2934 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
REFERENCES
Etchepare, R., Oliveira, H., Nicknig, M., et al. 2017.
Nanobubbles: generation using a multiphase pump,
properties and features in flotation. Miner. Eng.
112:19–26.
Hu, H., Finch, J.A., Zhou, Z., and Xu, Z. 1998. Numerical
and experimental study of a hydrodynamic cavitation
tube. Metall. Mat. Trans. B 29(4):911–917.
Huang, J., Haipeng, L., Liu, Q., et al. 2016. Enhancing
gold recovery from Nevada double refractory gold
ores using a novel dual bubble generator. In: IMPC
2016: XXVIII International Mineral Processing Congress
Proceedings. Canadian Institute of Mining, Metallurgy
and Petroleum, Quebec City.
Martínez-Gómez, V., Pérez-Garibay, R., and Rubio, J.
2013. Factors involving the solids carrying flotation
capacity of microbubbles. Miner. Eng. 53:160–166.
Oliveira, H., Azevedo, A., and Rubio, J. 2018. Nanobubbles
generation in a high-rate hydrodynamic cavitation
tube. Miner. Eng. 116:32–34.
Ross, V., Singh, A., and Pillay, K. 2019. Improved flotation
of PGM tailings with a high-shear hydrodynamic cavi-
tation device. Miner. Eng. 137:133–139.
Singh, A. 2016. Enhanced flotation of platinum mineral
fines through feed cavitation: ‘Bringing the mountain
to Mohamed’. In: IMPC 2016: XXVIII International
Mineral Processing Congress Proceedings. Canadian
Institute of Mining, Metallurgy and Petroleum,
Quebec City.
Sobhy, A., and Tao, D. 2013. Nanobubble column flota-
tion of fine coal particles and associated fundamentals.
Int. J. Miner. Process. 124:109–116.
Tao, D. 2005. Role of bubble size in flotation of coarse and
fine particles – a review. Sep.Sci. Tech. 39(4):741–760.
Tao, Y., Liu, J., Yu, S., and Tao, D. 2006. Pico-bubble
enhanced fine coal flotation. Sep. Sci. Tech. 41
(16):3597–3607.
REFERENCES
Etchepare, R., Oliveira, H., Nicknig, M., et al. 2017.
Nanobubbles: generation using a multiphase pump,
properties and features in flotation. Miner. Eng.
112:19–26.
Hu, H., Finch, J.A., Zhou, Z., and Xu, Z. 1998. Numerical
and experimental study of a hydrodynamic cavitation
tube. Metall. Mat. Trans. B 29(4):911–917.
Huang, J., Haipeng, L., Liu, Q., et al. 2016. Enhancing
gold recovery from Nevada double refractory gold
ores using a novel dual bubble generator. In: IMPC
2016: XXVIII International Mineral Processing Congress
Proceedings. Canadian Institute of Mining, Metallurgy
and Petroleum, Quebec City.
Martínez-Gómez, V., Pérez-Garibay, R., and Rubio, J.
2013. Factors involving the solids carrying flotation
capacity of microbubbles. Miner. Eng. 53:160–166.
Oliveira, H., Azevedo, A., and Rubio, J. 2018. Nanobubbles
generation in a high-rate hydrodynamic cavitation
tube. Miner. Eng. 116:32–34.
Ross, V., Singh, A., and Pillay, K. 2019. Improved flotation
of PGM tailings with a high-shear hydrodynamic cavi-
tation device. Miner. Eng. 137:133–139.
Singh, A. 2016. Enhanced flotation of platinum mineral
fines through feed cavitation: ‘Bringing the mountain
to Mohamed’. In: IMPC 2016: XXVIII International
Mineral Processing Congress Proceedings. Canadian
Institute of Mining, Metallurgy and Petroleum,
Quebec City.
Sobhy, A., and Tao, D. 2013. Nanobubble column flota-
tion of fine coal particles and associated fundamentals.
Int. J. Miner. Process. 124:109–116.
Tao, D. 2005. Role of bubble size in flotation of coarse and
fine particles – a review. Sep.Sci. Tech. 39(4):741–760.
Tao, Y., Liu, J., Yu, S., and Tao, D. 2006. Pico-bubble
enhanced fine coal flotation. Sep. Sci. Tech. 41
(16):3597–3607.