A compartment model for the mass transfer inside a conventional flotation cell |
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| Institution: | 1. Mining and Metallurgy Institute, Bor, Sector for Science, Mineral Processing Department, Zeleni Bulevar 35, Bor, Serbia;2. University of Belgrade, Faculty of Mining and Geology, Department of Applied Computing and System Engineering, Djusina 7, Belgrade, Serbia;3. JKP 3. Oktobar Bor, 7 juli 60, Bor, Serbia;1. CSIRO, Mineral Resources, Bayview Ave., Clayton, Vic 3169, Australia;2. Macquarie University, 2 Technology Place, North Ryde, NSW 2109, Australia |
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| Abstract: | A model is developed by taking into account the simultaneous mechanisms of true flotation and entrainment in a conventional flotation cell. The total volume of the cell is divided into three compartments: pulp collection zone, pulp quiescent zone and froth region, with the mechanisms being modeled as occurring at the same time but originating at different places: true flotation from the collection zone and entrainment from the quiescent one. A particle is referred to as suspended in water or attached to an air bubble, depending upon its original state before crossing the pulp–froth interface (whether or not it remains in that state all the way to the concentrate launder). The model is obtained by solving a set of equations describing the mass conservation of solids and water between adjacent compartments. The principal mass transfer factors are identified as: the flotation rate constant, the mean residence time in the collection zone, the froth recovery of attached particles, the degree of entrainment through the froth and the water recovery from the feed to the concentrate. The development presented here allows the intricate nature of the mass transfer in a flotation cell to be reduced to one single equation, overcoming the need of numerical methods for simulation purposes. Moreover, it is shown that reliable prediction of grade and recovery can be obtained without detailed information on the pulp hydrodynamics or on any froth sub-process either than drainage, bubble bursting and bubble coalescence. |
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