582 XXXI International Mineral Processing Congress 2024 Proceedings/Washington, DC/Sep 29–Oct 3
[32] Selective Flocculation of Chromite Tailings |
Transactions of the Indian Institute of Metals [www
Document], n.d. URL https://link.springer.com
/article/10.1007/s12666-020-02175-5 (accessed
2.7.24).
[33] Singh, R.K., Dey, S., Mohanta, M.K., Das, A.,
2014a. Enhancing the Utilization Potential of a Low
Grade Chromite Ore through Extensive Physical
Separation. Sep. Sci. Technol. 49, 1937–1945. doi:
10.1080/01496395.2014.903495.
[34] Singh, R.K., Dey, S., Mohanta, M.K., Das, A.,
2014b. Enhancing the Utilization Potential of a Low
Grade Chromite Ore through Extensive Physical
Separation. Sep. Sci. Technol. 49, 1937–1945. doi:
10.1080/01496395.2014.903495.
[35] Subandrio, S., Dahani, W., Alghifar, M.,
Purwiyono, T.T., 2019. Enrichment Chromite
Sand Grade Using Magnetic Separator. IOP
Conf. Ser. Mater. Sci. Eng. 588, 012033. doi:
10.1088/1757-899X/588/1/012033.
[36] Tripathy, S., Murthy, Y., Singh, V., Farrokhpay,
S., Filippov, L., 2019. Improving the Quality of
Ferruginous Chromite Concentrates Via Physical
Separation Methods. Minerals 9, 667. doi: 10.3390
/min9110667.
[37] Tripathy, S.K., Banerjee, P.K., Suresh, N., Murthy,
Y.R., Singh, V., 2017. Dry High-Intensity Magnetic
Separation In Mineral Industry—A Review Of
Present Status And Future Prospects. Miner.
Process. Extr. Metall. Rev. 38, 339–365. doi:
10.1080/08827508.2017.1323743.
[38] Tripathy, S.K., Murthy, Y.R., 2012. Multiobjective
optimisation of spiral concentrator for separation of
ultrafine chromite. Int. J. Min. Miner. Eng. 4, 151.
doi: 10.1504/IJMME.2012.052440.
[39] Tripathy, S.K., Murthy, Y.R., Singh, V., Farrokhpay,
S., Filippov, L.O., 2019a. Improving the Quality of
Ferruginous Chromite Concentrates Via Physical
Separation Methods. Minerals 9, 667. doi: 10.3390
/min9110667.
[40] Tripathy, S.K., Murthy, Y.R., Singh, V., Suresh,
N., 2016a. Processing of Ferruginous Chromite
Ore by Dry High-Intensity Magnetic Separation.
Miner. Process. Extr. Metall. Rev. 37, 196–210. doi:
10.1080/08827508.2016.1168418.
[41] Tripathy, S.K., Murthy, Y.R., Singh, V., Suresh,
N., 2016b. Processing of Ferruginous Chromite
Ore by Dry High-Intensity Magnetic Separation.
Miner. Process. Extr. Metall. Rev. 37, 196–210. doi:
10.1080/08827508.2016.1168418.
[42] Tripathy, S.K., Prasad, S., Khan, S.Z., Rama Murthy,
Y., Singh, V., Kapure, G., 2019b. Upgradation of low-
grade ferruginous chromite ore by reduction roasting
using conventional and microwave heating: 29th
International Mineral Processing Congress, IMPC
2018. IMPC 2018—29th International Mineral
Processing Congress 4073–4082.
[43] Tripathy, S.K., Singh, V., Ramamurthy, Y., 2012.
Improvement in Cr:Fe Ratio of Indian Chromite Ore
for Ferro Chrome Production.
[44] Wang, Y., Pugh, R.J., Forssberg, E., NaN/NaN/
NaN. Carrier Coagulation of Chromite Fines in Wet
Magnetic Separation. Phys. Sep. Sci. Eng. 5, 33–52.
doi: 10.1155/1993/40239.
[45] Xie, S., Hu, Z., Lu, D., Zhao, Y., 2022. Dry
Permanent Magnetic Separator: Present Status and
Future Prospects. Minerals 12, 1251. doi: 10.3390
/min12101251.
[46] Zong, Q.X., Fu, L.Z., Bo, L., 2018. Variables
and Applications on Dry Magnetic Separator.
