Abstract:To explore the impact of wind power station grid-connection sites on the resilience of power networks, this paper introduces a new analytical framework for assessing the resilience of wind power network. By integrating the network's structural and functional models and applying relevant resilience assessment metrics, we propose a Q-Learning-based grid-connection strategy to identify the optimal grid-connection locations for wind power station. We validate this strategy using the IEEE 118 power grid model, which incorporates wind power grid-connection. Our research shows that the Q-Learning-based grid-connection strategy surpasses traditional heuristic methods and genetic algorithms in reducing operational costs and the risk of overload, highlighting the crucial role of strategic grid-connection in strengthening the network's resilience.
李伟莎, 王淑良, 宋博. 基于强化学习风电并网策略下的韧性分析[J]. 复杂系统与复杂性科学, 2025, 22(2): 128-134.
LI Weisha, WANG Shuliang, SONG Bo. Reinforcement Learning-based Resilience Analysis of Wind Power Grid Under Integration Strategy[J]. Complex Systems and Complexity Science, 2025, 22(2): 128-134.
[1] LIU K, CHEN W, CHEN G, et al. Application and analysis of hydraulic wind power generation technology[J]. Energy Strategy Reviews, 2023, 48: 101117. [2] 郭明健, 高岩. 基于复杂网络理论的电力网络抗毁性分析[J]. 复杂系统与复杂性科学, 2023, 19(4): 16. GUO M J, GAO Y. Invulnerability analysis of power network based on complex network[J]. Complex Systems and Complexity Science, 2023, 19(4): 16. [3] PANI S R, SAMAL R K. Evaluation of power grid vulnerability indices accounting for wind power uncertainty[J]. Sustainable Energy, Grids and Networks, 2024, 38: 101354. [4] ZHANG H, ZHANG S, CHENG H, et al. Boosting the power grid resilience under typhoon disasters by coordinated scheduling of wind energy and conventional generators[J]. Renewable Energy, 2022, 200: 303319. [5] LIANG Y, LIN S, FENG X, et al. Optimal resilience enhancement dispatch of a power system with multiple offshore wind farms considering uncertain typhoon parameters[J]. International Journal of Electrical Power & Energy Systems, 2023, 153: 109337. [6] 陈思谕, 邹艳丽, 王瑞瑞, 等. 电网输电线路耦合强度分配策略研究[J]. 复杂系统与复杂性科学, 2018, 15(2): 4553. CHEN S Y, ZOU Y L, WANG R R, et al. On the coupling strength distribution strategy of power transmission lines[J]. 2018, 15(2): 4553. [7] MAYER M J, BIRÓ B, SZÜCS B, et al. Probabilistic modeling of future electricity systems with high renewable energy penetration using machine learning[J]. Applied Energy, 2023, 336: 120801. [8] MEMON Z A, TRINCHERO R, MANFREDI P, et al. Machine Learning for the Uncertainty Quantification of Power Networks[J]. IEEE Letters on Electromagnetic Compatibility Practice and Applications, 2020, 2(4): 138141. [9] LI Q, ZHANG X, GUO J, et al. Integrating reinforcement learning and optimal power dispatch to enhance power grid resilience[J]. IEEE Transactions on Circuits and Systems II: Express Briefs, 2021, 69(3): 14021406. [10] HOSSEINI M M, PARVANIA M. Resilient operation of distribution grids using deep reinforcement learning[J]. IEEE Transactions on Industrial Informatics, 2021, 18(3): 21002109. [11] ALAVI S M S, MALEKI A, NOROOZIAN A, et al. Simultaneous optimal site selection and sizing of a grid-independent hybrid wind/hydrogen system using a hybrid optimization method based on ELECTRE: A case study in Iran[J]. International Journal of Hydrogen Energy, 2024, 55: 970983. [12] CACEOĞGLU E, YILDIZ H K, OĞGUZ E, et al. Offshore wind power plant site selection using Analytical Hierarchy Process for Northwest Turkey[J]. Ocean Engineering, 2022, 252: 111178. [13] UMUNNAKWE A, HUANG H, OIKONOMOU K, et al. Quantitative analysis of power systems resilience: Standardization, categorizations, and challenges[J]. Renewable and Sustainable Energy Reviews, 2021, 149: 111252. [14] AHMADIAN N, LIM G J, CHO J, et al. A quantitative approach for assessment and improvement of network resilience[J]. Reliability Engineering & System Safety, 2020, 200: 106977. [15] JIANG J, XIA Y, XU S, et al. An asymmetric interdependent networks model for cyber-physical systems[J]. Chaos: An Interdisciplinary Journal of Nonlinear Science, 2020, 30(5): 053135. [16] ZHANG C, LIU Q, ZHOU B, et al. A central limit theorem-based method for dc and ac power flow analysis under interval uncertainty of renewable power generation[J]. IEEE Transactions on Sustainable Energy, 2023, 14(1): 563575.
