高温质子交换膜燃料电池用电解质膜研究进展被引量：1

Recent Development of Proton Exchange Membranes for High Temperature Proton Exchange Membrane Fuel Cells

下载PDF

导出

摘要高温质子交换膜燃料电池(HT-PEMFC)具有更好的CO耐受性、更简化的水热管理系统、更快的阴极过程、和更优的热利用特性等诸多优点,因而,近年来受到了研究者的广泛关注。本文综述了近年来高温质子交换膜的研究进展,简要评述了改性全氟磺酸膜体系的高温质子交换膜的研究概况,展望了高温质子交换膜的发展趋势。 High temperature proton exchange membrane fuel cells, with many advantages such as higher CO tolerance, simpler water and thermal management system, faster cathode process, and more convenient residual-heat utilization approach, have drawn much attention from researchers. This paper summarizes the development of various types of high temperature proton exchange membranes,including modified PFSAs, and the directions in this domain are also discussed in the paper.

作者宋义超余波

机构地区海军驻武汉中国船舶重工集团公司第七一二研究所

出处《船电技术》 2011年第12期46-49,共4页 Marine Electric & Electronic Engineering

关键词高温质子交换膜燃料电池全氟磺化膜 high temperature proton exchange membrane fuel cell PFSA

分类号 TM911.4 [电气工程—电力电子与电力传动]

引文网络
相关文献

参考文献23

1毛宗强,ed.燃料电池.2004,化学工业出版社:北京.
2Adjemian, K.T., et al., Function and characterization of metal oxide-nation composite membranes for elevated-temperature H-2/O-2 PEM fuel cells. Chemistry of Materials, 2006. 18(9): p. 2238-2248.
3Shao, Z.G., et al., Hybrid Nation-inorganic oxides membrane doped with heteropolyacids for high temperature operation of proton exchange membrane fuel cell. Solid State Ionics, 2006. 177(7-8): p. 779-785.
4Ke, C.C., et al., Investigation on sulfuric acid sulfonation of in-situ sol-gel derived Nation/SiO2 composite membrane. International Journal of Hydrogen Energy, 2011.36(5): p. 3606-3613.
5Deng, Q., R.B. Moore, and K.A. Mauritz, Nation (R) (SiO2, ORMOSIL, and dimethylsiloxane) hybrids via in situ sol-gel reactions: Characterization of fundamental properties. Journal of Applied Polymer Science, 1998.68(5): p. 747-763.
6Di Noto, V., et al., New inorganic-organic proton conducting membranes based on Nation (R) and [ (ZrO 2)center dot(SiO2) (O. 6 7)] nanoparticles : Synthesis vibrational studies and conductivity. Journal of Power Sources, 2008. 178(2): p. 561-574.
7Shao, Z.G., P. Joghee, and I.M. Hsing, Preparation and characterization of hybrid Nation-silica membrane doped with phosphotungstic acid for high temperature operation of proton exchange membrane fuel cells. Journal of Membrane Science, 2004. 229(1-2): p. 43-51.
8Tang, H., et al., Self-assembled Nation-silica nanoparticles for elevated-high tempe;'ature polymer electrolyte membrane fuel cells. E!ectrochemistry Communications, 2007.9(8): p. 2003-2008.
9Adjemian, K.T., et al., Silicon oxide Nation composite membranes for proton-exchange membrane fuel cell operation at 80-140 degrees C. Journal of the Electrochemical Society, 2002. 149(3): p. A256-A261.
10Park, Y.S., et al., High proton-conducting Nation~calcium hydroxyphosphate composite membranes for fuel cells. Eleetrochimica Aeta, 2004. 50(2-3): p. 595-599.

