Performance Analysis of a Permanent Magnet Motor with Continuous Hairpin Winding

2023 IEEE Workshop on Electrical Machines Design, Control and Diagnosis (WEMDCD) Pub Date : 2023-04-13 DOI:10.1109/WEMDCD55819.2023.10110948

Mohammad Soltani, S. Nuzzo, D. Barater, M. D. Nardo

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Abstract

The global decarbonization targets require increasingly higher levels of efficiency, torque and power density, reliability, etc. of electrical machines intended for transport applications. Recently, hairpin windings are receiving more and more interest from both industry and academia, as they are a promising solution to achieve the above requirements altogether. However, a number of challenges still need to be addressed, including electromagnetic, thermal and manufacturing aspects. One of these is the reliability of the welding process, where the solution could be adopting continuous hairpin windings. However, these result in open slot designs or special stator arrangements, which can produce undesirable effects in motors, such as ripple torque, increased permanent magnet losses, etc. This paper aims at comparing the main electromagnetic performance metrics for a conventional hairpin winding, wound onto a benchmark stator with a semi-closed slot opening design, and a continuous hairpin winding, where the slot opening is open. Finally, the adoption of semi-magnetic slot wedges is investigated and aimed at improving overall motor performance.

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连续发夹绕组永磁电机的性能分析

全球脱碳目标对用于运输应用的电机的效率、扭矩和功率密度、可靠性等要求越来越高。最近，发夹绕组越来越受到工业界和学术界的关注，因为它们是一种有前途的解决方案，可以完全实现上述要求。然而，仍有许多挑战需要解决，包括电磁、热和制造方面。其中之一是焊接过程的可靠性，解决方案可能是采用连续发夹绕组。然而，这会导致开槽设计或特殊的定子布置，这可能会对电机产生不良影响，例如纹波转矩，增加永磁体损耗等。本文的目的是比较传统发夹绕组和连续发夹绕组的主要电磁性能指标，前者绕在半封闭槽口设计的基准定子上，而前者的槽口是打开的。最后，研究了半磁性槽楔的采用，旨在提高电机的整体性能。

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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来源期刊

2023 IEEE Workshop on Electrical Machines Design, Control and Diagnosis (WEMDCD)

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