Electromagnetic-thermal Coupled Analyses and Joint Optimisation of Electrically-excited Flux-switching Linear Machines

Hui Wen;Yufei Wang;Yuting Zheng;Wen Zeng;Xiao Qu;Jiongjiong Cai
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Abstract

Electrically-excited flux-switching machines are advantageous in simple and reliable structure, good speed control performance, low cost, etc., so they have arouse wide concerns from new energy field. However, they have much lower torque density/thrust density compared with the same type PM machines. To overcome this challenge, electromagnetic-thermal coupled analysis is carried out with respect to water-cooled electrically-excited flux-switching linear machines (EEFSLM). The simulation results indicate that the conventional fixed copper loss method (FCLM) is no longer suitable for high thrust density design, since it is unable to consider the strong coupling between the electromagnetic and thermal performance. Hence, a multi-step electromagnetic-thermal joint optimisation method is proposed, which first ensures the consistency between the electromagnetic and thermal modelling and then considers the effect of different field/armature coil sizes. By using the proposed joint optimisation method, it is found that the combination of relatively large size of field coil and relatively low field copper loss is favourable for achieving high thrust force for the current EEFSLM design. Moreover, the thrust force is raised by 13-15% compared with using the FCLM. The electromagnetic and thermal performance of the EEFSLM is validated by the prototype test.
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电励磁磁通开关线性电机的电磁热耦合分析及联合优化
电励磁磁通开关机具有结构简单可靠、调速性能好、成本低等优点,引起了新能源领域的广泛关注。然而,与同类型的PM机器相比,它们具有低得多的扭矩密度/推力密度。为了克服这一挑战,对水冷电励磁磁通开关线性电机(EEFSLM)进行了电磁-热耦合分析。仿真结果表明,传统的固定铜耗法(FCLM)由于无法考虑电磁性能和热性能之间的强耦合,已不再适用于高推力密度设计。因此,提出了一种多步骤电磁-热联合优化方法,该方法首先确保电磁和热建模之间的一致性,然后考虑不同磁场/电枢线圈尺寸的影响。通过使用所提出的联合优化方法,发现相对较大尺寸的励磁线圈和相对较低的励磁铜损耗的组合有利于实现当前EEFSLM设计的高推力。此外,与使用FCLM相比,推力提高了13-15%。通过样机试验验证了EEFSLM的电磁和热性能。
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