722 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
REFERENCES
Abraham, A. A., Robinson, T. J., &Anderson-Cook, C. M.
(2009). A Graphical Approach for Assessing Optimal
Operating Conditions in Robust Design. Quality
Technology &Quantitative Management, 6(3), 235–
253. doi: 10.1080/16843703.2009.11673197.
Ait-khouia, Y., Benzaazoua, M., Elghali, A., Chopard, A.,
&Demers, I. (2022). Feasibility of reprocessing gold
tailings: Integrated management approach for the con-
trol of contaminated neutral mine drainage. Minerals
Engineering, 187(September). doi: 10.1016/j.mineng
.2022.107821.
Alam, N., Ozdemir, O., Hampton, M. A., &Nguyen, A. V.
(2011). Dewatering of coal plant tailings: Flocculation
followed by filtration. Fuel, 90(1), 26–35. doi:
10.1016/j.fuel.2010.08.006.
Amarjargal, B., &Taşdemir, T. (2023). A Comparative Study:
Evaluation of Wastewater Suspensions Flocculation
Performance Using Laboratory Graduated Cylinder
and Jar Test Methods. Water, Air, and Soil Pollution,
234(9), 1–13. doi: 10.1007/s11270-023-06605-0.
Ardaman &Associates, I. (1985). Evaluation of Phosphatic
Clay Disposal and Reclamation Methods. Volume
7_ Engineering Properties of Flocculated Phosphatic
Clays.
Bahmani-Ghaedi, A., Hassanzadeh, A., Sam, A., &
Entezari-Zarandi, A. (2022). The effect of residual floc-
culants in the circulating water on dewatering of Gol-e-
Gohar iron ore. Minerals Engineering, 179(February),
107440. doi: 10.1016/j.mineng.2022.107440.
Bahmani-ghaedi, A., Hassanzadeh, A., Sam, A., Entezari-
zarandi, A., &R, C. T. Des. (2022). The effect
of residual flocculants in the circulating water on
dewatering of Gol-e-Gohar iron ore. Minerals
Engineering, 179(February), 107440. doi: 10.1016
/j.mineng.2022.107440.
Bezerra, M. A., Santelli, R. E., Oliveira, E. P., Villar, L.
S., &Escaleira, L. A. (2008). Response surface meth-
odology (RSM) as a tool for optimization in analyti-
cal chemistry. Talanta, 76(5), 965–977. doi: 10.1016
/j.talanta.2008.05.019.
Boshrouyeh Ghandashtani, M., Costine, A., Edraki, M., &
Baumgartl, T. (2022). The impacts of high salinity and
polymer properties on dewatering and structural char-
acteristics of flocculated high-solids tailings. Journal
of Cleaner Production, 342(January), 130726. doi:
10.1016/j.jclepro.2022.130726.
By Russell R. Barton. (1999). Graphical Methods for the
Design of Experiments. In Journal of the American
Statistical Association (Vol. 96, Issue 453). doi:
10.1198/jasa.2001.s379.
Castillo, C., Fawell, P., &Costine, A. (2023). Optimising
the activity of acrylamide-based polymer solutions used
to flocculate mineral processing tailings suspensions –
A review. Chemical Engineering Research and Design,
199, 214–237. doi: 10.1016/j.cherd.2023.10.001.
Costine, A., Cox, J., Travaglini, S., Lubansky, A., Fawell, P.,
&Misslitz, H. (2018). Variations in the molecu-
lar weight response of anionic polyacrylamides
under different flocculation conditions. Chemical
Engineering Science, 176, 127–138. doi: 10.1016
/j.ces.2017.10.031.
Cutright, T. J., &Meza, L. (2007). Evaluation of the aero-
bic biodegradation of trichloroethylene via response
surface methodology. Environment International,
33(3), 338–345. doi: 10.1016/j.envint.2006.11.012.
Derhy, M., Taha, Y., Ait-khouia, Y., &Elghali, A. (2024).
Enhancing selective calcite and dolomite flota-
tion in the phosphate ores :Investigation, model-
ing, and automated mineralogy assessment. Minerals
Engineering, 207(June 2023), 108569. doi: 10.1016
/j.mineng.2023.108569.
Derhy, M., Taha, Y., Benzaazoua, M., El-Bahi, A., Ait-
Khouia, Y., &Hakkou, R. (2022). Assessment of the
selective flotation of calcite, apatite and quartz using
bio-based collectors: Flaxseed, nigella, and olive oils.
Minerals Engineering, 182(January), 107589. doi:
10.1016/j.mineng.2022.107589.
Eskanlou, A., &Huang, Q. (2021). Phosphatic waste clay:
Origin, composition, physicochemical properties,
challenges, values and possible remedies – A review.
Minerals Engineering, 162(October 2020), 106745.
doi: 10.1016/j.mineng.2020.106745.
Fan, Y., Dong, X., Feng, Z., &Dong, Y. (2020).
Characterisation of floc size, effective density and sedi-
mentation under various flocculation mechanisms.
Water Science &Technology, 1–11. doi: 10.2166
/wst.2020.385.
Gunson, A. J., Klein, B., Veiga, M., &Dunbar, S.
(2012). Reducing mine water requirements. Journal
of Cleaner Production, 21(1), 71–82. doi: 10.1016
/j.jclepro.2011.08.020.
Jarvis, P., Jefferson, B., Gregory, J., &Parsons, S. A.
(2005). A review of floc strength and breakage.
Water Research, 39(14), 3121–3137. doi: 10.1016
/j.watres.2005.05.022.
