Transient AC Overvoltage Suppression Orientated Reactive Power Control of the Wind Turbine in the LCC-HVDC Sending Grid

Bo Pang;Xiao Jin;Quanwang Zhang;Yi Tang;Kai Liao;Jianwei Yang;Zhengyou He
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Abstract

High-voltage direct current (HVDC) transmission is a crucial way to solve the reverse distribution of clean energy and loads. The line commutated converter-based HVDC (LCC-HVDC) has become a vital structure for HVDC due to its high technological maturity and economic advantages. During the DC fault of LCC-HVDC, such as commutation failure, the reactive power regulation of the AC grid always lags the DC control process, causing overvoltage in the AC sending grid, which brings off-grid risk to the wind power generation based on power electronic devices. Nevertheless, considering that wind turbine generators have fast and flexible reactive power control capability, optimizing the reactive power control of wind turbines to participate in the transient overvoltage suppression of the sending grid not only improves the operational safety at the equipment level but also enhances the voltage stability of the system. This paper firstly analyses the impact of wind turbine's reactive power on AC transient overvoltage. Then, it proposes an improved voltage-reactive power control strategy, which contains a reactive power control delay compensation and a power command optimization based on the voltage time series prediction. The delay compensation is used to reduce the contribution of the untimely reactive power of wind turbines on transient overvoltage, and the power command optimization enables wind turbines to have the ability to regulate transient overvoltage, leading to the variation of AC voltage, thus suppressing the transient overvoltage. Finally, the effectiveness and feasibility of the proposed method are verified in a ±800kV/5000MW LCC-HVDC sending grid model based on MATLAB/Simulink.
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LCC-HVDC 送出电网中风力涡轮机的瞬态交流过电压抑制定向无功功率控制
高压直流(HVDC)输电是解决清洁能源与负荷逆向分布的重要途径。基于线路换向变流器的高压直流输电(LCC-HVDC)因其技术成熟度高和经济性好而成为高压直流输电的重要结构。在 LCC-HVDC 发生换向故障等直流故障时,交流电网的无功调节总是滞后于直流控制过程,导致交流送出电网过电压,给基于电力电子装置的风力发电带来脱网风险。然而,考虑到风力发电机具有快速灵活的无功控制能力,优化风力发电机的无功控制,使其参与到送电网的暂态过电压抑制中,不仅能提高设备层面的运行安全性,还能增强系统的电压稳定性。本文首先分析了风力发电机无功功率对交流暂态过电压的影响。然后,提出了一种改进的电压-无功控制策略,其中包括无功控制延迟补偿和基于电压时间序列预测的功率指令优化。延时补偿用于降低风力发电机的非及时无功功率对暂态过电压的贡献,功率指令优化使风力发电机具备调节暂态过电压的能力,从而导致交流电压的变化,进而抑制暂态过电压。最后,基于 MATLAB/Simulink 的 ±800kV/5000MW LCC-HVDC 送出电网模型验证了所提方法的有效性和可行性。
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