| 1 |
The effect of cell hydrodynamics on flotation performance
Tabosa E, Runge K, Holtham P
International Journal of Mineral Processing, 156, 99, 2016 |
| 2 |
Improving flotation energy efficiency by optimizing cell hydrodynamics
Tabosa E, Runge K, Hoitham P, Duffy K
Minerals Engineering, 96-97, 194, 2016 |
| 3 |
RESIDENCE TIME MEASUREMENTS IN PILOT-SCALE ELECTROLYTIC CELLS: APPLICATION OF LASER-INDUCED FLUORESCENCE
Schubert M, Kryk H, Hessel G, Friedrich HJ
Chemical Engineering Communications, 197(9), 1172, 2010 |
| 4 |
CFD SIMULATION ON INFLUENCE OF SUPERFICIAL GAS VELOCITY, COLUMN SIZE, SPARGER ARRANGEMENT, AND TAPER ANGLE ON HYDRODYNAMICS OF THE COLUMN FLOTATION CELL
Chakraborty D, Guha M, Banerjee PK
Chemical Engineering Communications, 196(9), 1102, 2009 |
| 5 |
Modelling attachment rates of multi-sized bubbles with particles in a flotation cell
Koh PTL, Schwarz MP
Minerals Engineering, 21(12-14), 989, 2008 |
| 6 |
CFD model of a self-aerating flotation cell
Koh PTL, Schwarz MP
International Journal of Mineral Processing, 85(1-3), 16, 2007 |
| 7 |
Hydrodynamics and scale up in Rushton turbine flotation cells: Part 2. Flotation scale-up for laboratory and pilot cells
Newell R, Grano S
International Journal of Mineral Processing, 81(2), 65, 2006 |
