考虑参数扰动的风力发电系统并网逆变器积分型连续滑模控制策略

doi:10.19595/j.cnki.1000-6753.tces.241991

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摘要风力发电系统（WPGS）中的并网逆变器（GCI）在运行过程中常受参数扰动影响,这会导致WPGS并网性能下降。为此,该文考虑GCI的内外参数扰动,基于连续高阶滑模超螺旋（Super-Twisting）算法设计GCI鲁棒控制系统。首先,构建了包含直流电压外环、交流电流内环和交流电压内环的GCI系统模型,同时考虑直流母线瞬时功率波动和GCI内部参数扰动;其次,为减少传统SMC的固定增益与抖振问题,根据GCI电流环与电压环的工作特性,分别构造具有时变增益与可预估增益的积分型Super-Twisting滑模控制器（STSMC）,以高效控制GCI与电网侧的交互功率,减少因系统不确定性边界造成的过度控制增益的能量损耗;然后,根据Lyapunov理论证明了该文所提控制策略的稳定性和有限时间收敛性;最后,设计了考虑参数扰动的多工况仿真和实验,结果表明所提控制策略有效地减小了GCI系统受扰后的输出信号波动,提高了其动态响应能力与WPGS的并网电能质量。

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关键词 ：并网逆变器, Super-Twisting算法, 风力发电系统, 参数扰动, 积分型滑模

Abstract：In the burgeoning field of clean wind energy, integrating wind power generation systems (WPGSs) into the power grid has become a critical area of research and development. The performance and reliability of the grid-connected inverter (GCI) play a pivotal role in ensuring efficient and stable electricity supply from wind farms. However, the GCI often faces parameter disturbances during operation, which are exacerbated by fluctuations on both the generation side and the grid side, significantly impacting the quality of grid connection and the overall performance of the WPGSs. However, current GCI control approaches neglect disturbance parameters and compromise the system's resilience and stability, making it vulnerable to operational unpredictability. Therefore, a novel approach is introduced, considering the GCI's typical internal and external parameter perturbations. A robust control system is developed using the continuous higher-order super-twisting sliding mode control (STSMC) strategy.
The specific design method of the STSMC strategy for the GCI system is as follows. Firstly, a model of the GCI system is constructed with a DC voltage outer loop, an AC current inner loop, and an AC voltage inner loop, considering DC bus instantaneous power fluctuations and internal parameter disturbances of the GCI. Compared with the traditional PI strategy, the designed parameter perturbation model effectively suppresses internal parameter disturbances in the GCI when paired with the STSMC. Additionally, the design of the DC voltage outer loop has successfully stabilized the DC input power of the GCI, thereby reducing the impact of disturbances on the WPGS generation side on the performance of the GCI. Secondly, the integral-type STSMC controllers with time-varying and predictable gains are constructed for the GCI current and voltage loops. Thus, the interaction power between the GCI and the grid side can be controlled, and energy loss from excessive control gain caused by system uncertainty boundaries can be improved. Compared with the traditional terminal sliding mode control (TSMC) and Twisting algorithm SMC, the time-varying gain of the current loop helps the STSMC overcome the slow current response speed inherent in the Twisting algorithm. Moreover, the predictable gain of the voltage loop produces a smaller steady-state error than the TSMC. Finally, the stability and finite-time convergence of the proposed control strategy are proved based on Lyapunov theory.
Simulations and experiments are designed considering parameter disturbances under multiple conditions. The STSMC system exhibits a 79.55% reduction in output power disturbance error compared to PI control, with the output power ripple amplitude lowered by 25.4% and 52.72% compared to TSMC and Twisting, respectively. The designed predictable gain and integral control term reduce the harmonic content of the GCI output capacitor voltage and current by 0.27% and 5.62%. The adoption of time-varying control gain further constrains the output power error to within 4.92% and 0.15%. In subsequent research, the investigation will be expanded to account for the practical influence of switching losses within the GCI and the effects of grid-side harmonics on the control system, aiming to construct a complete mathematical model of the GCI. Furthermore, the strategy's adaptability for application under unbalanced grids will be examined in depth.

