ISSN 1608-4039 (Print)
ISSN 1680-9505 (Online)

For citation:

Kamenev Y. B., Chunts N. I., Shtompel' G. A., Skachkov Y. V. Research of influence of carbon additives in negative active material on work of the lead-acid batteries in partial state of charge mode.. Electrochemical Energetics, 2011, vol. 11, iss. 3, pp. 146-153. DOI: 10.18500/1608-4039-2011-11-3-146-153, EDN: OWWFSD

This is an open access article distributed under the terms of Creative Commons Attribution 4.0 International License (CC-BY 4.0).
Language: 
Russian
Heading: 
Acid batteries
Article type: 
Article
DOI: 
10.18500/1608-4039-2011-11-3-146-153
EDN: 
OWWFSD

Research of influence of carbon additives in negative active material on work of the lead-acid batteries in partial state of charge mode.

Autors: 
Kamenev Yurii Borisovich, Scientific and Technological Center of JSC Elektrotyaga
Chunts Nataliya Ivanovna, Scientific and Technological Center of JSC Elektrotyaga
Shtompel' Georgii Alekseevich, Scientific and Technological Center of JSC Elektrotyaga
Skachkov Yurii Vasil'evich, 1 Central Research Institute of the Ministry of Defence of the Russian Federation
Abstract: 

Influence of the carbon additive in negative active material (NAM) on a resource of the lead-acid batteries working in a partial state of charge mode is studied. Extreme character of dependence of speed of degradation NAM from the maintenance in it of carbon is confirmed. Perceptivity of introduction of the carbon additive in negative electrodes of the lead-acid batteries working at partial state of charge mode is demonstrated.

Key words: 
свинцово-кислотный аккумулятор
добавка графита
постоянный недозаряд
отрицательная активная масса
Reference: 

1. Culpin B., Rand J. // J. Power Sources. 1991. Vol. 36. P. 415–438.
2. Lam L. T., Ceylan H., Haigh N. P., Lwin T., Phyland C. G., Rand J., Vella D. G. // ALABC Project N3.1, Influence of residual elements on the oxygen- and/or hydrogen-gassing rates of lead-acid batteries, Final Report, July 2000 to June 2002, Advanced Lead-Acid Battery Consortium, Research Triangle Park, NC, USA, 2002.
3. Lam L. T., Newnham R. H., Ozgun H., Fleming F. A. // J. Power Sources. 2000. Vol. 88. P. 92–97.
4. Pat. 6555265 US, H01M 2/24 (09707753). Value regu lated lead acid battery.
5. Pat. 5691087 US, H01M 4/68 (08673149). Sealed lead acid cells and batteries.
6. Pat. 5434025 US, H01M 4/68 (08144688). Battery grids and plates and lead-acid batteries made using such grids and plates.
7. Jones W. E. M., Vanasse H. A., Sabotta C. E., Clapper J. E., Price E. F. // Proceedings of the 20th Intern. Telecommunications Energy Conference. San Francisco, CA, USA, IEEE, 1998. P. 461–469.
8. Lam L. T., Haigh N. P., Lim O. V., Rand J., Manders J. E. // J. Power Sources. 1999. Vol. 78. P. 139–146.
9. Pavlov D., Rogachev T., Nikolov P. // J. Power Sources. 2009. Vol. 191. P. 58–75.
10. Clive D. S., Lim E. H. // Modern Battery Techn. New York; London; Toronto, 1991.
11. Справочник по электрохимии / под ред. А. М. Сухотина. Л.: Химия. Ленингр. отд-ние, 1981.
12. Rand D. Valve-Regulated Lead-Acid Batteries. Amsterdam; Boston; London: Elsevier, 2004.
13. Calabek M., Micka K. // J. Power Sources. 2006. Vol. 158. P. 864–867.

Received: 
30.10.2011
Accepted: 
30.10.2011
Published: 
30.11.2011