Sizing electrolyzer capacity in conjunction with an off-grid photovoltaic system for the highest hydrogen production

Q2 Engineering Energy Harvesting and Systems Pub Date : 2023-01-11 DOI:10.1515/ehs-2022-0107
Q. Hassan, Majid K. Abbas, V. S. Tabar, S. Tohidi, Imad Saeed Abdulrahman, H. M. Salman
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引用次数: 11

Abstract

Abstract The electrolysis of renewable energy to produce hydrogen has become a strategy for supporting a decarbonized economy. However, it is typically not cost-effective compared to conventional carbon-emitting methods. Due to the predicted intermediate of low-and zero-marginal-cost renewable energy sources, the ability of electrolysis to connect with electricity pricing offers a novel way to cost reduction. Moreover, renewables, particularly photovoltaics, have a deflationary effect on the value of the grid when they are deployed. This study investigates solar electrolysis configurations employing photovoltaic cells to feed a proton exchange membrane water electrolyzer for hydrogen production. Using experimental meteorological data at 1-min precision, the system has been evaluated in Baghdad, the capital of Iraq. Positioned at the yearly optimum tilt angle for the selected site, the solar array is rated at 12 kWp. Temperature effects on solar module energy loss are taken into account. Several electrolyzers with capacities ranging from 2 to 14 kW in terms of hydrogen production were examined to determine the efficacy and efficiency of renewable sources. MATLAB was utilized for the simulation procedure, with a 2021–2035 project lifespan in mind. The results suggest that a variety of potentially cost-competitive options exist for systems with market configurations that closely approximate wholesale renewable hydrogen. At 4313 h of operation per year, the planned photovoltaic array generated 18,892 kWh of energy. The achieved hydrogen production cost ranges between $5.39/kg and $3.23/kg, with an ideal electrolyzer capacity of 8 kW matching a 12 kWp photovoltaic array capable of producing 450 kg/year of hydrogen at a cost of $3.23/kg.
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与离网光伏系统一起调整电解槽容量,以实现最高的氢气产量
可再生能源电解制氢已成为支持脱碳经济的一种战略。然而,与传统的碳排放方法相比,它通常不具有成本效益。由于低边际成本和零边际成本的可再生能源的预测中间,电解与电价相结合的能力为降低成本提供了一种新的途径。此外,可再生能源,特别是光伏发电,在部署时对电网的价值有通货紧缩效应。本研究研究了利用光伏电池为质子交换膜水电解槽提供氢气的太阳能电解配置。利用1分钟精度的试验气象数据,在伊拉克首都巴格达对该系统进行了评估。定位在选定地点的年度最佳倾斜角度,太阳能电池阵列的额定功率为12千瓦时。考虑了温度对太阳能组件能量损失的影响。研究了几个容量从2到14千瓦的电解槽,以确定可再生能源的功效和效率。仿真过程使用MATLAB,考虑到2021-2035年的项目寿命。结果表明,对于市场配置接近批发可再生氢的系统,存在各种潜在的成本竞争选择。每年运行4313小时,计划的光伏阵列产生18,892千瓦时的能量。实现的氢气生产成本在5.39美元/公斤到3.23美元/公斤之间,理想的电解槽容量为8千瓦,与12千瓦的光伏阵列相匹配,能够以3.23美元/公斤的成本生产450公斤/年的氢气。
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来源期刊
Energy Harvesting and Systems
Energy Harvesting and Systems Energy-Energy Engineering and Power Technology
CiteScore
2.00
自引率
0.00%
发文量
31
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