同被引文献21

1李辰楠,孙公权,任素贞,吴智谋,刘瑾,辛勤.应用于燃料电池的全氟磺酸膜及其改性[J].科学通报,2005,50(19):2049-2054. 被引量：7
2J. Lobato, P. Canizares, M. A. Rodrigo, F. J. Pinar. Three-dimensionalmodel of a 50 cm2 high temperature PEM fuel cell: Study of the flowchannel geometry influence[J]. INT J HYDROGEN ENERG,2010(35):5510-5520.
3J. S. Wainright, J. T. Wang, D. Weng, R. F. Savinell, M. Litt.Acid-dopedpolybenzimidazoles: a new polymer electrolyte[J]. Electrochem.1995(142): 1211.
4D, Cheddie, N. Munroe. Parametric model of an intermediatetemperature PEMFC[J]. J POWER SOURCES, 2006(156):414^23.
5K. Scott, S. Pilditch, M. Mamlouk, Modelling and experimentalvalidation of a high temperature polymer electrolyte fuel cell[J], JAppl Electrochem, 2007(37):1245-1259.
6J. W. Hu, H.M.Zhang, G Liu. Diusion-convection/electrochemicalmodel studies on polybenzimidazole (PBI) fuel cell based on ACimpedance technique[J].Energy Conversion and Management,2008(49):1019-1027.
7D. Cheddie, N. Munroe. Modeling of High Temperature PEM FuelCells using FEMLAB[J].J POWER SOURCES’ 2006(160):215-223.
8J. W. Hu, H. M. Zhang, J. Hu, Y. F. Zhai, B. L. Yi. Two dimensionalmodeling study of PBI/H3PO4 high temperature PEMFCs based onelectrochemical methods[J].J POWERSOURCES,2006(160):1026-1034.
9D. Cheddie, N. Munroe. Three-dimensional modeling of hightemperature PEM fuel cells[J]. J POWER SOURCES,2006(160):215-223.
10C. Siegel, G Bandlamudi, A. Heinzel. Systematic characterization of aPBI/H3P04 sol-gel membrane—Modeling and simulation[J]. JPOWER SOURCES, 2011(196):2735-2749.

引证文献1

1赵茜茜,屈树国.高温质子交换膜燃料电池机理模型研究进展[J].当代化工,2014,43(8):1558-1561. 被引量：3

二级引证文献3

1乔宗文,孟龙.温度对质子交换膜尺寸稳定性的影响[J].当代化工,2018,47(11):2352-2355. 被引量：1
2乔宗文,邓嘉琪.相分离程度对侧链脂肪磺酸型质子交换膜尺寸稳定性的影响[J].化学与生物工程,2018,35(8):32-35.
3邹静,崔秋娟,杨艳丽,马少华.磺化聚苯并咪唑-聚醚砜高温复合质子交换膜的制备及性能研究[J].合成材料老化与应用,2021,50(6):55-58.

1潘静静,张海宁,潘牧.燃料电池用高温质子交换膜研究进展[J].电池工业,2008,13(5):357-360. 被引量：5
2于先进,谭小耀,李中芳.燃料电池技术的发展概述(一)[J].山东工程学院学报,2000,14(1):24-27. 被引量：1
3余仕禧,史仲,罗国恩,禹筱元.制备正极材料LiFePO_4的研究进展[J].电池,2010,40(4):226-228. 被引量：4
4谢德明.中国镍氢电池的产业化[J].新能源,1997,19(11):35-37. 被引量：1
5伍昌维,张朝平.尖晶石型LiMn_2O_4电池材料的研究现状[J].贵州大学学报（自然科学版）,2006,23(2):157-162. 被引量：4
6梅先焘.沼气发电设备及热利用工程设计[J].上海节能,1996(9):20-24.
7专利信息[J].太阳能,2006(6):63-65.
8李慧琳,沈春晖,尹珊珊,李伟.基于PBI的高温质子交换膜研究进展[J].化工新型材料,2016,44(6):31-33. 被引量：1
9兰月.“十二五”新能源开发七大重点[J].电源技术应用,2011,14(6):72-73.
10李琼,李薇,张海宁,潘牧.聚合物质子溶剂在质子交换膜中的应用[J].电源技术,2011,35(4):473-475. 被引量：1

船电技术

2011年第12期

浏览历史

内容加载中请稍等...

高温质子交换膜燃料电池用电解质膜研究进展被引量：1

参考文献23

同被引文献21

引证文献1

二级引证文献3

相关作者

相关机构

相关主题

浏览历史

高温质子交换膜燃料电池用电解质膜研究进展 被引量：1

参考文献23

同被引文献21

引证文献1

二级引证文献3

相关作者

相关机构

相关主题

浏览历史

高温质子交换膜燃料电池用电解质膜研究进展被引量：1