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Advances and development trend in key technologies for all-vanadium redox flow battery |
LIU Tao1,2,3,4, GE Ling1,2,3,4, ZHANG Yi-min1,2,3,4 |
1. School of Resource and Environmental Engineering, Wuhan University of Science and Technology, Wuhan 430081, Hubei, China; 2. State Environmental Protection Key Laboratory of Mineral Metallurgical Resources Utilization and Pollution Control, Wuhan University of Science and Technology, Wuhan 430081, Hubei, China; 3. Hubei Provincial Engineering Technology Research Center of High Efficient Cleaning Utilization for Shale Vanadium Resource, Wuhan 430081, Hubei, China; 4. Hubei Provincial Collaborative Innovation Center for High Efficient Utilization of Vanadium Resources, Wuhan 430081, Hubei, China |
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Abstract Energy has been the basis of society′s survival and development since time immemorial. In the face of the deterioration of natural environment and weather caused by global fossil resource consumption, low carbon strategies have been developed to promote the sustainable use of renewable and green energy. All-vanadium redox flow battery energy storage systems can address the problems of strong volatility, discontinuity, and environmental and weather limitations of green energy such as wind, hydro and solar, etc. The electrolyte and stack are important components of the vanadium battery system, which determine the performance of the vanadium battery capacity, power and stability, and are also the main cost outlet for the vanadium battery industry. The research progress, key technologies and commercial applications of the vanadium battery electrolytes and stacks at home and abroad in recent years are introduced, and the development potential and subsequent direction of all-vanadium redox flow battery are discussed.
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Received: 27 December 2022
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[1] |
JIA Z,SUN D,ZHANG Y,et al. What China can learn from the US history of energy strategy development[J]. Sino-global Energy,2016,21(2):1.
|
[2] |
DAI H,SU Y,KUANG L,et al. Contemplation on China′s energy-development strategies and initiatives in the context of its carbon neutrality goal[J]. Engineering,2021,7(12):1684.
|
[3] |
熊超,李新,创李冰. 双碳目标下的钢铁节能理念创新与能源结构重塑探讨[J]. 中国冶金,2021,31(9):59.
|
[4] |
张华民,周汉涛,赵平,等. 储能技术的研究开发现状及展望[J]. 能源工程,2005(3):1.
|
[5] |
Skyllas-Kazacos M,Cao L,Kazacos M,et al. Vanadium electrolyte studies for the vanadium redox battery—A review[J]. ChemSusChem,2016,9(13):1521.
|
[6] |
吴晴,张照志,潘昭帅,等. 2020—2035年我国钒需求预测[J]. 中国矿业,2021,30(5):45.
|
[7] |
高永璋. 中国钒矿资源及供需形势分析[J]. 中国矿业,2019,28(增刊2):5.
|
[8] |
王新东,王少娜,耿立唐,等. 绿色低碳提钒关键技术及产业化应用[J]. 中国冶金,2022,32(4):135.
|
[9] |
曲璇,赵阳,习小慧,等. 一种低碳含钒超高强高锰TRIP钢组织性能的研究[J]. 轧钢,2021,38(6):19.
|
[10] |
王培文,赵新华,杜传治,等. 钒微合金钢的高温力学性能分析[J]. 轧钢,2020,37(1):45.
|
[11] |
程玉君,张明博,张文涛,等. 氮化钒铁强化高强钢翘皮缺陷分析[J]. 连铸,2019(6):65.
|
[12] |
张鑫. 2020年中国钒电池行业市场现状分析,钒电池即将产业化,迎来黄金十年[EB/OL]. [2021-09-04]. https://www.huaon.com/channel/trend/745461.html.
|
[13] |
陈勇. 全钒液流电池电解液研究[D]. 长沙:中南大学,2014.
|
[14] |
李林德,张波,黄可龙,等. 全钒离子液流电池电解液的电解制备方法:CN1598063[P]. 2005-03-23.
|
[15] |
缪强. 钒氧化还原液流电池电解液的制备方法:CN1828991A[P]. 2006-09-06.
