corrected change, Bcorr,is given as follows:D Bcorr5 108/ AN!*t1t2edt2DH At2 A! /A customary units!(3)DBcorr5 1/AN!*t1t2edt2 0DH At A! /A SI units! (4)where:A = average cross-sectional a

30、rea of the sensing coil,cm2m2;D H = change in field from t1until t2, Oe A/m; and0= magnetic constant 4p 10-7H/m.5.2 Determining Intrinsic Induction:4Available from International Electrotechnical Commission (IEC), 3 rue deVaremb, P.O. Box 131, CH-1211, Geneva 20, Switzerland.TABLE 1 Symbols, Quantiti

31、es, and UnitsNOTE 1IEC nomenclature calls Br“remanence,” when Brrepresentsthe B at H = 0 of the outermost hysteresis loop, and it calls Br“remanentmagnetic induction” for B at H = 0 at smaller loops.Symbol Quantity SI UnitCustomarycgs-emuAtCross section of search coil m2cm2BdMagnetic induction at BH

32、maxT GBrecMagnetic induction at low point ofrecoil loopT GBrMagnetic induction at remanence T GdlDiameter of pole piece m cmd2Diameter of homogeneous field m cmHdMagnetic field strength at BHmaxA/m OeHpMagnetic field strength at lowpoint ofrecoil loopA/m Oel Distance between pole faces m cmlrLength

33、of test sample m cmN Number of turns of test coile Voltage induced in test coil V Vd Total air gap between testsample andpole facesm cm0A constant with value 0=4p10-7H/mrecRecoil permabilityA 977/A 977M 0725.2.1 For high-coercivity magnets, it is more convenient tosense directly an electrical signal

34、 proportional to the intrinsicinduction, derive the average Biby dividing this flux by thearea-turns product of the surrounding B coil, and to plot Biversus H. B then is obtained by mathematical or electronicaddition of H to B.5.2.2 The change of intrinsic induction in the test specimencan be determ

35、ined by integrating the voltage induced in adevice comprising two sensing coils, both subject to the sameapplied field H, where the test specimen is contained in onlyone of the coils (Coil 1). If each individual coil has the samearea-turns product, and if the windings are connected electri-cally in

36、opposition, the signal induced by the flux linking Coil2 (not containing the specimen) will compensate for the outputof Coil 1 except for Biwithin the test specimen. The change ofintrinsic induction in the specimen then is given as follows:D Bi5108/AN!*t1t2edtcustomary units! (5)FIG. 1 Normal and In

37、trinsic Hysteresis Loops and Initial Magnetization Curves for Permanent Magnet Materials Illustrating TwoExtremes of Virgin Sample BehaviorA 977/A 977M 073DBi5 1/AN!*t1t2edt SI units! (6)where:Bi= intrinsic induction, G T;A = cross section of the test specimen, cm2m2; andN = number of turns on Coil

38、1 containing the test speci-men.5.2.3 The two-sensing-coil device shall lie totally within thehomogeneous field defined by Eq A1.1 and Eq A1.2. Testspecimens of lower-coercivity magnets having a range ofcross-sectional areas and shapes can then be measured with thesame coil device.An arrangement of

39、side-by-side coils of equalsize is useful. Serious errors, however, are incurred whenmeasuring Bithis way on high-Bror high/coercivity magnets,or both, at applied fields of about 10 kOe or more. The errorsare most severe for test specimens of short pole-to-pole length.Local pole-piece saturation cau

40、ses strong field inhomogene-ities. The specimen then must fill the cross section of Coil 1,and Coil 2 must be a thin and flat coil, or a coaxial annular coil,either centered on the specimen or in close proximity to itssurface (see 5.3).5.2.4 The total error of measuring Bishall be not greaterthan 62

41、%.5.3 Measuring the Magnetic Field Strength:5.3.1 For correct magnetization curves, one should knowthe magnetic field strength, H, inside the test specimen,averaged over the specimen volume if H is not uniform. Butthis inner field cannot be measured. At the surface of the testspecimen, H is equal to

42、 the local field strength just inside thespecimen in those locations (and only there) where the Hvector is parallel to the side surface of the specimen. Therefore,a magnetic field strength sensor of small dimensions relative tothe specimen is placed near the specimen surface and sym-metrical with re

43、spect to the end faces, covering the shortestpossible center portion of the specimen length. It shall be sooriented that it correctly measures the tangential field compo-nent.5.3.2 To determine the magnetic field strength, a flat surfacecoil, a tightly fitted annular coil, a magnetic potentiometer,

44、ora Hall probe is used together with suitable instruments. Thedimensions of the magnetic field sensor and its location shallbe such that it is within an area of limited diameter around thetest specimen (see Annex A1).5.3.3 The provisions of 5.3.2 are adequate for measure-ments on magnets having low-

45、to-moderate intrinsic coercivity,such as Alnico and bonded ferrites. For high-coercivity, denseferrites and especially for most rare earth-transition metalmaterials, it is essential for accurate measurement to use thinflat or radially thin annular H-sensing coils of short length(1/5 to 1/3 of the sp

46、ecimen length), centered on the specimenand placed as close as possible to the specimen surface.5.3.4 The same considerations apply to the H-flux compen-sation coil used in Bimeasurements (see 5.2.3.) When polesaturation can occur, Coil 2 also shall be a thin conforming flatsurface coil for rectangu

47、lar specimen shapes or a thin annularcoil closely surrounding a cyclindrical specimen, and thespecimen essentially shall fill the open cross-sectional area ofthe Bsensing Coil 1.5.3.5 To reduce other measurement errors, the air gapsbetween the flat ends of the test specimen and the pole piecesshall

48、be kept small, typically in the range 0.001 to 0.002 in.0.025 to 0.050 mm (see Fig. 4).5.3.6 The magnetic field strength measuring system shall becalibrated. Any temperature dependence of the measuringinstruments, (for example, Hall probes), must be taken intoaccount. The total error of measuring H

49、shall be not greaterthan 62%.NOTE 1The end faces of the test specimen should be in intimatecontact with the pole faces. There are always unavoidable small air gapsas a result of surface roughness, poor parallelism of sample or pole faces,FIG. 2 Normal and Intrinsic Demagnetization Curves withSymbols for Special Points of Interest and Definition of SalientProperties. Illustration of Maximum Energy Product, CoerciveFields, and Definition of Knee FieldFIG. 3 Normal and Intrinsic Demagnetization Curves withSymbols