Advanced search
Publication Cover
International Journal of Coal Preparation and Utilization Volume 42, 2022 - Issue 7
Submit an article Journal homepage
284
Views
3
CrossRef citations to date
0
Altmetric
Review

Challenges of using froth features to predict clean coal ash content in coal flotation

Jiakun TanKey Laboratory of Coal Processing & Efficient Utilization of Ministry of Education, School of Chemical Engineering and Technology, China University of Mining and Technology, Xuzhou, ChinaView further author information
,
Long LiangKey Laboratory of Coal Processing & Efficient Utilization of Ministry of Education, School of Chemical Engineering and Technology, China University of Mining and Technology, Xuzhou, ChinaCorrespondence[email protected]
View further author information
,
Yaoli PengKey Laboratory of Coal Processing & Efficient Utilization of Ministry of Education, School of Chemical Engineering and Technology, China University of Mining and Technology, Xuzhou, ChinaView further author information
&
Guangyuan XieKey Laboratory of Coal Processing & Efficient Utilization of Ministry of Education, School of Chemical Engineering and Technology, China University of Mining and Technology, Xuzhou, ChinaView further author information
Pages 1991-2027 | Received 23 Jun 2019, Accepted 28 Jun 2020, Published online: 12 Jul 2020

References

  • Aktas, Z., J. Cilliers, and A. Banford. 2008. Dynamic froth stability: Particle size, airflow rate and conditioning time effects. International Journal of Mineral Processing 87:65–71.
  • Aldrich, C., C. Marais, B. Shean, and J. Cilliers. 2010. Online monitoring and control of froth flotation systems with machine vision: A review. International Journal of Mineral Processing 96:1–13.
  • Aldrich, C., D. Moolman, F. Gouws, and G. Schmitz. 1997b. Machine learning strategies for control of flotation plants. Control Engineering Practice 5:263–69.
  • Aldrich, C., D. Moolman, S.-J. Bunkell, M. Harris, and D. Theron. 1997a. Relationship between surface froth features and process conditions in the batch flotation of a sulphide ore. Minerals Engineering 10:1207–18.
  • Angarska, J. K., D. S. Ivanova, and E. D. Manev. 2015. Drainage of foam films stabilized by nonionic, ionic surfactants and their mixtures. Colloids and Surfaces. A, Physicochemical and Engineering Aspects 481:87–99.
  • Ata, S., N. Ahmed, and G. J. Jameson. 2002. Collection of hydrophobic particles in the froth phase. International Journal of Mineral Processing 64:101–22.
  • Ata, S., N. Ahmed, and G. J. Jameson. 2003. A study of bubble coalescence in flotation froths. International Journal of Mineral Processing 72:255–66.
  • Ata, S., N. Ahmed, and G. J. Jameson. 2004. The effect of hydrophobicity on the drainage of gangue minerals in flotation froths. Minerals Engineering 17:897–901.
  • Awatey, B., W. Skinner, and M. Zanin. 2013. Effect of particle size distribution on recovery of coarse chalcopyrite and galena in Denver flotation cell. Canadian Metallurgical Quarterly 52 (4):465–72.
  • Barbian, N., E. Ventura-Medina, and J. Cilliers. 2003. Dynamic froth stability in froth flotation. Minerals Engineering 16:1111–16.
  • Barbian, N., J. J. Cilliers, S. H. Morar, and D. J. Bradshaw. 2007. Froth imaging, air recovery and bubble loading to describe flotation bank performance. International Journal of Mineral Processing 84:81–88.
  • Barbian, N., K. Hadler, E. Ventura-Medina, and J. Cilliers. 2005. The froth stability column: Linking froth stability and flotation performance. Minerals Engineering 18:317–24.
  • Barbian, N., K. Hadler, and J. J. Cilliers. 2006. The froth stability column: Measuring froth stability at an industrial scale. Minerals Engineering 19:713–18.
  • Bartolacci, G., P. Pelletier, J. Tessier, C. Duchesne, P.-A. Bossé, and J. Fournier. 2006. Application of numerical image analysis to process diagnosis and physical parameter measurement in mineral processes—part I: Flotation control based on froth textural characteristics. Minerals Engineering 19:734–47.
