XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3 1513
Ballantyne, G. R., &Powell, M. S. (2014). Benchmarking
comminution energy consumption for the process-
ing of copper and gold ores. Minerals Engineering, 65,
109–114. doi: 10.1016/j.mineng.2014.05.017.
Ballantyne, G. R., Powell, M. S., &Tiang, M. (2012).
Proportion of energy attributable to comminution.
11th Mill operator`s conference, 25–30.
Beke, B. (1981). The process of fine grinding. Akadémiai
Kiadó.
Bergerman, M. G., &Delboni Jr, H. (2020). Development
and validation of a simplified laboratory test to design
vertical stirred mills. KONA Powder and Particle Journal,
37(37), 187–194. doi: 10.14356/kona.2020007.
Bergeron, Y., Kojovic, T., Gagnon, M.-N., &Okono, P.
(2017). Applicability of the HIT for evaluating com-
minution and geomechanical parameters from drill
core samples -the Odissey project case study. The
Conference of Metallurgists.
Bilen, C. (2021). Limestone grindability in terms of HGI
and a new approach for the understanding of grinding
energy. Powder Technology, 392, 1–13. doi: 10.1016/j.
powtec.2021.06.044.
Bond, F. C. (1954). Crushing and grinding calculations.
Transactions, LVII, 286–292.
Bond, F. C. (1960). Confirmation of the third theory.
AIME Transactions, 217(February 1959), 139–153.
Bond, F. C. (1961). Crushing and grinding. British
Chemical Engineering, 29(2), 378–385. doi: 10.1021/
ie50481a012.
Bueno, M., Almeida, T., &Powell, M. (2023). Extensive
Validation of a New Rock Breakage Test. doi: 10.20944/
preprints202307.1348.v1.
Bueno, M. P., Kojovic, T., Powell, M. S., &Shi, F.
(2013). Multi-component AG/SAG mill model.
Minerals Engineering, 43–44, 12–21. doi: 10.1016
/j.mineng.2012.06.011.
Bueno, M., Torvela, J., Chandramohan, R., Chavez Matus,
T., Liedes, T., &Powell, M. (2021). The double
wheel breakage test. Minerals Engineering, 168. doi:
10.1016/j.mineng.2021.106905.
Chandramohan, R., Lane, G. S., Foggiatto, B., &Bueno,
M. P. (2015). Reliability of some ore characterization
tests. SAG Conference.
Curry, J. A., Ismay, M. J. L., &Jameson, G. J. (2014).
Mine operating costs and the potential impacts of
energy and grinding. Minerals Engineering, 56, 70–80.
doi: 10.1016/j.mineng.2013.10.020.
David, D. (2014). Geometallurgical guidelines for miners,
geologists and process engineers: Discovery to design.
Em Mineral Resources and Ore Reserve Estimation: The
AUSIMM Guide to Good Practice (2nd ed, p. 443–450).
Australasian Institute of Mining and Metallurgy.
Doll, A. (2023). Database of public grindability testwork.
https://www.sagmilling.com/articles.
Global Mining Guidelines Group. (2021). The Morrell
method to determine the efficiency of industrial grinding
circuits (GMG04-MP-2021).
Guimarães Bergerman, M., Pamparana, G., Delboni, H., &
Klein, B. (2023). Development of a simplified test for
the determination of the Bond Ball Mill Work Index
using a modified Hardgrove test. Minerals Engineering,
203(April). doi: 10.1016/j.mineng.2023.108359.
Heiskari, H., Kurki, P., Luukkanen, S., Sinche Gonzalez,
M., Lehto, H., &Liipo, J. (2018). Development of
comminution test method for small ore samples.
Comminution 2018.
Herbst, J. A., Lo, Y. C., &Flintoff, B. (2003). Size reduc-
tion and liberation. Em Principles of mineral processing
(p. 61–118). SME.
Hesse, M., Popov, O., &Lieberwirth, H. (2017). Increasing
efficiency by selective comminution. Minerals
Engineering, 103–104, 112–126. doi: 10.1016/j.
mineng.2016.09.003.
Hilden, M., &Suthers, S. (2010). Comparing energy
efficiency of multi-pass High Pressure Grinding Roll
(HPGR)circuits. XXV International Mineral Processing
Congress, 801–811.
Hower, J. C., Barron, L. S., &Moshier, S. O. (1992).
Application of the Hardgrove grindability index in
carbonate characterization. Minerals and Metallurgical
Processing, 9(3), 146–150. doi: 10.1007/bf03402987.
Jankovic, A. (2003). Variables affecting the fine grinding of
minerals using stirred mills. Minerals Engineering, 16(4),
337–345. doi: 10.1016/S0892-6875(03)00007-4.
José Neto, D., Bergerman, M. G., Young, A. S., &Petter,
C. O. (2019). Pre-concentration potential evaluation
for a silicate zinc ore by density and sensor-based sort-
ing methods. REM -International Engineering Journal,
72(2),335–343.doi:10.1590/0370-44672018720155.
Kaya, E., Fletcher, P. C., &Thompson, P. (2002).
Reproducibility of Bond Work Index with different
standard ball mills. 2002 SME Annual Meeting, 1–3.
Klein, B., Bambar, A., Weatherwax, T., Dozdiak, J.,
Nadolski, S., Roufail, R., Parry, J., Roufail, R., &
Tong, L. (2010). Energy efficiency technologies for the
mining industry. CIM AGM.