E3S Web Conf. 53, 02019. doi: 10.1051/e3sconf
/20185302019.
[32] Selective Flocculation of Chromite Tailings |
Transactions of the Indian Institute of Metals [www
Document], n.d. URL https://link.springer.com
/article/10.1007/s12666-020-02175-5 (accessed
2.7.24).
[33] Singh, R.K., Dey, S., Mohanta, M.K., Das, A.,
2014a. Enhancing the Utilization Potential of a Low
Grade Chromite Ore through Extensive Physical
Separation. Sep. Sci. Technol. 49, 1937–1945. doi:
10.1080/01496395.2014.903495.
[34] Singh, R.K., Dey, S., Mohanta, M.K., Das, A.,
2014b. Enhancing the Utilization Potential of a Low
Grade Chromite Ore through Extensive Physical
Separation. Sep. Sci. Technol. 49, 1937–1945. doi:
10.1080/01496395.2014.903495.
[35] Subandrio, S., Dahani, W., Alghifar, M.,
Purwiyono, T.T., 2019. Enrichment Chromite
Sand Grade Using Magnetic Separator. IOP
Conf. Ser. Mater. Sci. Eng. 588, 012033. doi:
10.1088/1757-899X/588/1/012033.
[36] Tripathy, S., Murthy, Y., Singh, V., Farrokhpay,
S., Filippov, L., 2019. Improving the Quality of
Ferruginous Chromite Concentrates Via Physical
Separation Methods. Minerals 9, 667. doi: 10.3390
/min9110667.
[37] Tripathy, S.K., Banerjee, P.K., Suresh, N., Murthy,
Y.R., Singh, V., 2017. Dry High-Intensity Magnetic
Separation In Mineral Industry—A Review Of
Present Status And Future Prospects. Miner.
Process. Extr. Metall. Rev. 38, 339–365. doi:
10.1080/08827508.2017.1323743.
[38] Tripathy, S.K., Murthy, Y.R., 2012. Multiobjective
optimisation of spiral concentrator for separation of
ultrafine chromite. Int. J. Min. Miner. Eng. 4, 151.
doi: 10.1504/IJMME.2012.052440.
[39] Tripathy, S.K., Murthy, Y.R., Singh, V., Farrokhpay,
S., Filippov, L.O., 2019a. Improving the Quality of
Ferruginous Chromite Concentrates Via Physical
Separation Methods. Minerals 9, 667. doi: 10.3390
/min9110667.
[40] Tripathy, S.K., Murthy, Y.R., Singh, V., Suresh,
N., 2016a. Processing of Ferruginous Chromite
Ore by Dry High-Intensity Magnetic Separation.
Miner. Process. Extr. Metall. Rev. 37, 196–210. doi:
10.1080/08827508.2016.1168418.
[41] Tripathy, S.K., Murthy, Y.R., Singh, V., Suresh,
N., 2016b. Processing of Ferruginous Chromite
Ore by Dry High-Intensity Magnetic Separation.
Miner. Process. Extr. Metall. Rev. 37, 196–210. doi:
10.1080/08827508.2016.1168418.
[42] Tripathy, S.K., Prasad, S., Khan, S.Z., Rama Murthy,
Y., Singh, V., Kapure, G., 2019b. Upgradation of low-
grade ferruginous chromite ore by reduction roasting
using conventional and microwave heating: 29th
International Mineral Processing Congress, IMPC
2018. IMPC 2018—29th International Mineral
Processing Congress 4073–4082.
[43] Tripathy, S.K., Singh, V., Ramamurthy, Y., 2012.
Improvement in Cr:Fe Ratio of Indian Chromite Ore
for Ferro Chrome Production.
[44] Wang, Y., Pugh, R.J., Forssberg, E., NaN/NaN/
NaN. Carrier Coagulation of Chromite Fines in Wet
Magnetic Separation. Phys. Sep. Sci. Eng. 5, 33–52.
doi: 10.1155/1993/40239.
[45] Xie, S., Hu, Z., Lu, D., Zhao, Y., 2022. Dry
Permanent Magnetic Separator: Present Status and
Future Prospects. Minerals 12, 1251. doi: 10.3390
/min12101251.
[46] Zong, Q.X., Fu, L.Z., Bo, L., 2018. Variables
and Applications on Dry Magnetic Separator.
E3S Web Conf. 53, 02019. doi: 10.1051/e3sconf
/20185302019.