English
往期目录
新闻公告
More
化学进展 2009, Vol. 21 Issue (11): 2333-2340 前一篇   后一篇

• 《化学进展》创刊20周年纪念专辑 •

液流储能电池技术研究进展

张华民1*; 张宇2; 刘宗浩1; 王晓丽2   

  1. (1. 中国科学院大连化学物理研究所    大连 116023; 2. 大连融科储能技术发展有限公司    大连 116025)
  • 收稿日期:2009-06-05 出版日期:2009-11-24 发布日期:2009-10-09
  • 通讯作者: 张华民 E-mail:zhanghm@dicp.ac.cn
下载PDF ( 4593 ) 引用
导出 被引次数 ( 114 | 6 )

Redox Flow Battery Technology

Zhang Huamin1*;    Zhang Yu2;    Liu Zonghao1;    Wang Xiaoli2   

  1. (1. Dalian Institute of Chemical Physics of Chinese Academy of Science, Dalian 116023, China;2. Dalian RONGKEPOWER Co.,Ltd., Dalian 116025, China)
  • Received:2009-06-05 Online:2009-11-24 Published:2009-10-09
  • Contact: Zhang Huamin E-mail:zhanghm@dicp.ac.cn

液流储能电池技术是一种高效、大规模电化学储能技术,在风能、太阳能等可再生能源发电、智能电网建设等方面有着广阔的应用前景。本文重点对全钒、多硫化钠-溴和锌-溴液流储能电池的工作原理、特点、国内外研究现状及发展趋势进行了综述,并对其他探索性液流储能电池体系进行了介绍。提出了制约液流储能电池技术发展瓶颈问题,展望了液流储能电池未来发展趋势。

关键词: 液流储能电池, 全钒, 多硫化钠-溴, 锌-溴

Redox flow battery technology is a new electrical energy storage technology with virtues of high efficiency and large scale. It can meet the great demands of promoting the wide application of the renewable resources, pushing the construction of smart grid and achieving the target for energy saving and emission reduction. In this paper, we focus on the introduction to the working principles, characteristics, R&D progress and development trend of the all-vanadium, sodium polysulfide/bromine and zinc/bromine redox flow batteries. Also we discuss other types of flow batteries. Finally, the key problems limiting the technology development are pointed out and the suggestions for future research are given.

Contents
1 Introduction
2 All-vanadium redox flow battery
2.1 Principles and characteristics of all-vanadium redox flow battery
2.2 Progress and trend of all-vanadium redox flow battery
3 Sodium polysulfide/bromine redox flow battery
3.1 Principles and characteristics of sodium polysulfide/bromine redox flow battery
3.2 Progress and trend of sodium polysulfide/bromine redox flow battery
4 Zinc/bromine battery
4.1 Principles and characteristics of zinc/bromine battery
4.2 Progress and trend of zinc/bromine battery
5 Other redox flow batteries
5.1 Fe/Cr redox flow battery
5.2 Vanadium/polyhalid redox flow battery
5.3 New lead acid and zinc/ nickel redox flow batteries
5.4 Mn/V redox flow battery
5.5 Ce/V redox flow battery
5.6 All chromium redox flow battery
5.7 All ruthenium redox flow battery
5.8 Actinide redox flow battery
6 Issues and perspectives

Key words: redox flow battery for energy storage, all-vanadium, sodium polysulfide/bromine, zinc/bromine

中图分类号: 

()

