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Steinmetz Decoded

Magnetism, Hysteresis, And Core Loss

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Why This Family Matters

Section titled “Why This Family Matters”

Routes formulas for magnetic materials, flux, loss, effective resistance, and hysteresis behavior.

38

candidate records in this family.

27

reviewable relation candidates.

6

sources represented.

Candidate Formula Cards

Section titled “Candidate Formula Cards”
#1Theory and Calculation of Electric CircuitsChapter 5: Magnetism- line 9202
(\pi’actically non-magnetic, lowers the permeability to /x = 1.4.)
OCR source linePi’actically non-magnetic, lowers the permeability to /x = 1.4.
#2Theory and Calculation of Electric CircuitsChapter 3: Magnetism- line 6282
(- 1.12, jB= - 1.0: the rising magnetization curve B ’” then passes)
OCR source line- 1.12, jB= - 1.0: the rising magnetization curve B ’” then passes
#3Theoretical Elements of Electrical EngineeringTheory Section 1: Magnetism and Electric Current- line 820
(9. (3) What is the- total magnetic flux per I = 1000 m. length,)
OCR source line9. (3) What is the- total magnetic flux per I = 1000 m. length,
#4Theory and Calculation of Electric CircuitsChapter 3: Magnetism- line 6841
(and B = +13.6, and a given value of flux density, such as B =)
OCR source lineand B = +13.6, and a given value of flux density, such as B =
#5Theory and Calculation of Electric CircuitsChapter 3: Magnetism- line 6884
(ing amplitude, with ff = 1, as mean value, the flux density gradu-)
OCR source lineing amplitude, with ff = 1, as mean value, the flux density gradu-
#6Theory and Calculation of Electric CircuitsChapter 4: Magnetism- line 8975
(Bi = -|- 12,000 and -Bg = -4000, the increase of the hysteresis)
OCR source lineBi = -|- 12,000 and -Bg = -4000, the increase of the hysteresis
#7Theory and Calculation of Electric CircuitsChapter 5: Magnetism- line 9076
(paramagnetic metals, is /x = 1.003; the permeability of bismuth,)
OCR source lineparamagnetic metals, is /x = 1.003; the permeability of bismuth,
#8Theory and Calculation of Electric CircuitsChapter 5: Magnetism- line 9127
(silicon steel, a = 0.04 X 10”^, and the coefficient of hysteresis of)
OCR source linesilicon steel, a = 0.04 X 10”^, and the coefficient of hysteresis of
#9Theory and Calculation of Electric CircuitsChapter 5: Magnetism- line 9417
(""I = coefficient of hysteresis, in the 1.6*^ power law.)
OCR source line""I = coefficient of hysteresis, in the 1.6*^ power law.
#10Theory and Calculation of Electric CircuitsChapter 3: Magnetism- line 6804
(flux density, B2 = 2.6. If, however, this field strength ff = 1)
OCR source lineflux density, B2 = 2.6. If, however, this field strength ff = 1
#11Theory and Calculation of Alternating Current PhenomenaChapter 1: Introduction- line 1072
(If now 4> = the magnetic flux produced by, and inter-)
OCR source lineIf now 4> = the magnetic flux produced by, and inter-
#12Theoretical Elements of Electrical EngineeringTheory Section 1: Magnetism and Electric Current- line 751
(The permeability of air = 1 and is constant.)
OCR source lineThe permeability of air = 1 and is constant.
#13Theoretical Elements of Electrical EngineeringTheory Section 1: Magnetism and Electric Current- line 889
(in the yoke. The permeability of sheet iron is m = 2550 at)
OCR source linein the yoke. The permeability of sheet iron is m = 2550 at
#14Theoretical Elements of Electrical EngineeringTheory Section 1: Magnetism and Electric Current- line 890
(5i = 6880, MS = 2380 at B3 = 5950. The permeability of cast)
OCR source line5i = 6880, MS = 2380 at B3 = 5950. The permeability of cast
#15Theoretical Elements of Electrical EngineeringTheory Section 3: Generation of E.m.f.- line 1082
(T = 90°, or at the position of zero inclosure of magnetic flux)
OCR source lineT = 90°, or at the position of zero inclosure of magnetic flux
#16Theory and Calculation of Electric CircuitsChapter 3: Magnetism- line 6805
(is left on the magnetic circuit, the flux does not remain at B2 =)
OCR source lineis left on the magnetic circuit, the flux does not remain at B2 =
#17Theory and Calculation of Electric CircuitsChapter 4: Magnetism- line 7594
(but beyond B = 12, the flux carried by the magnetite rapidly)
OCR source linebut beyond B = 12, the flux carried by the magnetite rapidly
#18Radiation, Light and IlluminationLecture 10: Light Flux And Distribution- line 9569
(The light flux in the space from the downward direction </> = 0)
