Journal of Guangdong University of Technology ›› 2024, Vol. 41 ›› Issue (05): 22-29.doi: 10.12052/gdutxb.240074

• Electrical Engineering • Previous Articles     Next Articles

A Study of Control Modal Interaction and Internal Resonance of DFIG

Luo Jian-qiang1, Li Hao-xian2, Yang Ling1   

  1. 1. School of Automation, Guangdong University of Technology, Guangzhou 510006, China;
    2. Jiangmen Power Supply Bureau, Guangdong Power Grid Corporation Limited, Jiangmen 529000, China
  • Received:2024-07-12 Online:2024-09-25 Published:2024-10-08

Abstract: With the transformation of the national energy structure and the implementation of the “dual-carbon” strategy, large-scale wind power continues to be connected to the power system, which brings problems such as interactive resonance and converter drive stability to the system. By studying the influence of the control parameters of the machine-side converter and the outer ring of the grid-side converter control on the stability of doubly-fed asynchronous wind turbines, it is found that the parameter stabilization zones of the outer ring of the machine-side converter control are located in the lower left plane, and that the parameter stabilization zones of the outer ring of the grid-side converter control are located in the lower right plane, and that there exists a band of parameter risk areas between the parameter stabilization zones and the instability zones. When increasing the proportional and integral coefficients of the grid-side converter controllers, the system damping will be enhanced, but in a certain interval, a strong interaction and thus internal resonance will occur, leading to system destabilization. For the strong interaction between the controllers of the grid-side converter, Particle Swarm Optimization (PSO) is introduced to optimize the parameters of the PI controllers of the grid-side converter, and the optimization shortens the DC voltage recovery speed by half a cycle and reduces the overshooting amount by 40%.

Key words: doubly fed induction generator, modal interaction, internal resonance, control parameters, parameter optimization

CLC Number: 

