XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3 2433
Chile, for providing funding for process modelling and
control research.
REFERENCES
Amini, E. Xie, D. Bradshaw, D. (2016). Enhancement
of scale up capability on AMIRA P9 flotation model
by incorporating turbulence parameters. International
Journal of Mineral Processing, 156, 52–61.
Anzoom, S., Bournival, G., Ata, S. (2024). Coarse particle
flotation: A review. Minerals Engineering, 206 (2024)
108499
Arbiter, N. (2000). Development and scale-up of large flo-
tation cells. Mining Engineering, 52 (3), 28–33.
Arburo, K., Zúñiga, J., McDonald, A., Valdes, F., Concha,
J., Wasmund, E. (2022). Comissioning a Hydrofloat ®
in a copper concentrator application. International
Conference Copper 2022, Ed. IIMCh, Santiago,
Chile, Vol. 2, pp. 46–58.
Bergh, L., Yianatos, J., Acuña, C., Pérez H. and López F.
(1999). Supervisory control at Salvador flotation col-
umns. Minerals Engineering, 12(5), 565–569
Boeree, C.R. (2014). Up scaling of froth flotation equip-
ment. Master Thesis in Resource Engineering, Delf
University of Technology, Netherlands.
Cole, M. J., Galvin, K.P., Dickinson, J.E. (2021).
Maximizing recovery, grade and throughput in a single
stage Reflux Flotation Cell. Minerals Engineering, 163,
106761. doi: 10.1016/j.mineng.2020.106761
Cortés, F., Yianatos, J. (1995). Characterization of the
copper-moly collective flotation circuit at División
Andina, Codelco-Chile. International Conference
Copper 95, Vol.II, Mineral Processing and environ-
ment, Eds. Casali et al., The Metallurgical Society of
CIM.
FLSmidth (2024). Available online: https://www.flsmidth
.com/en-gb/products/flotation-and-attrition/wemco
-wear-parts, accessed on January 29th.
Galvin, K. (2023). Applications of the Boycott Effect in
fine and coarse particle flotation. The next frontier.
International Flotation Symposium, Celebrating
Science and Engineering Innovation, 13–14 July,
Newcastle, Australia.
Garay, B., Catalán, E. (2020). Performance of Jameson
cells in collective flotation stage. In Proceedings of
16th International Mineral Processing Conference,
Procemin-Geomet 2020, Santiago, Chile.
Glencore Technology (2023). Available online: https://
www.glencoretechnology.com/es/technologies
/jameson-cell/, accessed on December 20th.
Glencore Technology (2024). Available online: https://
www.glencoretechnology.com/en/technologies
/jameson-cell/how-it-works/operating-principles,
accessed on January 29th.
Grau, R., Tapia, J., Yañez, A., Hicks, M., Chavira, J., Muro,
G., Romero, J. (2018). Improving Buenavista del Cobre
flotation performance with Outotec TankCell ® e630
technology. In: 14th International Mineral Processing
Conference, Procemin-Geomet, Santiago, Chile.
Hassanzadeth, A. Safari, M. Hoang, D.H. Khoshdast, H.
Albijanic, B. Kowalczuk, P.B. (2022a). Technological
assessment on recent developments in fine and coarse
particle flotation systems. Minerals Engineering, 180,
107509.
Hassanzadeh, A., Safari, M., Khoshdast, H., Güner, M.K.,
Hoang, D.H., Sambrook, T., Kowalczuk, P.B. (2022b).
Introducing key advantages of intensified flotation cells
over conventionally used mechanical and column cells.
Physicochemical Problems of Mineral Processing, 58(5),
155101.
Jameson, G. (2010). New directions in flotation machine
design. Minerals Engineering, 23, 835–841.
Jameson, G. (2018). The Concord cell. Symposium on flo-
tation developments. Organised by Outotec, Helsinki,
Finland.
Jameson, G. (2023). Coarse particle flotation: The
next frontier. International Flotation Symposium,
Celebrating Science and Engineering Innovation,
13–14 July, Newcastle, Australia.
Jiang, K., Dickinson, J.E., Galvin, K.P. (2019). The kinetics
of fast flotation using the reflux flotation cell. Chemical
Engineering Science, 196, 463–477.
Meléndez, M. (2023). Evaluación metalúrgica y simulación
CFD de una celda de flotación de alta intensidad
StackCell ® SC-50. Congreso de Flotación FLOTAC,
Adtrium, Viña del Mar, Chile, March 31st 2023.
Mesa, D. (2020). The effect of impeller-stator design on
froth stability, flotation performance and flotation
hydrodynamics. PhD thesis, Royal School of Mines,
Imperial College London, UK.
Mesa, D. Brito-Parada, P. (2019). Scale-up in froth flo-
tation: A state-of-the-art review. Separation and
Purification Technology, 210, 950–962.
Savassi, O. (2005). A compartment model for the mass
transfer inside a conventional cell. International Journal
of Mineral Processing, 77, 65–79.
Swedburg, K., Samuels, M. (2016). Application of the
Woodgrove staged flotation reactor (SFR) technology
at the New Afton concentrator. 48th Annual Canadian
Minerals Processors Operators Conference, Ottawa.
