A  Systematic Investigation of Microwave Heating in Oxidised  Platinum Group Metal Ores

Edmore Takunda Mushonga; Clemence Sumanya; Wilbert Mtangi; David Jambgwa Simbi

Authors

Edmore Takunda Mushonga Institute of Materials Science, Processing and Engineering Technology, Chinhoyi University of Technology, Chinhoyi, Zimbabwe
Clemence Sumanya Institute of Materials Science, Processing and Engineering Technology, Chinhoyi University of Technology, Chinhoyi, Zimbabwe
Wilbert Mtangi Research, Innovation and Business Incubation Directorate, Chinhoyi University of Technology, Chinhoyi, Zimbabwe
David Jambgwa Simbi Institute of Materials Science, Processing and Engineering Technology, Chinhoyi University of Technology, Chinhoyi, Zimbabwe

Keywords:

Mineral processing, platinum group metal oxidic ores, microwaves, mineral liberation, differential heating

Abstract

Extraction of valuable Platinum Group Metals (PGM) in oxidised ores has been fraught with challenges due to their physio-chemical properties that hinder high/economic extraction rates. The aim of this study was to understand the potential of microwave heating to enhance mineral liberation in oxidized PGM ores (assumed to be represented by their respective metals) in microwave heating are studied using COMSOL Multiphysics computer simulations. The results showed that the ore constituents exhibited differential heating rates when mixed with a microwave absorbing additive, which is key to achieving thermal fracture within the ore to enhance mineral liberation. Also, an increase in microwave power resulted in an increase in the differential heating rate in the oxidized ores when an additive was present, suggesting that the presence of a microwave absorbing additive to the ores greatly improves the differential volumetric heating rate of oxidised ores. Of the elements tested, iron seems to have potential in increasing microwave heating in the oxidised ores when no additive is introduced. Copper was observed to be the one to first change state when heated thus giving a limit to the point at which the samples are heated. These findings suggest that microwave heating has the potential to be a viable technology for enhancing mineral liberation in oxidized PGM ores. Further research, such as A more detailed understanding of the size range of ore particles that are susceptible to differential heating at the micro-scale, is needed to optimize the microwave heating process and to develop new mineral processing techniques based on microwave heating. Overall, the study showed that microwave heating has the potential to be a versatile and effective technology for mineral liberation in oxidized PGM ores. Further research is needed to optimize the microwave heating process and to develop new mineral processing techniques based on microwave heating.

References

Chen, T. D. J. H. K. W. W. a. K. S., 1984. The relative transparency of minerals to microwave radiation. Canadian Metallurgical Quarterly, 23(3), pp. 349-351..

Gao-Ming, L., Xia-Ting, F. & Yuan-Hui, L. &. X., 2019. The Microwave-Induced Fracturing of Hard Rock. Rock Mechanics and Rock Engineering, pp. 1-13.

Haque, K., 1999. Microwave energy for mineral treatment processes a brief review. International Journal of Mineral Processing, 57(1), pp. 1-24.

Hill, J. M. & Jennings, M. J., 1993. Formulation of model equations for heating by microwave radiation. Applied Mathematical Modelling, pp. 369-379.

Hwang, Z. P. a. J.-Y., 2014. Microwave-assisted metallurgy. International Materials Reviews, 60(1), pp. 30-63. International Trade Administration, 2021. Zimbabwe - Country Commercial Guide, USA: International Trade Administration.

Jones, D., Lelyveld, T., Mavrofidis, S. & Kingman, S. &. M. N., 2002. Microwave Heating Applications in Environmental Engineering A Review. Resources, Conservation and Recycling, 34, 75-90.

Jones, R., 1999. Platinum smelting in South Africa. South African Journal of Science, 95, 525-534.

Jones, R., 2005. An overview of Southern African PGM smelting, nickel and cobalt 2005:Challenges in extraction and production. Alberta, Canadian Institute of Mining, Metallurgy and Petroleum.

Kelly.R.M & Rowson.N.A, 1995. Microwave reduction of oxidised ilmenite concentrates. Jouirnal of Minerals Engineering, 8(11), pp. 1427-1438.

