磁铁
扭矩
牵引电动机
牵引(地质)
汽车工程
转矩密度
控制理论(社会学)
直接转矩控制
电动汽车
逆变器
同步电动机
工程类
计算机科学
功率(物理)
电气工程
机械工程
电压
物理
感应电动机
控制(管理)
人工智能
热力学
量子力学
作者
Apoorva Athavale,Kensuke Sasaki,Brent S. Gagas,Takashi Kato,R. D. Lorenz
标识
DOI:10.1109/tia.2017.2701340
摘要
Variable flux permanent magnet synchronous machines (VF-PMSMs) in which the magnetization state of low coercive force permanent magnets can be actively controlled to reduce losses in applications that require wide-speed operation have been proposed recently. While prior focus has been on achieving magnetization state manipulation without oversizing the inverter and obtaining higher torque capability, this paper extends the design objectives to include the power requirements of an electric vehicle traction motor over its entire speed range. Finite-element methods are used to study the effect of combinations of low coercive-force and high coercive-force permanent magnets arranged in either series or parallel on the performance of VF-PMSMs. While both configurations help improve the torque density, only the series configuration can help improve the high speed power capability. Experimental results showing the variable magnetization state property, torque-speed capability, and loss reduction capability of a series magnet configuration VF-PMSM test machine are presented.
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