基于平行四边形推进线圈的超导直线同步电机推力波动抑制研究

doi:10.19595/j.cnki.1000-6753.tces.241791

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摘要在超导电动悬浮工况中, 超导直线同步电机的推力波动是保障列车运行平稳性与服役安全性的关键。该文提出了一种采用单层平行四边形推进线圈结构的超导直线同步电机, 并通过电磁模型构建与多目标优化设计实现了推力波动的精准计算与有效抑制。首先, 通过线圈中心线离散与空间坐标变换, 实现了线圈几何特征与悬浮架空间姿态的精准表征。其次, 采用离散诺依曼公式对推进线圈与超导磁体间的互感进行计算, 并通过虚功法得到了直线电机的瞬态电磁力。然后, 构建了超导直线同步电机有限元模型并搭建了实验测试平台。结果表明, 所提模型与有限元模型、测试结果相对误差分别小于2%和3%, 验证了电磁模型的可靠性。最后, 基于第三代非支配排序遗传算法（NSGA-Ⅲ）对超导直线同步电机进行了多目标优化设计, 探明了单层平行四边形推进线圈结构对于推力波动的抑制效果, 所得结论能够为超导直线电机的设计与优化提供重要理论参考。

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关键词 ：超导电动悬浮, 超导直线电机, 平行四边形线圈, 多目标优化设计

Abstract：As one of the most promising magnetic suspension technologies, superconducting electro- dynamic suspension relies on the electromagnetic interaction between the superconducting magnets and track coils to achieve the suspension, guidance, and drive of the vehicle. Therefore, the propulsion coil is a core component of the linear drive actuator for the superconducting electrodynamic suspension train, which is arranged discontinuously along the train's direction of travel. Harmonic components are challenging to avoid in the track traveling wave magnetic field, which further affects the operating stability of superconducting magnets and the safety of the train service. Although the existing double-layer structure of the propulsion coil can effectively suppress the harmonic components and thrust fluctuation of the system, it dramatically increases the manufacturing cost of the coil. This paper proposes a superconducting linear synchronous motor with a single-layer parallelogram structure of propulsion coils. The topological structure can achieve a balance between suppressing thrust fluctuations and reducing costs after an optimized design.
Firstly, the electromagnetic model of a superconducting linear synchronous motor is derived. The coil centerline discretization method is employed to accurately characterize the complex geometrical characteristics and spatial layout of propulsion coils and superconducting magnets, ensuring accuracy and efficiency. Secondly, the finite element model and experimental test platform are established. The results show that the relative errors of the proposed model are less than 2% and 3%, respectively, compared with the finite element model and test data. Finally, by coupling the electromagnetic model with a multi-objective optimization algorithm, a set of Pareto fronts is obtained. The thrust fluctuation is effectively suppressed using the non-dominated sorting genetic algorithm-III, while ensuring the output performance of the superconducting linear synchronous motor and the cost of propulsion coils. Based on optimized schemes, the influence of parallelogram structure dimensions on the electromagnetic performance of a superconducting linear synchronous motor is investigated.
The following conclusions can be drawn. (1) The thrust transient characteristics obtained by the proposed electromagnetic model are in good agreement with the finite element results and test data, which proves the reliability of the proposed model. (2) Compared with the finite element model, the calculation efficiency of the proposed model is improved by two orders of magnitude. (3) The parallelogram structure of the propulsion coil can effectively suppress the thrust fluctuation of the superconducting linear synchronous motor. In the optimized solution set, the inclination angle of the parallelogram ranges from approximately 10° to 50°, and the inhibition of thrust fluctuation increases significantly with the angle. (4) The single-layer parallelogram structure of the propulsion coils can reduce the amount of coil material and difficulty of installation while ensuring the thrust fluctuation suppression, which provides a scheme for the test line construction of low cost and easy maintenance.

Key words： Superconducting electrodynamic suspension superconducting linear motor parallelogram coil multi-objective optimization design

收稿日期: 2024-10-14

PACS:

TM37

基金资助:国家自然科学基金（52425702）和四川省自然科学基金创新研究群体（2023NSFSC1976）资助项目。

通讯作者: 马光同男, 1982 年生, 博士, 研究方向为超导磁体及低温系统、磁悬浮列车及其系统动力学。E-mail: gtma@swjtu.edu.cn

作者简介: 苏振华男, 1994 年生, 博士, 研究方向为磁悬浮与直线驱动技术。E-mail: ja5ue@my.swjtu.edu.cn

引用本文:

苏振华, 罗俊, 刘康, 崔李滨, 马光同. 基于平行四边形推进线圈的超导直线同步电机推力波动抑制研究[J]. 电工技术学报, 2025, 40(20): 6524-6536. Su Zhenhua, Luo Jun, Liu Kang, Cui Libin, Ma Guangtong. Thrust Fluctuation Suppression of Superconducting Linear Synchronous Motor Based on Parallelogram Propulsion Coil. Transactions of China Electrotechnical Society, 2025, 40(20): 6524-6536.

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