Mechanism and Characteristics of Subsynchronous Oscillation of Grid-Forming Direct-Drive Wind Farm Based on Matching Control
Gao Benfeng1, Deng Pengcheng1, Sun Dawei2, Wu Linlin2, Wang Xiao2, Deng Xiaoyang2
1. Hebei Key Laboratory of Distributed Energy Storage and Micro-Grid North China Electric Power University Baoding 071003 China; 2. State Grid Wind-Photovoltaic-Energy Storage Hybrid Power Generation Technology Laboratory North China Electric Power Research Institute Co. Ltd Beijing 100045 China
Abstract:When new energy, mainly wind power and photovoltaic, is connected to the AC grid through power electronic converters on a large scale, the power system is prone to form a weak AC grid environment, which brings severe challenges to the stable operation of traditional grid-following new energy units. Therefore, grid-forming new energy units with better adaptability to weak AC grid have become the forefront and hot spot of research at home and abroad in recent years, and a variety of grid-forming control strategies have been proposed, such as sagging control, virtual synchronous generator control and matching control. Compared with other grid-forming control strategies, matching control only needs to measure the DC voltage to realize the autonomous synchronization function and has a faster response speed, which has been widely used in new energy units, especially direct-driven wind turbines. However, at present, relevant studies of grid-forming new energy units based on matching control mainly focus on the supporting capacity and inertia response characteristics of AC grid, and its subsynchronous oscillation (SSO) stability under different AC grid strength is not clear. In order to solve the above problems, this paper firstly establishes the small signal model of grid-forming direct drive wind farm (DDWF) integrated to AC grid system based on the modular modeling method. Secondly, the eigenvalue analysis method is used to analyze the main oscillation modes and participating factors of the grid-forming DDWF, and to analyze its stability in the weak AC grid compared with the traditional grid-following DDWF. Then, the damping torque method in synchronous generator is used to analyze the oscillation mechanism of the grid-forming DDWF based on matching control. Finally, the influence of AC grid strength, the number of direct drive fans and reactive power controller PI parameter on SSO mode damping characteristics of the grid-forming DDWF integrated to AC grid system is studied by eigenvalue root locus. Based on the eigenvalue analysis, it is concluded that the SSO stability of the grid-forming DDWF integrated to AC grid system is mainly affected by the oscillation mode dominated by matching control. Under strong AC grid condition, the oscillation mode dominated by matching control presents negative damping characteristic, and the system has SSO risk. However, compared with the DC capacitance and phase-locked loop (PLL) oscillation modes in the grid-following DDWF, the oscillation mode dominated by matching control in the grid-forming DDWF have better adaptability to the weak AC grid. In addition, when the DC capacitance and the matching control act together, the oscillation mode dominated by matching control has a dynamic characteristic similar to the rotor motion equation of the synchronous machine, which makes the grid-forming DDWF may be unstable due to insufficient damping. The following conclusions can be drawn from the simulation and experiment analysis: (1) The oscillation mode dominated by matching control in the grid-forming DDWF presents negative damping characteristics under the strong AC grid, and the risk of SSO exists in the grid-forming DDWF integrated to AC grid system. However, the oscillation mode dominated by matching control has better adaptability to weak AC grid, and the grid-forming DDWF can run stably under the weak AC grid. (2) The oscillation mode dominated by matching control has a dynamic characteristic similar to the rotor motion equation of synchronous machine, which makes the grid-forming DDWF may have weakly damping oscillation. (3) Reducing the AC grid strength or the integral coefficient of reactive power controller, increasing the number of direct drive fans or the proportional coefficient of reactive power controller, can increase the damping of the oscillation mode dominated by matching control and reduce the SSO risk of the grid-forming DDWF.
高本锋, 邓鹏程, 孙大卫, 吴林林, 王潇, 邓晓洋. 基于匹配控制的构网型直驱风电场次同步振荡机理与特性研究[J]. 电工技术学报, 2024, 39(9): 2755-2770.
Gao Benfeng, Deng Pengcheng, Sun Dawei, Wu Linlin, Wang Xiao, Deng Xiaoyang. Mechanism and Characteristics of Subsynchronous Oscillation of Grid-Forming Direct-Drive Wind Farm Based on Matching Control. Transactions of China Electrotechnical Society, 2024, 39(9): 2755-2770.
