2018
DOI: 10.1108/compel-12-2017-0552
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Calculation approach of reluctance in the magnetic circuit of transformer employed to convert into equivalent electric circuit

Abstract: Purpose The theoretical method of converting the magnetic circuit into an electric circuit is mature, but the way to determine the inductances in the electric circuit is not reliable, especially for the core working in saturation status, and it is impossible to determine the inductances by the transformer terminal measurements, as the measurement information is not enough to determine a number of inductances. This paper aims to propose an approach of calculating the reluctances. Design/methodology/approach I… Show more

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Cited by 6 publications
(4 citation statements)
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“…Symmetrical excitation currents are applied for the magneto motive forces (FLV_a = NLV ia, FLV_b = NLV ib and FLV_c = NLV ic) required to produce instantaneous values of fluxes (ɸa, ɸb and ɸc). The reluctance of a core section or air region as a limb of the magnetic circuit is obtained by magnetic energy and magnetic flux related to magnetic sections of the core [32]. It is clear from the Fig 4b that there is a natural asymmetry in the core as the length of magnetic path of phase B between the points P1 and P2 is less than that of phase A and C. Using the superposition theorem to equivalent magnetic circuit [35] of the transformer at no load, instantaneous values of fluxes (ɸa, ɸb and ɸc) in every limb can be figured out by Eqs.…”
Section: Inductance Calculation For Designed Transformermentioning
confidence: 99%
“…Symmetrical excitation currents are applied for the magneto motive forces (FLV_a = NLV ia, FLV_b = NLV ib and FLV_c = NLV ic) required to produce instantaneous values of fluxes (ɸa, ɸb and ɸc). The reluctance of a core section or air region as a limb of the magnetic circuit is obtained by magnetic energy and magnetic flux related to magnetic sections of the core [32]. It is clear from the Fig 4b that there is a natural asymmetry in the core as the length of magnetic path of phase B between the points P1 and P2 is less than that of phase A and C. Using the superposition theorem to equivalent magnetic circuit [35] of the transformer at no load, instantaneous values of fluxes (ɸa, ɸb and ɸc) in every limb can be figured out by Eqs.…”
Section: Inductance Calculation For Designed Transformermentioning
confidence: 99%
“…Both of the MEC Linc-i curves were compared with the measured data to calculate the relative error of each point, as shown in Figure 12b. The maximum relative error emax and average error eavg were calculated by Equations (11) and (12), and presented in Table 2. = 100 × max…”
Section: Inductance Comparison Of Mec and Prototypementioning
confidence: 99%
“…The maximum relative error e max and average error e avg were calculated by Equations (11) and (12), and presented in Table 2.…”
Section: Discuss the Number Of Corner Branches Rcimentioning
confidence: 99%
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