Magnetic optimization of a fault-tolerant linear permanent magnet modular actuator for shipboard applications

2013 9th IEEE International Symposium on Diagnostics for Electric Machines, Power Electronics and Drives (SDEMPED) Pub Date : 2013-10-24 DOI:10.1109/DEMPED.2013.6645758

M. Bortolozzi, C. Bruzzese, F. Ferro, T. Mazzuca, M. Mezzarobba, G. Scala, A. Tessarolo, D. Zito

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引用次数: 17

Abstract

The reliability is a key requirement in electric actuators to be used for moving ship control surfaces. This paper addresses a fault-tolerant design for an innovative naval actuator based on an inverter-fed permanent magnet linear synchronous motor. Due to the highly non-conventional actuator concept, a detailed FEM modeling approach is presented in this paper for comparison of different design solutions. A fault tolerant modular stator structure is proposed. The modular winding can be designed based on an integer-slots or fractional-slots concept. The two solutions are compared in this paper, considering encumbrance and thrusting force performances. The linear motion can be reverted to rotary motion through a prismatic-rotoidal joint for coupling to on board ship steering gears used to drive control surfaces (rudders, stabilizing fins). A drive prototype has been built and is presently under testing to assess and refine the results of the FEM modeling presented in the paper.

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船用容错线性永磁模块执行器的磁力优化

对于用于移动船舶控制面的电动执行器，可靠性是一个关键的要求。本文研究了一种基于变频永磁直线同步电机的新型舰船执行器的容错设计。由于执行器概念的高度非常规，本文提出了一种详细的有限元建模方法，以比较不同的设计方案。提出了一种容错模块定子结构。模块化绕组可以基于整数槽或分数槽的概念进行设计。考虑阻力和推力性能，对两种方案进行了比较。直线运动可以恢复到旋转运动通过一个棱镜-旋转关节耦合到船上的船舶舵机用于驱动控制面(舵，稳定鳍)。已经建立了一个驱动器原型，目前正在测试中，以评估和完善本文中提出的有限元模型的结果。

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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2013 9th IEEE International Symposium on Diagnostics for Electric Machines, Power Electronics and Drives (SDEMPED)

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