Single-Phase Short-Circuit Fault Tolerant Control for Five-Phase Permanent Magnet Machines With Copper Loss Reduction

Huanran Wang; Chunyang Gu; Shuo Wang; Weiduo Zhao; Shun Bai; Giampaolo Buticchi; Chris Gerada; He Zhang

doi:10.1109/TIE.2022.3231322

Single-Phase Short-Circuit Fault Tolerant Control for Five-Phase Permanent Magnet Machines With Copper Loss Reduction

Huanran Wang, Chunyang Gu, Shuo Wang, Weiduo Zhao, Shun Bai, Giampaolo Buticchi, Chris Gerada, He Zhang

Research output: Journal Publication › Article › peer-review

7 Citations (Scopus)

Abstract

Five-phase machines represent a widely adopted choice for fault-tolerant applications due to their extra degrees of freedom. This article deals with the single-phase short-circuit fault tolerant control using original transformation matrix for five-phase permanent-magnet machines. The proposed method first follows the fundamental phase current injection (FCI) method based on the calculated SC current. Moreover, third-order harmonic phase current injection (THCI) method is presented to reduce copper loss. The computational method of derating factor is also adopted for industrial applications. The fault tolerance and dynamic performance are also verified by the experimental results. A reduction of copper loss in THCI method by about 15% is achieved, compared with general and FCI methods.

Original language	English
Pages (from-to)	11087-11097
Number of pages	11
Journal	IEEE Transactions on Industrial Electronics
Volume	70
Issue number	11
DOIs	https://doi.org/10.1109/TIE.2022.3231322
Publication status	Published - 1 Nov 2023

Keywords

Fault-tolerant operation
five-phase permanent magnet (PM) motor
short-circuit (SC) fault
third-order harmonic current injection

ASJC Scopus subject areas

Electrical and Electronic Engineering
Control and Systems Engineering

Access to Document

10.1109/TIE.2022.3231322

Cite this

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title = "Single-Phase Short-Circuit Fault Tolerant Control for Five-Phase Permanent Magnet Machines With Copper Loss Reduction",

abstract = "Five-phase machines represent a widely adopted choice for fault-tolerant applications due to their extra degrees of freedom. This article deals with the single-phase short-circuit fault tolerant control using original transformation matrix for five-phase permanent-magnet machines. The proposed method first follows the fundamental phase current injection (FCI) method based on the calculated SC current. Moreover, third-order harmonic phase current injection (THCI) method is presented to reduce copper loss. The computational method of derating factor is also adopted for industrial applications. The fault tolerance and dynamic performance are also verified by the experimental results. A reduction of copper loss in THCI method by about 15% is achieved, compared with general and FCI methods.",

keywords = "Fault-tolerant operation, five-phase permanent magnet (PM) motor, short-circuit (SC) fault, third-order harmonic current injection",

author = "Huanran Wang and Chunyang Gu and Shuo Wang and Weiduo Zhao and Shun Bai and Giampaolo Buticchi and Chris Gerada and He Zhang",

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AU - Wang, Huanran

AU - Gu, Chunyang

AU - Wang, Shuo

AU - Zhao, Weiduo

AU - Bai, Shun

AU - Buticchi, Giampaolo

AU - Gerada, Chris

AU - Zhang, He

PY - 2023/11/1

Y1 - 2023/11/1

N2 - Five-phase machines represent a widely adopted choice for fault-tolerant applications due to their extra degrees of freedom. This article deals with the single-phase short-circuit fault tolerant control using original transformation matrix for five-phase permanent-magnet machines. The proposed method first follows the fundamental phase current injection (FCI) method based on the calculated SC current. Moreover, third-order harmonic phase current injection (THCI) method is presented to reduce copper loss. The computational method of derating factor is also adopted for industrial applications. The fault tolerance and dynamic performance are also verified by the experimental results. A reduction of copper loss in THCI method by about 15% is achieved, compared with general and FCI methods.

AB - Five-phase machines represent a widely adopted choice for fault-tolerant applications due to their extra degrees of freedom. This article deals with the single-phase short-circuit fault tolerant control using original transformation matrix for five-phase permanent-magnet machines. The proposed method first follows the fundamental phase current injection (FCI) method based on the calculated SC current. Moreover, third-order harmonic phase current injection (THCI) method is presented to reduce copper loss. The computational method of derating factor is also adopted for industrial applications. The fault tolerance and dynamic performance are also verified by the experimental results. A reduction of copper loss in THCI method by about 15% is achieved, compared with general and FCI methods.

KW - Fault-tolerant operation

KW - five-phase permanent magnet (PM) motor

KW - short-circuit (SC) fault

KW - third-order harmonic current injection

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Single-Phase Short-Circuit Fault Tolerant Control for Five-Phase Permanent Magnet Machines With Copper Loss Reduction

Abstract

Keywords

ASJC Scopus subject areas

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