风电-光伏-抽蓄-电制氢多主体能源系统增益的合作博弈分配策略
收稿日期: 2022-12-26
修回日期: 2023-03-27
录用日期: 2023-03-31
网络出版日期: 2023-04-11
基金资助
国家自然科学基金(U1965104);国家重点研发计划(2019YFE0105200)
A Cooperative Game Allocation Strategy for Wind-Solar-Pumped Storage-Hydrogen Multi-Stakeholder Energy System
Received date: 2022-12-26
Revised date: 2023-03-27
Accepted date: 2023-03-31
Online published: 2023-04-11
根据清洁能源示范基地的建设需求,提出基于合作博弈论的风电-光伏-抽蓄-电制氢多主体能源系统联合优化运行的增益分配策略.为兼顾系统运行安全性,构建上网出力互补性评价指标.风电、光伏、抽蓄、电制氢利益主体通过内部电量交易进行合作,以系统运行收益最大为优化目标构建联合优化调度模型.根据调度结果,应用合作博弈论中的最大最小成本法分配系统合作增量收益.利用风电-光伏-抽蓄-电制氢清洁能源示范基地12利益主体系统算例进行仿真验证,结果表明联合优化运行可实现各利益主体自身收益正增长,抽蓄库容、上网电价以及运行安全性需求会影响系统的合作增量收益.
关键词: 风电-光伏-抽蓄-电制氢多主体能源系统; 短期调度; 增益分配策略; 合作博弈论; 最大最小成本法
段佳南 , 谢俊 , 邢单玺 . 风电-光伏-抽蓄-电制氢多主体能源系统增益的合作博弈分配策略[J]. 上海交通大学学报, 2024 , 58(6) : 872 -880 . DOI: 10.16183/j.cnki.jsjtu.2022.531
To meet the construction demand of clean energy demonstration bases, a gain allocation strategy for the joint optimization operation of wind-solar-pumped storage-hydrogen multi-stakeholder energy system based on the cooperative game theory is proposed. In order to take into consideration the security of system operation, evaluation indicators for the complementarity of on-grid output are constructed. The stakeholders of wind, solar, pumped storage, and power-to-hydrogen cooperate through the internal electricity transaction to construct a joint scheduling model with the optimization goal of maximizing the operation benefits. Then, the minimum cost remaining saving (MCRS) method in the cooperative game theory is applied to allocate the synergistic benefits based on the scheduling results. The simulation results of a 12-stakeholder wind-solar-pumped storage-hydrogen clean energy demonstration base show that each stakeholder can derive positive gains through joint operation, and the reservoir capacity of pumped storage station, on-grid price and operation security demand will affect the cooperative synergistic benefits of the system.
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