Chile, for providing funding for process modelling and
control research.
REFERENCES
Amini, E. Xie, D. Bradshaw, D. (2016). Enhancement
of scale up capability on AMIRA P9 flotation model
by incorporating turbulence parameters. International
Journal of Mineral Processing, 156, 52–61.
Anzoom, S., Bournival, G., Ata, S. (2024). Coarse particle
flotation: A review. Minerals Engineering, 206 (2024)
108499
Arbiter, N. (2000). Development and scale-up of large flo-
tation cells. Mining Engineering, 52 (3), 28–33.
Arburo, K., Zúñiga, J., McDonald, A., Valdes, F., Concha,
J., Wasmund, E. (2022). Comissioning a Hydrofloat ®
in a copper concentrator application. International
Conference Copper 2022, Ed. IIMCh, Santiago,
Chile, Vol. 2, pp. 46–58.
Bergh, L., Yianatos, J., Acuña, C., Pérez H. and López F.
(1999). Supervisory control at Salvador flotation col-
umns. Minerals Engineering, 12(5), 565–569
Boeree, C.R. (2014). Up scaling of froth flotation equip-
ment. Master Thesis in Resource Engineering, Delf
University of Technology, Netherlands.
Cole, M. J., Galvin, K.P., Dickinson, J.E. (2021).
Maximizing recovery, grade and throughput in a single
stage Reflux Flotation Cell. Minerals Engineering, 163,
106761. doi: 10.1016/j.mineng.2020.106761
Cortés, F., Yianatos, J. (1995). Characterization of the
copper-moly collective flotation circuit at División
Andina, Codelco-Chile. International Conference
Copper 95, Vol.II, Mineral Processing and environ-
ment, Eds. Casali et al., The Metallurgical Society of
CIM.
FLSmidth (2024). Available online: https://www.flsmidth
.com/en-gb/products/flotation-and-attrition/wemco
-wear-parts, accessed on January 29th.
Galvin, K. (2023). Applications of the Boycott Effect in
fine and coarse particle flotation. The next frontier.
International Flotation Symposium, Celebrating
Science and Engineering Innovation, 13–14 July,
Newcastle, Australia.
Garay, B., Catalán, E. (2020). Performance of Jameson
cells in collective flotation stage. In Proceedings of
16th International Mineral Processing Conference,
Procemin-Geomet 2020, Santiago, Chile.
Glencore Technology (2023). Available online: https://
www.glencoretechnology.com/es/technologies
/jameson-cell/, accessed on December 20th.
Glencore Technology (2024). Available online: https://
www.glencoretechnology.com/en/technologies
/jameson-cell/how-it-works/operating-principles,
accessed on January 29th.
Grau, R., Tapia, J., Yañez, A., Hicks, M., Chavira, J., Muro,
G., Romero, J. (2018). Improving Buenavista del Cobre
flotation performance with Outotec TankCell ® e630
technology. In: 14th International Mineral Processing
Conference, Procemin-Geomet, Santiago, Chile.
Hassanzadeth, A. Safari, M. Hoang, D.H. Khoshdast, H.
Albijanic, B. Kowalczuk, P.B. (2022a). Technological
assessment on recent developments in fine and coarse
particle flotation systems. Minerals Engineering, 180,
107509.
Hassanzadeh, A., Safari, M., Khoshdast, H., Güner, M.K.,
Hoang, D.H., Sambrook, T., Kowalczuk, P.B. (2022b).
Introducing key advantages of intensified flotation cells
over conventionally used mechanical and column cells.
Physicochemical Problems of Mineral Processing, 58(5),
155101.
Jameson, G. (2010). New directions in flotation machine
design. Minerals Engineering, 23, 835–841.
Jameson, G. (2018). The Concord cell. Symposium on flo-
tation developments. Organised by Outotec, Helsinki,
Finland.
Jameson, G. (2023). Coarse particle flotation: The
next frontier. International Flotation Symposium,
Celebrating Science and Engineering Innovation,
13–14 July, Newcastle, Australia.
Jiang, K., Dickinson, J.E., Galvin, K.P. (2019). The kinetics
of fast flotation using the reflux flotation cell. Chemical
Engineering Science, 196, 463–477.
Meléndez, M. (2023). Evaluación metalúrgica y simulación
CFD de una celda de flotación de alta intensidad
StackCell ® SC-50. Congreso de Flotación FLOTAC,
Adtrium, Viña del Mar, Chile, March 31st 2023.
Mesa, D. (2020). The effect of impeller-stator design on
froth stability, flotation performance and flotation
hydrodynamics. PhD thesis, Royal School of Mines,
Imperial College London, UK.
Mesa, D. Brito-Parada, P. (2019). Scale-up in froth flo-
tation: A state-of-the-art review. Separation and
Purification Technology, 210, 950–962.
Savassi, O. (2005). A compartment model for the mass
transfer inside a conventional cell. International Journal
of Mineral Processing, 77, 65–79.
Swedburg, K., Samuels, M. (2016). Application of the
Woodgrove staged flotation reactor (SFR) technology
at the New Afton concentrator. 48th Annual Canadian
Minerals Processors Operators Conference, Ottawa.