Optimal Designs of Wound Field Switched Flux Machines with Different DC Windings Configurations

Wenting Wang;Yuankui Wang;Enlin Ma;Lijian Wu
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Abstract

Wound field switched flux (WFSF) machines exhibits characteristics of the simple robust rotor, flexible flux-adjustable capability, and no risk of demagnetization. However, they suffer from a poor torque density compared with permanent magnet machines due to the saturation. Therefore, in this paper, two WFSF machines with single- and double-layer DC windings, respectively, are optimized for the maximum torque. The end-winding (EW) lengths differ in these two machines, which can affect the optimal design. Design parameters including the DC to armature winding copper loss ratio, slot area ratio and split ratio are optimized when two machines have the same copper loss and overall sizes. In addition, the influence of the flux density ratio, total copper loss, air-gap length and aspect ratio on the optimal split ratio is investigated using the finite element method and results are explained through the analytical model accounting for the saturation. It is discovered that the EWs have no effect on the optimal copper loss ratio, which is unity. In terms of the slot area ratio, the machine with single-layer DC windings prefers smaller DC slot areas than armature slot areas. In the WFSF machine with longer EWs, the optimal split ratio becomes smaller. Moreover, compared with other parameters, the flux density ratio can significantly affect the optimal split ratio.
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不同直流绕组配置的绕线式场开关磁通机的优化设计
绕线式磁场开关磁通(WFSF)电机具有转子简单坚固、磁通调节灵活、无退磁风险等特点。然而,与永磁电机相比,由于饱和,它们的转矩密度较差。因此,本文对两台分别带有单层和双层直流绕组的WFSF电机进行了最大转矩优化。这两种机器的端部绕组(EW)长度不同,这可能会影响优化设计。当两台机器具有相同的铜损耗和整体尺寸时,优化了直流与电枢绕组的铜损耗比、槽面积比和分流比等设计参数。此外,利用有限元方法研究了磁通密度比、总铜损耗、气隙长度和纵横比对最佳分流比的影响,并通过考虑饱和的分析模型解释了结果。研究发现,EW对铜的最佳损耗率没有影响,铜的最佳损失率是统一的。就槽面积比而言,具有单层直流绕组的机器比电枢槽面积更喜欢更小的直流槽面积。在EW较长的WFSF机器中,最佳分割比变小。此外,与其他参数相比,通量密度比可以显著影响最优分流比。
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