高功率因数横向磁通机的三维解析设计

M. Kremers, J. Paulides, E. Lomonova
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引用次数: 6

摘要

低速高扭矩应用,如风能发电,青睐高数量的极解决方案。对于传统的径向或轴向磁通机,这导致泄漏磁通增加,而功率输出不增加。对于横向磁通机(TFM),功率输出的增加与极数成正比。然而,在tfm中也存在较大的漏磁,降低了其功率因数和商业应用。需要快速准确的三维模型来模拟这种磁漏。通常采用包含大量单元的有限元模型来计算三维磁通密度分布。这种方法非常耗时,单个解决方案需要几个小时。一个快速和更准确的参数化模型是必不可少的,以尽量减少机器体积,同时保持所需的功率因数。在本文中,提出了一种设计方法,以获得具有预定义功率因数的最小体积TFM。采用解析三维磁荷模型对TFM的单磁周期进行了模拟。根据所需的功率因数和磁铁产生的磁通,计算出线圈的尺寸。利用TFM的单磁周期性能来确定整机尺寸。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Analytical 3-D design of a Transverse Flux Machine with high power factor
Low-speed high-torque applications, e.g. wind energy generation, favor high number of pole solutions. for traditional radial or axial flux machines this leads to an increase in leakage flux while the power output does not increase. For Transverse Flux Machines (TFM) the increase in power output is proportional to the number of poles. However, large flux leakage is also present in TFMs, reducing their power factor and commercial application. Fast and accurate 3-D models are required to model this flux leakage. Finite Element Models (FEM) comprising a large number of elements are commonly used to calculate the 3-D flux density distribution. This approach is very time consuming with hours for a single solution. A fast and more accurate parameterized model is essential to minimize the machine volume while maintaining the required power factor. In this paper, a design approach is presented to obtain a TFM of a minimum volume with a predefined power factor. An analytical 3-D magnetic charge model is used to model a single magnetic period of the TFM. With the required power factor and the obtained flux due to the magnets the coil dimensions are calculated. The performance of the single magnetic period of the TFM is used to determine the full machine dimensions.
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