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Optimization of flotation conditions in the beneficiation of PGMs tailings

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Języki publikacji
EN
Abstrakty
EN
For several years, mining waste has shown a negative impact on both the environment and human health. The mining industry remains the backbone of the economic growth. Different technologies have been implemented to beneficiate and recover platinum group metals from tailings. The recycling of tailings has been a point of research interest due to their extensive applications. Flotation has been the primary process of upgrading and recovering PGMs. The focus of this study was to optimize flotation conditions in the beneficiation of PGMs for particular small-scale mine tailings. This was done to obtain the most favourable conditions for the small-scale mine tailings to improve operating conditions of specific particle sizes. PGMs tailings obtained from a small-scale mine were characterized using XRD, XRF, SEM/EDS, and ICP - OES to understand the properties of the tailings prior to mineral processing. Flotation batch tests were conducted. The results showed that the chosen particle size was 75 µm, and the favorable reagent dosages were 150 g/Mg and 100 g/Mg for SIBX (collector) and Starch(depressant), respectively. At favourable conditions, the recovery was 65.75% (Pt = 70.38%, Pd = 59.33%, Ru = 34.56%), and the grade was 31.46 g/Mg (Pt = 21.43 g/Mg, Pd = 9.62 g/Mg, Ru = 0.41 g/Mg). It can be concluded that all the flotation parameters are related; lower particle sizes yield high recoveries and better grades due to the exposure of the particle surface to the reagents responsible for the flotation of the PGMs. It was observed that the high collector dosages produce high recoveries with low grades of PGMs. High depressant dosages produce low recoveries with high grades of PGMs. The relationship between the collector and the depressant is of essential importance in the flotation process.
Rocznik
Strony
art. no. 176859
Opis fizyczny
Bibliogr. 28 poz., rys., tab., wykr.
Twórcy
  • Department of Chemical, Metallurgical and Materials Engineering, Tshwane University of Technology, Pretoria, 0002, South Africa
  • Department of Chemical, Metallurgical and Materials Engineering, Tshwane University of Technology, Pretoria, 0002, South Africa
  • Department of Chemical, Metallurgical and Materials Engineering, Tshwane University of Technology, Pretoria, 0002, South Africa
Bibliografia
  • ALVAREZ-SILVA, M., WIESE, J., O’CONNOR, C.T., 2014. An investigation into the role of froth height and depressant dosage in the recovery of chromite in the flotation of UG2 ore using a laboratory column. Minerals Engineering, 55,.125- 131.
  • DAWSON, N.F., 2010. Experiences in the production of metallurgial and chemical grade UG2 chromite concentrate from PGM tailings streams. The Journal of The Southern African Institute of Mining and Metallurgy , 110, 683-690.
  • GAUDIN, A.M., SCHUHMANN, R., SCHLECHTEN, A.W., 1942. Flotation Kinetics II: The effect of size on the behavior of galena particles. Journal of Physical Chemistry, 46(8), 902-910.
  • GIBSON, B.A.K.K., NWAILA, G., MANZI, M., GHORBANI, Y., NDLOVU, S., PETERSEN, J., 2023. The valorisation of platinum group metals from flotation tailings: A review of challenges and opportunities. Minerals Engineering, 201, 105216.
  • GUPTA , A., YAN, D.S., 2016. Chapter 18: Flotation. In: Mineral Processing Design and Operations: An Introduction. Western Australia : Elsevier, 689-741.
  • HUDSON-EDWARDS, K., 2016. Tackling mine wastes. Science, 352, 288-290.
  • JAMESON, G.J., NGUYEN, A.V., ATA, S., 2007. Froth flotation: A century of innovation. In: M. C. Fuerstenau, G. J. Jameson & R. Hoon, eds. The flotation of fine and coarse particles. Littleton, CO: Society for Mining, Metallurgy and Exploration, 339–372.
  • JENA, M.S., MOHANTY, J.K., VENUGOPAL, R., MANDRE, N.R., 2016. Characterization of low grade PGE ores of Boula-Nuasahi Area, Odisha, India and implication on beneficiation. Ore Geology Reviews, 72, 629–640.
  • KAWATRA, S.K., 2011. Fundamental principles of froth flotation. In: D. P, ed. SME Mining Engineering Handbook 2. 3rd Edition ed. s.l.:s.n., 1517-1531.