[ 1 ]  Fabjan C , Garche J , Harrer B. Electrochimica Acta , 2001 , 47 (5) :825 —831
[ 2 ]  张华民( Zhang H M) . 电源技术( Chinese Journal of Power Sources) , 2007 , 31 (8) : 587 —591
[ 3 ]  Skyllas-Kazacos M. (2005-10-02) . http://www.ceic.unsw.edu.au/centers/vrb/overview.htm
[ 4 ]  Skyllas-Kazacos M, Kasherman D , Hong D R , et al . J . Power Sources , 1991 , 35 : 399 —404
[ 5 ]  Tokuda N , Kanno T, Hara T, et al . SEI Technical Review , 2000 ,50 : 88 —94
[ 6 ]  Miyake S. (2004-08-22) . http://www.electricitystorage.org/pubs/2001/IEEE-PES-Summer2001/Miyake.pdf
[ 7 ]  Kaneko H , Nozaki K, Wada Y, et al . Electrochimica Acta , 1991 ,36 (7) : 1191 —1196
[ 8 ]  Shibata A , Sato K. Power engineering J . , 1999 , 13 (3) : 130 —135
[ 9 ]  (2006-03-23) . http://www.vrbpower.com/applications/projects.html
[10 ]  [2009-04-28 ] . http://www.vrbpower.com
[11 ]  [2009-04-28 ] . http://www.cellstrom.at
[12 ]  [2009-04-30 ] . http://pemfckt.dicp.ac.cn/02news/31.htm
[13 ]  [2009-04-30 ] . http://pemfckt.dicp.ac.cn/02news/47.html
[14 ]  Hazza A , Pletcher D , Wills R. Phys. Chem. Chem. Phys. , 2004 ,6 : 1773 —1778
[15 ]  Pletcher D , Wills R. Phys. Chem. Chem. Phys. , 2004 , 6 :1779 —1785
[16 ]  Pletcher D , Wills R. J . Power Source , 2005 , 149 : 96 —102
[17 ]  Hazza A , Pletcher D , Wills R , Richard W. J . Power Source , 2005 ,149 : 103 —111
[18 ]  Pletcher D , Zhou H T, Kear G, et al . J . Power Source , 2008 ,180 : 621 —629
[19 ]  Xue F Q , Wang Y L , Wang W H , et al . Electrochimica Acta ,2008 , 53 : 6636 —6642
[20 ]  Bradley S. US312502 , 1885
[21 ]  David L , Thomas B R. Handbook of Batteries (3rd ed. ) , McGram Hill , 2002
[22 ]  [2009-04-30 ] . http://www.zbbenergy.com/
[23 ]  Phillip E. Development of Zinc/Bromine Batteries for Load-Leveling Applications : Phase 1 Final Report , 1999
[24 ]  Nanch C , Phillip E , Peter L. Development of Zinc/Bromine Batteries for Load-Leveling Applications : Phase 2 Final Report , 1999
[25 ]  Skyllas-Kazacos MJ . J . Power Source , 2003 , 124 : 299 —302
[26 ]  Cheng J , Zhang L , Yang Y S , et al . Electrochem. Commun. ,2007 , 9 (11) : 2639 —2642
[27 ]  Fang B , Iwasa S , Wei Y, et al . Electrochimica Acta , 2002 , 47 :3971 —3976
[28 ]  Paulenova A , Creagerb S E , Navratila J D , et al . J . Power Source ,2002 , 109 : 431 —438
[29 ]  Bae C H , Roberts E P L , Dryfe R A W. Electrochimica Acta ,2002 , 48 : 279 —287
[30 ]  Matsuda Y, Tanaka K, Okada M, et al . Applied Electrochemistry ,1988 , 18 : 909 —914
[31 ]  Yoshinobu S , Hajimu Y, Hirotake M. Journal of Nuclear Science and Technology , 2000 , 37 (3) : 253 —256
[32 ]  Hasegawa K, Kimura A , Yamamura T, et al . Physics and Chemistry of Solids , 2005 , 66 (2/4) : 593 —595
[33 ]  Yamamura T, Watanabe N , Shiokawa Y. J . Alloys and Compounds ,2006 , 408/412 : 1260 —1266
[1] 王斐然, 蒋峰景. 全钒液流电池离子导电膜[J]. 化学进展, 2021, 33(3): 462-470.
[2] 王刚, 陈金伟, 朱世富, 张洁, 刘效疆, 王瑞林. 全钒氧化还原液流电池碳素类电极的活化[J]. 化学进展, 2015, 27(10): 1343-1355.
[3] 王刚, 陈金伟, 汪雪芹, 田晶, 刘效疆, 王瑞林. 全钒氧化还原液流电池电解液[J]. 化学进展, 2013, 25(07): 1102-1112.
[4] 汪南方, 刘素琴*. 全钒液流电池隔膜的制备与性能[J]. 化学进展, 2013, 25(01): 60-68.
[5] 张亚萍 陈艳 周元林 何平. 全钒氧化还原液流电池隔膜*[J]. 化学进展, 2010, 22(0203): 384-387.
阅读次数
全文


摘要

液流储能电池技术研究进展