Adaptive VSG control of flywheel energy storage array for frequency support in microgridsOACSTPCDEI
The application of virtual synchronous generator(VSG)control in flywheel energy storage systems(FESS)is an effective solution for addressing the challenges related to reduced inertia and inadequate power supply in microgrids.Considering the significant variations among individual units within a flywheel array and the poor frequency regulation performance under conventional control approaches,this paper proposes an adaptive VSG control strategy for a flywheel energy storage array(FESA).First,by leveraging the FESA model,a variable acceleration factor is integrated into the speed-balance control strategy to effectively achieve better state of charge(SOC)equalization across units.Furthermore,energy control with a dead zone is introduced to prevent SOC of the FESA from exceeding the limit.The dead zone parameter is designed based on the SOC warning intervals of the flywheel array to mitigate its impact on regular operation.In addition,VSG technology is applied for the grid-connected control of the FESA,and the damping characteristic of the VSG is decoupled from the primary frequency regulation through power differential feedback.This ensures optimal dynamic performance while reducing the need for frequent involvement in frequency regulation.Subsequently,a parameter design method is developed through a small-signal stability analysis.Consequently,considering the SOC of the FESA,an adaptive control strategy for the inertia damping and the P/ωdroop coefficient of the VSG control is proposed to optimize the grid support services of the FESA.Finally,the effectiveness of the proposed control methods is demonstrated through electromagnetic transient simulations using MATLAB/Simulink.
Penghui Ren;Jingwen Zheng;Liang Qin;Ruyin Sun;Shiqi Yang;Jiangjun Ruan;Kaipei Liu;Tinghui Ouyang
Hubei Key Laboratory of Power Equipment&System Security for Integrated Energy,Wuhan 430072,P.R.China School of Electrical Engineering and Automation,Wuhan University,Wuhan 430072,P.R.ChinaElectric Power Research Institute,State Grid Hubei Electric Power Co.,Ltd.,Wuhan 430077,P.R.ChinaHubei Key Laboratory of Power Equipment&System Security for Integrated Energy,Wuhan 430072,P.R.China School of Electrical Engineering and Automation,Wuhan University,Wuhan 430072,P.R.ChinaHubei Key Laboratory of Power Equipment&System Security for Integrated Energy,Wuhan 430072,P.R.China School of Electrical Engineering and Automation,Wuhan University,Wuhan 430072,P.R.ChinaHubei Key Laboratory of Power Equipment&System Security for Integrated Energy,Wuhan 430072,P.R.China School of Electrical Engineering and Automation,Wuhan University,Wuhan 430072,P.R.ChinaHubei Key Laboratory of Power Equipment&System Security for Integrated Energy,Wuhan 430072,P.R.China School of Electrical Engineering and Automation,Wuhan University,Wuhan 430072,P.R.ChinaHubei Key Laboratory of Power Equipment&System Security for Integrated Energy,Wuhan 430072,P.R.China School of Electrical Engineering and Automation,Wuhan University,Wuhan 430072,P.R.ChinaCenter for Computational Sciences,University of Tsukuba(UT),Ibaraki 305-8577,Japan
动力与电气工程
Flywheel array controlVirtual Synchronous GeneratorMicrogridFrequency regulationAdaptive control
《Global Energy Interconnection》 2024 (5)
P.563-576,14
National Natural Science Foundation of China(51977160)“Voltage Self balancing Control Method for Modular Multilevel Converter Based on Switching State Matrix”.
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