Abstract
The performance characteristics of a multigravity separator for the recovery of heavy minerals of lead, zinc, copper and silver from a lead rougher-flotation concentrate were studied. Factorially designed experiments were carried out on three operating variables, i.e., the amount of wash water, the drum inclination and the drum rpm, of a multigravity separator. The experiments were carried out at two levels of each variable. With the experimental data, regression equations were developed for different metal grades and recoveries. The analysis revealed that drum speed has a major influence in determining the heavy-metal grade and recovery. Drum inclination is the next most important variable, with the amount of wash water being the least important. A concentrate containing 40% lead, 9.4% zinc, 1.5% copper and 1,400ppm silver was obtained with recoveries of 74.8%, 65.9%, 64.1% and 53.2%, respectively. Finally, the predicted values of grades and recoveries at intermediate levels are compared to actual experimental data to test the validity of the equations developed.
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Discussion of this peer-reviewed and approved paper is invited and must be submitted to SME prior to Nov. 30, 1999.
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Udaya Bhaskar, K., Barnwal, J.P., Rao, T.C. et al. Multigravity separator to enrich heavy minerals from a lead flotation concentrate. Mining, Metallurgy & Exploration 16, 61–64 (1999). https://doi.org/10.1007/BF03402811
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DOI: https://doi.org/10.1007/BF03402811