  • KAWATRA, S.K., 2016. Froth Flotation-fundamental principles. [Online] Available at: http://www.chem.mtu.edu/chem_eng/faculty/kawatra/Flotation_Fundamentals.pdf [Accessed 6 March 2016].
  • LANGA, N.T., ADELEKE, A.A., MENDONIDIS, P., THUBAKGALE, C.K., 2014. Evaluation of sodium isobutyl xanthate as a collector in the froth flotation of a carbonatitic copper ore. International Journal of Industrial Chemistry, 5, 107–110.
  • MATTHEY, J., 2013. Platinum, United Kingdom: JM.
  • MBERI, T., MGUNI, L.L., NTULI, F., 2018. Effect of frother and depressant interaction on flotation of Great Dyke PGM ore. The Journal of the Southern African Institute of Mining and Metallurgy, 118, 65-69.
  • MOIMANE, T.M., CORIN, K.C., WIESE, J.G., 2016. The effect of varying pulp reagent chemistry on the flotation performance of a South African PGM ore. Minerals Engineering, 95, 155–160.
  • MPONGO, M.K. & SIAME, E., 2006. Effect of collector, frother and depressant addition on the copper recovery and concentrate grade of the Nchanga underground scavenger circuit of Konkola coppermine-Zambia. Afr J Sci Technol (AJST) Sci Eng Ser , 7(1), 8–11.
  • NIKOLOSKI, A.N., KWANG-LOON, A., LI, D., 2015. Recovery of platinum, palladium and rhodium from acidic chloride leach solution using ion exchange resins. Hydrometallurgy, 152, 20-32.
  • NORORI-MCCORMAC, A., BRITO-PARADA, P.R., HADLER, K., COLE, K., CILLIERS, J.J., 2017. The effect of particle size distribution on froth stability in flotation. Separation and Purification Technology, 184, 240–247.
  • PANI, S., 2013. Study of effect of process parameters and their interaction in the flotation of UG2 ore, Cape Town: University of Cape Town.
  • RAMIREZ-LLODRA, E., TRANNUM, H.C., EVENSET, A., LISALEVIN, L.A., ANDERSSON, M., FINNE, T.E., HILARIO, A., FLEM, B., CHRISTENSEN, G., SCHAANNING, M., VANREUSEL, A., 2015. Submarine and deepsea mine tailing placements: a review of current practices environmental issues, natural analogs and knowledge gaps in Norway and internationally. Mar. Pollut. Bull., 97, 13-35.
  • RODUNER, E., 2006. Size matters: Why nanomaterial are different. Chemical Society Reviews, 35, 583-592.
  • SEFAKO, R., 2018. Recovery of PGMs from an oxide ore by flotation and leaching, Johannesburg, South Africa: University of the Witwatersrand.
  • SEKGARAMETSO, K., 2018. Flotation of non-sulphide PGM ores - Optimization of flotation reagent suite and conditions, Johannesburg: University of Witwatersrand.
  • SUORANTA, T., ZUGAZUA, O., NIEMELÄ, M., PERÄMÄKI, P., 2015. Recovery of palladium, platinum, rhodium and ruthenium from catalyst materials using microwave-assisted leaching and cloud point extraction. Hydrometallurgy, 154 , 56–62.
  • UCURUM, . M. & BAYAT , O., 2007. Effect of operating variables on modified flotation parameters in the mineral separation. Separation and Purification Technology, 55(2), 173-181
  • VACCAREZZA, V., 2018. Beneficiation and hydrometallurgical treatment of norra kärr eudialyte mineral, Golden: Colorado School of Mines.
  • WANG, M., TAN, Q., CHIANG, J.F., LI, J., 2017. Recovery of rare and precious metals from urban mines—A Review. Frontiers of Environmental Science and Engineering, 11(5), 1.
  • WIESE, J., HARRIS, P. & BRADSHAW, D., 2005. Investigation of the role and interactions of a dithiophosphate collector in the flotation of sulphides from the Merensky reef. Minerals Engineering, 18(8), 791-800.
  • WIESE, J. G., BECKER , M., BRADSHAW, D.J., HARRIS, P. J., 2006. Interpreting the role of reagents in the flotation of platinum bearing Merensky ores. Rondebosch, South Africa, International Platinum Conference ‘Platinum Surges Ahead’.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-f6af355a-981a-4bcf-897a-445144f238c8
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