Finite Element Design and Multi-objective Optimization of Four Pole Reluctance Motor Based on NSGA-II Intelligent Algorithm

E. C. Abunike, O. Okoro, I. Davidson
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引用次数: 3

Abstract

The design of a four-pole reluctance motor with multiple objectives is discussed in this paper using a finite element design methodology based on multi-objective genetic algorithm. Non-dominated genetic algorithm (NSGA-II) is used because of its high performance and intensification in optimization problems. The global sensitivity chart revealed that the motor’s stator pole embrace and yoke thickness are key parameters for the optimization objectives, while the rotor’s pole embrace should be restrained and closely associated with these two key parameters. According to the optimization and sensitivity analysis results, a final design which is superior to the base design was achieved. There were 15 % and 13.2 % improvement in the optimized model in terms of the average torque and efficiency respectively. Also, the optimized model recorded a reduction in the average torque ripple and total loss by 1.55 % and 30.1 % respectively. This demonstrates the NSGA-II intelligent optimization program is a suitable framework to optimize specified objective functions.
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基于NSGA-II智能算法的四极磁阻电机有限元设计与多目标优化
本文采用基于多目标遗传算法的有限元设计方法,讨论了多目标四极磁阻电机的设计问题。非支配遗传算法(NSGA-II)因其在优化问题中的高性能和集约化而被广泛应用。全局灵敏度图显示,电机定子极拥抱和轭架厚度是优化目标的关键参数,而转子极拥抱应受到约束并与这两个关键参数密切相关。根据优化和灵敏度分析结果,得出了优于基本设计的最终设计方案。优化后的模型在平均转矩和效率方面分别提高了15%和13.2%。此外,优化模型记录的平均转矩脉动和总损失分别减少了1.55%和30.1%。这表明NSGA-II智能优化程序是优化指定目标函数的合适框架。
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