Ballantyne, G. R., &Powell, M. S. (2014). Benchmarking
comminution energy consumption for the process-
ing of copper and gold ores. Minerals Engineering, 65,
109–114. doi: 10.1016/j.mineng.2014.05.017.
Ballantyne, G. R., Powell, M. S., &Tiang, M. (2012).
Proportion of energy attributable to comminution.
11th Mill operator`s conference, 25–30.
Beke, B. (1981). The process of fine grinding. Akadémiai
Kiadó.
Bergerman, M. G., &Delboni Jr, H. (2020). Development
and validation of a simplified laboratory test to design
vertical stirred mills. KONA Powder and Particle Journal,
37(37), 187–194. doi: 10.14356/kona.2020007.
Bergeron, Y., Kojovic, T., Gagnon, M.-N., &Okono, P.
(2017). Applicability of the HIT for evaluating com-
minution and geomechanical parameters from drill
core samples -the Odissey project case study. The
Conference of Metallurgists.
Bilen, C. (2021). Limestone grindability in terms of HGI
and a new approach for the understanding of grinding
energy. Powder Technology, 392, 1–13. doi: 10.1016/j.
powtec.2021.06.044.
Bond, F. C. (1954). Crushing and grinding calculations.
Transactions, LVII, 286–292.
Bond, F. C. (1960). Confirmation of the third theory.
AIME Transactions, 217(February 1959), 139–153.
Bond, F. C. (1961). Crushing and grinding. British
Chemical Engineering, 29(2), 378–385. doi: 10.1021/
ie50481a012.
Bueno, M., Almeida, T., &Powell, M. (2023). Extensive
Validation of a New Rock Breakage Test. doi: 10.20944/
preprints202307.1348.v1.
Bueno, M. P., Kojovic, T., Powell, M. S., &Shi, F.
(2013). Multi-component AG/SAG mill model.
Minerals Engineering, 43–44, 12–21. doi: 10.1016
/j.mineng.2012.06.011.
Bueno, M., Torvela, J., Chandramohan, R., Chavez Matus,
T., Liedes, T., &Powell, M. (2021). The double
wheel breakage test. Minerals Engineering, 168. doi:
10.1016/j.mineng.2021.106905.
Chandramohan, R., Lane, G. S., Foggiatto, B., &Bueno,
M. P. (2015). Reliability of some ore characterization
tests. SAG Conference.
Curry, J. A., Ismay, M. J. L., &Jameson, G. J. (2014).
Mine operating costs and the potential impacts of
energy and grinding. Minerals Engineering, 56, 70–80.
doi: 10.1016/j.mineng.2013.10.020.
David, D. (2014). Geometallurgical guidelines for miners,
geologists and process engineers: Discovery to design.
Em Mineral Resources and Ore Reserve Estimation: The
AUSIMM Guide to Good Practice (2nd ed, p. 443–450).
Australasian Institute of Mining and Metallurgy.
Doll, A. (2023). Database of public grindability testwork.
https://www.sagmilling.com/articles.
Global Mining Guidelines Group. (2021). The Morrell
method to determine the efficiency of industrial grinding
circuits (GMG04-MP-2021).
Guimarães Bergerman, M., Pamparana, G., Delboni, H., &
Klein, B. (2023). Development of a simplified test for
the determination of the Bond Ball Mill Work Index
using a modified Hardgrove test. Minerals Engineering,
203(April). doi: 10.1016/j.mineng.2023.108359.
Heiskari, H., Kurki, P., Luukkanen, S., Sinche Gonzalez,
M., Lehto, H., &Liipo, J. (2018). Development of
comminution test method for small ore samples.
Comminution 2018.
Herbst, J. A., Lo, Y. C., &Flintoff, B. (2003). Size reduc-
tion and liberation. Em Principles of mineral processing
(p. 61–118). SME.
Hesse, M., Popov, O., &Lieberwirth, H. (2017). Increasing
efficiency by selective comminution. Minerals
Engineering, 103–104, 112–126. doi: 10.1016/j.
mineng.2016.09.003.
Hilden, M., &Suthers, S. (2010). Comparing energy
efficiency of multi-pass High Pressure Grinding Roll
(HPGR)circuits. XXV International Mineral Processing
Congress, 801–811.
Hower, J. C., Barron, L. S., &Moshier, S. O. (1992).
Application of the Hardgrove grindability index in
carbonate characterization. Minerals and Metallurgical
Processing, 9(3), 146–150. doi: 10.1007/bf03402987.
Jankovic, A. (2003). Variables affecting the fine grinding of
minerals using stirred mills. Minerals Engineering, 16(4),
337–345. doi: 10.1016/S0892-6875(03)00007-4.
José Neto, D., Bergerman, M. G., Young, A. S., &Petter,
C. O. (2019). Pre-concentration potential evaluation
for a silicate zinc ore by density and sensor-based sort-
ing methods. REM -International Engineering Journal,
72(2),335–343.doi:10.1590/0370-44672018720155.
Kaya, E., Fletcher, P. C., &Thompson, P. (2002).
Reproducibility of Bond Work Index with different
standard ball mills. 2002 SME Annual Meeting, 1–3.
Klein, B., Bambar, A., Weatherwax, T., Dozdiak, J.,
Nadolski, S., Roufail, R., Parry, J., Roufail, R., &
Tong, L. (2010). Energy efficiency technologies for the
mining industry. CIM AGM.