A steady-state voltage control method for a multi-terminal hybrid UHVDC transmission system

被引：0

作者：

Yu X. ^{[1
]}

Lu J. ^{[1
]}

Dong Y. ^{[1
]}

Zhang Q. ^{[1
]}

Gan Z. ^{[2
]}

Wang Y. ^{[1
]}

机构：

[1] NR Electric Co., Ltd., Nanjing

[2] EHV Power Transmission Company, China Southern Power Grid Co., Ltd., Guangzhou

来源：

Dianli Xitong Baohu yu Kongzhi/Power System Protection and Control | 2022年 / 50卷 / 01期

关键词：

Adaptive; Line drop; Master-slave control; Multi-terminal hybrid DC transmission system; Steady-state voltage control; UHVDC;

D O I：

10.19783/j.cnki.pspc.210206

中图分类号：

学科分类号：

摘要：

In multi-terminal hybrid UHVDC transmission system, one task of the DC voltage station is to maintain the DC voltage of the head-end rectifier station at its set value. Line drop must be taken into account if the head-end rectifier station is not the DC voltage station and in such a case the traditional voltage margin control method and droop control method fail to achieve static error free control of the power and voltage. Based on the idea of a master-slave control method, this paper proposes a steady-state voltage control method for a multi-terminal hybrid UHVDC transmission system. First, the voltage drop between the DC voltage station and the head rectifier station is calculated based on system topology, line resistance and current. Then the control reference of the DC voltage station is modified to achieve precise voltage control of the head-end rectifier station. In addition, an adaptive method is proposed for the case where the line resistance is changing or totally unknown. Finally, a simulation model of three-terminal DC system using the real time digital simulator (RTDS) is built and simulation results demonstrate the correctness and validity of the proposed method. © 2022 Power System Protection and Control Press.

引用

页码：174 / 180

页数：6

共 23 条

[1] CAO Runbin, LI Yan, XU Shukai, Et al., Research on configuration and coordination of multi-terminal hybrid UHVDC line protection, Southern Power System Technology, 12, 11, pp. 52-58, (2018)
[2] PENG Zhong, SUN Panlei, HAN Wei, Et al., Control strategy of a hybrid UHVDC transmission system cascaded by LCC and VSC, Power System Protection and Control, 49, 19, pp. 162-172, (2021)
[3] LI Bin, HE Jiawei, LI Ye, Et al., A review of the protection for the multiterminal VSC-HVDC grid, Protection and Control of Modern Power Systems, 4, 3, pp. 239-249, (2019)
[4] ZHENG Anran, GUO Chunyi, CUI Peng, Et al., Voltage balancing control strategy of series-connected converter valve groups in hybrid multi-terminal UHVDC transmission system, Power System Technology, 43, 9, pp. 3408-3414, (2019)
[5] LIU Qiang, DU Zhongming, TONG Mingdong, Et al., Utilization and prospect analysis of UHV multi-terminal DC technologies, Southern Power System Technology, 12, 11, pp. 9-14, (2018)
[6] CHEN Lei, HE Huiwen, WANG Lei, Et al., Fault isolation method of a hybrid HVDC system based on the coordination of a fault current limiter and a DC circuit breaker, Power System Protection and Control, 48, 19, pp. 119-127, (2020)
[7] ZHANG Dahai, YANG Yuchen, LIU Yanmei, Et al., Hybrid HVDC line pilot protection method based on EMD and Spearman correlation coefficient, Power System Protection and Control, 49, 9, pp. 1-11, (2021)
[8] WANG Yongping, ZHAO Wenqiang, YANG Jianming, Et al., Hybrid high-voltage direct current transmission technology and its development analysis, Automation of Electric Power Systems, 41, 7, pp. 156-167, (2017)
[9] ZHANG Ming, MA Zhoujun, WANG Yong, Et al., Power flow calculation of AC/DC hybrid distribution network based on equivalent π-model of converter, Journal of Electric Power Science and Technology, 35, 2, pp. 30-37, (2020)
[10] ZHANG Ruidong, DENG Wei, ZHANG Xue, Et al., Control strategy for distribution networks with multi-terminal AC/DC hybrid power under an uninterruptible power supply, Journal of Electric Power Science and Technology, 34, 2, pp. 33-39, (2019)

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