风光互补联合制氢系统在河北省不同地区的适用性分析
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摘要
环境问题的突发,加快了人们对新型能源探索的步伐。在介绍风光互补联合制氢系统的基础上,简要分析系统的发展现状和运行原理,并结合河北省的太阳能与风能资源,分析该系统在河北省不同地区的适用性。该系统在河北省不同地区具有不同的运行模式,可将其适用性划为三类。通过对该系统的分析,结合系统建设地点的气候环境得出结论 :合理地配置风力发电机、太阳能电池以及储能模块的装机容量才能更好地实现系统的适用性。
The sudden emergence of environmental problems has accelerated the pace of people's exploration of new energy sources. Based on the introduction of wind-solar hybrid hydrogen storage energy storage systems, the paper briefly analyzes on the development status and operating principles of the system, by combining with solar energy and wind energy resources in Hebei province, to analyze the suitability of the system in different regions of Hebei province. The system has different operating modes in different regions of Hebei province, and its applicability can be classified into three categories. Through the analysis on this system, combined with the climate environment of the system construction site, it is concluded that a reasonable allocation of the installed capacity of wind turbines, solar cells, and energy storage modules can better achieve the system's applicability.
The sudden emergence of environmental problems has accelerated the pace of people's exploration of new energy sources. Based on the introduction of wind-solar hybrid hydrogen storage energy storage systems, the paper briefly analyzes on the development status and operating principles of the system, by combining with solar energy and wind energy resources in Hebei province, to analyze the suitability of the system in different regions of Hebei province. The system has different operating modes in different regions of Hebei province, and its applicability can be classified into three categories. Through the analysis on this system, combined with the climate environment of the system construction site, it is concluded that a reasonable allocation of the installed capacity of wind turbines, solar cells, and energy storage modules can better achieve the system's applicability.
引文
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[2]孙楠,邢德山,白静利,等.风光互补发电系统的发展与应用[C]/全国热力学分析与节能学术会议.2009.
[3]张建飞.独立小型风光互补发电系统的仿真研究[D].河北大学,2017.
[4]何勇琪,张建成.独立型风光互补系统中储能容量优化研究[J].电力科学与工程,2012,28(4):9-13.
[5]刘山凤,龙江,方韬.风光互补新能源成新趋势[J].电气技术,2008,(12):69-71.
[6]吴克河,龚瑞.风光储发电的现状及展望[J].科技展望,2015,25(25).
[7]王琪,杨立权,韩东全.我国太阳能光伏发电发展现状及前景[J].农业与技术,2015,35(23):168-170.
[8]谷芃.含有充电机的风光互补电站设计与研究[D].沈阳:东北大学,2014.
[9]黄朝阳.风力发电变桨距传动及控制系统的虚拟设计[D].西安:西安理工大学,2005.
[10]经琦,刘贤兴,施凯,等.风光互补发电系统设计及最大功率点跟踪控制[J].电力电子技术,2015,49(1):63-66.
[11]倪萌,M.K.H.Leung,K.Sumathy.电解水制氢技术进展[J].能源环境保护,2004,18(5):5-9.
[12]刘明义,郑建涛,徐海卫,等.电解水制氢技术在可再生能源发电领域的应用[C]/中国电机工程学会年会.2013.
[13]Baldwin R,Pham M,Leonida A,et al.Hydrogen oxygen proton-exchange membrane fuel cells and electrolyzers[J].Journal of Power Sources,1990,29(3):399-412.
[14]马霄平,宋世栋,谭忠印,等.固体聚合物电解质水电解池电极的优化研究[J].电源技术,2006,30(8):621-624.
[15]颜卓勇,孔祥威.非并网风电电解水制氢系统及应用研究[J].中国工程科学,2015,17(3):30-34.