4
be performed with different ores in lab, pilot, and industrial
scales to verify the gains in mass recovery, selectivity, con-
centrate quality, and energy saving.
REFERENCES
[1] Choi, Junhyun and Sang B. Kim (2023), “Influence
of pH and ionic strength on the floc-magnetic separa-
tion: Selective flocculation of fine iron ore,” Results in
Engineering, September.
[2] Gururaj, B., Sharma J. P., Baldawa, A., Arora, S. C.
D., Prasad, N., Biswas, A. K. (1983), “Dispersion-
flocculation studies on hematite-clay systems,”
International Journey of Mineral Processing, April,
285–302.
[3] ICMM (2020), Global Industry Standard on Tailings
Management.
[4] Klein, B. and M. Paulik (2005), “Rheology modi-
fiers for mineral suspensions,” in Minerals and
Metallurgical Processing, May, 83–88.
[5] Luo, L. and Anh V. Nguyen (2017), “A review of
principles and applications of magnetic flocculation
to separate ultrafine magnetic particles,” Separation
and Purification Technology, July, 85–99.
[6] Ma, X., W. J. Bruckard, R. Holmes (2009), “Effect of
collector, pH and ionic strength on the cationic flo-
tation of kaolinite,” International Journey of Mineral
Processing, May, 54–58.
[7] Morkun, V., N. Morkun, V. Tron, V. Golik, A.
Davidkovich (2021), “Increasing efficiency of iron
ore magnetic separation by using ultrasonic technolo-
gies,” in ICSF.
[8] Patra, A. S., D. Makhija, A. K. Mukherjee, R. Tiwari,
C. R. Sahoo, B. D. Mohanty (2016), “Improved
dewatering of iron ore fines by the use of surfactants,”
Powder Technology, 43–50.
[9] Rodrigues, O. M. S., A. E. C. Peres, A. H. Martins,
C. A. Pereira (2013), “Kaolinite and hematite flota-
tion separation using etheramine and ammonium
quaternary salts,” Minerals Engineering, 12–15.
[10] Roy, S. (2012), “Recovery improvement of fine mag-
netic particles by floc magnetic separation,” Mineral
Processing and Extractive Metallurgy, 170–179.
[11] Svoboda, J. T. Fujita (2003), “Recent developments
in magnetic methods of material separation,” Minerals
Engineering, 785–792.
be performed with different ores in lab, pilot, and industrial
scales to verify the gains in mass recovery, selectivity, con-
centrate quality, and energy saving.
REFERENCES
[1] Choi, Junhyun and Sang B. Kim (2023), “Influence
of pH and ionic strength on the floc-magnetic separa-
tion: Selective flocculation of fine iron ore,” Results in
Engineering, September.
[2] Gururaj, B., Sharma J. P., Baldawa, A., Arora, S. C.
D., Prasad, N., Biswas, A. K. (1983), “Dispersion-
flocculation studies on hematite-clay systems,”
International Journey of Mineral Processing, April,
285–302.
[3] ICMM (2020), Global Industry Standard on Tailings
Management.
[4] Klein, B. and M. Paulik (2005), “Rheology modi-
fiers for mineral suspensions,” in Minerals and
Metallurgical Processing, May, 83–88.
[5] Luo, L. and Anh V. Nguyen (2017), “A review of
principles and applications of magnetic flocculation
to separate ultrafine magnetic particles,” Separation
and Purification Technology, July, 85–99.
[6] Ma, X., W. J. Bruckard, R. Holmes (2009), “Effect of
collector, pH and ionic strength on the cationic flo-
tation of kaolinite,” International Journey of Mineral
Processing, May, 54–58.
[7] Morkun, V., N. Morkun, V. Tron, V. Golik, A.
Davidkovich (2021), “Increasing efficiency of iron
ore magnetic separation by using ultrasonic technolo-
gies,” in ICSF.
[8] Patra, A. S., D. Makhija, A. K. Mukherjee, R. Tiwari,
C. R. Sahoo, B. D. Mohanty (2016), “Improved
dewatering of iron ore fines by the use of surfactants,”
Powder Technology, 43–50.
[9] Rodrigues, O. M. S., A. E. C. Peres, A. H. Martins,
C. A. Pereira (2013), “Kaolinite and hematite flota-
tion separation using etheramine and ammonium
quaternary salts,” Minerals Engineering, 12–15.
[10] Roy, S. (2012), “Recovery improvement of fine mag-
netic particles by floc magnetic separation,” Mineral
Processing and Extractive Metallurgy, 170–179.
[11] Svoboda, J. T. Fujita (2003), “Recent developments
in magnetic methods of material separation,” Minerals
Engineering, 785–792.