Abstract
Finely-ground hematitic ore, too high in silica (quartz) to be commercially viable, was treated by emulsion flotation. A three-component emulsion mixture was used at temperatures ranging from ambient (22° C) to 30° C, 40° C, 49° C, 59° C and 68° C. The optimal emulsion dosage and composition at ambient temperature were used to determine that dosage for higher-temperature flotation tests.
The crushed ore (100%, −8 mesh) was repeatedly washed with tap water, and the filtrate’s ionic content was analyzed. The separation efficiency values (a measure of the selective separation and concentration of hematite from gangue minerals) demonstrated temperature dependence, with marked increases at temperatures above ambient. The optimal separation efficiency occurred within the range from 30° C to 60° C.
The improved separation efficiencies at temperatures exceeding ambient are explained by quartz depression. This depression is attributed to:
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the precipitation of quartz-activating cations, principally calcium and magnesium, at increasing temperature; and
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temperature’s effect on the collector’s solubility and attachment to the aqueous hematite surface.
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SME nonmeeting paper 91-629.
Discussion of this paper must be submitted, in duplicate, prior to Nov. 30, 1992.
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Ofor, O. Effect of temperature on the emulsion flotation of hematite. Mining, Metallurgy & Exploration 9, 115–118 (1992). https://doi.org/10.1007/BF03402982
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DOI: https://doi.org/10.1007/BF03402982