  • Bergeron, V. 1997. Disjoining pressures and film stability of alkyltrimethylammonium bromide foam films. Langmuir 13:3474–82.
  • Bikerman, J. J. 1973. Foams. New York: Springer-Verlag.
  • Bisshop, J. P., and M. E. White. 1976. Study of particle entrainment in flotation froths. Transactions of the Institution of Mining and Metallurgy Section C-Mineral Processing and Extractive Metallurgy 85:C191–C194.
  • Bonifazi, G., S. Serranti, F. Volpe, and R. Zuco. 2001. Characterisation of flotation froth colour and structure by machine vision. Computers & Geosciences 27:1111–17.
  • Bournival, G., R. Pugh, and S. Ata. 2012. Examination of NaCl and MIBC as bubble coalescence inhibitor in relation to froth flotation. Minerals Engineering 25:47–53.
  • Bournival, G., S. Ata, and E. J. Wanless. 2016. Behavior of bubble interfaces stabilized by particles of different densities. Langmuir 32:6226–38.
  • Briceño-Ahumada, Z., and D. Langevin. 2015. On the influence of surfactant on the coarsening of aqueous foams. Advances in Colloid and Interface Science 244:124–31.
  • Briceño-Ahumada, Z., W. Drenckhan, and D. Langevin. 2016. Coalescence in draining foams made of very small bubbles. Physical Review Letters 116:128302.
  • Britan, A., M. Liverts, G. Ben-Dor, S. Koehler, and N. Bennani. 2009. The effect of fine particles on the drainage and coarsening of foam. Colloids and Surfaces. A, Physicochemical and Engineering Aspects 344:15–23.
  • Buchavzov, N., and C. Stubenrauch. 2007. A disjoining pressure study of foam films stabilized by mixtures of nonionic and ionic surfactants. Langmuir 23:5315–23.
  • Cao, B., Y. Xie, W. Gui, L. Wei, and C. Yang. 2013. Integrated prediction model of bauxite concentrate grade based on distributed machine vision. Minerals Engineering 53:31–38.
  • Castro, S., C. Miranda, P. Toledo, and J. Laskowski. 2013. Effect of frothers on bubble coalescence and foaming in electrolyte solutions and seawater. International Journal of Mineral Processing 124:8–14.
  • Cho, Y.-S., and J. Laskowski. 2002. Effect of flotation frothers on bubble size and foam stability. International Journal of Mineral Processing 64:69–80.
  • Cilek, E., and Y. Umucu. 2001. A statistical model for gangue entrainment into froths in flotation of sulphide ores. Minerals Engineering 14:1055–66.
  • Citir, C., Z. Aktas, and R. Berber. 2004. Off-line image analysis for froth flotation of coal. Computers & Chemical Engineering 28:625–32.
  • Cole, K., G. Morris, and J. Cilliers. 2010. Froth touch samples viewed with scanning electron microscopy. Minerals Engineering 23:1018–22.
  • Craig, V. S. 2004. Bubble coalescence and specific-ion effects. Current Opinion in Colloid & Interface Science 9:178–84.
  • Del, Castillo, L. A., S. Ohnishi, and R. G. Horn. 2011. Inhibition of bubble coalescence: Effects of salt concentration and speed of approach. Journal of Colloid and Interface Science 356:316–24.
  • Dzuy, N. Q., and D. V. Boger. 1983. Yield stress measurement for concentrated suspensions. Journal of Rheology 27:321–49.
  • Engelbrecht, J. A., and E. T. Woodburn. 1975. The effects of froth height, aeration rate, and gas precipitation on flotation. Journal of the Southern African Institute of Mining and Metallurgy 76:125–32.
  • Fameau, A.-L., and A. Salonen. 2014. Effect of particles and aggregated structures on the foam stability and aging. Comptes Rendus Physique 15:748–60.
  • Farrokhpay, S. 2011. The significance of froth stability in mineral flotation-A review. Advances in Colloid and Interface Science 166:1–7.
  • Fauser, H., M. Uhlig, R. Miller, and R. von Klitzing. 2015. Surface adsorption of oppositely charged SDS: C12TAB mixtures and the relation to foam film formation and stability. The Journal of Physical Chemistry. B 119:12877–86.
