《电力自动化设备》

引用本文:	陆瑶,王杰,王子强,李鹏瀚,姚钢,刘辉.基于固定时间一致性算法的孤岛微电网分布式容错二次控制策略[J].电力自动化设备,2022,42(11):
	LU Yao,WANG Jie,WANG Ziqiang,LI Penghan,YAO Gang,LIU Hui.Distributed fault-tolerant secondary control strategy for islanded microgrid based on fixed-time consensus algorithm[J].Electric Power Automation Equipment,2022,42(11):

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基于固定时间一致性算法的孤岛微电网分布式容错二次控制策略
陆瑶¹, 王杰¹, 王子强¹, 李鹏瀚², 姚钢¹, 刘辉³
1.上海交通大学电力传输与功率变换控制教育部重点实验室，上海 200240;2.国家电网有限公司西北分部，陕西西安 710049;3.上海动力储能电池系统工程技术有限公司，上海 200241

摘要:

随着微电网信息侧和物理侧的耦合日益紧密，软件密集型控制器和电力电子设备的大规模应用增加了微电网遭受攻击和故障的可能性，从而影响微电网的稳定运行。为此，针对孤岛交流微电网控制通道中潜在的执行器故障和传感器故障，提出了一种基于固定时间一致性算法的分布式容错二次控制策略。首先，建立了同时计及执行器故障和传感器故障的下垂控制模型。其次，分别设计了上层分布式一致性控制算法和下层本地容错控制算法，分析了控制器对未知故障的抑制机理，从理论上证明了所提分布式容错二次控制策略的固定时间收敛特性，并进一步观测了传感器故障信号的波形。最后，算例仿真结果验证了所提控制策略的有效性。

关键词: 孤岛微电网分布式容错控制执行器故障传感器故障固定时间一致性

DOI：10.16081/j.epae.202205016

分类号:TM761

基金项目:国家自然科学基金资助项目(52077135)

Distributed fault-tolerant secondary control strategy for islanded microgrid based on fixed-time consensus algorithm

LU Yao¹, WANG Jie¹, WANG Ziqiang¹, LI Penghan², YAO Gang¹, LIU Hui³

1.Key Laboratory of Control of Power Transmission and Conversion, Shanghai Jiao Tong University, Ministry of Education, Shanghai 200240, China;2.Northwest Branch of State Grid Corporation of China, Xi’an 710049, China;3.Shanghai Power & Energy Storage Battery System Engineering Tech Co.,Ltd.,Shanghai 200241, China

Abstract:

With the increasingly close coupling between the cyber layer and the physical layer of microgrid, the large-scale application of software-intensive controllers and power electronic devices increases the possibility of attacks and faults of the microgrid, thereby affecting the stable operation of the microgrid. For the potential actuator faults and sensor faults in the control channel of the islanded AC microgrid, a distributed fault-tolerant secondary control strategy based on fixed-time consensus algorithm is proposed. Firstly, a droop control model considering both actuator faults and sensor faults is established. Secondly, distributed consensus control algorithms and fault-tolerant control algorithms are designed in the upper layer and lower layer respectively. The mitigating mechanism of the controllers for the unknown faults is analyzed, and the fixed-time convergence characteristics of the proposed strategy are theoretically proved. Furthermore, the signal of sensor faults is estimated. Finally, the simulation example verifies the effectiveness of the proposed control strategy.

Key words: islanded microgrid distributed fault-tolerant control actuator faults sensor faults fixed-time consensus

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