轴向磁通无铁芯永磁电机多层矩形扁线绕组涡流损耗解析计算及优化

doi:10.19595/j.cnki.1000-6753.tces.220911

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摘要轴向磁通无铁芯永磁电机的定子为无铁芯结构,采用扁线绕制的定子绕组盘具有槽满率高、平整度好、加工简单等特点。但是相对于圆形导线,矩形扁线具有截面积较大、涡流损耗大的缺点,导致电机损耗偏高,效率偏低。本文根据轴向无铁芯电机磁场的三维分布特性,针对矩形扁线涡流损耗分布不均匀的特点,推导了定子无铁芯扁线绕组特有的涡流损耗快速计算方法。在此基础上,基于涡流损耗的产生机理并以绕组铜耗最小为优化目标,建立了扁线绕组最优参数的求解公式。采用三维有限元软件仿真及样机测试的方法,验证了涡流损耗解析计算方法的有效性和准确性。结果表明,本文提出的涡流损耗计算公式以及导线参数优化方法可以实现扁线绕组的低损耗及电机的高效率,所得结论可为轴向无铁芯电机定子绕组的设计及优化提供理论依据。

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关键词 ：无铁芯电机, 扁线绕组, 涡流损耗, 绕组优化

Abstract：Coreless axial flux permanent magnet synchronous machine (CAFPMSM) is increasingly being used in various industrial applications due to the advantages such as compact structure, low maintenance cost, high power density, high torque ratio and power efficiency. Preformed flat wire has a relatively regular shape, which is adopted in CAFPMSM winding manufacturing because it can make full use of stator space and increase the power density of the machine. Although flat wire has many advantages, it also has some problems. Since the coreless winding is directly exposed to the air gap flux field, the large across section of the flat wire will resulting in significantly eddy current losses. This phenomenon becomes more serious when the speed goes higher. In order to reduce the eddy current losses, it is important to accurately calculate the eddy current losses of the winding. Some useful methods have been presented to calculate the eddy current loss of the traditional round winding. But both of them are not applicable to CAFPMSM with flat wire. This paper derives the formula specific to flat wire for the uneven distribution of eddy current losses generated by the air gap flux field. According to the theoretical analysis of eddy current loss and taking the minimum copper loss as the optimization objective, the solution of the optimal parameters of flat wire is established. The calculation formula and parameter optimization method can reduce the eddy current loss and improve the efficiency.
Firstly, the distribution characteristics of both the flux field in the axial direction and circumferential direction has been analyzed. Secondly, the amplitude of leakage flux density between the two adjacent permanent magnets is approximately linear with the position in the axial direction. The amplitude of the leakage flux density in different positions can be expressed in terms of the distance in the axial direction. The eddy current loss produced by the leakage flux can be calculated. Thirdly, the amplitude of the main flux density waveform can be expressed by the average value, which can simplify the calculation of the eddy current loss produced by the main flux. Finally, the theoretical analysis method has been proposed and the eddy current loss of the winding can be obtained by the sum of the eddy current loss produced by the main flux and leakage flux. According to the proposed theoretical analysis, the length and width of the cross-section of flat wire are optimized with the constraint of the current density. And the mothed for selecting the length and width of the cross-section are proposed to obtain the lowest eddy current loss of the winding. Establishing equivalent model of the winding by finite element method, the simulation results of the eddy current loss validate the correctness of the theoretical analysis. According to the established model, the prototype is manufactured and the experiment has been done. The measured result of the eddy current loss proves the accuracy of theoretical analysis and the error is 6%.
The following conclusions can be drawn from the analysis: 1) Both axial and circumferential components of air gap flux field will produce eddy current loss in the rectangular conductor. The eddy current loss caused by the leakage flux field cannot be ignored. 2) The eddy current loss of the machine is related to the ratio of the length and width of the flat wire section as well as the density of the air gap flux field. By changing the ratio of section length to width, the eddy current loss of the winding can be minimized with the same direct current loss. 3) The measured results of the prototype at different speeds are basically consistent with the theoretical analysis and finite element analysis results, which verifies the correctness of the analytical calculation and finite element results. The conclusion provides a reference for the design of the machine windings with different structures.

Key words： Coreless axial flux permanent magnet synchronous machine Flat wire Calculation of eddy current loss Optimization of winding

PACS:

TM351

基金资助:湖北省教育厅科学技术研究计划重点项目（D20201407）资助项目

通讯作者: 王晓光男,1984年生,副教授,研究方向为永磁电机及其控制。E-mail：xgwang84@foxmail.com

作者简介: 尹浩男,1997年生,硕士研究生,研究方向为永磁电机及其控制。E-mail：haoyinhbut@163.com

引用本文:

王晓光, 尹浩, 余仁伟. 轴向磁通无铁芯永磁电机多层矩形扁线绕组涡流损耗解析计算及优化[J]. 电工技术学报, 0, (): 23-23. Wang Xiaoguang, Yin Hao, Yu Renwei. Analytical Calculation and Parameter Optimization of Eddy Current Loss for Coreless Axial Flux Permanent Magnet Synchronous Machine with Multilayer Flat Wire Winding. Transactions of China Electrotechnical Society, 0, (): 23-23.

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