  • Fauser, H., and R. von Klitzing. 2014. Effect of polyelectrolytes on (de) stability of liquid foam films. Soft Matter 10:6903–16.
  • Feteris, S., J. Frew, and A. Jowett. 1987. Modelling the effect of froth depth in flotation. International Journal of Mineral Processing 20:121–35.
  • Finch, J., J. Yianatos, and G. Dobby. 1989. Column froths. Mineral Procesing and Extractive Metallurgy Review 5:281–305.
  • Firouzi, M., and A. V. Nguyen. 2014. Effects of monovalent anions and cations on drainage and lifetime of foam films at different interface approach speeds. Advanced Powder Technology 25:1212–19.
  • Forbes, G. 2007. Texture and bubble size measurements for modelling concentrate grade in flotation froth systems. PhD thesis, University of Cape Town, Cape Town, South Africa.
  • Fortes, M. 1986. The average rate of growth of individual cells in a cellular structure: Effect of the number of topological elements. Journal of Materials Science 21:2509–13.
  • Glazier, J. A. 1993. Grain growth in three dimensions depends on grain topology. Physical Review Letters 70:2170–73.
  • Gorain, B., M. Harris, J.-P. Franzidis, and E. Manlapig. 1998. The effect of froth residence time on the kinetics of flotation. Minerals Engineering 11:627–38.
  • Gui, X., J. Liu, Y. Cao, G. Cheng, H. Zhang, and Y. Wang. 2013. Process intensification of fine coal separation using two-stage flotation column. Journal of Central South University 20:3648–59.
  • Guillermic, R.-M., A. Salonen, J. Emile, and A. Saint-Jalmes. 2009. Surfactant foams doped with laponite: Unusual behaviors induced by aging and confinement. Soft Matter 5:4975–82.
  • Gupta, A. K., P. Banerjee, A. Mishra, and P. Satish. 2007. Effect of alcohol and polyglycol ether frothers on foam stability, bubble size and coal flotation. International Journal of Mineral Processing 82:126–37.
  • Hadler, K., C. Smith, and J. Cilliers. 2010. Recovery vs. mass pull: The link to air recovery. Minerals Engineering 23:994–1002.
  • Hadler, K., and J. J. Cilliers. 2009. The relationship between the peak in air recovery and flotation bank performance. Minerals Engineering 22:451–55.
  • Haffner, B., Y. Khidas, and O. Pitois. 2014. Flow and jamming of granular suspensions in foams. Soft Matter 10:3277–83.
  • Haffner, B., Y. Khidas, and O. Pitois. 2015. The drainage of foamy granular suspensions. Journal of Colloid and Interface Science 458:200–08.
  • Haralick, R. M., and K. Shanmugam. 1973. Textural features for image classification. IEEE Transactions on Systems, Man, and Cybernetics: Systems 3:610–21.
  • Hargrave, J., N. Miles, and S. Hall. 1996. The use of grey level measurement in predicting coal flotation performance. Minerals Engineering 9:667–74.
  • Hargrave, J., and S. Hall. 1997. Diagnosis of concentrate grade and mass flowrate in tin flotation from colour and surface texture analysis. Minerals Engineering 10:613–21.
  • Hätönen, J. 1999. Image analysis in mineral flotation. Master thesis. Helsinki University of Technology, Helsinki, Finland.
  • Hilgenfeldt, S., S. A. Koehler, and H. A. Stone. 2001. Dynamics of coarsening foams: Accelerated and self-limiting drainage. Physical Review Letters 86:4704–07.
  • Horozov, T. S. 2008. Foams and foam films stabilised by solid particles. Current Opinion in Colloid & Interface Science 13:134–40.
  • Huang, S. 2004. Research on image recognition of flotation froth about concentrated mineral’s grade. Master Thesis. Central South University, Changsha, China.
  • Ireland, P. M. 2009. Coalescence in a steady-state rising foam. Chemical Engineering Science 64:4866–74.
  • Ivanova, D. S., J. K. Angarska, and E. D. Manev. 2016. Critical thickness of foam films stabilized by nonionic, ionic surfactants and their mixtures. Acta Scientifica Naturalis 3:45–51.