|
[16] |
Takeshi S,Nobuyuki T,Takahiro K,et al. Manufacture of vanadium electrolyte:JP1997180745A[P].1997-01-11.
|
[17] |
DING M,LIU T,ZHANG Y,et al. Physicochemical and electrochemical characterization of vanadium electrolyte prepared with different grades of V2O5 raw materials[J]. Energies,2021,14(18):5958.
|
[18] |
LI H,HUANG S,YAO Z,et al. Flow battery electrolyte from carbon black incineration fly ash:A feasibility study of an environment friendly disposal process[J]. Waste Management,2021,133(1):28.
|
[19] |
LIU H,ZHANG Y,LIU T,et al. Preparing vanadium electrolyte from a black shale leaching solution with high concentration chloride using D2EHPA[J/OL]. [2022-04-15].Transactions of Nonferrous Metals Society of China. https://kns.cnki.net/kcms/detail/43.1239.TG.20220414.0952.026.html.
|
[20] |
赵宇,成城,吴田,等. 一种高纯度等摩尔浓度三价/四价钒电解液的制备装置及方法:CN 111106374 A[P]. 2020-05-05.
|
[21] |
杨亚东,张一敏,黄晶,等. 化学还原法制备钒电池电解液中还原剂选择及性能[J]. 化工进展,2017(1):274.
|
[22] |
胡越,刘宏辉,董玉明,等. 一种全钒液流电池电解液及其制备方法与应用:CN 113644304 A[P]. 2021-11-12.
|
[23] |
国家能源局. 全钒液流电池用电解液技术条件:NB/T 42133—2017[S]. 北京:中国电力出版社,2018.
|
[24] |
Skyllas-Kazacos M. Novel vanadium chloride/polyhalide redox flow battery[J]. Journal of Power Sources,2003,124(1):299.
|
[25] |
Skyllas-Kazacos M,Kazacos G,Poon G,et al. Recent advances with UNSW vanadium-based redox flow batteries[J]. International Journal of Energy Research,2010,34(2):182.
|
[26] |
张胜涛,李文坡,封雪松,等. 液流电池的研究进展[J]. 电源技术,2022,9(32):569.
|
[27] |
PENG S,WANG N F,WU X J,et al. Vanadium species in CH3SO3H and H2SO4 mixed acid as the supporting electrolyte for vanadium redox flow battery[J]. International Journal of Electrochemical Science,2012,7:643.
|
[28] |
LUO J,HU B,HU M,et al. Status and prospects of organic redox flow batteries toward sustainable energy storage[J]. ACS Energy Letters,2019,4(9):2220.
|
[29] |
HE Z,HE Y,CHEN C,et al. Study of the electrochemical performance of VO2+/VO+2♂ redox couple in sulfamic acid for vanadium redox flow battery[J]. Ionics,2014,20(7):949.
|
[30] |
Li L,Kim S,Wang W,et al. A stable vanadium redox-flow battery with high energy density for large-scale energy storage[J]. Advanced Energy Materials,2011,1(3):394.
|
[31] |
Kim S,Thomsen E,Xia G,et al. 1 kW/1 kW·h advanced vanadium redox flow battery utilizing mixed acid electrolytes[J]. Journal of Power Sources,2013,237:300.
|
[32] |
YANG Y,ZHANG Y,TANG L,et al. Investigations on physicochemical properties and electrochemical performance of sulfate-chloride mixed acid electrolyte for vanadium redox flow battery[J]. Journal of Power Sources,2019,434:226719.
|
[33] |
YANG Y,ZHANG Y,LIU T,et al. Improved broad temperature adaptability and energy density of vanadium redox flow battery based on sulfate-chloride mixed acid by optimizing the concentration of electrolyte[J]. Journal of Power Sources,2019,415:62.
|
[34] |
Nikiforidis G,Belhcen A,Anouti M. A highly concentrated vanadium protic ionic liquid electrolyte for the vanadium redox flow battery[J]. Journal of Energy Chemistry,2021,57:238.
