Investigation of Enhancing Reluctance Torque of a Delta-Type Variable Flux Memory Motor Having Large Flux Barrier for EV/HEV Traction

2020 IEEE Energy Conversion Congress and Exposition (ECCE) Pub Date : 2020-10-11 DOI:10.1109/ECCE44975.2020.9235600

R. Tsunata, M. Takemoto, S. Ogasawara, K. Orikawa

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引用次数: 10

Abstract

Delta-type permanent magnet (PM) arrangement and extended flux barriers are very effective in improving magnetization characteristics of variable flux memory motors (VFMMs). However, the reluctance torque tends to be declined because of small q-axis inductance. Therefore, a conventional VFMM using above two methods needs larger load current for achieving required maximum torque than that of a target traction motor which is mounted in TOYOTA PRIUS 4th generation. Hence, this paper proposes rotor shape that can increase the reluctance torque in order to achieve required maximum torque by applying same load current as that of the target motor. Finally, the proposed VFMM whose reluctance torque is improved can generate the target maximum torque with smaller load current than that of the conventional VFMM. In addition, the proposed VFMM has smaller maximum magnetizing current compared to that of the conventional model, and the proposed VFMM also indicates higher efficiency than that of the target traction motor in high speed region.

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用于电动汽车/混合动力汽车牵引的大磁通阻隔型δ型可变磁通记忆电机增强磁阻转矩研究

三角型永磁体和扩展磁阻是改善可变磁链记忆电机磁化特性的有效方法。然而，由于q轴电感较小，磁阻转矩趋于下降。因此，使用上述两种方法的传统VFMM需要比安装在丰田普锐斯第四代的目标牵引电机更大的负载电流来实现所需的最大转矩。因此，本文提出了可以增加磁阻转矩的转子形状，通过施加与目标电机相同的负载电流来达到所需的最大转矩。最后，与传统VFMM相比，改进磁阻转矩的VFMM可以在更小的负载电流下产生目标最大转矩。此外，与传统模型相比，所提出的VFMM具有更小的最大磁化电流，并且在高速区域内，所提出的VFMM也比目标牵引电机具有更高的效率。

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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2020 IEEE Energy Conversion Congress and Exposition (ECCE)

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