双并列转子永磁直驱电机转子不平衡力分析与优化

doi:10.19595/j.cnki.1000-6753.tces.230427

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摘要双并列转子永磁直驱电机受轴间距限制,设计时会切掉部分定子铁心和绕组,造成转子电磁力不平衡。为最大限度地抑制转子所受的不平衡电磁力,该文从双并列转子结构出发,分析了电机绕组电感参数不对称的原因,提出通过合理设计线圈跨距和分布平衡三相电感。在此基础上,构建转子所受总电磁力的数学模型,理论分析各个分力的来源及影响因素,研究各个分力对转子所受总电磁力的影响,提出了优化占空角、优化耦合间距、采用定子端部不对称结构、采用转子偏心结构和切除部分单元电机五种优化方法,实现对转子所受电磁力的优化,探讨了不同方法的优化效果,以及其对转矩脉动的影响,总结了不同优化方法的优缺点。

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关键词 ：双并列转子, 永磁直驱电机, 电磁力, 优化方法

Abstract：Most parallel synchronous drive equipment, such as the two-roll mill and twin-screw pump, are driven by an induction motor with synchronous mechanical gear. Such drive systems have large volumes, poor synchronization of master and slave shafts, requiring regular maintenance. A dual-parallel rotor permanent magnet direct-driven motor has gradually come into view.
Due to the distance limitation between rotating shafts, part of the stator core and windings are cut off in the design of a dual-parallel rotor permanent magnet direct-driven motor, resulting in unbalanced rotor electromagnetic force. Therefore, this paper analyzes the inductance parameter asymmetry of the motor windings. Inductance parameters of the motor with windings pitch of 4 and 3 are calculated. On this basis, a mathematical model for the total electromagnetic force on the rotor is constructed, and the influence of each component force on the rotor’s total electromagnetic force is studied. Five optimization methods are proposed to optimize the electromagnetic force on the rotor: optimizing the duty angle, optimizing the coupling distance, adopting the asymmetric stator end structure, adopting the eccentric rotor structure, and eliminating part of the unit motors. Finally, the optimization effects of different methods on torque ripple are discussed. The advantages and disadvantages of different optimization methods are summarized, laying a foundation for studying dual-parallel rotor permanent magnet direct-driven motors.
The following conclusions can be drawn: (1) The long-pitch coil of the modular structure may cause asymmetric three-phase inductance parameters. Three-phase inductance can be effectively balanced by reasonably selecting the winding pitch and the head end of the A-phase winding. (2) The electromagnetic force F_totalon the rotor includes the electromagnetic force F₁ between the stator with windings and the corresponding rotor, the magnetic force F_mag between two permanent magnet rotors in the coupling area, the force F_end between the core end and the rotor outside the duty area in the coupling area, and the magnetic resistance force F_end,cogof the rotor against the core end in the coupling area and additional electromagnetic force F_ad. The X direction force of F_total is related to the above forces, while the Y direction force of F_total is only relevant to F₁. F₁, F_mag, and F_endare the most important components of F_total. (3) According to the analysis of the F_total, five methods are proposed to weaken the F_total. The influence of the five optimization methods on the electromagnetic force is given, and the advantages and disadvantages of the five optimization methods are discussed. The method with a rotor eccentric structure has the best optimization effect but requires higher processing technology. The method of eliminating partial unit motors is the most practical. (4) The motor can output rated electromagnetic torque using five optimization methods. In practical application, the combination of various optimization methods can be considered.

Key words： Dual-parallel rotor permanent magnet direct-driven motor electromagnetic force optimization method

收稿日期: 2023-04-06 出版日期: 2024-06-07

PACS:

TM351

基金资助:国家自然科学基金资助项目（51777048）

通讯作者: 陶大军男,1982年生,教授,博士生导师,研究方向为大电机和特种电机的基础理论、设计与分析。E-mail: tao.dj@163.com

作者简介: 陈阳男,1995年生,博士研究生,研究方向为永磁及特种电机的设计与分析。E-mail: chenyang2022@foxmail.com

引用本文:

陶大军, 陈阳, 李峥, 戈宝军. 双并列转子永磁直驱电机转子不平衡力分析与优化[J]. 电工技术学报, 2024, 39(10): 2961-2973. Tao Dajun, Chen Yang, Li Zheng, Ge Baojun. Analysis and Optimization of Unbalanced Electromagnetic Force on the Rotor of Dual-Parallel Rotor Permanent Magnet Direct-Driven Motor. Transactions of China Electrotechnical Society, 2024, 39(10): 2961-2973.

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