[1] 卓振宇, 张宁, 谢小荣, 等. 高比例可再生能源电力系统关键技术及发展挑战[J]. 电力系统自动化, 2021, 45(9): 171-191. Zhuo Zhenyu, Zhang Ning, Xie Xiaorong, et al.Key technologies and developing challenges of power system with high proportion of renewable energy[J]. Automation of Electric Power Systems, 2021, 45(9): 171-191. [2] 杨明, 杨倬, 李玉龙, 等. 高渗透率下基于并网逆变器阻抗重塑的锁相环设计方法[J]. 电工技术学报, 2024, 39(2): 554-566. Yang Ming, Yang Zhuo, Li Yulong, et al.High permeability based on grid inverter phase-locked loop design method of impedance remodeling[J]. Transactions of China Electrotechnical Society, 2024, 33(2): 554-566. [3] 董文凯, 杜文娟, 王海风. 弱连接条件下锁相环动态主导的并网直驱风电场小干扰稳定性研究[J]. 电工技术学报, 2021, 36(3): 609-622. Dong Wenkai, Du Wenjuan, Wang Haifeng.Small-signal stability of a grid-connected PMSG wind farm dominated by dynamics of PLLs under weak grid connection[J]. Transactions of China Electrotechnical Society, 2021, 36(3): 609-622. [4] Rosso R, Wang Xiongfei, Liserre M, et al.Grid-forming converters: control approaches, grid-synchronization, and future trends—a review[J]. IEEE Open Journal of Industry Applications, 2021, 2: 93-109. [5] Popella H, Hennig T, Kaiser M, et al.Necessary development of inverter-based generation with grid forming capabilities in Germany[C]//20th International Workshop on Large-Scale Integration of Wind Power into Power Systems as well as on Transmission Networks for Offshore Wind Power Plants (WIW 2021), Hybrid Conference, Germany, 2021: 125-129. [6] Roscoe A, Knueppel T, Da Silva R, et al.Response of a grid forming wind farm to system events, and the impact of external and internal damping[J]. IET Renewable Power Generation, 2020, 14(19): 3908-3917. [7] 秦世耀, 齐琛, 李少林, 等. 电压源型构网风电机组研究现状及展望[J]. 中国电机工程学报, 2023, 43(4): 1314-1334. Qin Shiyao, Qi Chen, Li Shaolin, et al.Review of the voltage-source grid forming wind turbine[J]. Proceedings of the CSEE, 2023, 43(4): 1314-1334. [8] 詹长江, 吴恒, 王雄飞, 等. 构网型变流器稳定性研究综述[J]. 中国电机工程学报, 2023, 43(6): 2339-2359. Zhan Changjiang, Wu Heng, Wang Xiongfei, et al.An overview of stability studies of grid-forming voltage source converters[J]. Proceedings of the CSEE, 2023, 43(6): 2339-2359. [9] 薛翼程, 张哲任, 徐政, 等. 构网型变流器对交流系统低频振荡的影响分析与阻尼控制[J]. 电力系统自动化, 2023, 47(16): 103-113. Xue Yicheng, Zhang Zheren, Xu Zheng, et al.Impact analysis and damping control of grid-forming converter for low-frequency oscillation of AC system[J]. Automation of Electric Power Systems, 2023, 47(16): 103-113. [10] 许诘翊, 刘威, 刘树, 等. 电力系统变流器构网控制技术的现状与发展趋势[J]. 电网技术, 2022, 46(9): 3586-3595. Xu Jieyi, Liu Wei, Liu Shu, et al.Current state and development trends of power system converter grid-forming control technology[J]. Power System Technology, 2022, 46(9): 3586-3595. [11] Arghir C, Dörfler F.The electronic realization of synchronous machines: model matching, angle tracking, and energy shaping techniques[J]. IEEE Transactions on Power Electronics, 2020, 35(4): 4398-4410. [12] 桑顺, 张琛, 蔡旭, 等. 全功率变换风电机组的电压源控制(一):控制架构与弱电网运行稳定性分析[J]. 中国电机工程学报, 2021, 41(16): 5604-5616. Sang Shun, Zhang Chen, Cai Xu, et al.Voltage source control of wind turbines with full-scale converters (part Ⅰ): control architecture and stability analysis under weak grid conditions[J]. Proceedings of the CSEE, 2021, 41(16): 5604-5616. [13] 桑顺, 齐琛, 张新松, 等. 永磁直驱风电机组的构网型控制与黑启动[J]. 电网技术, 2022, 46(8): 3168-3180. Sang Shun, Qi Chen, Zhang Xinsong, et al.Grid-forming control and black start of PMSG-based direct-driven wind turbine[J]. Power System Technology, 2022, 46(8): 3168-3180. [14] 张琛, 蔡旭, 李征. 具有自主电网同步与弱网稳定运行能力的双馈风电机组控制方法[J]. 中国电机工程学报, 2017, 37(2): 476-486. Zhang Chen, Cai Xu, Li Zheng.Control of DFIG-based wind turbines with the capability of automatic grid-synchronization and stable operation under weak grid condition[J]. Proceedings of the CSEE, 2017, 37(2): 476-486. [15] 薛安成, 付潇宇, 乔登科, 等. 