Design of a radial flux permanent magnet wind generator with low coercive force magnets

2016 2nd International Conference on Intelligent Energy and Power Systems (IEPS) Pub Date : 2016-06-07 DOI:10.1109/IEPS.2016.7521864

J. Faiz, Z. Valipour, M. Shokri-Kojouri, M. A. Khan

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引用次数: 11

Abstract

In this paper, the design procedure of a three-phase radial flux permanent magnet synchronous generator (PMSG) is presented for a wind turbine application. This generator is intended for direct coupling to a wind turbine. Low coercive force AlNiCo permanent magnet (PM) material is used in place of common and costly NdFeB PMs. The low coercive force of AlNiCo PMs may result in demagnetization of the PMs when conventional structures of a PM machine is used. This occurs due to the demagnetization magneto-motive force due to stator currents under load conditions of the machine. This may result in irreversible change in the PMs and also unstable operation of the machine, which is the main problem in using AlNiCo PMs in PMSG design. This can be resolved through alternate rotor design that aims to achieve flux intensifying operation. Moreover, the optimal number of slot/pole/phase is determined for cogging torque reduction and generator performance improvement. In this paper, a design detailed approach is formulated and presented, achieves the afore-mentioned characteristics. Finally, the precision of the analytical design approach of the PMSG is validated by means of detailed finite element computations.

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低矫顽力磁体径向磁通永磁风力发电机的设计

本文介绍了用于风力发电的三相径向磁通永磁同步发电机的设计过程。该发电机用于直接耦合风力涡轮机。低矫顽力铝镍钴永磁体(PM)材料是用来代替常见的和昂贵的钕铁硼永磁。铝镍钴永磁材料矫顽力低，在使用传统永磁机械结构时，可能导致永磁材料退磁。这是由于在机器负载条件下定子电流产生的退磁磁动势造成的。这可能会导致永磁材料的不可逆变化和机器的不稳定运行，这是在永磁材料设计中使用铝镍钴永磁材料的主要问题。这可以通过交替转子设计来解决，旨在实现磁通强化运行。此外，还确定了最优槽/极/相数，以减小齿槽转矩，提高发电机性能。本文制定并提出了一种详细的设计方法，实现了上述特点。最后，通过详细的有限元计算验证了解析设计方法的精度。

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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2016 2nd International Conference on Intelligent Energy and Power Systems (IEPS)

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