REFERENCES
Abraham, A. A., Robinson, T. J., &Anderson-Cook, C. M.
(2009). A Graphical Approach for Assessing Optimal
Operating Conditions in Robust Design. Quality
Technology &Quantitative Management, 6(3), 235–
253. doi: 10.1080/16843703.2009.11673197.
Ait-khouia, Y., Benzaazoua, M., Elghali, A., Chopard, A.,
&Demers, I. (2022). Feasibility of reprocessing gold
tailings: Integrated management approach for the con-
trol of contaminated neutral mine drainage. Minerals
Engineering, 187(September). doi: 10.1016/j.mineng
.2022.107821.
Alam, N., Ozdemir, O., Hampton, M. A., &Nguyen, A. V.
(2011). Dewatering of coal plant tailings: Flocculation
followed by filtration. Fuel, 90(1), 26–35. doi:
10.1016/j.fuel.2010.08.006.
Amarjargal, B., &Taşdemir, T. (2023). A Comparative Study:
Evaluation of Wastewater Suspensions Flocculation
Performance Using Laboratory Graduated Cylinder
and Jar Test Methods. Water, Air, and Soil Pollution,
234(9), 1–13. doi: 10.1007/s11270-023-06605-0.
Ardaman &Associates, I. (1985). Evaluation of Phosphatic
Clay Disposal and Reclamation Methods. Volume
7_ Engineering Properties of Flocculated Phosphatic
Clays.
Bahmani-Ghaedi, A., Hassanzadeh, A., Sam, A., &
Entezari-Zarandi, A. (2022). The effect of residual floc-
culants in the circulating water on dewatering of Gol-e-
Gohar iron ore. Minerals Engineering, 179(February),
107440. doi: 10.1016/j.mineng.2022.107440.
Bahmani-ghaedi, A., Hassanzadeh, A., Sam, A., Entezari-
zarandi, A., &R, C. T. Des. (2022). The effect
of residual flocculants in the circulating water on
dewatering of Gol-e-Gohar iron ore. Minerals
Engineering, 179(February), 107440. doi: 10.1016
/j.mineng.2022.107440.
Bezerra, M. A., Santelli, R. E., Oliveira, E. P., Villar, L.
S., &Escaleira, L. A. (2008). Response surface meth-
odology (RSM) as a tool for optimization in analyti-
cal chemistry. Talanta, 76(5), 965–977. doi: 10.1016
/j.talanta.2008.05.019.
Boshrouyeh Ghandashtani, M., Costine, A., Edraki, M., &
Baumgartl, T. (2022). The impacts of high salinity and
polymer properties on dewatering and structural char-
acteristics of flocculated high-solids tailings. Journal
of Cleaner Production, 342(January), 130726. doi:
10.1016/j.jclepro.2022.130726.
By Russell R. Barton. (1999). Graphical Methods for the
Design of Experiments. In Journal of the American
Statistical Association (Vol. 96, Issue 453). doi:
10.1198/jasa.2001.s379.
Castillo, C., Fawell, P., &Costine, A. (2023). Optimising
the activity of acrylamide-based polymer solutions used
to flocculate mineral processing tailings suspensions –
A review. Chemical Engineering Research and Design,
199, 214–237. doi: 10.1016/j.cherd.2023.10.001.
Costine, A., Cox, J., Travaglini, S., Lubansky, A., Fawell, P.,
&Misslitz, H. (2018). Variations in the molecu-
lar weight response of anionic polyacrylamides
under different flocculation conditions. Chemical
Engineering Science, 176, 127–138. doi: 10.1016
/j.ces.2017.10.031.
Cutright, T. J., &Meza, L. (2007). Evaluation of the aero-
bic biodegradation of trichloroethylene via response
surface methodology. Environment International,
33(3), 338–345. doi: 10.1016/j.envint.2006.11.012.
Derhy, M., Taha, Y., Ait-khouia, Y., &Elghali, A. (2024).
Enhancing selective calcite and dolomite flota-
tion in the phosphate ores :Investigation, model-
ing, and automated mineralogy assessment. Minerals
Engineering, 207(June 2023), 108569. doi: 10.1016
/j.mineng.2023.108569.
Derhy, M., Taha, Y., Benzaazoua, M., El-Bahi, A., Ait-
Khouia, Y., &Hakkou, R. (2022). Assessment of the
selective flotation of calcite, apatite and quartz using
bio-based collectors: Flaxseed, nigella, and olive oils.
Minerals Engineering, 182(January), 107589. doi:
10.1016/j.mineng.2022.107589.
Eskanlou, A., &Huang, Q. (2021). Phosphatic waste clay:
Origin, composition, physicochemical properties,
challenges, values and possible remedies – A review.
Minerals Engineering, 162(October 2020), 106745.
doi: 10.1016/j.mineng.2020.106745.
Fan, Y., Dong, X., Feng, Z., &Dong, Y. (2020).
Characterisation of floc size, effective density and sedi-
mentation under various flocculation mechanisms.
Water Science &Technology, 1–11. doi: 10.2166
/wst.2020.385.
Gunson, A. J., Klein, B., Veiga, M., &Dunbar, S.
(2012). Reducing mine water requirements. Journal
of Cleaner Production, 21(1), 71–82. doi: 10.1016
/j.jclepro.2011.08.020.
Jarvis, P., Jefferson, B., Gregory, J., &Parsons, S. A.
(2005). A review of floc strength and breakage.
Water Research, 39(14), 3121–3137. doi: 10.1016
/j.watres.2005.05.022.