电工技术学报2026,Vol.41Issue(8):2822-2835,14.DOI:10.19595/j.cnki.1000-6753.tces.250800
弱电网下基于谐振阻尼优化的LCL型并网逆变器预测控制
Predictive Control of LCL-Type Grid-Connected Inverter Based on Optimized Resonance Damping under Weak Grid Conditions
摘要
Abstract
As the global energy structure accelerates its transition to green and low-carbon,the penetration rate of distributed new energy generation in the power system has increased significantly.However,due to the geographical dispersion and power output volatility of distributed energy sources such as photovoltaic and wind power,they were usually required to be connected to the primary grid through long-distance transmission lines.The significant inductive impedance characteristics formed by the line distribution parameters and transformer leakage inductance make the grid-connected coupling point exhibit weak grid characteristics.In such a weak grid condition,the increase in the equivalent grid impedance causes the resonance peak of the LCL-type grid-connected inverter to shift,thereby affecting the system stability and power transmission capacity.As the key energy interface between the new energy power generation system and the grid,ensuring the safe and stable operation of the grid-connected inverter is crucial. A resonant-damping optimization predictive control strategy based on capacitor voltage estimation was proposed.Firstly,according to the linear equivalence principle,a capacitor voltage estimation method was designed.The capacitor voltage was estimated,and the traditional capacitor voltage sensor was replaced.This method ensured measurement accuracy,significantly reduced hardware costs,and simplified the system structure.Secondly,a negative first-order high-pass filter was designed to dynamically reconstruct the super-local model of the inverter.The filter extracted the high-frequency oscillation components near the resonance frequency and provided real-time feedback signals for active damping control.Hence,the active damping characteristics at the resonance frequency were optimized,and the adverse effects caused by resonance peak shift were suppressed.Additionally,a two-step predictive current control strategy was designed to enhance the dynamic response performance of the system.Through the accurate prediction and advanced adjustment of the current at future moments,the system can quickly respond to load changes and grid disturbances,reducing current overshoot and adjustment time during the dynamic process.Meanwhile,by drawing Bode plots,the frequency characteristics of the proposed control strategy and the traditional control strategy were analyzed. Experimental results show that the strategy effectively suppresses the low-order harmonic distortion of the inverter itself under weak grid conditions by optimizing the resonance damping of the LCL filter,thereby significantly reducing the harmonic distortion rate of the grid-connected current and enhancing system stability.Even in extremely weak grid scenarios,the system can still maintain stable operation while improving the power transmission capacity.The proposed method significantly enhances the system's robustness and adaptability to weak grid conditions.关键词
电容电压估算/LCL型滤波器/预测控制/谐振阻尼/弱电网环境Key words
Capacitor voltage estimation/LCL filter/predictive control/resonance damping/weak grid conditions分类
信息技术与安全科学引用本文复制引用
汪凤翔,汤小雪,于新红,柯栋梁,张祯滨..弱电网下基于谐振阻尼优化的LCL型并网逆变器预测控制[J].电工技术学报,2026,41(8):2822-2835,14.基金项目
国家自然科学基金项目(52277070)、福建省科技计划项目(2022HZ028010,2024T3037)和泉州市科技计划项目(2023C002R)资助. (52277070)
