Statistical Analysis of Species Interaction and Optimization of Copper Flotation Process
Authors
-
Department of Fuel & Mineral Engineering, IIT(ISM), Dhanbad, Jharkhand, 826004 ,IN
Silpa Sweta Jena -
Department of Fuel & Mineral Engineering, IIT(ISM), Dhanbad, Jharkhand, 826004 ,INAbhyarthana Pattanaik
-
Department of Fuel & Mineral Engineering, IIT(ISM), Dhanbad, Jharkhand, 826004 ,INR. Venugopal
Keywords:
Chalcopyrite ore, flotation, reagent, metallurgical performance, statistical analysis.Abstract
Studies have been carried out for analyzing the flotation performance of chalcopyrite ore from Rakha mines, Jharkhand. The full factorial methodology has been used for design of experiments. The reagents (collector and frother) dosages and time were independent variables and recovery and grade has been considered as responses. The minimum and maximum values of operating conditions were chosen after performing preliminary experiments at different operating conditions. The effect of the variables (species interaction - main and interactional) on recovery and grade were studied. In this work, the experimental data were compared to data obtained from the factorial design of experiments to check the validation of model. The results obtained for bulk were analyzed to calculate the optimized condition for effective recovery and grade.
Downloads
Metrics
Downloads
Published
How to Cite
Issue
Section
License
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
References
Aslan, N., and Ünal, Ý. (2009): Optimization of some parameters on agglomeration performance of Zonguldak bituminous coal by oil agglomeration. Fuel, vol.88, pp.490–496.
Azizi, D., Gharabaghi, M., and Saeedi, N. (2014): Optimization of the coal flotation procedure using the Plackett - Burman design methodology and kinetic analysis. Fuel Processing Technology, vol.128, pp.111- 118.
Çilek, E.C., and Yýlmazer, B.Z. (2003). Effects of hydrodynamic parameters on entrainment and flotation performance”, Minerals Engineering, vol.16, pp.745-756.
Hangone, G., Bradshaw, D., and Ekmekci, Z. (2005): Flotation of a copper sulphide ore from Okiep using thiol collectors and their mixtures. The journal of the South African Institute of Mining and Metallurgy, vol.106, pp.199-206.
Joglekar, A.M., and May, A.T. (1987): Product excellence through design of experiments. Cereal Foods World, vol.32, pp.857–868.
Mohanty, M.K., and Honakar, R.Q., (1999): Performance optimization of Jameson flotation technology for fine coal recovery. Minerals Engineering, vol.12, pp.367-381.
Martýìnez-L.A., Uribe, S. A., Carrillo, P. F.R. , Coreño, A. J., and Ortiz, J.C. (2003): Study of celestite flotation efficiency using sodium dodecyl sulfonate collector: factorial experiment and statistical analysis of data. International Journal of Mineral processing, vol.70, pp.83-97.
Naik, P.K., Reddy, P.S.R., and Misra, V.N. (2004): Optimization of coal flotation using statistical technique. Fuel Processing Technology, vol.85, pp.1473-1485.
Naik. P.K., Reddy. P.S.R., and Misra V.N. (2005): Interpretation of interaction effects and optimization of reagent dosages for fine coal flotation”, International Journal of Mineral Processing, Vol.75, pp.83-90.
Naik, P.K. (2002a): Quantification of induced roll magnetic separation of mineral sands. Scandinavian Journal of Metallurgy, vol.31, no.6. pp.367-373.
Naik, P.K.S., and Das, S.C. 2002b. Extraction of manganese from low grade Nishikhal ore using pyritiferous lignite in acidic medium. Minerals and Metallurgical Processing, vol.19, pp.110-112.
Owusu, C., Fornasiero, D., Addai-Mensah,J., and Zanin, M. (2015): Influence of pulp aeration on the flotation of chalcopyrite with xanthate in chalcopyrite/ pyrite mixtures. International Journal of Mineral Processing, Vol-134, pp 50-57.
Özgen, S., Yildiz, A., Çalýþkan, A., and Sabah, E. (2009): Modelling and optimization of hydro cyclone processing of low grade bentonites. Applied Clay Science, vol.46, no.3, pp.305-313.
Rao, G.V., and Mohanty. S. 2002. Optimization of flotation parameters for enhancement of grade and recovery of phosphate from lowgrade dolomitic rock phosphate ore from Jhamarkotra, India. Minerals and Metallurgical Processing, vol.19, pp.154-160.
Rao, T.C., Pillai, K.J., and Vanangamudi, M., (1982): Statistical analysis of coal flotation– a prelude to process optimization. Proceedings of the IX International Coal Preparation Congress, New Delhi, 1982 (pp. c2-1 -c2-12).
Sutherland K.L., Wark, I.W. (1955): Principles of Flotation. Australasian Institute of Mining and Metallurgy, Malbourne, Australia, pp.92.
Thorne, G.C., Manlapig, E.V., Hall J.S., and Lynch, A.J. (1976): Modelling of industrial sulphide flotation circuits. Flotation – A. M. Gaudin Memorial Volume, (Ed) M.C.Fuerstenau, p.725.
Twidle, T.R., and Engelbrecht, P.C. (1984): Developments in the flotation of copper at Black Mountain. The Journal of the South African Institute of Mining and Metallurgy, vol 84, no.6, pp-164-178.
Wills’, B.A. and Finch, J.A. (2016): “Wills’ Mineral Processing Technology: An Introduction to the Practical Aspects of Ore Treatment and Mineral Recovery”, 8th edition, Elsevier Science and Technology Books, Amsterdam.