  • Jahedsaravani, A., M. H. Marhaban, and M. Massinaei. 2014. Prediction of the metallurgical performances of a batch flotation system by image analysis and neural networks. Minerals Engineering 69:137–45.
  • Johansson, G., and R. J. Pugh. 1992. The influence of particle size and hydrophobicity on the stability of mineralized froths. International Journal of Mineral Processing 34:1–21.
  • Joshi, K., A. Baumann, S. Jeelani, C. Blickenstorfer, I. Naegeli, and E. Windhab. 2009. Mechanism of bubble coalescence induced by surfactant covered antifoam particles. Journal of Colloid and Interface Science 339:446–53.
  • Kaartinen, J., J. Hätönen, H. Hyötyniemi, and J. Miettunen. 2006. Machine-vision-based control of zinc flotation—a case study. Control Engineering Practice 14:1455–66.
  • Kaartinen, J., J. Hatonen, J. Miettunen, and O. Ojala 2002. Image analysis based control of zinc flotation-A multi-camera approach. 7th international conference on control, automation, robotics and vision, 2, 920–25. Singapore: IEEE.
  • Kaptay, G. 2004. Interfacial criteria for stabilization of liquid foams by solid particles. Colloids and Surfaces A 230:67–80.
  • Karakashev, S. I., D. S. Ivanova, Z. K. Angarska, E. D. Manev, R. Tsekov, B. Radoev, R. Slavchov, and A. V. Nguyen. 2010. Comparative validation of the analytical models for the Marangoni effect on foam film drainage. Colloids and Surfaces. A, Physicochemical and Engineering Aspects 365:122–36.
  • Khidas, Y., B. Haffner, and O. Pitois. 2014. Capture-induced transition in foamy suspensions. Soft Matter 10:4137–41.
  • Klitzing, R. 2005. Effect of interface modification on forces in foam films and wetting films. Advances in Colloid and Interface Science 114:253–66.
  • Koehler, S. A., S. Hilgenfeldt, E. R. Weeks, and H. A. Stone. 2002. Drainage of single plateau borders: Direct observation of rigid and mobile interfaces. Physical Review E 66:040601(R.
  • Koehler, S. A., S. Hilgenfeldt, and H. Stone. 2004. Foam drainage on the microscale: I. Modeling flow through single plateau borders. Journal of Colloid and Interface Science 276:420–38.
  • Koehler, S. A., S. Hilgenfeldt, and H. A. Stone. 1999. Liquid flow through aqueous foams: The node-dominated foam drainage equation. Physical Review Letters 82:4232–35.
  • Koehler, S. A., S. Hilgenfeldt, and H. A. Stone. 2000. A generalized view of foam drainage: Experiment and theory. Langmuir 16:6327–41.
  • Kowalczuk, P. B. 2013. Determination of critical coalescence concentration and bubble size for surfactants used as flotation frothers. Industrial & Engineering Chemistry Research 52:11752–57.
  • Kracht, W., and H. Rebolledo. 2013. Study of the local critical coalescence concentration (l-CCC) of alcohols and salts at bubble formation in two-phase systems. Minerals Engineering 50:77–82.
  • Kristen, N., and R. von Klitzing. 2010. Effect of polyelectrolyte/surfactant combinations on the stability of foam films. Soft Matter 6:849–61.
  • Krustev, R., and H. Müller. 1999. Effect of film free energy on the gas permeability of foam films. Langmuir 15:2134–41.
  • Kurniawan, A. U., O. Ozdemir, A. V. Nguyen, P. Ofori, and B. Firth. 2011. Flotation of coal particles in MgCl2, NaCl, and NaClO3 solutions in the absence and presence of Dowfroth 250. International Journal of Mineral Processing 98:137–44.
  • Laplante, A., J. Toguri, and H. Smith. 1983. The effect of air flow rate on the kinetics of flotation. Part 2: The transfer of material from the froth over the cell lip. International Journal of Mineral Processing 11:221–34.
  • Laskowski, J. S., Y. S. Cho, and K. Ding. 2003. Effect of frothers on bubble size and foam stability in potash ore flotation systems. The Canadian Journal of Chemical Engineering 81:63–69.
  • Leonard, R. A., and R. Lemlich. 1965. A study of interstitial liquid flow in foam. Part I. Theoretical Model and Application to Foam Fractionation. AIChE Journal 11:18–25.