Kingman, S., 2006. Recent developments in microwave processing of minerals. International Materials Reviews, February, p. 13.

Kingman, S., Vorster, W. & Rowson, N., 1999. The Influence of Mineralogy on Microwave Assisted Grinding. Minerals Engineering, 13(3), pp. 313-327.

Kingman, S. W. a. R. A., 1998. Microwave treatment of minerals – a review. Minerals Engineering, 11, 1081-1087.

Liddell KS, M. L. D. R., 1986. Process routes for beneiciation of noble metals from Merensky and UG-2 ores. Mintek Review, 4, 33-44.

Liu, C. & Xu, Y. a. H. Y., 1990. Application of microwave radiation to extractive metallurgy. Journal of Material Science and Technology, 6, 121-124. 27

Lovás, M., Murová, I., Mockovciaková, A. & Rowson, N. &. J. Š., 2003. Intensification of Magnetic Separation and Leaching of Cu-Ores by Microwave Radiation. Separation and Purification Technology, 31, 291-299.

Lovás, M., Znamenáčková, I., Zubrik, A. & Dolinská, M. K. a. S., 2011. The Application of Microwave Energy in Mineral Processing – a Review. Acta Montanistica Slovaca, pp. 137-148.

Lu, G., Li, Y. & Hassani, F. a. Z. X., 2017. The influence of microwave irradiation on thermal properties of main rock-forming minerals. Applied Thermal Engineering, 112, 1523 -1532. material-properties.org, 2021. material-properties.org. [Online] Available at: https://material-properties.org/properties-of-chemical-elements/

Mugumbate, F., n.d. OVERVIEW OF ZIMBABWE’S MINERAL RESOURCE POTENTIAL – TIP OF THE ICEBERG?, s.l.: Zimbabwe Geological Survey.

Multiphysics, C., 2016. Application Gallery Microwave Oven. In: s.l.:s.n.

Oberthür, T. M. F. B. P. a. L. M., 2013. The oxidized ores of the Main Sulphide Zone, Great Dyke, Zimbabwe: turning resources into minable reserves - mineralogy is the key. Journal of the Southern African Institute of Mining and Metallurgy, 13(3), pp. 00-00.

Ramonotsi, M., 2011. Characterisation of the effect of alteration on the PPM platinum ore and evaluation of selected strategies to improve metallurgical performance. Capetown, University of Cape Town. RT, J., 1999. Platinum smelting in South Africa. South African Journal of Science, Volume 95, pp. 525-534.

Safarzadeh MS, H. M. V. R. A., 2018. Review of recovery of platinum group metals from copper leach residues and other resources. Mineral Processing and Extractive Metallurgy Review, 39(1), pp. 1-17.

Sefako, R. S. V. a. S., 2019. PGM extraction from oxidized ores using flotation and leaching. The Southern African Insitute of Mining and Metallurgy, November.p. 929.

Shackleton, N. M. V. a. O. C., 2007. Surface characteristics and flotation behaviour of platinum and palladium telluride. Minerals Engineering, 20(13), p. 1232–1245.

StandishH.K, W. ,., 1991. Particle size effect in microwave heating of granular materials. Powder Technology, 66(3), pp. 225-230.

Standish, N. &. W. H., 1996. Microwave Application in the Reduction of Metal Oxides. Journal of Microwave Power and electromagnetic Energy, 25(3), pp. 177-180.

T. Oberthür, F. M. P. B. a. M. L., 2012. The oxidized ores of the Main Sulphide Zone, Great Dyke, Zimbabwe: turning resources into minable reserves–mineralogy is the ke. Journal of the Southern African Institute of Mining and Metallurgy, 113(3). 28

Ulloa, R. Z., Santiago, M. G. H. & Rueda, V. L. V., n.d. The Interaction of Microwaves with Materials of Different Properties. In: Electromagnetic Fields and Waves. s.l.:IntechOpen.

A Systematic Investigation of Microwave Heating in Oxidised Platinum Group Metal Ores

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