Cd|KOH|NiOOH

Zn|NH4CI|MnO2

Li|LiClO4|MnO2

Pb|H2SO4|PbO2

H2|KOH|O2

Nonlinear structural model of the battery, research of processes of relaxation after charge

It is shown that the nonlinear structural model of the battery can be used for modeling the voltage relaxation processes after a charge of batteries. The solution obtained is valid for alkaline, acid and lithium-ion batteries. Comparison of solutions, with the experimental data for nickel-cadmium batteries, showed, that the relative error does not exceed 3%.

Authors: 
Galushkin Nikolai Efimovich, Institute of Services Industry and Businesses (branch) of DGTU, 147, Shevchenko St., Mines, Rostov Region, 346500, galushkinne@mail.ru
Yazvinskaya Natal'ya Nikolaevna, Institute of Services Industry and Businesses (branch) of DGTU, 147, Shevchenko St., Mines, Rostov Region, 346500, galushkinne@mail.ru
Galushkin Dmitrii Nikolaevich, Institute of Services Industry and Businesses (branch) of DGTU, 147, Shevchenko St., Mines, Rostov Region, 346500, dmitrigal@rambler.ru
Galushkina Inna Aleksandrovna, Novoshakhtinsk Branch of the Southern Federal University, 2, to st. is 40 years of October, Novoshakhtinsk, the Rostov Region, 346900, dmitrigal@rambler.ru
Key words: 
modeling, alkaline battery, acid battery, lithium-ion battery
Literature

1. Achaibou N., Haddadi M., Malek A. J. Power Sources, 2008, vol. 185, pp.1484.
2. Michelis De, Ferella F., Karakaya E., Beolchini F., Vegli`o F. J. Power Sources, 2007, vol. 172, pp. 975.
3. Schiffer J. , Sauer D. U., Bindner H., Cronin T., Lundsager P., Kaiser R. J . Power Sources, 2007, vol. 168, pp. 66.
4. Chizmadzhev Ju. A., Markin V. S., Chirkov Ju. G. Makrokinetika processov v poristyh sredah [ The macrokinetics of processes in porous media], Moskow, Nauka Publ., 1971 (in Russian).
5. Siniard K., Xiao M., Choe S-Y. J. Power Sources, 2010, vol. 195, pp. 7102.
6. Venkatraman M., Van Zee J. W. J. Power Sources, 2007, vol. 166, pp.537.
7. Zavalis T.G., Behm M., Lindbergh G. J. Electrochem. Soc., 2012, vol. 159, pp. A848.
8. Boovaragavan V., Methakar R. N., Ramadesiga V., Subramanian V. R. J. Electrochem. Soc., 2009, vol. 156, pp. A854.
9. Albertus P., Couts J., Srinivasan V., Newman J. J. Power Sources, 2008, vol. 183, pp. 771.
10. Johansen J. F., Farrell T. W., Please C. P. J. Power Sources, 2006, vol. 156, pp. 645.
11. Bergveld H.J. , Kruijt W.S., Notten P. H.L. J. Power Sources, 1999, vol. 77, pp. 143.
12. Hausmann A., Depcik C. J. Power Sources, 2013, vol. 235, pp. 148.
13. Tremblay O., Dessaint L. A., Dekkiche A. I. Vehicle Power and Propulsion Conference, VPPC, IEEE. Arlington, USA, 2007, pp. 284.
14. Tremblay O., Dessaint L.A. World Electric Vehicle Journal, 2009, vol. 3, pp. 1–10.
15. Thele M., Schiffer J., Karden E., Surewaard E., Sauer D. U. J. Power Sources, 2007, vol. 168, pp. 31.
16. Vasebi A., Partovibakhsh M., Taghi Bathaee S. M. J. Power Sources, 2007, vol. 174, pp. 30.
17. Roscher M.A., Sauer D. U. J. Power Sources, 2011, vol. 196, pp. 331.
18. Andrea D., Meilera M., Steinera K., Walza H., Soczka-Gutha T., Sauerb D. U. J. Power Sources, 2011, vol. 196, p. 5349.
19. Rezaei Niya S. M., Hejabi M., Gobal F. J. Power Sources, 2010, vol. 195, pp. 5789.
20. Stoinov Z. B., Grafov B. M., Savova-Stoinova B., Elkin V. V. Elektrohimicheskij impedans [ Electrochemical impedance], Moskow, Nauka Publ., 1991 (in Russian).
21. Galushkin N. E., Galushkina N. N. Elektrokhimicheskaya Energetika [Electrochemical Energetics], 2005, vol. 5, pp. 43–49 (in Russian).
22. Galushkin D. N., Galushkina N. N. Elektrokhimicheskaya Energetika [Electrochemical Energetics], 2006, vol. 6, pp.41–45 (in Russian).
23. Galushkin N. E. Modelirovanie raboty HIT [ Modeling of work of a chemical power source], Shahty, DGAC Publ., 1998 (in Russian).
24. Galushkin N. E. Modelirovanie raboty shhelochnyh akkumuljatorov v stacionarnyh i nestacionarnyh rezhimah [ Modeling of operation of alkaline accumulators in stationary and non-stationary modes. Doct. dis.]. Novocherkassk, 1998, 465 p. (in Russian).
25. Galushkin N. E.,, Yazvinskaya Н. Е., Kukoz F. I., Galushkin D.N. Strukturnoe modelirovanie raboty jelektrohimicheskih akkumuljatorov [ Structural modeling of operation of electrochemical accumulators], Shahty, izd-vo JuRGUJeS Publ., 2009. (in Russian).
26. Галушкин Н. Е., Кукоз Ф. И., Язвинская Н. Н., Галушкин Д. Н. Modelirovanie raboty akkumuljatorov [Modeling of operation of accumulators], Shahty, izd-vo JuRGUJeS Publ., 2009 (in Russian).
27. Galushkin N. E., Yazvinskaya N. N., Galushkin D. N. // J. Electrochem. Soc. 2012. Vol. 159, pp. A1315.
28. Barnard R., Randell C. F., Tye F. L. J. Appl. Electrochem., 1980, vol. 10, pp. 127.
29. Gindelis Ja. E. Samorazrjad shhelochnyh akkumuljatorov [ Self-discharge of alkaline accumulators Doct. dis.]. Leningrad, 1954. 25 p. (in Russian).
30. Skipworth S. E., Donne S. W. J. Power Sources, 2007, vol. 174, pp. 186.
31. Danilenko I. F., Haskina S. M., Smirnova T. N., Leonova M. V., Zolotov A. I. Sbornik nauchnyh trudov po himicheskim istochnikam toka [Scientific works on chemical power sources], Leningrad, Energoatomizdat Publ., 1989, pp. 87 (in Russian).
32. Garcia-Valle R., Pecas Lopes J. A., eds. Electric Vehicle Integration into Modern Power Networks, Power Electronics and Power Systems. New York, Springer Science+Business Media, 2013.
33. Xing Y., Ma E. W., Tsui K. L., Pecht M. Energies., 2011, vol. 4, pp. 1840.
34. Romanov V. V., Hashev Ju. M. Himicheskie istochniki toka [Chemical power sources], Мoskow, Sovetskoe radio Publ., 1978 (in Russian).
35. Amiria M., Esfahanianb M., Hairi-Yazdic M. R., Esfahanianc V. J. Power Sources, 2009, vol. 190, pp. 372.

Journal issue: 
2014. Т. 14, № 1
Heading: 
Alkaline batteries
DOI: 
https://doi.org/10.18500/1608-4039-2014-14-1-45-50
Full Text (PDF):
download
(downloads: 80)