Hydrodynamic enhancement of flotation using a Reflux flotation cell

Dickinson, James; Galvin, Kevin

Title: Hydrodynamic enhancement of flotation using a Reflux flotation cell
Creator: Dickinson, James; Galvin, Kevin
Relation: XXVII International Mineral Processing Congress. IMPC2014: Online Proceedings (Santiago Chile 20-24 October, 2014) p. 5-1-5-10
Relation: http://www.impc2014.org/english/proceedings
Publisher: Gecamin Digital Publications
Resource Type: conference paper
Date: 2014
Description: The Reflux Flotation Cell (RFC) consists of an inverted fluidized bubbly bed, located above a system of parallel inclined channels. This novel arrangement enhances the hydrodynamics of flotation in a number of ways. Firstly, the free-surface of the flotation cell is enclosed via a fluidized bed distributor, ensuring uniform application of wash water to promote desliming. Secondly, foams can be variable in their stability and lack permeability. Hence this system is preferably operated in the absence of foam, instead opting for a bubbly zone of high bubble volume fraction through the use of a very high gas flux and/or wash water flux. Discharge of the product proceeds upwards through a central port of narrow cross-sectional area. Thirdly, the system of inclined channels increases the segregation between the bubbles and the water, ensuring the bubbly zone remains contained within the upper vertical zone, and the liquid flux reporting to the overflow is low. The expanded operating regime of the RFC was investigated by covering a very broad range of gas fluxes, up to 5.5 cm/s, and wash water fluxes, over 2 cm/s. Both laboratory and pilot plant performances were quantified by the recovery of hydrophobic particles and rejection of the hydrophilic particles, using model and industrial coal feeds. The new system hydrodynamics was found to offer significant advantages in flotation kinetics, desliming, and particle recovery across a broad particle size range. Bubble interfacial flux reached as high as 600 m2/m-2s-1. The upper system consists entirely of a high volume fraction of bubbles, which provides a “safety-net” to protect against the detachment of coarse particles, and a highly permeable zone for counter-current washing of the flotation product. Under relatively extreme conditions selective stripping of the product is observed, resulting in grade recovery values beyond those achievable using the tree flotation method.
Subject: flotation machines; hydrodynamics; kinetics
Identifier: http://hdl.handle.net/1959.13/1067519
Identifier: uon:18418
Identifier: ISBN:9789569393167
Language: eng
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