本文对太阳能高温电解水蒸气制氢系统进行了设计.该系统以太阳能为唯一的一次能源,采用太阳能分频技术,提供高温电解水蒸气制氢所需的电能和热能.此外,利用余热回收器回收电解产物的余热.热力学分析表明:(1)系统制氢效率可达34.8%;(2)太阳能聚光-分频热电联产装置是系统能量和(火用)损失最大的环节.提高电解温度和降低操作电压可减小电解环节的(火用)损失.
In this paper,a new solar hydrogen production system with high temperature steam electrolysis(HTSE)is designed.The system utilizes solar energy as the only prime energy source.Solar concentrating and spectral beam splitting technologies are employed to provide electricity and thermal energy for high temperature steam electrolysis.Additionally,the heat of electrolysis products is recuperated by heat exchanger.Thermodynamic analysis results show that (1) the system hydrogen production efficiency can reach 34.8%,and (2) the solar concentrating and spectral beam splitting device is the principal thermodynamics loss source.It is found that an increase in temperature and decrease in operating voltage can reduce the exergy destruction in the electrolysis cell.
参考文献
[1] | 毛宗强.氢能-21世纪的绿色能源[M].北京:化学工业出版社,2005:41-42. |
[2] | Arashi H;Naito H;Miura H .Hydrogen Production from High-Temperature Steam Electrolysis Using Solar Energy[J].International Journal of Hydrogen Energy,1991,16(09):603-608. |
[3] | Rachid Miri;Sofiane Mraoui .Electrolyte process of hydrogen production by solar energy[J].Desalination: The International Journal on the Science and Technology of Desalting and Water Purification,2007(1/3):69-77. |
[4] | J. Padin;T. N. Veziroglu;A. Shahin .Hybrid solar high-temperature hydrogen production system[J].International journal of hydrogen energy,2000(4):295-317. |
[5] | Stuart Licht .Solar water splitting to generate hydrogen fuel—a photothermal electrochemical analysis[J].International journal of hydrogen energy,2005(5):459-470. |
[6] | Rosen M A .Energy and Exergy Analysis of Electrolytic Hydrogen Production[J].International Journal of Hydrogen Energy,1995,20(07):547-553. |
[7] | Meng Ni;Michael K.H. Leung;Dennis Y.C. Leung .Energy and exergy analysis of hydrogen production by solid oxide steam electrolyzer plant[J].International journal of hydrogen energy,2007(18):4648-4660. |
[8] | Liu Mingyi;Yu Bo;Xu Jingming;Chen Jing .Thermodynamic analysis of the efficiency of high-temperature steam electrolysis system for hydrogen production[J].Journal of Power Sources,2008(2):493-499. |
[9] | Youngjoon Shin;Wonseok Park;Jonghwa Chang;Jongkuen Park .Evaluation of the high temperature electrolysis of steam to produce hydrogen[J].International journal of hydrogen energy,2007(10/11):1486-1491. |
[10] | Lasich J B;Cleeve A;Kaila N.Close Packed Cell Arrays for Dish Concentrotors[A].Hawwi,1994:1938-1941. |
[11] | Akiba Segal;Michael Epstein;Amnon Yogev .Hybrid concentrated photovoltaic and thermal power conversion at different spectral bands[J].Solar Energy,2004(5):591-601. |
[12] | Richard Petela .Exergy of undiluted thermal radiation[J].Solar Energy,2003(6):469-488. |
[13] | G McKellar M;McKellar M;A Harvego E.A Process Model for the Production of Hydrogen Using High Temperature Electrolysis[A].Florida,USA,2006 |
[14] | Martin A G .Solar Cell Efficiency Tables[J].Progress in Photovoltaics: Research and Applications,2007,15:425-430. |
[15] | Nelson A. Kelly;Thomas L. Gibson;David B. Ouwerkerk .A solar-powered, high-efficiency hydrogen fueling system using high-pressure electrolysis of water: Design and initial results[J].International journal of hydrogen energy,2008(11):2747-2764. |
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