Suspension force model for bearingless AC homopolar machines designed for flywheel energy storage

2013 7th IEEE GCC Conference and Exhibition (GCC) Pub Date : 2013-11-01 DOI:10.1109/IEEEGCC.2013.6705789

E. Severson, R. Nilssen, T. Undeland, N. Mohan

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引用次数: 26

Abstract

Bearingless ac homopolar machines combine magnetic bearing and motor/generator functionality into a single electric machine which features variable excitation, high power density at high rotational speed, a simple and robust rotor structure, and magnet-less excitation. These features make the bearingless ac homopolar machine a promising machine for highspeed flywheel energy storage systems (FESS). The variable excitation of the bearingless ac homopolar machine has the potential to increase the FESS's efficiency by allowing for low excitation during periods of free-wheeling and high-speed operation. However, the magnetic suspension's position stiffness and current stiffness depend upon the excitation level. This dependency must be taken into account in the suspension controller or the magnetic suspension may become unstable at certain excitation levels. A technique for modeling this dependence is presented in this paper and explored through 3D finite element simulation. A prototype design is analyzed for two rotor structures: one with a square airgap length profile and one with an inverted sinusoidal airgap length profile.

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飞轮储能无轴承交流均极电机悬架力模型

无轴承交流同极电机将磁轴承和电机/发电机的功能结合成一个单一的电机，具有可变励磁，高转速下的高功率密度，简单而坚固的转子结构和无磁励磁。这些特点使无轴承交流单极电机成为高速飞轮储能系统(FESS)的理想电机。无轴承交流单极电机的可变励磁有可能通过允许在自由旋转和高速运行期间的低励磁来提高FESS的效率。然而，磁悬浮的位置刚度和电流刚度取决于激励水平。在悬架控制器中必须考虑到这种依赖性，否则磁悬浮在某些激励水平下可能变得不稳定。本文提出了一种模拟这种依赖关系的技术，并通过三维有限元仿真进行了探索。分析了两种转子结构的原型设计:一种是方形气隙长度型，另一种是反正弦气隙长度型。

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 7th IEEE GCC Conference and Exhibition (GCC)

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