Design and Strength Optimization of the Carbon Fiber Sleeve of High-Power High-Speed PMSM with Flat Structure
Wan Yuan1, Cui Shumei1, Wu Shaopeng1, Ostanin Sergei Yurievich2, Milyaev Igor Matveevich3
1. School of Electrical Engineering and Automation Harbin Institute of Technology Harbin 150080 China;
2. Moscow Power Engineering Institute Moscow 111250 Russia;
3. Institute of Metallurgy and Materials Russian Academy of Sciences Ekaterinburg 620016 Russia
For the design of carbon fiber sleeve of the high-speed permanent magnet synchronous motor with segmented permanent magnets and flat structure, parametric model was proposed to achieve the rapid design of the sleeve. Influences of interference value between sleeve and magnets, radial compressive stress of magnets, and diameter of rotor on the design of sleeve were analyzed. A 3-D finite element model was built to verify the analytical results. In addition, with the temperature rise results of the rotor, it was used to investigate the problem of bending stress of the sleeve caused by pole spacers under different temperature which may result in destruction of the sleeve. The influences of different pole spacer materials on the bending stress of the sleeve were compared. As a result, the bending stress of the sleeve could be greatly decreased by titanium alloy pole spacers and the strength was optimized. A prototype was manufactured and the test was provided.
万援, 崔淑梅, 吴绍朋, OstaninSergeiYurievich, MilyaevIgorMatveevich. 扁平大功率高速永磁同步电机的护套设计及其强度优化[J]. 电工技术学报, 2018, 33(1): 55-63.
Wan Yuan, Cui Shumei, Wu Shaopeng, Ostanin Sergei Yurievich, Milyaev Igor Matveevich. Design and Strength Optimization of the Carbon Fiber Sleeve of High-Power High-Speed PMSM with Flat Structure. Transactions of China Electrotechnical Society, 2018, 33(1): 55-63.
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2018, Vol. 33 