Key words： Grid-connected inverters Super-Twisting algorithm wind power system parameter perturbation integral type sliding mode

收稿日期: 2024-11-08

PACS:

TM464

基金资助:国家自然科学基金项目（52238002, 52277006）、港口自发电集装箱码头智能微电网关键技术研究项目（2023-ZGKJ-ZDYF-03）和哈尔滨市科技创新人才项目（RC2024DY395）资助

通讯作者: 王艳敏女,1983年生,副教授,博士生导师,研究方向为电气系统的优化控制、建筑信息化与智能化控制。E-mail: wangyanmin@hit.edu.cn

作者简介: 张伟琦男,1997年生,博士研究生,研究方向为可再生能源发电系统并/离网机制、储能电力变换器的非线性控制策略。E-mail: zwq1191678801@163.com

引用本文:

张伟琦, 王艳敏, 宋凯, 何俊彪, 徐青云. 考虑参数扰动的风力发电系统并网逆变器积分型连续滑模控制策略[J]. 电工技术学报, 2025, 40(22): 7313-7333. Zhang Weiqi, Wang Yanmin, Song Kai, He Junbiao, Xu Qingyun. Integrated Continuous Sliding Mode Control Strategy of Grid-Connected Inverter for Wind Power System Considering Parameter Perturbation. Transactions of China Electrotechnical Society, 2025, 40(22): 7313-7333.