风电参与的电力系统次同步振荡机理研究综述和展望[J]. 电力自动化设备, 2020, 40(9): 118-128. Xue Ancheng, Fu Xiaoyu, Qiao Dengke, et al.Review and prospect of research on sub-synchronous oscillation mechanism for power system with wind power participation[J]. Electric Power Automation Equipment, 2020, 40(9): 118-128. [16] 张天翼, 王海风. 风电并入弱交流系统引发次同步振荡的研究方法综述[J]. 电力系统保护与控制, 2021, 49(16): 177-187. Zhang Tianyi, Wang Haifeng.Research methods for subsynchronous oscillation induced by wind power under weak AC system: a review[J]. Power System Protection and Control, 2021, 49(16): 177-187. [17] 刘其辉, 高瑜, 郭天飞, 等. 风电并网系统阻抗稳定性分析及次同步振荡因素研究[J]. 太阳能学报, 2022, 43(1): 89-100. Liu Qihui, Gao Yu, Guo Tianfei, et al.Research on impedance stability analysis and subsynchronous oscillation factors of wind power grid-connected system[J]. Acta Energiae Solaris Sinica, 2022, 43(1): 89-100. [18] Li Gaoxiang, Chen Yandong, Luo An, et al.Analysis and mitigation of subsynchronous resonance in series-compensated grid-connected system controlled by a virtual synchronous generator[J]. IEEE Transactions on Power Electronics, 2020, 35(10): 11096-11107. [19] 韩应生, 孙海顺, 秦世耀, 等. 电压源型双馈风电并网系统小扰动低频稳定性分析[J]. 电工技术学报, 2023, 38(5): 1312-1324, 1374. Han Yingsheng, Sun Haishun, Qin Shiyao, et al.Low-frequency stability analysis of voltage-sourced doubly-fed wind power grid-connected system under small disturbance[J]. Transactions of China Electrotechnical Society, 2023, 38(5): 1312-1324, 1374. [20] 刘志坚, 骆军, 梁宁, 等. 虚拟同步控制对风电并网系统次同步振荡阻尼影响分析[J]. 电力系统自动化, 2023, 47(1): 135-142. Liu Zhijian, Luo Jun, Liang Ning, et al.Analysis of influence of virtual synchronous control on subsynchronous oscillation damping for grid-connected wind power system[J]. Automation of Electric Power Systems, 2023, 47(1): 135-142. [21] 高本锋, 刘毅, 李蕴红, 等. 直驱风电场与LCC-HVDC次同步交互作用的扰动传递路径及阻尼特性分析[J]. 中国电机工程学报, 2021, 41(5): 1713-1729. Gao Benfeng, Liu Yi, Li Yunhong, et al.Analysis on disturbance transfer path and damping characteristics of sub-synchronous interaction between D-PMSG-based wind farm and LCC-HVDC[J]. Proceedings of the CSEE, 2021, 41(5): 1713-1729. [22] 高本锋, 王义, 曾四鸣, 等. 直驱风电场并入弱交流电网的次同步分量通路及阻尼特性分析[J]. 中国电机工程学报, 2022, 42(14): 5089-5103. Gao Benfeng, Wang Yi, Zeng Siming, et al.Analysis of sub-synchronous component path and damping characteristics of D-PMSG-based wind farm incorporated into weak AC grid[J]. Proceedings of the CSEE, 2022, 42(14): 5089-5103. [23] 李龙源, 付瑞清, 吕晓琴, 等. 接入弱电网的同型机直驱风电场单机等值建模[J]. 电工技术学报, 2023, 38(3): 712-725. Li Longyuan, Fu Ruiqing, Lü Xiaoqin, et al.Single machine equivalent modeling of weak grid connected wind farm with same type PMSGs[J]. Transactions of China Electrotechnical Society, 2023, 38(3): 712-725. [24] 董文凯, 任必兴, 王海风, 等. 适用于系统次同步振荡分析的风电场等值建模方法综述[J]. 电力工程技术, 2022, 41(4): 33-43. Dong Wenkai, Ren Bixing, Wang Haifeng, et al.Small-signal equivalent modeling methods of the wind farm and its application in sub-synchronous oscillations analysis of gird-connected wind power systems[J]. Electric Power Engineering Technology, 2022, 41(4): 33-43. [25] 赵书强, 李忍, 高本锋, 等. 适用于多源系统次同步振荡分析的图形化建模方法[J]. 电工技术学报, 2017, 32(14): 184-193, 228. Zhao Shuqiang, Li Ren, Gao Benfeng, et al.A graphical modeling method applied for multi-sources system subsynchronous oscillation analysis[J]. Transactions of China Electrotechnical Society, 2017, 32(14): 184-193, 228. [26] 高本锋, 崔意婵, 邵冰冰, 等. 直驱风电机组全运行区域的次同步振荡特性分析[J]. 电力建设, 2020, 41(2): 85-93. Gao Benfeng, Cui Yichan, Shao Bingbing, et al.Sub-synchronous oscillation characteristics of direct-drive PMSG under all operation regions when wind farms connected to weak AC system[J]. Electric Power Construction, 2020, 41(2): 85-93.
2024, Vol. 39 
