太阳能光伏/电解槽混合系统的氢气/氧气和热电生产评估

IF 6 Q1 ENGINEERING, MULTIDISCIPLINARY Results in Engineering Pub Date : 2024-09-20 DOI:10.1016/j.rineng.2024.102920
Armel Zambou Kenfack , Modeste Kameni Nematchoua , Venant Sorel Chara-Dackou , Elie Simo
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引用次数: 0

摘要

为了实现可持续的低碳能源未来,有必要开发创新的综合解决方案。然而,可再生能源发展的主要障碍之一是储存。有鉴于此,太阳能与制氢相结合的混合系统具有巨大潜力。本文重点评估了太阳能 PV/T(光伏-热能)系统与电解槽的结合,以实现氢气和热能的联合生产。仿真在 MATLAB 中进行。分析结果表明,在光伏/热供电的情况下,电能和热能的生产潜力估计分别为 179.6 W 和 551.9 W。通过评估水电解过程中所用能源的质量,旨在优化系统的深入研究使得分析某些运行参数的影响成为可能。在水流量为 5.7 ×10-3 m3/h、电流密度为 200 mA/ cm2 和电解槽温度为 60 °C 的条件下,氢气和氧气的月产量分别达到 4.85 m3 和 2.42 m3 的最大值。因此,最高能效为 57.8%。这项研究证明了氢气产量与电流密度之间的线性关系,在高密度情况下,电流密度会降低放能效能。
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Evaluation of the hydrogen/oxygen and thermoelectric production of a hybrid solar PV/T-electrolyzer system
In order to achieve a sustainable, low-carbon energy future, it is necessary to develop innovative and integrated solutions. However, one of the main obstacles to the advancement of renewable energy is storage. With this in mind, hybrid systems combining solar energy and hydrogen production have great potential. This article focuses on the evaluation of a solar PV/T (photovoltaic-thermal) system coupled with an electrolyser for the joint production of hydrogen and heat. Simulations are performed in MATLAB. The analysis reveals that with PV/T power supply, the production potential is estimated at 179.6 W and 551.9 W respectively for electrical and thermal power. An in-depth study aimed at optimizing the system by evaluating the quality of the energy used in the water electrolysis process makes it possible to analyze the effect of certain operating parameters. With a water flow of 5.7 ×103 m3/h, a current density of 200 mA/ cm2 and an electrolyzer temperature of 60 °C, the monthly production of hydrogen and oxygen reaches the maximum values of 4.85 m3 and 2.42 m3 respectively. This led to a maximum exergy efficiency of 57.8 %. This study demonstrates the linearity between hydrogen production and current density which at high density reduces exergy performance.
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来源期刊
Results in Engineering
Results in Engineering Engineering-Engineering (all)
CiteScore
5.80
自引率
34.00%
发文量
441
审稿时长
47 days
期刊最新文献
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