|
[35] |
Choi C,Kim S,Kim R,et al. A review of vanadium electrolytes for vanadium redox flow batteries[J]. Renewable and Sustainable Energy Reviews,2017,69:263.
|
[36] |
Mousa A,Skyllas-Kazacos M. Effect of additives on the low-temperature stability of vanadium redox flow battery negative half-cell electrolyte[J]. ChemElectroChem,2015,2(11):1742.
|
[37] |
Kausar N,Mousa A,Skyllas-Kazacos M. The effect of additives on the high-temperature stability of the vanadium redox flow battery positive electrolytes[J]. ChemElectroChem,2016,3(2):276.
|
[38] |
Rahman F,Skyllas-Kazacos M. Vanadium redox battery:Positive half-cell electrolyte studies[J]. Journal of Power Sources,2009,189(2):1212.
|
[39] |
张华民. 液流电池储能技术及应用[M]. 北京:科学出版社,2022.
|
[40] |
Jiang F,Liao W,Ayukawa T,et al. Enhanced performance and durability of composite bipolar plate with surface modification of cactus-like carbon nanofibers[J]. Journal of Power Sources,2021,482:228903.
|
[41] |
Jeong K I,Jeong J M,Oh J,et al. An integrated composite structure with reduced electrode / bipolar plate contact resistance for vanadium redox flow battery[J]. Composites,Part B. Engineering,2022,233:109657.1.
|
[42] |
谢丽丽. 化学镀在钯复合膜制备及石墨电极修饰中的应用研究[D]. 天津:天津大学化工学院,2012.
|
[43] |
李鹏辉,李强,孙红,等. 氮气氛热处理石墨毡对VRFB性能影响[J]. 电源技术,2019(43):1496.
|
[44] |
Fetyan A,El-Nagar G A,Derr I,et al. A neodymium oxide nanoparticle-doped carbon felt as promising electrode for vanadium redox flow batteries[J]. Electrochimica Acta,2018,268:59.
|
[45] |
Sodiq A,Fasmin F,Mohapatra L,et al. Enhanced electrochemical performance of modified thin carbon electrodes for all-vanadium redox flow batteries[J]. Materials Advances,2020,1(6):2033.
|
[46] |
Ashraf Gandomi Y,Aaron D,Nolan Z,et al. Direct measurement of crossover and interfacial resistance of ion-exchange membranes in all-vanadium redox flow batteries[J]. Membranes,2020,10(6):126.
|
[47] |
LIN C H,YANG M C,WEI H J. Amino-silica modified Nafion membrane for vanadium redox flow battery[J]. Journal of Power Sources,2015,282:562.
|
[48] |
Lupo F,Kamalakaran R,Scheu C,et al. Microstructural investigations on zirconium oxide-carbon nanotube composites synthesized by hydrothermal crystallization[J]. Carbon,2004,42(10):1995.
|
[49] |
Divya K,Rana D,Sri Abirami Saraswathi M S,et al. Custom-made sulfonated poly (vinylidene fluoride-co-hexafluoropropylene) nanocomposite membranes for vanadium redox flow battery applications[J]. Polymer Testing,2020,90:106685.
|
[50] |
Parasuraman A,Lim T M,Menictas C,et al. Review of material research and development for vanadium redox flow battery applications[J]. Electrochimica Acta,2013,101:27.
|
[51] |
Ghimire P C,Bhattarai A,Lim T M,et al. In-situ tools used in vanadium redox flow battery research-Review[J]. Batteries,2021,7(3):53.
|
[52] |
Park D J,Jeon K S,Ryu C H,et al. Performance of the all-vanadium redox flow battery stack[J]. Journal of Industrial and Engineering Chemistry,2017,45:387.
|
[53] |
张华民. 全钒液流电池的技术进展、不同储能时长系统的价格分析及展望[J]. 储能科学与技术,2022,9 (11):2772.
|
[54] |
LDES. 澳大利亚投建年产能为1 GW/8 GWh的钒电池超级工厂[EB/OL]. [2022-11-25]. https://www.esplaza.com.cn/article-2317-1.html.
|
|
|
|