ASTM A340-2017a Standard Terminology of Symbols and Definitions Relating to Magnetic Testing《与磁性试验有关的符号和定义的标准术语》.pdf

1、Designation: A340 17A340 17aStandard Terminology ofSymbols and Definitions Relating to Magnetic Testing1This standard is issued under the fixed designation A340; the number immediately following the designation indicates the year oforiginal adoption or, in the case of revision, the year of last revi

2、sion. A number in parentheses indicates the year of last reapproval. Asuperscript epsilon () indicates an editorial change since the last revision or reapproval.INTRODUCTIONIn preparing this glossary of terms, an attempt has been made to avoid, where possible, vectoranalysis and differential equatio

3、ns so as to make the definitions more intelligible to the average workerin the field of magnetic testing. In some cases, rigorous treatment has been sacrificed to securesimplicity, but it is believed that none of the definitions will prove to be misleading.It is the intent of this glossary to be con

4、sistent in the use of symbols and units with those found inANSI/IEEE 260-1978 and USA Standard Y 10.5-1968.Part 1Symbols Used in Magnetic TestingSymbol Term cross-sectional area of B coilA cross-sectional area of specimenA solid areaB Hmagnetic flux densitymagnetic inductionB excursion range of indu

5、ctionBb biased inductionBd remanent inductionBdm remanenceBdHd energy product(BdHd)m maximum energy product(BH)max maximum energy productB incremental inductionBi intrinsic inductionBm maximum induction in a hysteresis loopBmax maximum induction in a flux current loopBr residual inductionBrs retenti

6、vityBs saturation inductioncf crest factorCM cyclically magnetized conditiond lamination thicknessDB demagnetizing coefficientdf distortion factorDm magnetic dissipation factorE exciting voltageE1 induced primary voltageE2 induced secondary voltageEf flux voltsf cyclic frequency in hertz magnetomoti

7、ve forceff form factorH magnetic field strengthH excursion range of magnetic field strengthHb biasing magnetic field strength1 This terminology is under the jurisdiction of ASTM Committee A06 on Magnetic Properties and is the direct responsibility of Subcommittee A06.92 on Terminologyand Definitions

8、.Current edition approved July 1, 2017Oct. 15, 2017. Published July 2017October 2017. Originally approved in 1949. Last previous edition approved in 20162017 asA340 16A340 17.1. DOI: 10.1520/A0340-17.10.1520/A0340-17A.This document is not an ASTM standard and is intended only to provide the user of

9、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 consult prior editions as appropriate. In all cases only the current versionof the standard as publ

10、ished 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 States1HcB coercive field strengthHcJ intrinsic coercive field strengthHd demagnetizing field strengthH incremental magnetic field streng

11、thHg air gap magnetic field strengthHL ac magnetic field strength (from an assumedpeak value of magnetizing current)Hm maximum magnetic field strength in a hyster-esis loopHmax maximum magnetic field strength in a flux-current loopHp ac magnetic field strength (from a measuredpeak value of exciting

12、current)Ht instantaneous magnetic field strength (coinci-dent with Bmax)Hz ac magnetic field strength force (from an as-sumed peak value of exciting current)I ac exciting current (rms value)Ic ac core loss current (rms value)Idc constant currentIm ac magnetizing current (rms value)J magnetic polariz

13、ationk coupling coefficient! flux path length!1 effective flux path length!g gap length+ (also N ) flux linkage+m mutual flux linkageL self inductanceL1 core inductanceL incremental inductanceLi intrinsic inductanceLm mutual inductanceL0 initial inductanceLs series inductanceLw winding inductancem m

14、agnetic momentM magnetizationm total mass of a specimenm1 active mass of a specimenND demagnetizing factorN1 turns in a primary windingN2 turns in a secondary windingN1I/!1 ac excitationp magnetic pole strength3 permeanceP active (real) powerPa apparent powerPa (B;f) specific apparent powerPc total

15、core lossPc (B;f) specific core lossPc incremental core lossPe normal eddy current core lossPe incremental eddy current core lossPh normal hysteresis core lossPh incremental hysteresis core lossPq reactive (quadrature) powerPr residual core lossPw winding loss (copper loss)Pz exciting powerPz (B;f)

16、specific exciting powerQm magnetic storage factor5 reluctanceR1 core resistanceRw winding resistanceS lamination factor (stacking factor)SCM symmetrically cyclically magnetized conditionTc Curie temperaturew lamination widthWh hysteresis loop loss linear expansion, coefficient (average) incremental