  • Li, C., K. Runge, F. Shi, and S. Farrokhpay. 2016. Effect of flotation froth properties on froth rheology. Powder Technology 294:55–65.
  • Li, C., S. Farrokhpay, F. Shi, and K. Runge. 2015. A novel approach to measure froth rheology in flotation. Minerals Engineering 71:89–96.
  • Liang, L., Z. Li, Y. Peng, J. Tan, and G. Xie. 2015. Influence of coal particles on froth stability and flotation performance. Minerals Engineering 81:96–102.
  • Liu, D., and Y. Peng. 2014. Reducing the entrainment of clay minerals in flotation using tap and saline water. Powder Technology 253:216–22.
  • Liu, G., Y. Hou, G. Zhang, and V. S. Craig. 2009. Inhibition of bubble coalescence by electrolytes in binary mixtures of dimethyl sulfoxide and propylene carbonate. Langmuir 25:10495–500.
  • Liu, J., J. MacGregor, C. Duchesne, and G. Bartolacci. 2005. Flotation froth monitoring using multiresolutional multivariate image analysis. Minerals Engineering 18:65–76.
  • Liu, W., M. Lu, Z. Wang, Y. Wang, and F. Wang. 2002a. Research on digital image processing of coal flotation froth (I)– The liner neighbor algorithm for extracting features of digital coal flotation froth image. Journal of China University of Mining and Technology 31:120–23.
  • Liu, W., M. Lu, Z. Wang, Y. Wang, and F. Wang. 2002b. Research on digital image processing of coal flotation froth (II) –The square neighbor algorithm for extracting features of digital coal flotation froth image. Journal of China University of Mining and Technology 31:233–36.
  • Louvet, N., R. Höhler, and O. Pitois. 2010. Capture of particles in soft porous media. Physical Review E 82:041405.
  • Manev, E. D., and A. V. Nguyen. 2005. Effects of surfactant adsorption and surface forces on thinning and rupture of foam liquid films. International Journal of Mineral Processing 77:1–45.
  • Marais, C., and C. Aldrich. 2011a. Estimation of platinum flotation grades from froth image data. Minerals Engineering 24:433–41.
  • Marais, C., and C. Aldrich. 2011b. The estimation of platinum flotation grade from froth image features by using artificial neural networks. Journal of the Southern African Institute of Mining and Metallurgy 111:81–85.
  • Massinaei, M., A. Jahedsaravani, E. Taheri, and J. Khalilpour. 2019. Machine vision based monitoring and analysis of a coal column flotation circuit. Powder Technology 343:330–41.
  • Mehrabi, A., N. Mehrshad, and M. Massinaei. 2014. Machine vision based monitoring of an industrial flotation cell in an iron flotation plant. International Journal of Mineral Processing 133:60–66.
  • Micheau, C., P. Bauduin, O. Diat, and S. Faure. 2013. Specific salt and pH effects on foam film of a pH sensitive surfactant. Langmuir 29:8472–81.
  • Monin, D., A. Espert, and A. Colin. 2000. A new analysis of foam coalescence: From isolated films to three-dimensional foams. Langmuir 16:3873–83.
  • Moolman, D., C. Aldrich, and J. Van Deventer. 1995. The monitoring of froth surfaces on industrial flotation plants using connectionist image processing techniques. Minerals Engineering 8:23–30.
  • Moolman, D., C. Aldrich, J. Van Deventer, and D. Bradshaw. 1995a. The interpretation of flotation froth surfaces by using digital image analysis and neural networks. Chemical Engineering Science 50:3501–13.
  • Moolman, D., C. Aldrich, J. Van Deventer, and W. Stange. 1994. Digital image processing as a tool for on-line monitoring of froth in flotation plants. Minerals Engineering 7 (9):1149–64. doi:https://doi.org/10.1016/0892-6875(94)00058-1.
  • Moolman, D., C. Aldrich, J. Van Deventer, and W. Stange. 1995b. The classification of froth structures in a copper flotation plant by means of a neural net. International Journal of Mineral Processing 43:193–208.
  • Moolman, D., J. Eksteen, C. Aldrich, and J. Van Deventer. 1996. The significance of flotation froth appearance for machine vision control. International Journal of Mineral Processing 48:135–58.
