Kinetic analysis of total Lead from spent Car battery by hydrochloric acid leaching

A. Baba, Alafara; A. Adekola, Folahan; K. Ghosh, Malay; Young, Tryphena; I. Olawale, Kemi; R. Sheik, Abdul

Manuscript ID : 518410 Visit : 42 Page: 291 - 300

Article Type: Original Research

Kinetic analysis of total Lead from spent Car battery by hydrochloric acid leaching

Subject Areas : Journal of the Iranian Chemical Research

Alafara A. Baba ¹ (Chemistry Department, University of Ilorin, P.M.B. 1515, Ilorin-240003, Nigeria.)
Folahan A. Adekola ² (Chemistry Department, University of Ilorin, P.M.B. 1515, Ilorin-240003, Nigeria.)
Malay K. Ghosh ³ (Hydro & Electrometallurgy Department, Institute of Minerals and Materials Technology, Bhubaneswar- 751013, India.)
Tryphena Young ⁴ (Chemistry Department, University of Ilorin, P.M.B. 1515, Ilorin-240003, Nigeria.)
Kemi I. Olawale ⁵ (Chemistry Department, University of Ilorin, P.M.B. 1515, Ilorin-240003, Nigeria.)
Abdul R. Sheik ⁶ (Hydro & Electrometallurgy Department, Institute of Minerals and Materials Technology, Bhubaneswar- 751013, India.)

Received: 2011-07-07 Accepted : 2011-10-25 Published : 2011-03-19

Keywords: leaching, Lead, kinetic analysis, spent battery, hydrochloric acid,

Abstract :

A study of the kinetic analysis of total lead from spent Car battery ash by hydrochloric acidleaching has been examined. The physico-chemical analysis of the ash powder was carried outby the Inductively Coupled Plasma-Mass Spectrometry (ICP-MS) and X–ray diffraction (XRD).The effects of the acid concentration, temperature and particle size on the rate of battery ashdissolution have been investigated. The dissolution rate increased with hydrochloric acidconcentration and temperature with decreasing particle size. The kinetic study indicated that thedissolution of total lead could be represented by a shrinking core model with product layerdiffusion control mechanism at lower temperatures and a surface chemical reaction controlledmechanism at higher temperatures. The activation energy, Ea and reaction order of 44.13 kJ/moland 1.14 were obtained, respectively for the dissolution process under the following establishedconditions: solid/liquid ratio = 10 g/L, HCl concentration = 4M, temperature= 80 °C, Stirringspeed = 300 rpm, Particle size = 0.050–0.063 mm for 120 minutes.

References:

[1] L. Thornton, R. Radu, S. Brush, Bulletin. IC Consultants Ltd, London, UK, 1-159. 2001.
[2] Lead Information, LDA International, http://www.idaint.org/information,htm, retrieved on 9th May,
2000.
[3] J.A. Daoud, S.I. El-Dessonky, Y.A. El-Nadi, I.M. Ahmed, E.A. Saad, Chemical Engineering and
Processing, 47 (2008) 177-183
[4] D.P Mantuano, G. Dorella, R.C.A Elias, M.B. Mansur, J. of Power Sources, 159 (2006) 1510-1518.
[5] A.L. Salgado, A.M.O. Veloso, D.D. Pereira, G.S. Gontijo, A. Salim, M.B. Mansur, J. of Power
Sources, 115 (2003) 367-373.
[6] R.Y. Thomas, O.B. Lugo, H.R. Newman, D.R. Wilburn. Bulletin, Mineral Industries in Africa, 26-76,
2005.
[7] A.M. Bernades, D.C.R Espinosa, J.A.S. Tenorio, J. Power Sources, 130 (2004) 291-298.
[8] D.A. Bertwol, A.M. Bernades, H. Holeczek, J. Fetzer, Acta Metallurgica Slovaca, 12 (2006), 13-19.
[9] A.A. Baba, F.A. Adekola, G.D. Ewuloye, Acta Metallurgica Slovaca, 16(3), (2010) 194-204.
[10] C. Caravaca, A. Coba, F.J. Alguacil, Resourc. Conserv. Recycl. 10(1994) 35-41.
[11] H.S. Altundogan, M.D. Turan, F. Tumen, Hydrometallurgy, 75 (2004) 169-176.
[12] S. Nagib, K. Inoue, Hydrometallurgy, 56(3) (2000) 269-292.
[13] A.A. Baba, F.A. Adekola, R.B. Bale, J. Hazardous Materials, 171 (2009) 838-844.
[14] D. C. R. Espinosa, A. M. Bernardes, J.A.S. Tenorio, J. Power Sources, 135 (2004) 311-319.
[15] M. Dimitrijevic, M.M. Antonijevic, V. Dimitrijevic, Min. Engineering, 12(2) (1999) 165-174.
[16] G. Ucar, Hydrometallurgy, 95 (2009) 39-43.
[17] G. Demopolous, V.G. Papangelakis, Hydrometallurgy, 49 (1998) 23.
[18] G. Svehla, VOGEL’S Textbook of Macro and Semi-micro Qualitative Inorganic Analysis, 5th Ed.,
Longman, London, 458, 1979.
[19] G.W. Warren, S. Kim, H. Henein, Metallurgical Transactions B, 15B (1986) 59-69.
[20] O.Levenspiel, Chemical Reaction Engineering, 2nd ed., Wiley, New York, 1972.
[21] H.Y. Shon, M.E. Wadsworth, Rate Process of Extractive Metallurgy, Plenum Press, New York,
1979.
[22] S. Aydogan, A. Aras, M. Canbazoghu, Chem. Engr. Journal, 114 (2005) 67-72.
[23] E. Olanipekun, Hydrometallurgy, 53 (1999) 1-10.
A.A. Baba & et al. / J. Iran. Chem. Res. 4 (2011) 291-300
300
[24] M.M. Antonijevic, M. Dimitrijevic, Z. Jankovic, Hydrometallurgy, 46 (1997) 71-83.
[25] A.A. Baba, F.A. Adekola, Hydrometallurgy, 10 (2010) 69-75.

Simultaneous spectrophotometric determination of ampicillin and penicillin in human plasma using multivariate calibration
Print Date : 2012-03-20
Simplex design method in simultaneous spectrophotometric determination of silicate and phosphate in boiler water of power plant and sewage sample by partial least squares
Print Date : 2010-12-20
Review High-performance liquid chromatographic enantioseparation of drugs containing multiple chiral centers on chiral stationary phases
Print Date : 2009-03-20
Kinetic study of cis-polybutadiene epoxidation by using 1HNMR spectroscopy in buffered oxone® solution with tetra-n-butyl ammonium bromide as phase transfer catalyst (PTC)
Print Date : 2011-03-20
Copper concentration using micelle-mediated extraction in real samples
Print Date : 2008-10-20
Anodic stripping voltammetry determination of Pb, Cd, Zn, and Cu in blood samples of children in some areas of Ibb governorate
Print Date : 2011-03-20

Share To

Article Url

Kinetic analysis of total Lead from spent Car battery by hydrochloric acid leaching