Impacts of Laminating Core Materials on Permanent Magnet Synchronous Motor by Newton–Raphson Methodc

IF 2.1 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE
Prabhu Sundaramoorthy;Arun Vijayakumar;Kuppapillai Rajkumar;Jamuna Ponnusamy;Gokul Chandrasekaran;Vijayakumar Madhaiyan
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引用次数: 0

Abstract

The permanent magnet synchronous motor (PMSM) has a more efficiency, high torque density, and high power density, but it suffers from torque ripple. This article describes the electromagnetic (EM) behavior of M19 29Ga material assists PMSM for 310 V, 5 A, and 1500 r/min. In addition, various materials as Losil 34050, Arnon 5, 50M290, M19 USS Transformer 72–29 gauge, and TR80 USS Transformer 80–29 gauge incorporated PMSM and which material has superiority, and with the superiority kept constant, changed the various magnet materials. The EEC 26-T350, MQP-14–12 835995, N45M, Recoma 22, Samarium Cobalt 20/30, Vacodym 890TP, and Vacomax 240 incorporated PMSM also investigated for EM finite-element analysis. The results of this study of the variable as torque ripple forecast the highest torque ( $T_{\mathrm {max}})$ , lowest power output ( $T_{\mathrm {min}})$ , and overall torque ( $T_{\mathrm {avg}})$ . The superior motor among various materials unified PMSM by its ripple and field characteristics. The outcomings of the modeled motor are validated with numerical equations.
用牛顿-拉斐逊法研究层压铁芯材料对永磁同步电机的影响c
永磁同步电机(PMSM)具有更高的效率、高转矩密度和高功率密度,但却存在转矩纹波问题。本文介绍了 M19 29Ga 材料辅助 PMSM 在 310 V、5 A 和 1500 r/min 下的电磁(EM)行为。此外,Losil 34050、Arnon 5、50M290、M19 USS Transformer 72-29 gauge 和 TR80 USS Transformer 80-29 gauge 等各种材料在 PMSM 中的应用以及哪种材料更具优势,在优势保持不变的情况下,改变了各种磁体材料。此外,还对 EEC 26-T350、MQP-14-12 835995、N45M、Recoma 22、钐钴 20/30、Vacodym 890TP 和 Vacomax 240 等 PMSM 进行了电磁有限元分析。这项研究的结果为扭矩纹波变量预测了最高扭矩($T_{\mathrm {max}} )$、最低功率输出($T_{\mathrm {min}} )$ 和总扭矩($T_{\mathrm {avg}})$ 。在各种材料的电机中,PMSM 电机的纹波和磁场特性更胜一筹。模型电机的结果与数值方程进行了验证。
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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CiteScore
3.70
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