Split-Winding Switched Reluctance Machine to Minimize Torque Ripple

2022 IEEE International Conference on Power Electronics, Drives and Energy Systems (PEDES) Pub Date : 2022-12-14 DOI:10.1109/PEDES56012.2022.10080363

N. Sundar S., Prathap B. Reddy, Subhabrata Basak, L. Umanand, K. Gopakumar

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Abstract

Switched reluctance machines (SRM) are recommended for electric vehicle applications due to their merit points over other rotating electrical machines like robust structure, high efficiency at a lower speed, higher fault tolerance capability, and permanent magnet-less feature. However, in conventional SRM, the torque ripple is high, which causes vibration issues. The torque ripple will be further amplified in proportion to the power rating of the machine. In this paper, a split-winding switched reluctance machine (SW -SRM) is presented with a split-winding concept. The actual phase winding of one phase is distributed over the two adjacent poles of SRM. The split winding helps to maintain the torque in an aligned as well as unaligned position of the rotor and stator poles and reduce the torque ripple produced by the SRM with a proper excitation scheme. To validate the proposed split winding concept, a 50kW SW-SRM has been modeled and simulated with the help of FEA (Finite Element Analysis) tools. From these studies, the magnetic characteristics like flux density, inductance, and torque for various rotor positions and stator currents are captured and used as a lookup table. These look-up tables are utilized for modeling the SW-SRM in MATLAB. A comparison study on torque ripple produced by 50kW SRM and SW-SRM is performed based on the MATLAB simulation results.

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分绕组开关磁阻电机，以减少转矩波动

开关磁阻电机(SRM)被推荐用于电动汽车应用，因为它们比其他旋转电机具有坚固的结构，低速下的高效率，更高的容错能力和无永磁特性等优点。然而，在传统的SRM中，转矩脉动很大，导致振动问题。转矩波动将进一步放大成比例的额定功率的机器。本文提出了一种采用分绕组概念的分绕组开关磁阻电机(SW -SRM)。一个相的实际相绕组分布在SRM的相邻两极上。分体绕组有助于保持转矩在转子和定子极点的对齐和非对齐位置，并通过适当的激励方案减少SRM产生的转矩脉动。为了验证所提出的分绕组概念，在有限元分析工具的帮助下，对50kW SW-SRM进行了建模和仿真。从这些研究中，捕获了不同转子位置和定子电流的磁特性，如磁通密度，电感和转矩，并将其用作查找表。利用这些查询表在MATLAB中对SW-SRM进行建模。基于MATLAB仿真结果，对50kW SRM和SW-SRM产生的转矩脉动进行了对比研究。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE International Conference on Power Electronics, Drives and Energy Systems (PEDES)

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