Please use this identifier to cite or link to this item: https://cris.library.msu.ac.zw//handle/11408/5495
Title: Using Process Mineralogy as a Tool to Investigate Blending Potential of the Pentlandite-Bearing Ores at the Nkomati Ni Mine in South Africa
Authors: Thomas Dzvinamurungu
Derek Hugh Rose
Ngonidzashe Chimwani
Fanus Viljoen
Midlands State University, Private Bag 9055, Senga Road, Gweru, Zimbabwe
Department of Geology, University of Johannesburg, Auckland Park, Kingsway Campus, P.O. Box 524, Johannesburg 2006, South Africa
Department of Mining, University of South Africa (UNISA), Florida Campus, Private Bag X6, Johannesburg 1710, South Africa * Author to whom correspondence should be addressed.
Department of Geology, University of Johannesburg, Auckland Park, Kingsway Campus, P.O. Box 524, Johannesburg 2006, South Africa
Keywords: ore texture
grind sizes
milling
liberation analysis
pentlandite
flotation
flotation kinetics
recovery
Issue Date: 20-May-2022
Publisher: MDPI
Abstract: The mineralogy and texture of Ni-sulfide ores at the Nkomati nickel mine are highly variable, and this results in often erratic nickel recovery at the mine. The variability of the ore presents an opportunity to study the influence of grind size on the flotation-based recovery of Ni in highly heterogeneous sulfide ores, which would be applicable to this ore type at many other mines worldwide. In view of this, a process mineralogy investigation was conducted on thirteen mineralogically and texturally different nickel-sulfide ores from the Nkomati Nickel Mine, with a view on the influence of grind size on the flotation performance of pentlandite. Ore types presented include medium- and high-grade variants of the bleb, disseminated, massive, semi-massive, and net-textured sulfide ores of the Main Mineralized Zone (MMZ), as well as disseminated chromite-rich nickel sulfide ore and massive chromitite ore of the Peridotitic Chromitite Mineralized Zone (PCMZ). Laboratory scale metallurgical test work, comprising of sequential grinding and bench-top flotation testing of the ores, was conducted in combination with quantitative mineralogical investigation of the flotation feed and associated flotation products, using a FEI 600F Mineral Liberation Analyzer. The ore types under consideration require a variety of grind sizes (i.e., milling times) in order to attain optimal recovery of nickel through flotation. This is predominantly controlled by ore texture, and also partly by the abundance of the major constituent minerals in the ore, being pyroxenes, base metal sulfides, and chromite. Liberation of pentlandite is directly correlated with grind size (milling time), which is also positively correlated with the level of nickel recovery through flotation. A grind size of P80 at 75 µm results in the highest concentrate nickel grades of 7.5–8.1% in the PCMZ ores’ types which is the current grind for the PCMZ ores at Nkomati. A grind size of P77 at 75 µm yields the best overall pentlandite liberation, Ni recoveries of 84–88% and grades of 5.3–5.6% in the MMZ ores. This holds the potential to produce the best overall pentlandite liberation, nickel grades, recoveries from blending the MMZ and PCMZ ore types, and milling the composite ore at a target grind of P80 at 75 µm.
Description: Abstract
URI: https://cris.library.msu.ac.zw//handle/11408/5495
Appears in Collections:Research Papers

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