17、tolerance hysteretic angle loss anglecos magnetic power factorp proton gyromagnetic ratio0 magnetic constant densityA340 17a2 susceptibilityac Permeabilities:a ideal permeabilityL inductance permeabilityL incremental inductance permeability0d initial dynamic permeabilityp peak permeabilityp incremen

18、tal peak permeabilityi instantaneous permeabilityz impedance permeabilityz incremental impedance permeabilitydc Permeabilities: normal permeabilityabs absolute permeabilityd differential permeability incremental permeabilityeff effective circuit permeabilityi incremental intrinsic permeabilitym maxi

19、mum permeabilityi initial permeabilityr relative permeabilityv space permeabilityrev reversible permeability/cot figure of merit reluctivity the numeric 3.1416 resistivity magnetic fluxN flux linkage (see +) mass susceptibility0 initial susceptibility angular frequency in radians per secondPart 2Def

20、inition of Terms Used in Magnetic Testingac excitation, N1I/1the ratio of the rms ampere-turns of exciting current in the primary winding of an inductor to the effectiveflux path length of the inductor.active (real) power, Pthe product of the rms current, I, in an electrical circuit, the rms voltage

21、, E, across the circuit, and thecosine of the angular phase difference, between the current and the voltage.P 5 EI cosDISCUSSIONThe portion of the active power that is expended in a magnetic core is the total core loss, Pc.aging coefficientthe percentage change in a specific magnetic property result

22、ing from a specific aging treatment.DISCUSSIONThe aging treatments usually specified are:(a) 100 h at 150C or(b) 600 h at 100C.aging, magneticthe change in the magnetic properties of a material resulting from metallurgic change due to a normal orspecified aging condition.DISCUSSIONThis term implies

23、a deterioration of the magnetic properties of magnetic materials for electronic and electrical applications, unless otherwise specified.air-gap magnetic field strength, Hgthe magnetic field strength required to produce the induction existing at some point in anonmagnetic gap in a magnetic circuit.DI

24、SCUSSIONIn the cgs-emu system of units, Hg is numerically equal to the induction existing at such a point and exceeds the magnetic field strength in the magneticmaterial.A340 17a3amorphous alloya semiprocessed alloy produced by a rapid quenching, direct casting process resulting in metals withnoncry

25、stalline structure.ampere (turn),Athe unit of magnetomotive force in the SI system of units. The symbolArepresents the unit of electric current,ampere, in the SI system of units.ampere per metre, A/mthe unit of magnetic field strength in the SI system of units.anisotropic materiala material in which

26、 the magnetic properties differ in various directions.anisotropy of lossthe ratio of the specific core loss measured with flux parallel to the rolling direction to the specific core losswith flux perpendicular to the rolling direction.anisotropy of loss5Pc B;f! lPc B;f! twhere:Pc (B;f) l = specific

27、core loss value with flux parallel to the rolling direction, W/lb W/kg, andPc (B;f) t = specific core loss value with flux perpendicular to the rolling direction, W/lb W/kg.DISCUSSIONThis definition of anisotropy normally applies to electrical steels with measurements made in an Epstein frame at a f

28、lux density of 15 kG 1.5 T anda frequency of 60 Hz (see Test Method A343).anisotropy of permeabilitythe ratio of relative peak permeability measured with flux parallel to the rolling direction to therelative peak permeability measured with flux perpendicular to the rolling direction.anisotropy of pe

29、rmeability5prlprtwhere:prl = relative peak permeability value with flux parallel to the rolling direction, andprt = relative peak permeability value with flux perpendicular to the rolling direction.DISCUSSIONThis definition of anisotropy normally applies to electrical steels with measurements made i

30、n an Epstein frame at a flux density of 15 kG 1.5 T anda frequency of 60 Hz (see Test Method A343).antiferromagnetic materiala feebly magnetic material in which almost equal magnetic moments are lined up antiparallel toeach other. Its susceptibility increases as the temperature is raised until a cri

31、tical (Nel) temperature is reached; above thistemperature the material becomes paramagnetic.apparent power, Pathe product (volt-amperes) of the rms exciting current and the applied rms terminal voltage in an electriccircuit containing inductive impedance. The components of this impedance as a result

32、 of the winding will be linear, while thecomponents as a result of the magnetic core will be nonlinear. The unit of apparent power is the volt-ampere, VA.apparent power, specific, Pa(B;f)the value of the apparent power divided by the active mass of the specimen, that is,volt-amperes per unit mass. T

33、he values of voltage and current are those developed at a maximum value of cyclically varyinginduction B and specified frequency f.area, Athe geometric cross-sectional area of a magnetic path which is perpendicular to the direction of the induction.Bloch walla domain wall in which the magnetic momen