  • TM712
[1] 谢小荣, 贺静波, 毛航银, 等. “双高”电力系统稳定性的新问题及分类探讨[J]. 中国电机工程学报, 2021, 41(2): 461-474.
XIE X R, HE J B, MAO H Y, et al. New issues and classification of power system stability with high shares of renewables and power electronics[J]. Proceedings of the CSEE, 2021, 41(2): 461-474.
[2] 高本锋, 刘晋, 李忍, 等. 风电机组的次同步控制相互作用研究综述[J]. 电工技术学报, 2015, 30(16): 154-161.
GAO B F, LIU J, LI R, et al. Studies of sub-synchronous control interaction in wind turbine generators[J]. Transactions of China Electrotechnical Society, 2015, 30(16): 154-161.
[3] 王伟胜, 张冲, 何国庆, 等. 大规模风电场并网系统次同步振荡研究综述[J]. 电网技术, 2017, 41(4): 1050-1060.
WANG W S, ZHANG C, HE G Q, et al. Overview of research on subsynchronous oscillations in large-scale wind farm integrated system[J]. Power System Technology, 2017, 41(4): 1050-1060.
[4] 陈晨, 杜文娟, 王海风. 风电场接入引发电力系统次同步振荡机理综述[J]. 南方电网技术, 2018, 12(1): 84-93.
CHEN C, DU W J, WANG H F. Review on mechanism of sub-synchronous oscillations caused by grid-connected wind farms in power systems[J]. Southern Power System Technology, 2018, 12(1): 84-93.
[5] VARMA R K, MOHARANA A. SSR in Double-cage induction generator-based wind farm connected to series-compensated transmission line[J]. IEEE Transactions on Power Systems, 2013, 28(3): 2573-2583.
[6] 王亮, 谢小荣, 姜齐荣, 等. 大规模双馈风电场次同步谐振的分析与抑制[J]. 电力系统自动化, 2014, 38(22): 26-31.
WANG L, XIE X R, JIANG Q R, et al. Analysis and mitigation of SSR problems in large-scale wind farms with doubly-fed wind turbines[J]. Automation of Electric Power Systems, 2014, 38(22): 26-31.
[7] 吕敬, 蔡旭, 张占奎, 等. 海上风电场经MMC-HVDC并网的阻抗建模及稳定性分析[J]. 中国电机工程学报, 2016, 36(14): 3771-3780.
LYU J, CAI X, ZHANG Z K, et al. Impedance modeling and stability analysis of MMC-based HVDC for offshore wind farms[J]. Proceedings of the CSEE, 2016, 36(14): 3771-3780.
[8] 栗然, 卢云, 刘会兰, 等. 双馈风电场经串补并网引起次同步振荡机理分析[J]. 电网技术, 2013, 37(11): 3073-3079.
LI R, LU Y, LIU H L, et al. Mechanism analysis on subsynchronous oscillation caused by grid-integration of doubly fed wind power generation system via series compensation[J]. Power System Technology, 2013, 37(11): 3073-3079.
[9] WANG L, XIE X, JIANG Q, et al. Investigation of SSR in practical DFIG-based wind farms connected to a series-compensated power system[J]. IEEE Transactions on Power Systems, 2015, 30(5): 2772-2779.
[10] 胡应宏, 邓春, 谢小荣, 等. 双馈风机–串补输电系统次同步谐振的附加阻尼控制[J]. 电网技术, 2016, 40(4): 1169-1173.
HU Y H, DENG C, XIE X R, et al. Additional damping control of DFIG series compensated transmission system under sub-synchronous resonance[J]. Power System Technology, 2016, 40(4): 1169-1173.
[11] OSTADI A, YAZDANI A, VARMA R K. Modeling and stability analysis of a DFIG-based wind-power generator interfaced with a series-compensated line[J]. IEEE Transactions on Power Delivery, 2009, 24(3): 1504-1514.
[12] IRWIN G D, JINDAL A K, ISAACS A L. Sub-synchronous control interactions between type 3 wind turbines and series compensated AC transmission systems[C]//2011 IEEE Power and Energy Society General Meeting. Detroit, MI: IEEE, 2011: 1-6.
[13] DU W, CHEN C, WANG H. Subsynchronous interactions induced by DFIGs in power systems without series compensated lines[J]. IEEE Transactions on Sustainable Energy, 2018, 9(3): 1275-1284.
[14] DU W, FU Q, WANG H, et al. Concept of modal repulsion for examining the subsynchronous oscillations caused by wind farms in power systems[J]. IEEE Transactions on Power Systems, 2019, 34(1): 518-526.
[15] 熊浩清, 何鹏飞, 孙冉, 等. 双馈风电场无串补并网振荡场景及关键影响因素研究[J]. 高电压技术, 2024, 50(2): 660-672.
XIONG H Q, HE P F, SUN R, et al. Oscillation scenarios of grid integrated wind farm with DFIGs without series compensation and effects of key factors[J]. High Voltage Engineering, 2024, 50(2): 660-672.
[16] LUO J, TONG N, BU S, et al. Internal modal resonance analysis for full converter-based wind generation using analytical inertia model[J]. IEEE Transactions on Power Systems, 2024, 39(2): 3509-3522.
[17] LUO J, BU S, ZHU J, et al. Modal shift evaluation and optimization for resonance mechanism investigation and mitigation of power systems integrated with FCWG[J]. IEEE Transactions on Power Systems, 2020, 35(5): 4046-4055.
[18] LUO J, TENG F, BU S, et al. Converter-driven stability constrained unit commitment considering dynamic interactions of wind generation[J]. International Journal of Electrical Power & Energy Systems, 2023, 144: 108614
[19] LUO J, BU S, TENG F. An optimal modal coordination strategy based on modal superposition theory to mitigate low frequency oscillation in FCWG penetrated power systems[J]. International Journal of Electrical Power & Energy Systems, 2020, 120: 105975
[20] LUO J, BU S, ZHU J. A novel PMU-based adaptive coordination strategy to mitigate modal resonance between full converter-based wind generation and grids[J]. IEEE Journal of Emerging and Selected Topics in Power Electronics, 2021, 9(6): 7173-7182.
[21] LUO J, BU S, CHUNG C Y. Design and comparison of auxiliary resonance controllers for mitigating modal resonance of power systems integrated with wind generation[J]. IEEE Transactions on Power Systems, 2021, 36(4): 3372-3383
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