Development of closed-form solutions for fast thermal modeling of rotating electric machinery

2013 International Electric Machines & Drives Conference Pub Date : 2013-05-12 DOI:10.1109/IEMDC.2013.6556189

V. T. Buyukdegirmenci, M. Magill, S. Nategh, P. Krein

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引用次数: 5

Abstract

Accurate knowledge of winding temperature is critical for the control, protection, and real-time monitoring of high-performance electric machines. Lumped parameter and finite element analyses can be used to model thermal stress, but both have drawbacks in applications where fast estimates of local temperature distributions are necessary. To overcome this, a closed-form solution for the steady-state stator temperature distribution over one slot pitch in a radial air gap electric machine is presented. Machine symmetry and material thermal properties are used to create a representative layer model in which a solution to Laplace's equation is developed. In addition to lumped parameter and three-dimensional (3D) finite element models, the method is verified through experimental results. Analytical model winding temperature predictions are within about 2.5% of finite element model predictions. Estimates of stator slot, tooth, and end-winding temperatures are within 7% of experimental measurements. The results are shown to have value for parametric machine design and protection.

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旋转电机快速热建模封闭解的发展

准确了解绕组温度对于高性能电机的控制、保护和实时监控至关重要。集总参数分析和有限元分析可用于模拟热应力，但在需要快速估计局部温度分布的应用中，两者都有缺点。为了克服这一问题，提出了径向气隙电机定子在一个螺距上的稳态温度分布的封闭解。利用机器的对称性和材料的热学性质建立了一个具有代表性的层模型，并在此模型中建立了拉普拉斯方程的解。除了集总参数和三维有限元模型外，还通过实验结果对该方法进行了验证。解析模型预测的绕组温度在有限元模型预测的2.5%以内。定子槽、齿和端绕组温度的估计在实验测量值的7%以内。研究结果对机械的参数化设计和保护具有一定的参考价值。

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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2013 International Electric Machines & Drives Conference

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