Optimization and operation strategy for energy storage configurations in high-proportion clean energy systems considering both supply reliability and energy utilization

doi:10.19799/j.cnki.2095-4239.2024.1089

Abstract

Abstract:

In weak-export grids with a high proportion of clean energy, the lack of sufficient outbound transmission capacity and limited flexible, adjustable resources significantly exacerbates the curtailment of wind and solar power during peak renewable generation periods. Additionally, the high penetration of clean energy further reduces the operating range of traditional synchronous generators, weakening grid regulation capabilities and increasing the risks to load supply reliability. These conditions intensify the interconnected challenges of renewable energy curtailment and load power shortages, making the conflict more complex and severe. Electrochemical energy storage emerges as a key solution for smoothing renewable energy fluctuations and addressing supply-demand imbalances. It plays a critical role in ensuring the safe, stable, and flexible operation of power grids. This paper proposes an optimized energy storage configuration and operational strategy designed to balance both load supply reliability with renewable energy utilization. First, this study focuses on clean energy systems with high renewable penetration, identifying two critical requirements: ensuring reliable load supply and maximizing renewable energy utilization. Based on these objectives, three risk assessment indices are established to evaluate grid balance, clean energy utilization, and load supply reliability. Second, leveraging the proposed risk assessment framework, objective functions, and constraints are formulated to address both load supply reliability and renewable energy utilization. A bilevel optimization model is developed. The upper-level model determines the energy storage planning and configuration, while the lower-level model optimizes the operational strategy of the energy storage system. This approach integrates the dual objectives of ensuring supply reliability and promoting renewable energy utilization. Finally, the feasibility and effectiveness of the proposed strategy are validated through four case studies conducted on a high-proportion clean energy grid in Western China. Results show that compared to strategies focusing solely on renewable energy accommodation or power supply assurance, the proposed strategy significantly improves both power supply reliability and renewable energy utilization rates. Additionally, it effectively reduces operational costs and enhances the economic efficiency of the power grid.

Key words: energy storage configuration, optimized operation, load supply reliability, clean energy absorption, mixed integer linear programming

CLC Number:

TM 732

Yunyao CHEN, Yuzhou CHEN, Yanglamu JIA, Qingyuan ZHANG, Zixuan ZHENG, Shan JIANG, Jie LI, Siyuan XIONG. Optimization and operation strategy for energy storage configurations in high-proportion clean energy systems considering both supply reliability and energy utilization[J]. Energy Storage Science and Technology, 2025, 14(5): 2043-2056.

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一级指标	二级指标	三级指标
电网平衡风险	备用不足	正备用不足、负备用不足
清洁能源消纳风险	弃光、弃风	弃光量、弃风量
负荷保供风险	限电、断电	缺电量、缺电时长、缺电频率

参数	火力发电机组	水力发电机组	光伏出力	联络线
额定功率/MW	281.2	3031	2537	120
调节区间/MW	[0.5P(t),P(t)]	[0,P(t)]	[0,P(t)]	[0,P(t)]

算例二	节点	2		42		49		51
	额定功率/MW	45.9		112.3		87.1		120
	额定容量/MWh	163.8		449.2		348.3		480
算例三	节点	1	2	5	6	8		9
	额定功率/MW	120	120	10.8	52.4	12.8		10
	额定容量/MWh	480	480	43.1	209.7	51.1		40
算例四	节点	1	2	3	5	9	42	50	51
	额定功率/MW	120	120	23.6	46.8	10	108.1	87.1	120
	额定容量/MWh	480	480	94.4	187.1	40	432.4	348.2	480

算例	火电成本	水电成本	光伏成本	储能成本	联络线成本	弃光惩罚	缺负荷惩罚	总成本/万元
算例一	2.19	1.86	7.7	0	1.11	1.85	1.86	1658
算例二	2.19	1.83	7.6	1.71	0.84	0.44	1.39	1600
算例三	2.2	1.97	6.51	1.54	0.76	1.74	0.46	1531
算例四	2.19	1.93	7.6	3.01	1.85	0.43	0.46	1647

项目	消除不平衡功率的变化量/MW	总成本/万元	边际成本/(元/MW)
算例一	19726	1658	840.5
算例二	22406	1600	714.1
算例三	21241	1531	720.8
算例四	23401	1647	703.8