This review article surveys the subject of choice of high gradient magnetic separation processes for removal of Fe2O3 carriers from quartz raw material by electromagnetic separator with magnetic field intensity of 1.4 T. The review is based on current experience of authors during research phase, as well as project development phase and initial operation of facilities in several locations. Quartz mineral raw material in those locations appeared as sandstone or as loose material. In addition to that, quartz raw material from those locations contained various impurities, i.e. Fe2O3 carriers. The choice of this process for Fe2O3 removal depended on mineralogical composition, shape and the content of minerals, and Fe2O3 removal rate after this process was from 29 to 65%. Magnetic separation is magnetic induction of 1.4 T. It is applied on commercial assortments which were previously subjected to washing and classification processes. It is always the assortment which has to have the lowest F...e2O3 content. The choice of, "dry" or, "wet" magnetic separation (with water flush) also depends on the fact whether this desired assortment is intended for market as dry or wet, as well as on the composition of magnetic impurities. In most cases, the process applied is the wet one.
Keywords:
quartz raw material / preparation processes / minerals / impurities / high gradient magnetic separation
TY - JOUR
AU - Sekulić, Živko
AU - Bartulović, Zoran
AU - Mihajlović, Slavica
AU - Ignjatović, Miroslav R.
AU - Savić, Ljubinko
AU - Jovanović, Vladimir
AU - Nisić, Dragana
PY - 2017
UR - https://ritnms.itnms.ac.rs/handle/123456789/420
AB - This review article surveys the subject of choice of high gradient magnetic separation processes for removal of Fe2O3 carriers from quartz raw material by electromagnetic separator with magnetic field intensity of 1.4 T. The review is based on current experience of authors during research phase, as well as project development phase and initial operation of facilities in several locations. Quartz mineral raw material in those locations appeared as sandstone or as loose material. In addition to that, quartz raw material from those locations contained various impurities, i.e. Fe2O3 carriers. The choice of this process for Fe2O3 removal depended on mineralogical composition, shape and the content of minerals, and Fe2O3 removal rate after this process was from 29 to 65%. Magnetic separation is magnetic induction of 1.4 T. It is applied on commercial assortments which were previously subjected to washing and classification processes. It is always the assortment which has to have the lowest Fe2O3 content. The choice of, "dry" or, "wet" magnetic separation (with water flush) also depends on the fact whether this desired assortment is intended for market as dry or wet, as well as on the composition of magnetic impurities. In most cases, the process applied is the wet one.
PB - Polska Akad Nauk, Polish Acad Sciences, Miner & Energy Econ Res Inst Pas, Warszawa
T2 - Gospodarka Surowcami Mineralnymi-Mineral Resources Management
T1 - The choice of high gradient magnetic separation processes for removal of Fe2O3 carriers from quartz raw material
EP - 106
IS - 4
SP - 93
VL - 33
DO - 10.1515/gospo-2017-0047
UR - conv_813
ER -
@article{
author = "Sekulić, Živko and Bartulović, Zoran and Mihajlović, Slavica and Ignjatović, Miroslav R. and Savić, Ljubinko and Jovanović, Vladimir and Nisić, Dragana",
year = "2017",
abstract = "This review article surveys the subject of choice of high gradient magnetic separation processes for removal of Fe2O3 carriers from quartz raw material by electromagnetic separator with magnetic field intensity of 1.4 T. The review is based on current experience of authors during research phase, as well as project development phase and initial operation of facilities in several locations. Quartz mineral raw material in those locations appeared as sandstone or as loose material. In addition to that, quartz raw material from those locations contained various impurities, i.e. Fe2O3 carriers. The choice of this process for Fe2O3 removal depended on mineralogical composition, shape and the content of minerals, and Fe2O3 removal rate after this process was from 29 to 65%. Magnetic separation is magnetic induction of 1.4 T. It is applied on commercial assortments which were previously subjected to washing and classification processes. It is always the assortment which has to have the lowest Fe2O3 content. The choice of, "dry" or, "wet" magnetic separation (with water flush) also depends on the fact whether this desired assortment is intended for market as dry or wet, as well as on the composition of magnetic impurities. In most cases, the process applied is the wet one.",
publisher = "Polska Akad Nauk, Polish Acad Sciences, Miner & Energy Econ Res Inst Pas, Warszawa",
journal = "Gospodarka Surowcami Mineralnymi-Mineral Resources Management",
title = "The choice of high gradient magnetic separation processes for removal of Fe2O3 carriers from quartz raw material",
pages = "106-93",
number = "4",
volume = "33",
doi = "10.1515/gospo-2017-0047",
url = "conv_813"
}
Sekulić, Ž., Bartulović, Z., Mihajlović, S., Ignjatović, M. R., Savić, L., Jovanović, V.,& Nisić, D.. (2017). The choice of high gradient magnetic separation processes for removal of Fe2O3 carriers from quartz raw material. in Gospodarka Surowcami Mineralnymi-Mineral Resources Management
Polska Akad Nauk, Polish Acad Sciences, Miner & Energy Econ Res Inst Pas, Warszawa., 33(4), 93-106.
https://doi.org/10.1515/gospo-2017-0047
conv_813
Sekulić Ž, Bartulović Z, Mihajlović S, Ignjatović MR, Savić L, Jovanović V, Nisić D. The choice of high gradient magnetic separation processes for removal of Fe2O3 carriers from quartz raw material. in Gospodarka Surowcami Mineralnymi-Mineral Resources Management. 2017;33(4):93-106.
doi:10.1515/gospo-2017-0047
conv_813 .
Sekulić, Živko, Bartulović, Zoran, Mihajlović, Slavica, Ignjatović, Miroslav R., Savić, Ljubinko, Jovanović, Vladimir, Nisić, Dragana, "The choice of high gradient magnetic separation processes for removal of Fe2O3 carriers from quartz raw material" in Gospodarka Surowcami Mineralnymi-Mineral Resources Management, 33, no. 4 (2017):93-106,
https://doi.org/10.1515/gospo-2017-0047 .,
conv_813 .
