Control strategy of wind turbine LVRT test equipment based on MMC

被引：0

作者：

Liu Z. ^{[1
,2
]}

Wang P. ^{[1
]}

Guo J. ^{[2
]}

Zhao W. ^{[1
]}

Zhu L. ^{[2
]}

Ou W. ^{[2
]}

Su L. ^{[1
]}

Wu X. ^{[2
]}

机构：

[1] Electric Power Research Institute of Guangdong Power Grid Co., Ltd., Guangzhou

[2] Guangdong Electric Power Research Institute Energy Technology Co., Ltd., Guangzhou

来源：

Dianli Xitong Baohu yu Kongzhi/Power System Protection and Control | 2021年 / 49卷 / 19期

关键词：

Low-voltage ride through; Modular multilevel converter; Test device; Voltage dip; Wind turbine;

D O I：

10.19783/j.cnki.pspc.201420

中图分类号：

学科分类号：

摘要：

The Low Voltage Ride Through (LVRT) test device of a wind turbine based on power electronics has the advantages of flexible control, high precision, diverse functions and low interference to the power grid. The key problem of the device's control strategy is how to emulate different kinds of grid-fault voltage waveform as defined in standards. To this end, three-phase and two-phase virtual fault circuits are constructed first. By using the symmetrical component method, the analytical expressions of grid-fault voltage and short circuit impedance ratio of power grid with voltage drop percentage as an input condition are derived in detail. Secondly, the grid fault voltage is taken as the reference value of the voltage drop instruction of the LVRT test device, and the required test voltage waveform can be output through closed-loop control. Considering the LVRT test device of a wind turbine based on modular multilevel converter topology, the control strategy of MMCs connected to the grid and wind turbine separately is provided finally. A simulation model of the LVRT test device for large capacity wind turbines is built, and the effectiveness of the method is verified by simulation of two typical working conditions. © 2021 Power System Protection and Control Press.

引用

页码：38 / 47

页数：9

共 25 条

[1] Global wind report 2019, (2020)
[2] ZHANG Changjiu, WU Xiaobo, XIE Xiaoying, Research on low voltage ride through of DG characteristics based on GB/T33593 standard, Power System Protection and Control, 47, 24, pp. 76-83, (2019)
[3] QIAN Feng, CHEN Yi, LIU Junlei, Et al., Coordinated control strategy for power systems with large-scale wind power integration, Guangdong Electric Power, 32, 11, pp. 12-18, (2019)
[4] LIN Zekun, PENG Xiangang, CHEN Shen, Probability model of wind turbines off-grid, Guangdong Electric Power, 28, 8, pp. 23-27, (2015)
[5] ZHOU Jichen, LU Yinjie, YANG Chengzhi, Et al., Distributionally robust co-optimization of energy and reserve dispatch considering uncertain wind power output, Power System Protection and Control, 48, 20, pp. 66-73, (2020)
[6] SUN Huadong, ZHANG Zhenyu, LIN Weifang, Et al., Analysis and enlightenment of 2011 Northwest Power Grid fan off-grid accident, Power System Technology, 36, 10, pp. 76-80, (2012)
[7] HE Jingbo, ZHUANG Wei, XU Tao, Et al., Risk analysis and countermeasures of chain off-grid of wind turbines caused by transient overvoltage, Power System Technology, 40, 6, pp. 1839-1844, (2016)
[8] LIU Lu, GENG Hua, MA Shaokang, Et al., DFIG type wind farm synchronous stability and reactive current control method during low voltage ride through, Proceedings of the CSEE, 37, 15, pp. 4399-4407, (2017)
[9] HU Wenping, ZHOU Wen, WANG Lei, Et al., Study on suppression strategy for wind turbine drive train torsional vibration under grid fault based on co-simulation, Power System Protection and Control, 44, 24, pp. 196-201, (2016)
[10] WEN Dong, JIA Rong, HAN Jie, Et al., Reactive power compensation calculation for large-scale centralized wind power grid integration, High Voltage Apparatus, 55, 4, pp. 193-197, (2019)

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