Investigation of Torque and Reduction of Torque Ripples through Assisted-Poles in Low-Speed, High-Torque Density Spoke-Type PMSMs

Machines Pub Date : 2024-05-10 DOI:10.3390/machines12050327
Sayyed Haleem Shah, Yun-Chong Wang, D. Shi, Jian-Xin Shen
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Abstract

In this article, rotor designs utilizing assisted-poles are investigated for a high-torque density spoke-type permanent magnet synchronous machine (PMSM) with fractional slot concentrated winding (FSCW) to explore the rich air-gap magnetic field harmonics and torque generation mechanism. Due to their higher average torque output, spoke-type PMSMs with FSCW are increasingly used in high-torque density applications. However, slot harmonics generate torque ripples that are difficult to eliminate in FSCW spoke-type PMSMs. Removing slot harmonics from the stator or winding results in a large drop in torque since their winding factors are identical to those of the main harmonic. Therefore, rotor designs having assisted-poles (symmetrical and asymmetrical) are investigated in this work to mitigate slot harmonics and minimize torque ripples. Firstly, the air-gap flux density is analyzed for the machines having assisted-poles, and a model of interaction between the stator and rotor-MMF harmonics is created and validated through Finite element analysis (FEA) to analyze the torque production mechanism. In addition, an analytical relationship between the assisted-poles’ dimensions and the generated torque harmonics is proposed. Furthermore, a generalized torque ripple reduction concept for the FSCW spoke-type PMSM having asymmetrically designed assisted-poles is presented. The proposed design and optimization method are validated through analytical calculations and FEA simulations, and a brief comparative analysis is presented for the analyzed machine prototypes. It has been established that the machine designed by applying the proposed asymmetrical assisted-poles can achieve a reduction in torque ripples while also significantly lowering cogging torque in comparison to the conventional spoke-type PMSMs and other spoke-type PMSMs with rotor having symmetrical assisted-poles.
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研究低速、高扭矩密度辐条式 PMSM 扭矩和通过辅助极降低扭矩波纹
本文研究了带分数槽集中绕组(FSCW)的高扭矩密度辐条式永磁同步电机(PMSM)利用辅助极的转子设计,以探索丰富的气隙磁场谐波和扭矩产生机制。由于具有更高的平均扭矩输出,带 FSCW 的辐条式 PMSM 越来越多地应用于高扭矩密度场合。然而,槽谐波会产生扭矩波纹,这在 FSCW 轮辐式 PMSM 中很难消除。从定子或绕组中去除槽谐波会导致转矩大幅下降,因为它们的绕组因数与主谐波的绕组因数相同。因此,本文研究了具有辅助极(对称和非对称)的转子设计,以减轻槽谐波并将转矩纹波降至最低。首先,分析了具有辅助磁极的机器的气隙磁通密度,创建了定子和转子-MMF 谐波之间的相互作用模型,并通过有限元分析(FEA)验证了该模型,以分析转矩产生机制。此外,还提出了辅助磁极尺寸与产生的转矩谐波之间的分析关系。此外,还提出了一种用于 FSCW 轮辐式 PMSM 的通用转矩纹波降低概念,该 PMSM 具有不对称设计的辅助磁极。通过分析计算和有限元分析仿真验证了所提出的设计和优化方法,并对所分析的机器原型进行了简要的对比分析。结果表明,与传统的辐条式 PMSM 和其他转子具有对称辅助磁极的辐条式 PMSM 相比,采用所建议的非对称辅助磁极设计的机器可以减少扭矩波纹,同时还能显著降低齿槽转矩。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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