  • Morar, S. H., D. J. Bradshaw, and M. C. Harris. 2012. The use of the froth surface lamellae burst rate as a flotation froth stability measurement. Minerals Engineering 36:152–59.
  • Morar, S. H., M. C. Harris, and D. J. Bradshaw. 2012. The use of machine vision to predict flotation performance. Minerals Engineering 36:31–36.
  • Morris, G., S. Neethling, and J. J. Cilliers. 2014. Predicting the failure of a thin liquid film loaded with spherical particles. Langmuir 30:995–1003.
  • Morris, G. D., S. J. Neethling, and J. J. Cilliers. 2011. A model for the stability of films stabilized by randomly packed spherical particles. Langmuir 27:11475–80.
  • Moys, M. H. 1984. Residence time distributions and mass transport in the froth phase of the flotation process. International Journal of Mineral Processing 13:117–42.
  • Muruganathan, R. M., R. Krastev, H. J. Müller, and H. Möhwald. 2006. Foam films stabilized with dodecyl maltoside. 2. Film stability and gas permeability. Langmuir 22:7981–85.
  • Narsimhan, G. 2016. Drainage of particle stabilized foam film. Colloids and Surfaces. A, Physicochemical and Engineering Aspects 495:20–29.
  • Neethling, S., and J. Cilliers. 2009a. The entrainment factor in froth flotation: Model for particle size and other operating parameter effects. International Journal of Mineral Processing 93:141–48.
  • Neethling, S. J., H. T. Lee, and J. J. Cilliers. 2002. A foam drainage equation generalized for all liquid contents. Journal of Physics: Condensed Matter 14:331–42.
  • Neethling, S. J., H. T. Lee, and J. J. Cilliers. 2003. Simple relationships for predicting the recovery of liquid from flowing foams and froths. Minerals Engineering 16:1123–30.
  • Neethling, S. J., and J. J. Cilliers. 2002. The entrainment of gangue into a flotation froth. International Journal of Mineral Processing 64:123–34.
  • Neethling, S. J., and J. J. Cilliers. 2009b. The entrainment factor in froth flotation: Model for particle size and other operating parameter effects. International Journal of Mineral Processing 93:141–48.
  • Nguyen, A. V. 2002. Liquid drainage in single Plateau borders of foam. Journal of Colloid and Interface Science 249:194–99.
  • Qu, X., L. Wang, and A. V. Nguyen. 2013. Correlation of air recovery with froth stability and separation efficiency in coal flotation. Minerals Engineering 41:25–30.
  • Quinn, J., J. Sovechles, J. Finch, and K. Waters. 2014. Critical coalescence concentration of inorganic salt solutions. Minerals Engineering 58:1–6.
  • Rekvig, L., B. Hafskjold, and B. Smit. 2004. Molecular simulations of surface forces and film rupture in oil/water/surfactant systems. Langmuir 20:11583–93.
  • Roth, A. E., C. D. Jones, and D. J. Durian. 2012. Coarsening of a two-dimensional foam on a dome. Physical Review E 86:021402.
  • Ruckenstein, E., and A. Sharma. 1987. A new mechanism of film thinning: Enhancement of Reynolds’ velocity by surface waves. Journal of Colloid and Interface Science 119:1–13.
  • Runge, K., J. McMaster, M. Wortley, D. La Rosa, and O. Guyot 2007. A correlation between Visiofroth™ measurements and the performance of a flotation cell. 9th Mill Operators Conference, 79–86, Fremantle, Australia.
  • Sadr-Kazemi, N., and J. Cilliers. 1997. An image processing algorithm for measurement of flotation froth bubble size and shape distributions. Minerals Engineering 10:1075–83.
  • Sadr-Kazemi, N., and J. Cilliers. 2000. A technique for measuring flotation bubble shell thickness and concentration. Minerals Engineering 13:773–76.
  • Saint-Jalmes, A. 2006. Physical chemistry in foam drainage and coarsening. Soft Matter 2:836–49.
  • Samanta, S., and P. Ghosh. 2011a. Coalescence of bubbles and stability of foams in brij surfactant systems. Industrial & Engineering Chemistry Research 50:4484–93.
