基于直流电压控制的新能源并网系统暂态电压稳定性分析

doi:10.19595/j.cnki.1000-6753.tces.250731

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摘要传统电力系统中的暂态电压稳定问题主要聚焦于受端电网中感应电动机的暂态稳定,然而随着新能源电源大规模接入送端电网,系统故障恢复期间同样面临严重的暂态电压失稳问题。目前研究多采用数值仿真手段分析新能源接入对系统故障期间电压跌落程度的影响,并基于工程经验判据分析系统的电压稳定性,对新能源控制作用下系统暂态电压失稳的机理尚不清晰。为此,本文在揭示直流电压控制下新能源的暂态电压失稳机理的基础上,进一步对比分析了传统电力系统中感应电动机与新能源并网系统暂态电压失稳机理的异同。之后,量化分析了新能源暂态同步稳定边界与暂态电压稳定边界的基础上提出了暂态稳定主导因子指标,论证了弱电网中暂态电压稳定主导系统的暂态稳定边界的合理性。最后,基于电磁暂态仿真验证了所提失稳机理和分析方法的有效性。

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	刘昕宇
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关键词 ：新能源并网系统, 暂态电压失稳, 直流电压控制, 电压稳定边界, 暂态稳定主导因子

Abstract：The transient voltage stability issues in traditional power systems mainly focus on the transient stability of induction motors in receiving-end power grids. However, with the large-scale integration of renewable energy sources (RES) into the sending-end grid, the system also faces serious transient voltage instability problems during fault recovery process. At present, the numerical simulation methods are mostly utilized to analyze the influence of RES on the voltage drop during fault, and the transient voltage stability is analyzed by numerically calculating the time-domain integration of the voltage lower than 0.8 p.u., which is determined based on the engineering experience criteria. However, the voltage dynamics during fault recovery process is mainly determined by the voltage control mechanism of various equipments, the voltage stability of the system cannot be determined by the period of voltage recovery process. To avoid the misjudgment of the transient voltage stability of the RES integrated system, it is urgent to reveal the voltage instability mechanism considering the control strategies of RES. Therefore, based on the analogy of the transient instability process of synchronous generators, the transient voltage instability mechanism of RES under DC voltage control is revealed, the similarities and differences of transient voltage stability in RES integrated power systems and the traditional power system is sorted out. Afterwards, based on the quantitative analysis of boundaries for transient synchronous stability and transient voltage stability of RES integrated system, the transient stability dominance factor is proposed, and the rationality of the dominance of transient voltage stability in weak grids is demonstrated. Finally, the effectiveness of the proposed instability mechanism and analysis method is validated by electromagnetic transient simulations.
The following conclusions can be drawn from the simulation analysis:( 1) With the DC voltage control, the RES integrated system crosses the unstable equilibrium point under the unbalanced active power during fault. Then, the positive-feedback voltage control mechanism of RES is caused, which results in the continuous increase of the active current and continuous decrease of AC voltage, and the transient voltage instability of RES integrated system happens. (2) When the grid is strong and reactive power gain of RES is large enough, the unbalanced active power during fault is relatively small, the increase of the active current is retarded, and the transient voltage stability of the system is improved. Moreover, increasing the proportional gain of DC voltage controller can enhance the system’s ability to respond the unbalanced power and provide additional braking effect. However, considering the lagging of integrator for DC voltage controller, increasing the integration gain will lead to the decrease of deceleration area of the system, and the transient voltage stability of the system is deteriorated. (3) The RES integrated system faces the transient synchronous instability and transient voltage instability risks simultaneously, and the transient voltage instability issue must be considered first when the grid is weak and the reactive power support of RES is insufficient. (4) The active power output by the RES during fault recovery process is increased with the decrease of PLL control bandwidths, and the transient voltage stability of the RES integrated system is improved after considering the PLL dynamics. Therefore, a conservative evaluation result is derived in this paper due to the neglect of PLL dynamics.

Key words： RES integrated power systems transient voltage stability DC voltage control transient voltage stability boundary transient stability dominance factor

收稿日期: 2025-04-30

PACS:

TM712

基金资助:智能电网重大专项(2030)（2024ZD0801000）和国网浙江省电力有限公司科技项目（B311DS25000A）资助

通讯作者: 辛焕海男,1981年生,教授,博士生导师,研究方向为交直流混联电力系统和高比例新能源电力系统稳定性分析和控制。E-mail：xinhh@zju.edu.cn

作者简介: 刘昕宇男,1998年生,博士,研究方向为新能源电力系统暂态电压稳定。E-mail：liuxinyu_up@163.com.

引用本文:

刘昕宇, 单永鹏, 辛焕海, 郑迪. 基于直流电压控制的新能源并网系统暂态电压稳定性分析[J]. 电工技术学报, 0, (): 250731-. Liu Xinyu, Shan Yongpeng, Xin Huanhai, Zheng Di. Transient Voltage Stability Analysis of Voltage Source Converters Integrated System under DC Voltage Control. Transactions of China Electrotechnical Society, 0, (): 250731-.

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