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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 983The Elimination of Pollution of Toxic Cadmium and...

The Elimination of Pollution of Toxic Cadmium and Arsenic in Lead-Based Alloys of Lead-Acid Batteries in China

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Abstract:

An overview of the development of lead-based alloys in lead-acid batteries is presented. Advantages and historical achievements of toxic cadmium, arsenic alloys are affirmed. Compared to cadmium-free and arsenic-free batteries, the shortcomings and performance gapes of cadmium-containing, arsenic-containing batteries are noted. Focusing the prospect of rare earth alloy, and overall promotion of cadmium-free and arsenic-free alloys in China.

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Advanced Materials and Engineering

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Periodical:

Advanced Materials Research (Volume 983)

Pages:

319-323

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.983.319

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Online since:

June 2014

Authors:

Xue Liu, Jun Chao Cai, Yue Hong Shu*

Keywords:

Arsenic-Free Alloys, Cadmium-Free Alloys, Grid Materials, Lead-Acid Batteries, Low-Antimony Arsenic Alloy, Rare Earth Alloys

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© 2014 Trans Tech Publications Ltd. All Rights Reserved

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* - Corresponding Author

[1] Guo Ziqiang, green electric bike use "green, battery - from cadmium-containing battery to cadmium-free battery, J. Chinese Bicycles (2009), pp.40-44.

[2] Guo Ziqiang, Lead-acid batteries with cadmium-free alloy will replace cadmium-containing batteries imperatively, J. Battery Industry, vol. 13 (2008), pp.401-404.

[3] Shenyang Institute of Mining and Metallurgy, Liu Yumin, and Sun Zhen, Status and development direction of lead-acid battery grid alloy, J. Nonferrous Metallurgy, Section 5 (1997), pp.46-48.

[4] Harbin Institute of Technology Department of Electrochemical, Dong Baoguang, and Liu Xiurong, Lead-antimony-arsenic-selenium (sulfur) study on quaternary alloys, J. Batteries, vol. 1 (1983), pp.10-13.

[5] Tangming Cheng, Zhou Huawen, Study of lead-acid batteries with lead alloy, J. Hunan Nonferrous Metals, vol. 21 (2005), pp.27-29.

[6] Shanghai Battery Plant, Testing and use of lead-antimony-arsenic alloy, J. Batteries, vol. 4 (1983), pp.1-6.

[7] Alfred A. Duker, E.J.M. Carranza, Arsenic geochemistry and health, [J]. Environment International, vol. 31 (2005), pp.631-641.

DOI: 10.1016/j.envint.2004.10.020

[8] Prosun Bhattacharya, Alan H. Welch, Kenneth G, Arsenic in the environment: Biology and Chemistry, J. Science of The Total Environment, vol. 379 (2007), pp.109-120.

[9] Thomas S.Y. Choong, T.G. Chuah, Y, Arsenic toxicity, health hazards and removal techniques from water: an overview, J. Desalination, vol. 217 (2007), pp.139-166.

DOI: 10.1016/j.desal.2007.01.015

[10] Li Dangguo, Zhou Genshu, Yao Liang, Study on the anodic behavior of rare-earth lead alloy in sulfuric acid solution, J. Chinese Journal of Rare Earth, vol. 23 (2005), pp.224-227.

[11] Li Dangguo, Zhou Genshu, Zheng Maosheng, Orthogonal experimental design of new lead-acid battery grid materials, J. Non-ferrous Metals, vol. 56 (2004), pp.48-51.

[12] Wenqing Zhang, Aiju Li, Hongyu Chen, The effect of rare earth metals on the microstructure and electrochemical corrosion behavior of lead calcium grid alloys in sulfuric acid solution, J. Journal of Power Sources, vol. 189 (2009), pp.1204-1211.

DOI: 10.1016/j.jpowsour.2011.11.067

[13] Li Dangguo, Zhou Genshu, Zheng Maosheng, Research progress of grid materials of lead-acid batteries, J. Battery, vol. 34 (2010), pp.132-135.

[14] Tong Ming Xin, Lin Guanfa, Study on properties of lead-based grid materials of rare earth, J. Physical and Chemical Testing, vol. 42 (2006), pp.60-62.

[15] Liu Hou-Tian, Yang jiong, Liang Haihe, Cerium content effects on anodic behavior of Pb-Ce alloy in sulfuric acid solution, J. Fudan Journal, vol. 40 (2001), pp.401-407.

[16] H.Y. Chen, S. Li, A. J. Li, D. Shu, Lead–samarium alloys for positive grids of valve-regulated lead–acid batteries, J. Journal of Power Sources, vol. 168 (2007), pp.79-89.

DOI: 10.1016/j.jpowsour.2006.11.091

[17] Zhao Jinzhu, Dai Changsong, Wang Jinyu, Overview of lead-acid batteries grid alloy, J. Power Technology, vol. 26 (2002), pp.16-18.

[18] S. Zhong, H.K. Liu, S.X. Dou, Evaluation of lead-calcium-tin-aluminium grid alloys for valve-regulated lead/acid batteries, J. Journal of Power Sources, vol. 59 (1996), pp.123-129.

DOI: 10.1016/0378-7753(95)02312-7

[19] H. Li, W.X. Guo, H.Y. Chen, Study on the microstructure and electrochemical properties of lead-calcium-tin-aluminum alloys, J. Journal of Power Sources, vol. 191 (2009), pp.111-118.

DOI: 10.1016/j.jpowsour.2008.10.059

[20] Dou Chuanlong, Li Ruizhen, Chen Hongyu, Study of lead-acid batteries of lead-based alloy for positive grid, J. Power Technology, vol. 34 (2010), pp.276-279.