  • Samanta, S., and P. Ghosh. 2011b. Coalescence of bubbles and stability of foams in aqueous solutions of Tween surfactants. Chemical Engineering Research and Design 89:2344–55.
  • Samanta, S., and P. Ghosh. 2011c. Coalescence of air bubbles in aqueous solutions of alcohols and nonionic surfactants. Chemical Engineering Science 66:4824–37.
  • Savassi, O. N. 1998. Direct estimation of the degree of entrainment and the froth recovery of attached particles in industrial flotation cells. PhD Thesis, University of Queensland, Brisbane, Australia.
  • Schelero, N., G. Hedicke, P. Linse, and R. von Klitzing. 2010. Effects of counterions and co-ions on foam films stabilized by anionic dodecyl sulfate. The Journal of Physical Chemistry. B 114:15523–29.
  • Schelero, N., R. Miller, and R. von Klitzing. 2014. Effect of oppositely charged hydrophobic additives (alkanoates) on the stability of C14TAB foam films. Colloids and Surfaces. A, Physicochemical and Engineering Aspects 460:158–67.
  • Schelero, N., and R. von Klitzing. 2015. Ion specific effects in foam films. Current Opinion in Colloid & Interface Science 20:124–29.
  • Schulze-Schlarmann, J., N. Buchavzov, and C. Stubenrauch. 2006. A disjoining pressure study of foam films stabilized by tetradecyl trimethyl ammonium bromide C14TAB. Soft Matter 2:584–94.
  • Shean, B., and J. Cilliers. 2011. A review of froth flotation control. International Journal of Mineral Processing 100:57–71.
  • Shi, F., and X. Zheng. 2003. The rheology of flotation froths. International Journal of Mineral Processing 69:115–28.
  • Simulescu, V., J. Angarska, and E. Manev. 2008. Drainage and critical thickness of foam films from aqueous solutions of mixed nonionic surfactants. Colloids and Surfaces. A, Physicochemical and Engineering Aspects 319:21–28.
  • Srinivas, A., and P. Ghosh. 2011. Coalescence of bubbles in aqueous alcohol solutions. Industrial & Engineering Chemistry Research 51:795–806.
  • Stubenrauch, C., J. Schlarmann, and R. Strey. 2002. A disjoining pressure study of n-dodecyl- -D-maltoside foam films. Physical Chemistry Chemical Physics 4:4504–13.
  • Suryanarayana, G., and P. Ghosh. 2010. Adsorption and coalescence in mixed-surfactant systems: Air− water interface. Industrial & Engineering Chemistry Research 49:1711–24.
  • Tan, J., J. Wang, A. V. Nguyen, and G. Xie. 2020. Regimes of drainage instability caused by wash water. Minerals Engineering 148:106202.
  • Tan, J., L. Liang, W. Xia, and G. Xie. 2018b. Effect of different flotation operating parameters on froth properties and their relation with clean coal ash content. Separation Science and Technology 53 (9):1434–44.
  • Tan, J., L. Liang, W. Xia, and Y. Peng. 2018a. Effects of fine coal particles on the recovery of coarse coal in collectorless coal flotation. International Journal of Coal Preparation and Utilization. doi:https://doi.org/10.1080/19392699.2018.1455669.
  • Tan, J., L. Liang, Y. Peng, and G. Xie. 2016. The concentrate ash content analysis of coal flotation based on froth images. Minerals Engineering 92:9–20.
  • Tan, J., L. Liang, Y. Peng, and G. Xie. 2019. Effect of particle size on the froth property in coal flotation. Journal of China University of Mining & Technology 48 (1):176–84.
  • Tang, D., E. Wightman, J.-P. Franzidis, and G. Montes-Atenas. 2010. Assessment of the consistency between different laboratory froth stability measurements. In XXV International Mineral Processing Congress (IMPC) proceedings, , Australasian Institute of Mining and Metallurgy, 3: 2425–32. Brisbane, Australia.
  • Tao, D., G. Luttrell, and R.-H. Yoon. 2000. A parametric study of froth stability and its effect on column flotation of fine particles. International Journal of Mineral Processing 59:25–43.
  • Tsatouhas, G., S. Grano, and M. Vera. 2006. Case studies on the performance and characterisation of the froth phase in industrial flotation circuits. Minerals Engineering 19:774–83.