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[1] 张祥宇, 黄泳漩, 付媛. 非线性弹性耦合下双馈风电机组的暂态能量转移与振荡特性分析[J]. 电工技术学报, 2024, 39(13): 3956-3974.
Zhang Xiangyu, Huang Yongxuan, Fu Yuan.Transient energy transfer and oscillation characteri- stics analysis of doubly-fed wind turbine under nonlinear elastic coupling[J]. Transactions of China Electrotechnical Society, 2024, 39(13): 3956-3974.
[2] 刘昊, 方天治, 张惠丽, 等. 弱电网下应对复杂稳定性问题的并网逆变器改进电压前馈通路研究[J]. 电工技术学报, 2024, 39(16): 4955-4967.
Liu Hao, Fang Tianzhi, Zhang Huili, et al.Research on an improved voltage feedforward path of grid- connected inverter coping with complex stability issues in weak grid[J]. Transactions of China Elec- trotechnical Society, 2024, 39(16): 4955-4967.
[3] Liu Jianhong, Cheng Jiesheng.Online voltage security enhancement using voltage sensitivity-based coherent reactive power control in multi-area wind power generation systems[J]. IEEE Transactions on Power Systems, 2021, 36(3): 2729-2732.
[4] Mahdavi M, Jurado F, Schmitt K, et al.Electricity generation from cow manure compared to wind and photovoltaic electric power considering load uncer- tainty and renewable generation variability[J]. IEEE Transactions on Industry Applications, 2024, 60(2): 3543-3553.
[5] 洪国庆, 吴国旸, 金宇清, 等. 电力系统风力发电建模与仿真研究综述[J]. 电力系统自动化, 2024, 48(17): 22-36.
Hong Guoqing, Wu Guoyang, Jin Yuqing, et al.Review on research of modeling and simulation for wind power generation in power system[J]. Auto- mation of Electric Power System, 2024, 48(17): 22-36.
[6] 李啸骢, 罗雪丽, 侯立亮, 等. 基于分数阶LCL滤波器的风力发电网侧控制研究[J]. 太阳能学报, 2022, 43(12): 383-391.
Li Xiaocong, Luo Xueli, Hou Liliang, et al.Research on grid-side control of wind power generation based on fractional LCL filter[J]. Acta Energiae Solaris Sinica, 2022, 43(12): 383-391.
[7] Chow J H.Enabling inverter-based resource stability control in power systems with high renewable penetration[J]. CSEE Journal of Power and Energy Systems, 2023, 9(3): 1248-1250.
[8] Sung W Y, Ahn H M, Oh C Y, et al.Design and control of a bidirectional power conversion system with 3-level T-type inverter for energy storage systems[J]. Journal of Electrical Engineering & Technology, 2018, 13(1): 326-332.
[9] Ebrahimi J, Eren S.A multi-source DC/AC converter for integrated hybrid energy storage systems[J]. IEEE Transactions on Energy Conversion, 2022, 37(4): 2298-2309.
[10] Lai Jinmu, Yin Xin, Yin Xianggen, et al.Fractional order harmonic disturbance observer control for three-phase LCL-type inverter[J]. Control Engin- eering Practice, 2021, 107: 104697.
[11] Liang Weihua, Liu Yushan, Ge Baoming, et al.DC-link voltage balance control strategy based on multidimensional modulation technique for quasi- Z-source cascaded multilevel inverter photovoltaic power system[J]. IEEE Transactions on Industrial Informatics, 2018, 14(11): 4905-4915.
[12] Sellali M, Betka A, Djerdir A, et al.A novel energy management strategy in electric vehicle based on H_∞ self-gain scheduled for linear parameter varying systems[J]. IEEE Transactions on Energy Conversion, 2021, 36(2): 767-778.
[13] 周汉斌, 杨建, 黄连生, 等. 基于有限状态机的三电平逆变器双矢量模型预测控制策略[J]. 电力系统自动化, 2023, 47(11): 155-164.
Zhou Hanbin, Yang Jian, Huang Liansheng, et al.Double-vector model predictive control strategy of three-level inverter based on finite state machine[J]. Automation of Electric Power Systems, 2023, 47(11): 155-164.
[14] 任志玲, 叶俊, 王继超. 三相并网逆变器改进定频模型预测电流控制[J]. 电源学报, 2023, 21(4): 88-96.
Ren Zhiling, Ye Jun, Wang Jichao.Model predictive current control with improved fixed-frequency for three-phase grid-connected inverter[J]. Journal of Power Supply, 2023, 21(4): 88-96.
[15] 施建强, 李双, 赵宁宁, 等. 基于神经网络的逆变器约束自适应PI控制[J]. 太阳能学报, 2023, 44(10): 19-27.
Shi Jianqiang, Li Shuang, Zhao Ningning, et al.Constrained adaptive PI control of inverter based on neural network[J]. Acta Energiae Solaris Sinica, 2023, 44(10): 19-27.
[16] 许水清, 许晓凡, 何怡刚, 等. 基于自适应滑模观测器的中点钳位型三电平并网逆变器开关管和电流传感器故障诊断[J]. 电工技术学报, 2024, 39(13): 4066-4078.
Xu Shuiqing, Xu Xiaofan, He Yigang, et al.A diagnosis method for power switch and current sensor faults in grid-connected three-level neutral-point clamped inverters based on adaptive sliding mode observer[J]. Transactions of China Electrotechnical Society, 2024, 39(13): 4066-4078.
[17] Tran T V, Kim K H, Lai J S.H₂/H_∞ robust observed- state feedback control based on slack LMI-LQR for LCL-filtered inverters[J]. IEEE Transactions on Industrial Electronics, 2023, 70(5): 4785-4798.
[18] Heydari R, Young H, Flores-Bahamonde F, et al.Model-free predictive control of grid-forming inver- ters with LCL filters[J]. IEEE Transactions on Power Electronics, 2022, 37(8): 9200-9211.
[19] Prasad M V S. Design and implementation of model parameter independent robust current control scheme of three-phase inverter-a neural network-based classification approach[J]. CPSS Transactions on Power Electronics and Applications, 2024, 9(2): 166-174.
[20] Zhao Zhenhua, Yang Jun, Li Shihua, et al.Continuous output feedback TSM control for uncertain systems with a DC-AC inverter example[J]. IEEE Transa- ctions on Circuits and Systems II: Express Briefs, 2018, 65(1): 71-75.
[21] Liu Xiangjie, Wang Ce, Kong Xiaobing, et al.Tube- based distributed MPC for load frequency control of power system with high wind power penetration[J]. IEEE Transactions on Power Systems, 2023, 39(2): 3118-3129.
[22] Fu Cheng, Zhang Chenghui, Zhang Guanguan, et al.Current sensorless sliding-mode voltage control for LC filtered three-level T-type inverters[J]. IEEE Transactions on Circuits and Systems II: Express Briefs, 2024, 71(4): 2264-2268.
[23] Liu Zhongqian, Wu Hongbin, Jin Wei, et al.Two-step method for identifying photovoltaic grid-connected inverter controller parameters based on the adaptive differential evolution algorithm[J]. IET Generation, Transmission & Distribution, 2017, 11(17): 4282-4290.
[24] Tran T V, Kim K H, Lai J S.Optimized active disturbance rejection control with resonant extended state observer for grid voltage sensorless LCL-filtered inverter[J]. IEEE Transactions on Power Electronics, 2021, 36(11): 13317-13331.
[25] Yuan Xin, Xie Shuangchun, Chen Jiahao, et al.An enhanced deadbeat predictive current control of SPMSM with linear disturbance observer[J]. IEEE Journal of Emerging and Selected Topics in Power Electronics, 2022, 10(5): 6304-6316.
[26] 彭寥廓, 陈艳慧. 单相全桥离网逆变器输出侧功率解耦电路研究[J]. 电气技术, 2022, 23(1): 42-48, 55.
Peng Liaokuo, Chen Yanhui.Research on a single- phase full-bridge off-grid inverter with active power decoupling circuit at output side[J]. Electrical Engineering, 2022, 23(1): 42-48, 55.
[27] Gong Cheng, Sou W K, Lam C S.Reinforcement learning based sliding mode control for a hybrid- STATCOM[J]. IEEE Transactions on Power Elec- tronics, 2023, 38(6): 6795-6800.
[28] Kandil M S, Dubois M R, Bakay L S, et al.Application of second-order sliding-mode concepts to active magnetic bearings[J]. IEEE Transactions on Industrial Electronics, 2018, 65(1): 855-864.