光伏电站与弱交流电网间次同步交互作用路径及阻尼特性分析

doi:10.19595/j.cnki.1000-6753.tces.221776

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摘要大规模光伏发电经长距离输电线路并入主网时,光伏电站和弱交流电网的交互作用可能使光伏并网系统面临次同步振荡（SSO）的威胁,但目前针对系统内部次同步交互作用的相关研究较少。针对上述问题,该文首先将阻尼转矩法推广到锁相环（PLL）振荡模态,并推导了光伏并网系统的线性化闭环传递函数框图。然后,基于闭环传递函数框图,揭示了PLL主导的SSO模式下系统阻尼构成和光伏电站与弱交流电网间动态交互过程。最后,借鉴等效阻尼系数量化评估了次同步交互作用的阻尼特性。结果表明,光伏并入弱交流电网系统存在PLL主导的SSO风险;光伏电站与弱交流电网的次同步交互作用向光伏并网系统提供负阻尼,是系统SSO的主导因素;增加PLL比例系数、交流电网强度、光伏电站光照强度或温度,减小PLL积分系数或光伏容量,能够增加次同步交互作用的阻尼贡献,提高光伏并网系统稳定性。时域仿真验证了理论分析结果的正确性。

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关键词 ：光伏电站, 次同步振荡, 次同步交互作用, 阻尼转矩法, 锁相环

Abstract：When a large-scale photovoltaic (PV) plant is integrated into the AC grid through long transmission lines, the interaction between the PV plant and weak AC grid may make the integration face the threat of subsynchronous oscillation (SSO). However, the mechanism of the subsynchronous interaction between the PV plant and weak AC grid are unclear, and quantifying the damping characteristics of the subsynchronous interaction is difficult by the existing analysis methods. Therefore, this paper proposes a damping torque method extended to the dynamic equation of phase-locked loop (PLL) to analyze the subsynchronous interaction between the PV plant and weak AC grid.
Firstly, the damping torque method is extended to the PLL dynamic equation to analyze the stability of the PV plant integrated into the weak AC grid system in the SSO mode dominated by PLL. Secondly, the linearization model of the PV plant integration and its corresponding closed-loop transfer function block diagram are derived. Based on the closed-loop transfer function diagram, the coupling relationship and interaction path between the PV plant and weak AC grid are revealed from the perspective of internal disturbance transfer, and the dynamic process of the interaction path affecting SSO mode damping is analyzed. Thirdly, through transfer function derivation, the damping path reflecting the subsynchronous interaction is separated, and the equivalent damping coefficient is used to quantify the SSO mode damping of the subsynchronous interaction. Finally, the influences of PLL control parameters, PV capacity, AC grid strength, PV plant intensity, and temperature on the damping characteristics of subsynchronous interaction are analyzed.
The mechanism analysis shows that the PV plant-weak AC grid current disturbance and the grid-side voltage disturbance drive each other at the point of common coupling, forming the subsynchronous interaction path. Then, the subsynchronous interaction path will form a closed-loop damping path through the PLL in the SSO mode dominated by PLL, affecting the system SSO mode damping. Therefore, the damping contribution of the PV plant and subsynchronous interaction are quantitatively evaluated through the damping path separation. The results show that the PV plant and the subsynchronous interaction provide positive damping and negative damping to the system, respectively, resulting in the SSO of the PV plant integrated into the weak AC grid system. In addition, the subsynchronous interaction damping can be decreased by increasing the PLL proportion coefficient, AC grid strength, PV plant intensity or temperature, or decreasing the PLL integration coefficient or PV capacity, thereby improving the stability of the PV plant integrated to weak AC grid system.
The following conclusions can be drawn from the theoretical analysis: (1) The subsynchronous interaction between the PV plant and weak AC grid will form the damping path through the PLL, affecting the SSO mode damping of the system. There is the SSO risk dominated by PLL in the PV plant integration. (2) The subsynchronous interaction provides negative damping to the system, which is the dominant factor for the SSO of the PV plant integration. (3) Reasonable design of system parameters according to the negative damping characteristics of subsynchronous interaction can effectively increase the SSO mode damping and better maintain the original positive damping characteristics of the PV plant.

Key words： Photovoltaic plant subsynchronous oscillation subsynchronous interaction damping torque method phase-locked loop

收稿日期: 2022-09-18

PACS:

TM712

基金资助:国家重点研发计划资助项目“响应驱动的大电网稳定性智能增强分析与控制技术”（2021YFB2400800）

通讯作者: 邓鹏程男,1998年生,硕士,研究方向为新能源并网系统次同步振荡分析。E-mail: 1533202670@qq.com

作者简介: 高本锋男,1981年生,副教授,研究方向为高压直流输电和电力系统次同步振荡。E-mail: gaobenfeng@126.com

引用本文:

高本锋, 邓鹏程, 梁纪峰, 赵宇皓. 光伏电站与弱交流电网间次同步交互作用路径及阻尼特性分析[J]. 电工技术学报, 2023, 38(24): 6679-6694. Gao Benfeng, Deng Pengcheng, Liang Jifeng, Zhao Yuhao. Analysis of Path and Damping Characteristics of Subsynchronous Interaction Between Photovoltaic Plant and Weak AC Grid. Transactions of China Electrotechnical Society, 2023, 38(24): 6679-6694.

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