XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3 2707
Dankwah, J. B., Asamoah, R. K., Zanin, M. &Skinner, W.
2022. Dense liquid flotation: Can coarse particle flo-
tation performance be enhanced by controlling fluid
density? Minerals Engineering, 180, 107513.
Farrokhpay, S. 2011. The significance of froth stability in
mineral flotation — A review. Advances in Colloid and
Interface Science, 166, 1–7.
Hanumanth, G. &Williams, D. 1992. A three-phase
model of froth flotation. International journal of min-
eral processing, 34, 261–273.
Jameson, G. J. 2012. The effect of surface liberation and
particle size on flotation rate constants. Minerals
Engineering, 36–38, 132–137.
Jameson, G. J., Cooper, L., Tang, K. K. &Emer, C. 2020.
Flotation of coarse coal particles in a fluidized bed: The
effect of clusters. Minerals Engineering, 146, 106099.
Jameson, G. J. &Emer, C. 2019. Coarse chalcopyrite recov-
ery in a universal froth flotation machine. Minerals
Engineering, 134, 118–133.
Johansson, G. &Pugh, R. J. 1992. The influence of particle
size and hydrophobicity on the stability of mineralized
froths. International Journal of Mineral Processing, 34,
1–21.
Kohmuench, J., Mankosa, M., Thanasekaran, H. &
Hobert, A. 2018. Improving coarse particle flotation
using the HydroFloat ™(raising the trunk of the ele-
phant curve). Minerals Engineering, 121, 137–145.
Mankosa, M. J., Kohmuench, J. N., Luttrell, G. H.,
Herbst, J. A. &Noble, A. Split-feed circuit design
for primary sulfide recovery. Proceedings, XXVIII
International Mineral Processing Congress, September,
2016. 11–15.
Morris, G., Hadler, K. &Cilliers, J. 2015. Particles in
thin liquid films and at interfaces. Current Opinion in
Colloid &Interface Science, 20, 98–104.
Norori-Mccormac, A., Brito-Parada, P., Hadler, K.,
Cole, K. &Cilliers, J. 2017. The effect of particle size
distribution on froth stability in flotation. Separation
and Purification Technology, 184, 240–247.
Pugh, R. 2005. Experimental techniques for studying the
structure of foams and froths. Advances in colloid and
interface science, 114, 239–251.
Rahman, R. M., Ata, S. &Jameson, G. J. 2012. The effect
of flotation variables on the recovery of different parti-
cle size fractions in the froth and the pulp. International
Journal of Mineral Processing, 106, 70–77.
Schramm, L. L. &Wassmuth, F. 1994. Foams: basic prin-
ciples. ACS Publications.
Soto, H. &Barbery, G. 1991. Flotation of coarse particles
in a counter-current column cell. Mining, Metallurgy
&Exploration, 8, 16–21.
Sutherland, K. L. 1955. Principles of flotation. In: WARK, I.
W. (ed.) [Rev. and enlarged ed.] ed. Melbourne ::
Australasian Institute of Mining and Metallurgy.
Vieira, A. M. &Peres, A. E. 2007. The effect of amine type,
pH, and size range in the flotation of quartz. Minerals
engineering, 20, 1008–1013.
Dankwah, J. B., Asamoah, R. K., Zanin, M. &Skinner, W.
2022. Dense liquid flotation: Can coarse particle flo-
tation performance be enhanced by controlling fluid
density? Minerals Engineering, 180, 107513.
Farrokhpay, S. 2011. The significance of froth stability in
mineral flotation — A review. Advances in Colloid and
Interface Science, 166, 1–7.
Hanumanth, G. &Williams, D. 1992. A three-phase
model of froth flotation. International journal of min-
eral processing, 34, 261–273.
Jameson, G. J. 2012. The effect of surface liberation and
particle size on flotation rate constants. Minerals
Engineering, 36–38, 132–137.
Jameson, G. J., Cooper, L., Tang, K. K. &Emer, C. 2020.
Flotation of coarse coal particles in a fluidized bed: The
effect of clusters. Minerals Engineering, 146, 106099.
Jameson, G. J. &Emer, C. 2019. Coarse chalcopyrite recov-
ery in a universal froth flotation machine. Minerals
Engineering, 134, 118–133.
Johansson, G. &Pugh, R. J. 1992. The influence of particle
size and hydrophobicity on the stability of mineralized
froths. International Journal of Mineral Processing, 34,
1–21.
Kohmuench, J., Mankosa, M., Thanasekaran, H. &
Hobert, A. 2018. Improving coarse particle flotation
using the HydroFloat ™(raising the trunk of the ele-
phant curve). Minerals Engineering, 121, 137–145.
Mankosa, M. J., Kohmuench, J. N., Luttrell, G. H.,
Herbst, J. A. &Noble, A. Split-feed circuit design
for primary sulfide recovery. Proceedings, XXVIII
International Mineral Processing Congress, September,
2016. 11–15.
Morris, G., Hadler, K. &Cilliers, J. 2015. Particles in
thin liquid films and at interfaces. Current Opinion in
Colloid &Interface Science, 20, 98–104.
Norori-Mccormac, A., Brito-Parada, P., Hadler, K.,
Cole, K. &Cilliers, J. 2017. The effect of particle size
distribution on froth stability in flotation. Separation
and Purification Technology, 184, 240–247.
Pugh, R. 2005. Experimental techniques for studying the
structure of foams and froths. Advances in colloid and
interface science, 114, 239–251.
Rahman, R. M., Ata, S. &Jameson, G. J. 2012. The effect
of flotation variables on the recovery of different parti-
cle size fractions in the froth and the pulp. International
Journal of Mineral Processing, 106, 70–77.
Schramm, L. L. &Wassmuth, F. 1994. Foams: basic prin-
ciples. ACS Publications.
Soto, H. &Barbery, G. 1991. Flotation of coarse particles
in a counter-current column cell. Mining, Metallurgy
&Exploration, 8, 16–21.
Sutherland, K. L. 1955. Principles of flotation. In: WARK, I.
W. (ed.) [Rev. and enlarged ed.] ed. Melbourne ::
Australasian Institute of Mining and Metallurgy.
Vieira, A. M. &Peres, A. E. 2007. The effect of amine type,
pH, and size range in the flotation of quartz. Minerals
engineering, 20, 1008–1013.