Determination of the inductances of salient pole synchronous machines based on the voltage equation of a single coil in the stator winding

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Authors

  • Onur Misir
  • Seyed Morteza Raziee
  • Bernd Ponick

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Original languageEnglish
Article number7469874
Pages (from-to)3792-3804
Number of pages13
JournalIEEE Transactions on Industry Applications
Volume52
Issue number5
Publication statusPublished - 1 Sept 2016

Abstract

An improved model for calculating the current distribution of salient pole synchronous machines with internal faults in the stator winding is established using the multiloop method. For this purpose, good knowledge of the time-depending inductances is necessary. In this paper, a calculation method is presented to determine the inductances of a salient pole synchronous machine based on the voltage equation of a single coil in the stator winding, in particular, the mutual- and self-inductances of the stator coils, the mutual inductances between the stator coils and the field winding, the self-inductance of the field winding, the mutual inductance between the stator coils and the damper loops, the mutual inductance between the field winding and the damper loops, as well as the mutual inductance between the damper loops. The method presented here considers the analytical calculation of the magnetic flux density based on the magnetomotive force and the time-depending air-gap permeance function of the salient pole synchronous machine. The analytical approach has been validated with the finite-element method and experimental results for two different salient pole synchronous motors.

Keywords

    Air-gap permeance, damper loop, electric loading, field winding, magnetomotive force (MMF), multiloop method, mutual inductance, salient pole, self-inductance, stator coil, synchronous machines

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Determination of the inductances of salient pole synchronous machines based on the voltage equation of a single coil in the stator winding. / Misir, Onur; Raziee, Seyed Morteza; Ponick, Bernd.
In: IEEE Transactions on Industry Applications, Vol. 52, No. 5, 7469874, 01.09.2016, p. 3792-3804.

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abstract = "An improved model for calculating the current distribution of salient pole synchronous machines with internal faults in the stator winding is established using the multiloop method. For this purpose, good knowledge of the time-depending inductances is necessary. In this paper, a calculation method is presented to determine the inductances of a salient pole synchronous machine based on the voltage equation of a single coil in the stator winding, in particular, the mutual- and self-inductances of the stator coils, the mutual inductances between the stator coils and the field winding, the self-inductance of the field winding, the mutual inductance between the stator coils and the damper loops, the mutual inductance between the field winding and the damper loops, as well as the mutual inductance between the damper loops. The method presented here considers the analytical calculation of the magnetic flux density based on the magnetomotive force and the time-depending air-gap permeance function of the salient pole synchronous machine. The analytical approach has been validated with the finite-element method and experimental results for two different salient pole synchronous motors.",
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AU - Raziee, Seyed Morteza

AU - Ponick, Bernd

N1 - Publisher Copyright: © 1972-2012 IEEE. Copyright: Copyright 2018 Elsevier B.V., All rights reserved.

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