| 1,974 | 19 | 167 |
| 下载次数 | 被引频次 | 阅读次数 |
由于氢能具有单位质量热值高、用途广泛和可再生等优点,越来越多科研工作者对氢能产生了兴趣。文章对目前主流制氢路线做了对比,发现电解水制氢与风电耦合具有很大的优势。分析孤网、并网和非并网三种运行模式下的技术可行性。结论表明"孤网运行:风力发电+电解水制氢设备+储能设施"的耦合模式最具有发展潜力,为将来开展大规模风电耦合制氢提供可选的技术思路。
Abstract:More and more researchers are interested in hydrogen energy because of its high calorific value per unit mass,wide use and renewable and other advantages.The paper compares the main hydrogen production route and finds that the coupling of electrolysis water to hydrogen production and wind power has great advantages.This paper analyzes the technical feasibility of three operating modes:isolated network,connected network and non-connected network.The conclusion shows that the coupling mode of "isolated network operation:wind power generation + electrolytic water hydrogen production equipment + energy storage facilities" has the greatest development potential,which provides an alternative technical idea for large-scale wind power coupling hydrogen production in the future.
[1]贾光.日本氢能技术发展现状[J].安全健康环境,2019(19):1-4.
[2]吴善略,张丽娟.世界主要国家氢能发展规划综述[J].科技中国,2019(7):91-98.
[3]S.Carr,G.C.Premier,A.J.Guwy,等.Hydrogen storage and demand to increase wind power onto electricity distribution networks[J].International Journal of Hydrogen Energy,2014,39(19):10195-10207.
[4]国家能源局.全国能源工作2019年终综述[R].(2019-12-16)[2020-03-03]http://www.nea.gov.cn/2019-12/16/c_138635653.htm.
[5]郝伟峰,贾丹瑶,李红军.基于可再生能源水电解制氢技术发展概述[J].价值工程,2018,37(29):236-237.
[6]高慧,杨艳,赵旭,等.国内外氢能产业发展现状与思考[J].国际石油经济,2019,27(4):9-18.
[7]王茂辉,吴震.浅谈电解水制氢的原理及发展[J].汽车实用技术,2019,(15):237-239.
[8]何仲辉,李林,马芳平,等.推动富余水电制氢促进绿色低碳发展[J].专家建议,2019,41(7):5-11.
[9]吕泽伟,韩敏芳.光伏、光热联合SOC 制氢、发电系统设计[J].储能科学与技术,2017,6(2):276-281.
[10]R.Loisel,L.Baranger,N.Chemouri,等.Economic evaluation of hybrid off-shore wind power and hydrogen storage system[J].International Journal of Hydrogen Energy,2015,40(21):6727-6739.
[11]孙鹤旭,李争,陈爱兵,等.风电制氢技术现状及发展趋势[J].电工技术学报,2019,34(19):4072-4085.
[12]时绿丽,高虎,王红芳.风电制氢经济性分析[J].可再生能源,2015,37(2):11-15.
[13]L.Aiche-Hamane,M.Belhamel,B.Benyoucef,等.Feasibility study of hydrogen production from wind power in the region of Ghardaia[J].International Journal of Hydrogen Energy,2009,34(11):4947-4952.
[14]宁楠.水电解制氢装置宽功率波动适应性研究[J].舰船科学技术,2017,39(11):134-138.
[15]郑熙东.基于风电波动平抑的储能技术与控制策略研究[J].质量管理,2019,(18):133-134.
基本信息:
DOI:10.13500/j.dlkcsj.issn1671-9913.2021.02.013
中图分类号:TM614;TQ116.21
引用信息:
[1]田江南,罗扬.风电耦合电解水制氢技术研究[J].电力勘测设计,2021,No.150(02):63-67.DOI:10.13500/j.dlkcsj.issn1671-9913.2021.02.013.
基金信息: