A novel efficient solar-gas assisted hydrogen-electricity cogeneration system based on photo-thermal energy cascade conversion: modeling and performance analysis

IF 9 1区工程技术 Q1 ENERGY & FUELS

Renewable Energy Pub Date : 2025-06-10 DOI:10.1016/j.renene.2025.123698

Zihui Xu, Shiquan Shan, Biao Zhang, Zhihua Wang, Zhijun Zhou, Kefa Cen

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引用次数: 0

Abstract

In this study, an efficient solar-gas assisted hydrogen-electricity cogeneration system is proposed. It constructs from thermos-photovoltaics (TPV), supercritical carbon dioxide Brayton cycle (SCO₂-BC) and Cu-Cl chemical cycle according to photo-thermal energy cascade conversion. A system thermophysical analysis model is established and the effect of parameters on the electricity/hydrogen production efficiency and irreversible loss are investigated based on second law. The design concept is proposed that using by-product oxygen from hydrogen generation to assist combustion for system stable running. Besides, the superiority of the novel system is discussed by comparing with different configurations. The results show that the concentration ratio, TPV area, and turbine inlet temperature can be used to adjust the ratio of electricity/hydrogen production. In actual applications, the system can keep continuous and efficient by appropriately increasing the oxygen ratio when solar energy input is insufficient. The second law analysis shows the exergy destruction factor of TPV module is the largest (about 30 %), followed by receiver module (11.68 %). The system energy efficiency can reach 61.26 % for electricity/hydrogen cogeneration, and the equivalent electrical efficiency can reach 52.98 %, which has obvious advantages compared with other different system configurations. This work provides guidance for the development of solar high-efficiency hydrogen/electricity cogeneration technology.

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基于光热串级转换的新型高效太阳能-气体辅助氢电热电联产系统：建模与性能分析

在本研究中，提出了一种高效的太阳能-气体辅助氢电热电联产系统。它由热-光电（TPV）、超临界二氧化碳布雷顿循环（SCO2-BC）和Cu-Cl化学循环组成，根据光热级联转换。建立了系统热物理分析模型，根据第二定律研究了系统参数对制氢电效率和不可逆损失的影响。提出了利用制氢副产物氧辅助燃烧的设计理念，保证了系统的稳定运行。此外，通过对不同配置的比较，讨论了新系统的优越性。结果表明，浓度比、TPV面积和涡轮进口温度可以调节产氢比。在实际应用中，在太阳能输入不足的情况下，通过适当提高氧气比，系统可以保持连续高效。第二定律分析显示，TPV组件的火用破坏系数最大（约30%），其次是接收模块（11.68%）。电/氢热电联产系统能效可达61.26%，等效电效率可达52.98%，与其他不同系统配置相比优势明显。该工作对太阳能高效氢电热电联产技术的发展具有指导意义。

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来源期刊

Renewable Energy 工程技术-能源与燃料

CiteScore

18.40

自引率

9.20%

发文量

1955

审稿时长

6.6 months

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