A discharge control strategy of high-speed flywheel energy storage system

被引:1
作者
机构
[1] College of Electrical Engineering, Zhejiang University, Hangzhou
来源
| 1600年 / Acta Press, Building B6, Suite 101, 2509 Dieppe Avenue S.W., Calgary, AB, T3E 7J9, Canada卷 / 34期
关键词
Decoupling algorithm; Discharge control strategy; Flywheel energy storage system; Load current compensation; Power balance;
D O I
10.2316/Journal.203.2014.2.203-0040
中图分类号
学科分类号
摘要
This paper is focused on the discharge control strategy of high-speed flywheel energy storage system (FESS). Field oriented synchronous frame equivalent model of the high-speed FESS in both charge and discharge mode is derived, and conventional discharge control strategy with double closed-loop PI controller is analysed. Then a modified strategy based on the power balance between the converter AC and DC side is put forward, which utilizes the load current to compensate the output value of outer voltage loop regulator and recalculate the reference value of inner current loop regulator with DC bus voltage, motor speed and flux considered. A decoupling algorithm is also added to the inner current loop for eliminating the influence of cross-coupled voltage at high speed. The strategy can effectively improve the current tracking ability, accelerate the dynamic response of DC bus voltage recovery and eliminate DC bus voltage fluctuation in the sudden change of load current. Simulation results with MATLAB verify the effectiveness and improvement of the proposed method.
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页码:51 / 62
页数:11
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