OCR source lineThe light flux in the space from the downward direction </> = 0
#19Theoretical Elements of Electrical EngineeringTheory Section 4: Power and Effective Values- line 1403
(14 miles = 22,400 m. The magnetic flux produced by /)
OCR source line14 miles = 22,400 m. The magnetic flux produced by /
#20Theoretical Elements of Electrical EngineeringTheory Section 1: Magnetism and Electric Current- line 500
(therefore of flux &#36;> = 4 xw, assuming a uniform distribution in)
OCR source linetherefore of flux $> = 4 xw, assuming a uniform distribution in
#21Theoretical Elements of Electrical EngineeringTheory Section 2: Magnetism and E.m.f.- line 985
(cylinder, if the magnetic flux of the electromagnet is <£ = 25)
OCR source linecylinder, if the magnetic flux of the electromagnet is <£ = 25
#22Theoretical Elements of Electrical EngineeringTheory Section 3: Generation of E.m.f.- line 1192
(15 rev. per sec., this flux is cut 4 X 15 = 60 times per second by)
OCR source line15 rev. per sec., this flux is cut 4 X 15 = 60 times per second by
#23Theory and Calculation of Alternating Current PhenomenaChapter 4: Graphic Representation- line 2212
(3> = maximum value of magnetic flux, in webers.)
OCR source line3> = maximum value of magnetic flux, in webers.
#24Theory and Calculation of Alternating Current PhenomenaChapter 4: Graphic Befrisxintation- line 2623
(4> = maximum value of magnetic flux, in webers.)
OCR source line4> = maximum value of magnetic flux, in webers.
#25Theory and Calculation of Electric CircuitsChapter 4: Magnetism- line 7593
(As seen, the magnetite carries practically no flux up to £ = 10,)
OCR source lineAs seen, the magnetite carries practically no flux up to £ = 10,
#26Theory and Calculation of Electric CircuitsChapter 5: Magnetism- line 9129
(con steel, 77 = 0.6 X 10”’. Hardness and hysteresis loss seem)
OCR source linecon steel, 77 = 0.6 X 10”’. Hardness and hysteresis loss seem
#27Theory and Calculation of Electric CircuitsChapter 3: Magnetism- line 6256
(back to B = 0, but a residual or remanent flux is left, in Fig. 25 :)
OCR source lineback to B = 0, but a residual or remanent flux is left, in Fig. 25 :
#28Theoretical Elements of Electrical EngineeringTheory Section 2: Magnetism and E.m.f.- line 990
(12.5 X 108 lines of magnetic flux per second. Hence the gener-)
OCR source line12.5 X 108 lines of magnetic flux per second. Hence the gener-
#29Theory and Calculation of Alternating Current PhenomenaChapter 3: Iiaw Of Eucctbo-Maonimc Induction- line 1999
(of ’ the flux inclosed by the turns, times 10~*.)
OCR source lineof ’ the flux inclosed by the turns, times 10~*.
#30Theory and Calculation of Alternating Current PhenomenaChapter 3: Iiaw Of Eucctbo-Maonimc Induction- line 2085
(flux X number of turns X 10~^)
OCR source lineflux X number of turns X 10~^
#31Theory and Calculation of Alternating Current PhenomenaChapter 3: Law Of Electromagnetic Induction- line 2115
(flux X number of turns X 10”^)
OCR source lineflux X number of turns X 10”^
#32Theoretical Elements of Electrical Engineeringsource index- line 269
(10. Hysteresis and Effective Resistance. 48)
OCR source line10. Hysteresis and Effective Resistance. 48
#33Theory and Calculation of Alternating Current PhenomenaChapter 3: Law Of Electro-Magnetic Induction- line 1632
(of the flux inclosed by the turns, times 10~8.)
OCR source lineof the flux inclosed by the turns, times 10~8.
#34Theory and Calculation of Alternating Current PhenomenaChapter 3: Law Of Electro-Magnetic Induction- line 1703
(flux X number of turns X 10~8)
OCR source lineflux X number of turns X 10~8
#35Theory and Calculation of Alternating Current PhenomenaChapter 4: Graphic Representation- line 2247
(The resultant magnetic flux, 4>, which in the secondary)
OCR source lineThe resultant magnetic flux, 4>, which in the secondary
#36Theory and Calculation of Alternating Current PhenomenaChapter 4: Graphic Befrisxintation- line 2658
(The resultant magnetic flux, 4>, which in the secondary)
OCR source lineThe resultant magnetic flux, 4>, which in the secondary
#37Theory and Calculation of Electric CircuitsChapter 3: Magnetism- line 5801
(Fig. 23 shows an average magnetization curve, of good standard)
OCR source lineFig. 23 shows an average magnetization curve, of good standard
#38Theory and Calculation of Electric CircuitsChapter 3: Magnetism- line 6853
(flux density decreasing, to Po, slower to P2 and then still slower,)
OCR source lineflux density decreasing, to Po, slower to P2 and then still slower,