Adaptive Reference Power Based Voltage Droop Control for VSC-MTDC Systems

Wang Yizhen; Qiu Fengliang; Liu Guowei; Lei Ming; Yang Chao; Wang Chengshan

DOI:10.35833/MPCE.2021.000307


Adaptive Reference Power Based Voltage Droop Control for VSC-MTDC Systems



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Author: Yizhen Wang¹, Fengliang Qiu¹, Guowei Liu², Ming Lei¹, Chao Yang³, Chengshan Wang¹
Author Affiliation: 1.Key Laboratory of Smart Grid of Ministry of Education, Key Laboratory of Smart Energy & Information Technology of Tianjin Municipality, Tianjin 300072, China 2.Shenzhen Power Supply Bureau Co., Ltd., Shenzhen 518001, China 3.Sichuan Energy Internet Research Institution, Tsinghua University, Chengdu 610213, China
Foundation:	This work was supported by the Key Science and Technology Projects of China Southern Power Grid Corporation (No. 090000KK52180116) and National Natural Science Foundation of China (No. 51807135).

Abstract:	Featuring low communication requirements and high reliability, the voltage droop control method is widely adopted in the voltage source converter based multi-terminal direct current (VSC-MTDC) system for autonomous DC voltage regulation and power-sharing. However, the traditional voltage droop control method with fixed droop gain is criticized for over-limit DC voltage deviation in case of large power disturbances, which can threaten stable operation of the entire VSC-MTDC system. To tackle this problem, this paper proposes an adaptive reference power based voltage droop control method, which changes the reference power to compensate the power deviation for droop-controlled voltage source converters (VSCs). Besides retaining the merits of the traditional voltage droop control method, both DC voltage deviation reduction and power distribution improvement can be achieved by utilizing local information and a specific control factor in the proposed method. Basic principles and key features of the proposed method are described. Detailed analyses on the effects of the control factor on DC voltage deviation and imbalanced power-sharing are discussed, and the selection principle of the control factor is proposed. Finally, the effectiveness of the proposed method is validated by the simulations on a five-terminal VSC based high-voltage direct current (VSC-HVDC) system.
Keywords:	DC voltage deviation ; power-sharing ; reference power ; voltage droop control ; voltage source converter (VSC) ; multi-terminal direct current (MTDC).

Received:May 19, 2021 Online Time:2023/01/28



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