Hybrid stochastic-robust planning of an electricity-hydrogen integrated energy storage station considering multi-timescale uncertainty

doi:10.19799/j.cnki.2095-4239.2022.0726

Abstract

Abstract:

Considering the impact of long-term uncertainty of supply and load on the robustness of the planning results of an electricity-hydrogen integrated energy storage station, a capacity planning method considering the uncertainty of multiple time scales is proposed. First, the structure of the hybrid electricity-hydrogen system is constructed, and the main operating modes of the energy storage station are designed. Second, taking into account the temporal correlation of wind, photovoltaic, electricity and hydrogen, the typical temporal scenarios of both source and load sides considering short-term uncertainty are extracted. Also, the capacity planning model of the energy storage station based on multi-scenario stochastic optimization is established to minimize the comprehensive annual cost. Then, further considering the long-term uncertainty, the planning model is improved based on the information gap decision theory. A stochastic robust hybrid planning method for energy storage stations is proposed considering long- and short-term uncertainties. Finally, the simulation is performed based on historical data of wind and photovoltaic power stations. Sensitivity analyses of critical factors, such as the energy shortage penalty cost coefficient and hydrogen price, are performed. The simulation results demonstrate that the proposed method can plan reasonably the capacity of the electric-hydrogen integrated energy storage station and improve the risk aversion ability of the hybrid electric-hydrogen system.

Key words: electric-hydrogen integrated energy storage station, capacity planning, multi-timescale, uncertainty, stochastic-robust mixed planning

CLC Number:

TM 911

Luan NI, Yufei WANG, Hua XUE, Aiqing YU. Hybrid stochastic-robust planning of an electricity-hydrogen integrated energy storage station considering multi-timescale uncertainty[J]. Energy Storage Science and Technology, 2023, 12(3): 846-856.

Figures/Tables 12

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类型	高压气态储氢	低温液态储氢	固态储氢
工作温度/℃	-40～85	<-253	-40～60
寿命/a	15～20	<10	15～30
储氢密度(质量分数)/%	1～3	>10	1～18
成本/(元/kg)	4000～7000	11000～15000	8000～11000

参数	数值
固态合金储氢罐单位成本/(元/kg)	8000
电解槽单位成本/(万元/MW)	200
燃料电池单位成本/(万元/MW)	400
电解槽效率/%	60
燃料电池效率/%	65
运行维护成本系数	0.04
弃风弃光成本/(元/MWh)	360
失电惩罚成本/(元/MWh)	2000
削氢惩罚成本/(元/kg)	150

规划模型	电解槽 /MW	燃料电池 /MW	固态储氢罐 /kg	年综合成本 /万元
随机规划	34.2	32.3	3943	3737.24
随机-鲁棒规划	36.5	36.7	4100	4110.96

成本	两阶段随机优化	常规IGDT	SP-IGDT
年综合成本	3936.41	4346.77	4110.96
建设成本	24212.0	26709.6	25260.0
弃风弃光成本	114.23	51.21	55.35
失电惩罚成本	17.51	11.64	12.49
削氢惩罚成本	15.26	10.01	10.77

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