利用永磁谐波注入减少整体槽 SPM 电机的振动并提高其扭矩

Q1 Engineering

Chinese Journal of Electrical Engineering Pub Date : 2023-08-29 DOI:10.23919/CJEE.2023.000028

Jinghua Ji;Deyou Liu;Yu Zeng;Tong Liu;Wenxiang Zhao

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引用次数: 0

摘要

本研究旨在通过优化谐波注入永磁体（PM）的形状，改善整体槽表面安装永磁（SPM）机器的振动和扭矩。首先，研究了在正弦永磁体形状中注入三次谐波对 36 槽/12 极 SPM 机器电磁性能的影响，包括扭矩性能和振动响应。结果发现，Sin+3 次谐波形状的 PM 对整体槽机器的扭矩和振动性能有相反的影响，它提高了扭矩能力，但恶化了振动性能。其次，基于平均扭矩和振动之间的权衡，采用响应面模型和 Barebones 多目标粒子群优化算法来确定最佳谐波注入量。随后，比较了最佳 Sin+3rd 形和偏心永磁机械的性能，结果表明所采用的方法具有出色的扭矩和振动性能。最后，制造并测试了一台原型机，以验证理论分析的结果。

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Vibration Reduction and Torque Improvement of Integral-slot SPM Machines Using PM Harmonic Injection

This study aimed to improve the vibration and torque of an integral-slot surface-mounted permanent magnet (SPM) machine by optimizing the shape of the harmonically injected permanent magnet (PM). First, the effect of the third harmonic injected into the sinusoidal PM shape on the electromagnetic performance of a 36-slot/12-pole SPM machine was investigated, including the torque performance and vibration response. It was found that the Sin+3rd harmonic-shaped PM had a contrary effect on the torque and vibration performance of the integral-slot machine, which improved the torque capability but worsened the vibration performance. Second, the response surface model and Barebones multi-objective particle swarm optimization algorithm based on a trade-off between the average torque and vibration were implemented to determine the optimal harmonic injection. Subsequently, the performances of the optimal Sin+3rd-shaped and eccentric PM machines were compared, showing the excellent torque and vibration performance of the adopted method. Finally, a prototype was manufactured and tested to verify the results of the theoretical analysis.

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