Fresh particle crowd optimisation of efficiency-oriented control in interior permanent magnet synchronous motor during operation

Hakchol Jong, Songchol Hyon, Chonung Kim, Sunghyok Kim
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引用次数: 0

Abstract

High-efficiency electric drive systems claim not only optimally designed electric machines but also efficiency-oriented control strategies. Taking machines and drives into synergetic consideration, this paper proposes a fresh particle crowd optimisation (FPCO) of efficiency-oriented control algorithm named maximum outer torque per ampere (MOPA) control and maximum efficiency per ampere (MEPA) control, aiming to maximise the efficiency of interior permanent magnet synchronous machines during operation. Difference from conventional id = 0 or maximum torque per ampere control, MOPA and MEPA fully consider the cross effect core loss, iron loss, supplementary loss and mechanical loss, from which the full-order loss model of interior permanent magnet synchronous motor (IPMSM) is built. In order to identify the accuracy of the efficiency-oriented control algorithm, the efficiency-oriented controlled system on based FPCO using non-singular terminal sliding (NTS) controller is built, on the base of this, the stabilisation of the current trajectory and the voltage vector from simulation and testing are inspected. After that, the higher effectiveness of MOPA and MEPA is proved through the operation experiment of IPMSM of which capacity is 82 kW.
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内嵌式永磁同步电机运行过程中面向效率控制的新鲜粒子群优化
高效电驱动系统不仅要求电机的优化设计,而且要求以效率为导向的控制策略。考虑到机器和驱动器的协同作用,本文提出了一种以效率为导向的新粒子群优化(FPCO)控制算法,即最大外转矩每安培(MOPA)控制和最大效率每安培(MEPA)控制,旨在使内部永磁同步电机在运行过程中效率最大化。与传统的id = 0或最大转矩/安培控制不同,MOPA和MEPA充分考虑了铁心损耗、铁损耗、补充损耗和机械损耗的交叉效应,并以此为基础建立了内啮合永磁同步电动机(IPMSM)的全阶损耗模型。为了验证效率导向控制算法的准确性,采用非奇异终端滑动(NTS)控制器构建了基于FPCO的效率导向控制系统,并在此基础上对仿真和测试的电流轨迹和电压矢量的稳定性进行了检验。随后,通过容量为82 kW的IPMSM运行试验,验证了MOPA和MEPA具有较高的有效性。
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来源期刊
International Journal of Power and Energy Conversion
International Journal of Power and Energy Conversion Energy-Energy Engineering and Power Technology
CiteScore
1.60
自引率
0.00%
发文量
8
期刊介绍: IJPEC highlights the latest trends in research in the field of power generation, transmission and distribution. Currently there exist significant challenges in the power sector, particularly in deregulated/restructured power markets. A key challenge to the operation, control and protection of the power system is the proliferation of power electronic devices within power systems. The main thrust of IJPEC is to disseminate the latest research trends in the power sector as well as in energy conversion technologies. Topics covered include: -Power system modelling and analysis -Computing and economics -FACTS and HVDC -Challenges in restructured energy systems -Power system control, operation, communications, SCADA -Power system relaying/protection -Energy management systems/distribution automation -Applications of power electronics to power systems -Power quality -Distributed generation and renewable energy sources -Electrical machines and drives -Utilisation of electrical energy -Modelling and control of machines -Fault diagnosis in machines and drives -Special machines
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