Optimization strategy for cooperative game operation of multi-microgrids based on the Nash bargaining model considering energy trading

被引：0

作者：

Tian H. ^{[1
]}

He S. ^{[1
,2
]}

Ai C. ^{[1
]}

Fan X. ^{[3
]}

Hu B. ^{[3
]}

Xu L. ^{[3
]}

机构：

[1] Key Laboratory of Renewable Energy Power Generation and Grid-connected Technology of Autonomous Region, Xinjiang University, Urumqi

[2] Engineering Research Center of Renewable Energy Power Generation and Grid-connected Control, Xinjiang University, Ministry of Education, Urumqi

[3] Xinjiang Institute of Engineering, Urumqi

来源：

Dianli Xitong Baohu yu Kongzhi/Power System Protection and Control | 2024年 / 52卷 / 06期

基金：

中国国家自然科学基金;

关键词：

cooperative games; energy trading; multi-microgrid systems; Nash bargaining;

D O I：

10.19783/j.cnki.pspc.231155

中图分类号：

学科分类号：

摘要：

In the context of energy trading, a cooperative game strategy based on the Nash bargaining model is proposed for the operation optimization problem in multi-microgrid cooperation, aiming to achieve cooperation among microgrids to maximize the overall benefits while considering energy trading and cost optimization. First, each microgrid is considered as a game participant, and a multi-microgrid cooperative game model based on the Nash bargaining theory is constructed to influence its energy costs and benefits by choosing strategies for energy trading and operation. Secondly, the alternating direction multiplier method (ADMM) is used to solve this multi-participant optimization problem by decomposing the original problem into sub-problems and introducing multiplier variables to achieve iterative solutions. Finally, in each iteration, each microgrid updates its energy trading and operation strategy based on its local information and uses the multiplier variables for information exchange and game coordination to achieve global consistency. The results show that this strategy can realize overall performance improvement in multi-microgrid cooperation, effectively promote the level of renewable energy consumption, balance the interests of each participant, and reduce the energy cost at the same time. © 2024 Power System Protection and Control Press. All rights reserved.

引用

页码：29 / 41

页数：12

共 27 条

[1] CHEN Houhe, HE Changhui, ZHANG Rufeng, Et al., Bi-level optimization of strategic energy management for industrial park microgrid participating in distribution market, Power System Technology, 47, 7, pp. 2671-2683, (2023)
[2] ZHONG Keifeng, XIE Shengli, XIE Kan, Et al., Cooperative P2P energy trading in active distribution networks: an MILP-based Nash bargaining solution, IEEE Transactions on Smart Grid, 12, 2, pp. 1264-1276, (2021)
[3] YAN Xiangwu, WANG Qing'ao, LU Junda, Et al., Microgrid energy scheduling with electric vehicles and flexible loads, Power System Protection and Control, 51, 17, pp. 69-79, (2023)
[4] HOU Hui, WANG Qing, XUE Mengya, Et al., Two-stage economic day-ahead dispatch of an islanded microgrid considering uncertainty and demand response, Power System Protection and Control, 50, 13, pp. 73-85, (2022)
[5] LIU Ren, LIU Yang, XU Lixiong, Et al., Multi-microgrid system collaborative optimization strategy considering distributed demand response, Electric Power Construction, 44, 5, pp. 72-83, (2023)
[6] ZHANG Cheng, KUANG Yu, LIU Jiajing, Et al., Two-stage optimal scheduling of a wind, photovoltaic, gas turbine, fuel cell and storage energy microgrid considering demand-side management, Power System Protection and Control, 50, 24, pp. 13-22, (2022)
[7] LIU Yingshu, CHEN Xi, LI Bin, Et al., State of art of the key technologies of multiple microgrids system, Power System Technology, 44, 10, pp. 3804-3820, (2020)
[8] LI Peng, WU Difan, LI Yuwei, Et al., Optimal dispatch of multi-microgrids integrated energy system based on integrated demand response and Stackelberg game, Proceedings of the CSEE, 41, 4, pp. 1307-1321, (2021)
[9] HUANG Kemeng, LIU Jichun, Optimal dispatch method of multi-microgrid alliance considering demand response & CHP, Smart Power, 49, 6, pp. 107-115, (2021)
[10] LI Ruirui, LI Qi, PU Yuchen, Et al., Optimal configuration of an electric-hydrogen hybrid energy storage multi-microgrid system considering power interaction constraints, Power System Protection and Control, 50, 14, pp. 53-64, (2022)

← 1 2 3 →