Time‐harmonic field‐circuit model for brushless doubly fed induction machine

A computationally efficient time‐harmonic finite element model for the steady‐state analysis of a brushless doubly fed induction machine (BDFIM) is proposed. In the model, the electromagnetic couplings of the BDFIM are described by means of the sum of two complex magnetic vector potentials that repr...

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Bibliographic Details
Published in:IET electric power applications 2023-07, Vol.17 (7), p.965-975
Main Authors: Jagiela, Mariusz, Wang, Xiaoyan, McMahon, Richard A., Garbiec, Tomasz
Format: Article
Language:English
Subjects:
AC machines
brushless machines
finite elements analysis
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Summary:A computationally efficient time‐harmonic finite element model for the steady‐state analysis of a brushless doubly fed induction machine (BDFIM) is proposed. In the model, the electromagnetic couplings of the BDFIM are described by means of the sum of two complex magnetic vector potentials that represent the two fundamental harmonic time components of the magnetic flux density distribution in the rotor frame of reference. As in an ordinary induction motor, the non‐linearity of the magnetisation characteristic is accounted for using an effective magnetic permeability. For the BDFIM, this is derived by considering the features of modulated magnetic flux density waveform. The accuracy of the approach has been validated by comparing the characteristics of a D270 machine operating in the double‐feed mode with ones obtained from the experimentally verified time‐stepping model at various operating conditions. High accuracy of the results coming from the proposed model is demonstrated even under deep saturation conditions within the magnetic circuit. A steady‐state time‐harmonic model for brushless doubly fed induction motor is presented considering non‐linearity of magnetisation characteristic. Effective permeability model is proposed. The approach is validated against time‐stepping model and measurements.
ISSN:1751-8660
1751-8679
DOI:10.1049/elp2.12317