A process mineralogy approach to gravity concentration of tantalum bearing minerals

Ghorbani, Y., Fitzpatrick, R., Kinchington, M. , Rollinson, G. and Hegarty, P. (2017) A process mineralogy approach to gravity concentration of tantalum bearing minerals. Minerals, 7 (10). ISSN 2075-163X

Full content URL: https://doi.org/10.3390/min7100194

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Item Type:Article
Item Status:Live Archive


The historic Penouta mine in northwest Spain is the focus of efforts to extract tantalum from tin mining waste. This paper describes the characterisation of the tantalum mineralogy of waste material from the deposit. Characterisation was realised using quantitative mineralogy and geochemistry. This paper further identifies other phases of interest and investigates the potential for extraction using gravity separation techniques. The gravity concentrate obtained through these tests was analysed using quantitative mineralogy and electron probe microanalysis. Following characterisation of the sample material to identify the key Ta-bearing mineral phases and assess liberation, a series of gravity separation trials were conducted using Heavy Liquid Separation (HLS), Mozley table, Knelson concentrator separation and shaking table. The laboratory shaking table used to conduct a rougher test and a rougher/cleaner test to simulate a spiral-table circuit using the Penouta material. Mass balance calculations were carried out to calculate the contained metal content of the feed material and concentrate products in order to assess recovery rates for Ta, Sn and Nb across a range of grains sizes. Ta was found to be present predominantly in the solidsolution columbite-group mineral, along with minor Ta present as microlite and as impurities within cassiterite. It was found that over 70% of the Ta is contained within the -125 µm fraction, with the Ta-bearing minerals tantalite and microlite being closely associated with quartz. Mozley table separation resulted in recoveries of 89% Ta and 85% Nb for the -125 µm fraction. The Knelson Concentrator trial was carried out on the -625 µm size fraction, thereby eliminating low grade material found in the coarsest fractions. Size analysis of the recovery rate for each product, shows that the Knelson concentrator is most efficient for recovery of -125 µm particles. © 2017 by the authors. Licensee MDPI, Basel, Switzerland.

Additional Information:cited By 20
Keywords:Gravity concentration, Penouta mine, Process mineralogy, Tantalum bearing minerals
Subjects:F Physical Sciences > F100 Chemistry
Divisions:College of Science > School of Chemistry
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ID Code:54541
Deposited On:06 Jul 2023 09:29

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