Abstract
Water is the mainstay for beneficiation of fine size coal and minerals; however, it is also the least desirable constituent in the final product. The basic concept of the novel process described in this paper is based on the differential surface heat conduction/absorption capacity of individual particles, which differs for different species of minerals. When a mixture of fine material is exposed to a radiant energy source, the various solids present in the mixture will absorb heat energy depending on their heat-conducting properties and there will be a difference in the surface temperature of the particles. When this differentially heated solid mixture is placed on a moving belt, which is coated with a low temperature melting resin, the hotter component of the mixture will stick to the belt and relatively cooler particles will stay free on the belt and fall off at the end of the belt run. Experiments were conducted with pyrite, coal, and quartz of 6 × 18 mesh particle size. The goal of the test program was to find the optimum conditions at which there exists a required temperature difference between minerals and coal particles by controlling the operating system variables. Preliminary tests results showed that there is a potential for separating mineral matter from coal using the thermo-adhesive separation technique.
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References
Bison RJ, Tangel OF (1959) Thermoadhesive separation of colored glass. Min Eng 12:1229
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Patil, D.P., Parekh, B.K. Thermo-adhesive Separation: a Novel Dry Coal Beneficiation Technique. Mining, Metallurgy & Exploration 39, 23–30 (2022). https://doi.org/10.1007/s42461-021-00519-3
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DOI: https://doi.org/10.1007/s42461-021-00519-3