Abstract
Chromitiferous overburden containing nickel in oxide form is reduced with CO-CO2-N2 gas mixtures. This converts the nickel oxide to metallic nickel and restricts the iron oxide to the magnetite state to extract the nickel. Reduction experiments were carried out on 500-g samples in a bench-scale vertical reactor. The tests were run to establish the process parameters, including the optimum partial pressure of CO, the reducing gas flow rate, granule size and roasting time. The reduced calcine is then subjected to an ammonia-ammoniacal carbonate leach to extract nickel selectively as its amine complex. More than 90% of the nickel could be extracted with a volumetric CO/(CO+CO2) ratio of 0.57 at 750°C and a roasting time of 90 min. The addition of 2.5% (by weight) charcoal to the granules improved nickel extraction by 11% to 19%. Nickel leaching efficiency with ammoniacal solution is compared to the bromine-methanol method.
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Swamy, Y.V., Murthy, B.V.R. & Reddy, B.R. Extraction of nickel from chromitiferous overburden by roasting with a CO-CO2-N2 gas mixture. Mining, Metallurgy & Exploration 17, 223–227 (2000). https://doi.org/10.1007/BF03403238
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DOI: https://doi.org/10.1007/BF03403238