[1] Gorain, B, Oravainen, H., Allenius, H., Peaker, R., Weber, A., and Tracyzk, F., 2009, Mechanical froth flotation cells, in Froth Flotation A Century of Innovation. Edited Fuerstenau, M.C., Jameson, G.J., Yoon, Society for Mining, Metallurgy, and Exploration, SME, Colorado, pp. 709-710
##
[2] Yianatos. J.B,
Moys. M.H, Villanueva. A. 2008. Froth recovery of industrial flotation cells. Minerals Engineering 21, 817– 825
[3] Amelunxen.P., Sandoval, G., Barriga, D, Amelunxen, R., 2014. The implications of the froth recovery at the laboratory scale. Minerals Engineering 66-68, 54– 61
[4] Amelunxen.P., LaDouceur, R., Amelunxen, R., Young, C., 2018. A phenomenological model of entrainment and froth recovery for interpreting laboratory flotation kinetics tests. Minerals Engineering 125, 60– 65
[5] Vera. M.A,
Z.TMathe. Z.T,
Franzidis. J.P,
Harris. M.C,
Manlapig.E.V,
O'Connor.C.T, 2002. The modelling of froth zone recovery in batch and continuously operated laboratory flotation cells. International Journal of Mineral Processing 64, 135-151
[6] Ata. S, 2012. Phenomena in the froth phase of flotation- A review. International Journal of Mineral Processing 102–103, 1–12
[7] Mathe. Z.T,
Harris. M.C,
O'Connor. C.T, 2000. A review of methods to model the froth phase in non-steady state flotation systems. Minerals Engineering, 13(2), 127-140
[8] Alexander. D.J, Franzidis. J.P, Manlapig. E.V, 2003. Froth recovery measurement in plant scale flotation cells. Minerals Engineering 16, 1197–1203
[9] Yianatos. J.B,
Bergh .L.G,
Cortés .G.A, 1998. Froth zone modeling of an industrial flotation column. Minerals Engineering, 11(5), 423-435
[10] Tsatouhas.G,
Grano. S.R, Vera. M, 2006. Case studies on the performance and characterization of the froth phase in industrial flotation circuits, Minerals Engineering 19, 774–783
[11] Farrokhpay.S, 2011. The significance of froth stability in mineral flotation - A review. Advances in Colloid and Interface Science 166, 1–7
[12] Yianatos. J.B., Vinnett, L., Carrasco, C., Alvarez-Silva, M., 2015. Effect of entrainment in bubble load measurement on froth recovery estimation at industrial scale. Minerals Engineering, 72, 31-35
[13] Finch, J.A., Dobby, G.S., 1990. Column Flotation, first ed. Pergamon Press, London, UK.
[14] Achaye.I, 2018. Effect of particle properties on froth stability.Ph.DThesis,University of Cape Town, South Africa, Cape Town
##
[15] Farrokhpay. S, Zanin, M 2011. Effect of water quality on froth stability in flotation. Chemeca 2011, Engineering a Better World Sydney, New South Wales, Australia, 18–21
##
[16] Xuan. Qu,
Wang. L,
Nguyen .V, 2013. Correlation of air recovery with froth stability and separation efficiency in coal flotation. Minerals Engineering 41, 25–30
##
[17] Feteris, S.M., Frew, J.A., Jowett, A., 1987. Modelling the effect of froth depth in flotation. International Journal of Mineral Processing 20, 121–135.
##
[18] Vera, M.A., Franzidis, J.P., Manlapig, E.V., 1999. Simultaneous determination of collection zone rate constant and froth zone recovery in a mechanical flotation environment. Minerals Engineering, 12, 1163–1176.
##
[19] Savassi, O.N., Alexander, D.J., Manlapig, E.V., Franzidis, J.P., 1998. An empirical model for entrainment in industrial flotation plants. Minerals Engineering, 11, 243–256
##
[20] Runge. K, Crosbie. R, Rivett. T, McMaster. J, 2010. An evaluation of froth recovery measurement techniques. XXV international mineral processing congress, 2313-2324
##
[21] Bhondayi.C, 2010. Measurements of particle loading on bubbles in froth flotation. Ph.D Thesis, University of the Witwatersrand,
Johannesburg South Africa
##
[22] Seaman. D.R,
Franzidis. J.P,
Manlapig. E.V., 2004. Bubble load measurement in the pulp zone of industrial flotation machines—a new device for determining the froth recovery of attached particles. International Journal of Mineral Processing 74, 1-13
##
[23] Falutsu, M., Dobby, G., 1992. Froth performance in commercial sized flotation columns. Minerals Engineering 5, 1207–1223.
##
[24] Bhondayi. C,
Moys. M.H, 2011. Determination of sampling pipe (riser) diameter for a flotation bubble load measuring device. Minerals Engineering 24, 1664–1676
##
[25] Rahman.R.M,
Ata. S, Jameson. G.J, 2013. Froth recovery measurements in an industrial flotation cell. Minerals Engineering 53, 193–202
##
[26] Moys. M.H,
Yianatos. J, Larenas. J, 2010. Measurement of particle loading on bubbles in the flotation process. Minerals Engineering 23, 131–136
##
[27]CS230 Carbon/Sulfur determinator: Instruction manual, 2008.
www.leco.com. LECO Corporation
##
[28] Iron ores — Determination of total iron Content, Titrimetric method after tin(II) chloride reduction ISO 2597-1:2006(E). 2006. International Organization for Standardization Provided by IHS under license with ISO
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