Detection Study of Static Eccentricity and Demagnetization Faults in IPMSM

2023 IEEE IAS Global Conference on Renewable Energy and Hydrogen Technologies (GlobConHT) Pub Date : 2023-03-11 DOI:10.1109/GlobConHT56829.2023.10087871

P. Verma, Himanshu Misra, Bharat Singh Rajpurohit

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Abstract

Permanent magnet synchronous machine is a compact and efficient machine with advantage of high energy density. In present scenario, the industrial use of permanent magnet machines increases tremendously. Therefore, condition monitoring and fault diagnosis of PMSM gaining more and more attention. This paper presents a study to address eccentricity and demagnetization faults in rotor of permanent magnet machines using FEM (Finite Element Method) in Ansys Mexwell-2D Environment. In context to PMSM faults, eccentricity faults accounts for nearly 10% of total faults of the machine. In present investigation, the eccentricity faults study is carried out to different level of severities ranging 10-40% and the radial components of airgap flux density spectrum of every severity level including its FFT is compared with healthy machine spectrum. The design process includes imperative assumptions and evaluates machine parameters. The design incorporates V-type magnet structure and NdFeB (N42) to utilize as rare earth material. The analysis results determine the effectiveness of anticipated machine design.

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永磁同步电动机静态偏心与退磁故障检测研究

永磁同步电机是一种结构紧凑、效率高的电机，具有能量密度高的优点。在目前的情况下，永磁电机的工业应用急剧增加。因此，永磁同步电机的状态监测与故障诊断越来越受到人们的重视。在Ansys Mexwell-2D环境下，采用有限元法研究了永磁电机转子偏心和退磁故障。在永磁同步电机故障中，偏心故障占整机总故障的近10%。本研究对10 ~ 40%不同严重程度的偏心故障进行了研究，并将各严重程度气隙磁通密度谱的径向分量及其FFT与健康机谱进行了比较。设计过程包括必要的假设和评估机器参数。设计采用v型磁铁结构，采用钕铁硼(N42)作为稀土材料。分析结果确定了预期机器设计的有效性。

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2023 IEEE IAS Global Conference on Renewable Energy and Hydrogen Technologies (GlobConHT)

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