Design Optimization and Performance Analysis of Rectangular Structured Moving Magnet Linear Actuator

2023 4th International Conference on Computing, Mathematics and Engineering Technologies (iCoMET) Pub Date : 2023-03-17 DOI:10.1109/iCoMET57998.2023.10099334

Muhammad Jawad, Yu Haitao, Zahoor Ahmad, Basharat Ullah, Baheej Alghamdi

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Abstract

This article examines a new linear oscillating actuator (LOA) design that uses rectangular-shaped core materials and permanent magnets (PMs). The paper's primary objective is to examine a novel LOA topology with a rectangular-shaped core and PMs as an alternative to the tubular LOA. A Static core material is housed between the mover's components, and two stator cores with two coils each are placed on either side of the mover. The dimensions of all the parameters are swept for optimization, and the optimal parameter dimension is chosen based on the optimal value of the electromagnetic (EM) force. An analysis is done for output parameters like EM force and stroke. EM force per PM mass of the investigated design of LOA is 67 percent higher than of conventional rectangular-shaped LOA. Additionally, the proposed design's EM force density is 23.8 percent higher than that of the conventional design of LOA. Furthermore, the stroke of the proposed LOA is also feasible and more than most of the designs of the LOA. Additionally, the proposed design of the LOA is simple structure, low-cost, and feasible for fabrication.

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矩形结构动磁直线作动器的设计优化与性能分析

本文研究了一种新的线性振荡致动器(LOA)设计，该设计使用矩形核心材料和永磁体(pm)。本文的主要目的是研究一种新的LOA拓扑结构，该拓扑结构采用矩形岩心和pm作为管状LOA的替代方案。静铁芯材料被安置在动器的组件之间，两个定子铁芯各有两个线圈，放置在动器的两侧。对各参数的尺寸进行扫描优化，并根据电磁力的最优值选择最优参数尺寸。对电磁力、行程等输出参数进行了分析。所研究的LOA设计的每PM质量的电磁力比传统矩形LOA高67%。此外，该设计的电磁力密度比传统LOA设计的电磁力密度高23.8%。此外，所提出的LOA行程也是可行的，并且超过了大多数LOA设计。此外，所提出的LOA设计结构简单，成本低，制造可行。

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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2023 4th International Conference on Computing, Mathematics and Engineering Technologies (iCoMET)

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