多逆变器并网系统有源阻尼器间交互作用及其对振荡抑制效果提升

doi:10.19595/j.cnki.1000-6753.tces.250624

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摘要在多逆变器并网系统中,逆变器与电网之间的动态交互作用严重威胁系统的稳定性,该系统还同时面临由逆变器间线路阻抗差异导致的功率分配不均以及潜在的电压跌落等电能质量问题。由于现有控制方法难以实现各控制器间的兼容,往往仅能解决上述部分问题,且对所引入控制器之间的交互作用缺乏研究。为此,该文提出一种基于有源阻尼控制的电能质量提升策略,以便同时解决上述问题：通过阻尼器K增强系统阻尼特性,利用虚拟阻抗Z_v(s)实现功率解耦与输出阻抗提升,确保功率精确分配;同时采用改进的自适应电压补偿下垂控制,实现并网点电压恢复。该文重点研究了各有源阻尼器间的交互作用及其对振荡抑制的提升效果,结果表明各有源控制器之间不仅具备良好的兼容性,阻尼器K和虚拟阻抗Z_v(s)之间还具有协同促进效果：二者可分别抑制中低频和高频段的动态交互作用,通过二者的协同配合可在全频段内规避发生动态交互作用的风险,从而显著提升系统的稳定性。最后通过实验验证所提策略的有效性。

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关键词 ：多逆变器并网系统, 动态交互作用, 功率均分, 电压跌落, 有源控制

Abstract：In a multi-inverter grid-connected system, due to the inverters' nonlinear characteristics and the weak grid characteristics, the dynamic interaction between the inverters and the grid poses a serious threat to system stability. Additionally, the system often faces power quality issues, including power-sharing mismatch caused by line impedance differences among inverters and potential voltage drop. Existing control methods struggle to achieve compatibility among controllers, which hinders their ability to address the three problems simultaneously.
This paper proposes an active damping-based control strategy to enhance power quality in a multi-inverter grid-connected system. The interaction between the active damper controllers is analyzed. The proposed strategy consists of three active controllers: damper K, virtual impedance Z_v(s), and an adaptive voltage compensator. Based on the established dq small-signal model of the multi-inverter grid-connected system, the impact of the proposed strategy on system damping is investigated. The strategy can amplify the system damping by a factor of [1+KG_i(s)/(R_f+G_i(s))], thereby enhancing robustness and improving the stability margin. By plotting the real/imaginary parts of the total inverter output impedance, the effectiveness of the proposed strategy in achieving power sharing is studied. The results demonstrate that the total output impedance can be reshaped. When the introduced virtual inductance L_v counteracts the line inductance L_x, the power decoupling condition can be satisfied. By increasing the introduced virtual resistance R_v, accurate power sharing can be achieved.
The co-action effect of the introduced active damper controllers on oscillation suppression is analyzed. It shows a synergistic interaction effect between the damper K and the virtual impedance Z_v(s): As the damper K increases, the dynamic interactions in the mid-to-low frequency range are better suppressed. Still, adverse effects are introduced in the high-frequency range. Instability at high frequencies should be avoided when increasing the value of K at low and medium frequencies. The virtual impedance Z_v(s) can eliminate the detrimental high-frequency impact caused by damper K and preserve the suppression performance in the mid-low frequency band. Virtual inductance (L_v) is introduced to mitigate dynamic interaction and enhance stability in the high-frequency range, while virtual resistance (R_v) is adjusted to improve stability at low frequencies. The coordinated operation of damper K and virtual impedance Z_v(s) eliminates the risk of dynamic interaction across the entire frequency range, improving system stability.
A hardware-in-the-loop experimental platform is established. The experimental results demonstrate that under the proposed control strategy, the system remains stable under weak grid conditions. The output power difference among inverters is as low as 0.22%, with a 98.5% improvement in power-sharing accuracy. Additionally, the PCC voltage deviation is reduced from 10% to 1.3%, and the inverter output active power is significantly enhanced from 18 330 W to 95 370 W, representing a 420% improvement. The proposed active damping control strategy demonstrates excellent compatibility in terms of system stability improvement, accurate power sharing, voltage recovery, and output power enhancement.

Key words： Multi-inverter grid-connected system dynamic interaction power sharing voltage drop active control

收稿日期: 2025-04-15

PACS:

TM464

基金资助:国家自然科学基金（52107185）、广东省基础与应用基础研究基金（2023A1515010061）、广州市基础与应用基础研究基金（2024A04J4673）和电能高效高质转化全国重点实验室开放基金（2024KF008）资助项目

通讯作者: 罗坚强男,1987年生,副教授,硕士生导师,研究方向为新能源电力系统稳定分析与控制。E-mail: jqluo@gdut.edu.cn

作者简介: 杨苓女,1992年生,博士,副教授,硕士生导师,研究方向为并网逆变器的建模与稳定性分析。E-mail: 1650148795@qq.com

引用本文:

杨苓, 朱涤凡, 叶美婷, 李杰文, 罗坚强. 多逆变器并网系统有源阻尼器间交互作用及其对振荡抑制效果提升[J]. 电工技术学报, 2026, 41(10): 3423-3436. Yang Ling, Zhu Difan, Ye Meiting, Li Jiewen, Luo Jianqiang. The Interaction Among Active Dampers in Multi-Inverter Grid-Connected System and Its Enhancement of Oscillation Suppression. Transactions of China Electrotechnical Society, 2026, 41(10): 3423-3436.

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