  • Ventura-Medina, E., and J. Cilliers. 2002. A model to describe flotation performance based on physics of foams and froth image analysis. International Journal of Mineral Processing 67:79–99.
  • Ventura-Medina, E., N. Barbian, and J. Cilliers. 2004. Solids loading and grade on mineral froth bubble lamellae. International Journal of Mineral Processing 74:189–200.
  • Wang, B., and Y. Peng. 2013. The behaviour of mineral matter in fine coal flotation using saline water. Fuel 109:309–15.
  • Wang, B., and Y. Peng. 2014. The effect of saline water on mineral flotation–A critical review. Minerals Engineering 66:13–24.
  • Wang, J., and A. V. Nguyen. 2016. Foam drainage in the presence of solid particles. Soft Matter 12:3004–12.
  • Wang, J., A. V. Nguyen, and S. Farrokhpay. 2016. A critical review of the growth, drainage and collapse of foams. Advances in Colloid and Interface Science 228:55–70.
  • Wang, L. 2012. Drainage and rupture of thin foam films in the presence of ionic and non-ionic surfactants. International Journal of Mineral Processing 102:58–68.
  • Wang, L. 2015. Modeling of bubble coalescence in saline water in the presence of flotation frothers. International Journal of Mineral Processing 134:41–49.
  • Wang, L., and R.-H. Yoon. 2004. Hydrophobic forces in the foam films stabilized by sodium dodecyl sulfate: Effect of electrolyte. Langmuir 20:11457–64.
  • Wang, L., and R.-H. Yoon. 2005. Hydrophobic forces in thin aqueous films and their role in film thinning. Colloids and Surfaces. A, Physicochemical and Engineering Aspects 263:267–74.
  • Wang, L., and R.-H. Yoon. 2006a. Role of hydrophobic force in the thinning of foam films containing a nonionic surfactant. Colloids and Surfaces. A, Physicochemical and Engineering Aspects 282:84–91.
  • Wang, L., and R.-H. Yoon. 2006b. Stability of foams and froths in the presence of ionic and non-ionic surfactants. Minerals Engineering 19:539–47.
  • Wang, L., and R.-H. Yoon. 2008. Effect of pH and NaCl concentration on the stability of surfactant-free foam films. Langmuir 25:294–97.
  • Wang, L., and X. Qu. 2012. Impact of interface approach velocity on bubble coalescence. Minerals Engineering 26:50–56.
  • Wang, L., Y. Peng, K. Runge, and D. Bradshaw. 2015. A review of entrainment: Mechanisms, contributing factors and modelling in flotation. Minerals Engineering 70:77–91.
  • Wang, W., -Y.-Y. Li, and L.-Q. Chen. 2013. Bubble delineation on valley edge detection and region merge. Journal of China University of Mining and Technology 42:1060–65.
  • Wei, T., Y. Peng, and S. Farrokhpay. 2014. Froth stability of coal flotation in saline water. Mineral Processing and Extractive Metallurgy 123:234–40.
  • Wright, B. A. 1999. The development of a vision-based flotation froth analysis system. Vacuum 99:26–27.
  • Yang, W., R. Wu, B. Kong, X. Zhang, and X. Yang. 2009. Molecular dynamics simulations of film rupture in water/surfactant systems. The Journal of Physical Chemistry. B 113:8332–38.
  • Yianatos, J., F. Contreras, F. Díaz, and A. Villanueva. 2009. Direct measurement of entrainment in large flotation cells. Powder Technology 189:42–47.
  • Zanin, M., E. Wightman, S. Grano, and J.-P. Franzidis. 2009. Quantifying contributions to froth stability in porphyry copper plants. International Journal of Mineral Processing 91:19–27.
  • Zhang, S. 2004. Coal chemistry: China. Xuzhou: University of Mining and Technology Press.
  • Zheng, X., J. Franzidis, and N. Johnson. 2006. An evaluation of different models of water recovery in flotation. Minerals Engineering 19:871–82.
  • Zheng, X., N. Johnson, and J.-P. Franzidis. 2006. Modelling of entrainment in industrial flotation cells: Water recovery and degree of entrainment. Minerals Engineering 19:1191–203.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.