Study on Suppression of Transient Overvoltage at DC Sending End by MGP

2022 IEEE International Conference on Power Systems and Electrical Technology (PSET) Pub Date : 2022-10-13 DOI:10.1109/PSET56192.2022.10100332

Hongyuan Deng, Xinyue Zhang, Yue Wang, Yongzhang Huang

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Abstract

With the increasing penetration of renewable energy power sending through HVDC, the transient overvoltage problem is threatening the sending end. Motor-Generator Pair is capable of leading phase operation, which can effectively restrain overvoltage. In this paper, based on the grid-connected structure of the MGP, the transient and sub-transient characteristics of MGP are analyzed, it is pointed out that the power angle and excitation regulation of the generator are the key factors to improving its dynamic reactive power compensation capability. Then, based on the fast response of the converter, a fast active power reduction and additional excitation control strategy are proposed, which takes the blocking signal and AC voltage of the converter station at the sending end as input signals, aiming at increasing the depth of MGP leading phase. Finally, based on PSCAD/EMTDC software, the simulation model of multiple new energy stations connected to grid through DC transmission is built, and the effectiveness of the coordinated control strategy is verified. The results show that the proposed strategy can enhance the transient overvoltage suppression capability of MGP at sending end.

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MGP抑制直流发送端瞬态过电压的研究

随着高压直流输电中可再生能源电力的日益普及，输电端面临着暂态过电压问题的威胁。电机-发电机对具有进相操作能力，能有效抑制过电压。本文基于MGP的并网结构，分析了MGP的暂态和亚暂态特性，指出发电机的功率角和励磁调节是提高其动态无功补偿能力的关键因素。然后，基于变换器的快速响应特性，提出了一种以发送端换流站的阻塞信号和交流电压为输入信号，以增加MGP超前相深度为目标的快速有功降功率加励磁控制策略。最后，基于PSCAD/EMTDC软件，建立了多个新能源站通过直流输电并网的仿真模型，验证了协调控制策略的有效性。结果表明，该策略可以提高MGP发送端的瞬态过电压抑制能力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2022 IEEE International Conference on Power Systems and Electrical Technology (PSET)

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