Megawatt Electric Motors With High Temperature Superconductors

2020 International Conference on Electrotechnical Complexes and Systems (ICOECS) Pub Date : 2020-10-27 DOI:10.1109/ICOECS50468.2020.9278488

F. Ismagilov, V. Vavilov, A. Varyukhin, R. Karimov, E. Zharkov, I. Sayakhov

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引用次数: 1

Abstract

Superconducting materials opens up new possibilities for electrical machines. They can carry significantly higher current densities compared to traditional copper conductors. Consequently, much higher air-gap magnetic flux densities and current loads can potentially be created, but at the expense of a more complex cryogenic cooling system. This paper presents a study of the possibility of creating a 1 MW electric motor using superconductors for the stator winding. Designs with radial flux and axial flux has been considered. For the design with radial flux, an external rotor motor has been chosen as having the potential to achieve higher power densities. Further optimization of electric motors with an external rotor concerned changes with the geometry of the stator tooth zone and the use of other magnetic rotor systems. During optimization, a reduction in the mass of active materials and a reduction in torque ripple has been obtained in comparison with a standard design of an electric motor with radial magnetic flux. Calculations were also carried out using a copper winding in cryogen, which showed comparable results with the design of an electric motor with high-temperature superconductors.

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具有高温超导体的兆瓦级电动机

超导材料为电机开辟了新的可能性。与传统的铜导体相比，它们可以携带更高的电流密度。因此，可以潜在地创建更高的气隙磁通密度和电流负载，但代价是更复杂的低温冷却系统。本文介绍了利用超导体作为定子绕组制造1兆瓦电动机的可能性。考虑了径向磁通和轴向磁通的设计。对于径向磁通的设计，选择了外转子电机，因为它具有实现更高功率密度的潜力。外转子电机的进一步优化涉及改变定子齿区的几何形状和使用其他磁转子系统。在优化过程中，与具有径向磁通的电动机的标准设计相比，得到了活性物质质量的减小和转矩脉动的减小。在低温环境中使用铜绕组也进行了计算，结果与使用高温超导体的电动机的设计结果相当。

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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2020 International Conference on Electrotechnical Complexes and Systems (ICOECS)

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