34、t at any point is substantially parallel to the wall surface. See alsodomain wall.Bohr magnetona constant that is equal to the magnetic moment of an electron because of its spin. The value of the constantis (9 274 078 1021 erg/gauss or 9 274 078 1024 J/T).cgs-emu system of unitsthe system for measur

35、ing physical quantities in which the base units are the centimetre, gram, andsecond, and the numerical value of the magnetic constant, 0, is unity.coercive field strength, HcBthe absolute value of the applied magnetic field strength (H) required to restore the magnetic fluxdensity (B) to zero.A340 1

36、7a4DISCUSSIONThe symbol Hc has historically been used to denote the coercive field strength determined from a (B,H) loop. Further use of this symbol in ASTMA06 standards is deprecated.DISCUSSIONThe coercive field strength monotonically increases with increasing maximum magnetic field strength (Hm) r

37、eaching a maximum or limiting valuetermed the coercivity. Unless it is known that the material has been magnetized to saturation, the term coercive field strength is preferred.DISCUSSIONThe coercive field strength is not completely described without knowing the maximum magnetic flux density (Bm) or

38、maximum magnetic field strength(Hm) used in the measurement.coercive field strength, intrinsic, HcJthe absolute value of the applied magnetic field strength (H) required to restore either themagnetic polarization (J) or magnetization (M) to zero.DISCUSSIONThe symbol Hci has historically been used to

39、 denote the intrinsic coercive field strength determined from a (Bi,H) loop. Further use of this symbol inASTM A06 standards is deprecated.DISCUSSIONThe intrinsic coercive field strength monotonically increases with increasing maximum magnetic field strength (Hm) reaching a maximum or limitingvalue

40、termed the intrinsic coercivity. Unless it is known that the material has been magnetized to saturation, the term intrinsic coercive field strengthis preferred.DISCUSSIONThe measured value of intrinsic coercive field strength will be the same whether it is measured from a magnetic polarization (J,H)

41、 or a magnetization(M,H) hysteresis loop and will always be numerically larger than the coercive field strength (HcB) measured from a magnetic flux density (B,H)hysteresis loop.DISCUSSIONThe intrinsic coercive field strength is not completely described without knowing the maximum magnetic polarizati

42、on, maximum magnetization ormaximum magnetic field strength (Hm) used in the measurement.coercivitysee coercive field strength.coercivity, intrinsicsee coercive field strength, intrinsic.core, laminateda magnetic component constructed by stacking suitably thin pieces of magnetic material which are s

43、tamped,sheared, or milled from sheet or strip material. Individual pieces usually have an insulating surface coating to minimize eddycurrent losses in the assembled core.core, matedtwo or more magnetic core segments assembled with the magnetic flux path perpendicular to the mating surface.core, powd

44、er(dust)a magnetic core comprised of small particles of electrically insulated metallic ferromagnetic material. Thesecores are characterized by low hysteresis and eddy current losses.core, tape-wounda magnetic component constructed by the spiral winding of strip material onto a suitable mandrel. The

45、 stripmaterial usually has an insulating surface coating which reduces interlaminar eddy current losses in the finished core.core loss, ac eddy current, incremental, Pethe power loss caused by eddy currents in a magnetic material that is cyclicallymagnetized.core loss, ac eddy current, normal, Pethe

46、 power losses as a result of eddy currents in a magnetic material that is symetricallycyclically magnetized.DISCUSSIONA340 17a5The voltage is generally assumed to be across the parallel combination of core inductance, L1, and core resistance, R1.core loss, ac, incremental, Pcthe core loss in a magne

47、tic material when the material is subjected simultaneously to a dc biasingmagnetizing force and an alternating magnetizing force.core loss, residual, Prthe portion of the core loss power, Pc, which is not attributed to hysteresis or eddy current losses fromclassical assumptions.core loss, ac, specif

48、ic, Pc(B;f)the active power (watts) expended per unit mass of magnetic material in which there is a cyclicallyvarying induction of a specified maximum value, B, at a specified frequency, f.core loss, ac, (total), Pcthe active power (watts) expended in a magnetic circuit in which there is a cyclicall

49、y alternatinginduction.DISCUSSIONMeasurements of core loss are normally made with sinusoidally alternating induction, or the results are corrected for deviations from the sinusoidalcondition.core loss densitythe active power (watts) expended in a magnetic core in which there is a cyclically varying induction of aspecified maximum value, B, at a specified frequency, f, divided by the effective volume of the core.DISCUSSIONThis param