基于经济分析的大规模光伏发电系统与氢气生产和储存的产能优化

Sheng Zhang, Bo Li, Dongjie Xu and Jinyang Zheng
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引用次数: 0

摘要

事实证明,可再生能源系统与氢气储存相结合,是减少输出功率变化、满足稳定氢气供应需求的合适方法。然而,利用可再生能源电解水制氢的成本过高,限制了其应用,而且电解槽和气态储氢罐的容量配置也受到过度依赖工程经验的影响,导致发电侧和氢气需求侧的不平衡。本研究提出了一个 300 兆瓦的光伏发电系统,以满足合成氨厂的原料需求,即每小时约 1000 千克氢气。我们提出了一个简化的数学模型,包括一个电解槽和一个氢气罐,以获得最佳产能配置。选择氢的平准化成本(LCOH)作为优化函数,并采用粒子群优化算法来获得最佳结果。仿真结果表明,最佳产能配置为电解槽 176.36 MW,氢气罐 14644.2 Nm3,LCOH 为 30.31 元/kg。与经验模型相比,基于优化模型的 LCOH 比经验模型低 8.87%,表明优化模型具有更好的经济效益。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Capacity optimization of a large-scale photovoltaic power generation system coupled with hydrogen production and storage based on economic analysis
The renewable energy system coupled with hydrogen storage has proven to be a suitable method to reduce the variability of output power and meet stable hydrogen supply demand. However, the excessive cost of hydrogen through water electrolysis using renewable energy restricts its application, and the capacity configuration of electrolyzers and gaseous hydrogen storage tanks is affected by the immoderate reliance on engineering experience, leading to the unbalance of generation side and hydrogen demand side. In this study, a 300 MW photovoltaic power generation system has been proposed to fit the raw material demand of a synthetic ammonia plant, i.e., around 1000 kg/h hydrogen. A simplified mathematical model including an electrolyzer and a hydrogen tank is proposed to get the best capacity configuration. The levelized cost of hydrogen (LCOH) is chosen as an optimization function, and a particle swarm optimization algorithm is adopted to get the optimal results. The simulation results indicate that the optimal capacity configuration is 176.36 MW for the electrolyzer and 14644.2 Nm3 for the hydrogen tank, and the LCOH is 30.31 Yuan/kg. Compared with the empirical model, the LCOH based on the optimization model is 8.87% lower than that of the empirical model, indicating better economic benefits of the optimization model.
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