Proposed methodology to combine design concept and manufacturing process selection for distributed wound stator cores

2015 IEEE International Electric Machines & Drives Conference (IEMDC) Pub Date : 2015-05-10 DOI:10.1109/IEMDC.2015.7409230

D. Ogilvie, S. Ratchev, C. Gerada, S. Grace

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引用次数: 0

Abstract

Current induction motor designs account for the majority of the motors used in the world today. However, their designs have not evolved to the extent to which permanent magnet machines have within the automotive and industrial sectors. Current methods of assembling distributed wound stator cores have the known issues of high process scrap, low slot fill and winding quality issues caused by assembly tooling. Design for Manufacturing and Assembly (DFMA) can remove these manufacturing issues but there is a conflict between DFMA and motor performance. By quantitatively assessing conventional and novel stator core design features and the available manufacturing technologies, this paper proposes a method of motor component design and process selection which enables multiple novel component design features to be effectively combined and assessed for their manufacturability and their electromagnetic performance. Using this methodology, this paper also shows that there are clear limitations to the current manufacturing technology used for stator core production.

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提出了将分布式绕线定子铁芯的设计理念与制造工艺选择相结合的方法

当前的感应电动机设计占当今世界上使用的电动机的大多数。然而，它们的设计还没有发展到永磁机器在汽车和工业领域的程度。目前装配分布式绕线定子铁芯的方法存在高工艺废品率、低槽填充率和由装配工具引起的绕线质量问题。制造与装配设计(DFMA)可以消除这些制造问题，但DFMA与电机性能之间存在冲突。通过对传统定子铁心设计特征和新型定子铁心设计特征及现有制造技术的定量评估，提出了一种电机部件设计和工艺选择方法，使多种新型部件设计特征能够有效地结合起来，并对其可制造性和电磁性能进行评估。使用这种方法，本文还表明，目前用于定子铁芯生产的制造技术存在明显的局限性。

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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2015 IEEE International Electric Machines & Drives Conference (IEMDC)

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