An Investigation into Magnetic Roasting-Separation of Refractory Iron Ore in Suspended State

Aiming at the disadvantages of traditional magnetic roasting process, suspension calcining process was suggested to dispose refractory iron ore. The experiment indicated that under the conditions of 750°C~850°C, CO volume percentage was 1%, the limonite and siderite could efficiently transformation into magnetite, which only needed 10~20 secs. Tests of roasting-magnetic separation could attained results as: concentrate iron grade be 49.26%, recovery of iron be 87.28%.

Recovering Iron from Iron Ore Tailings and Preparing Concrete Composite Admixtures

Minerals ◽

10.3390/min9040232 ◽

2019 ◽

Vol 9 (4) ◽

pp. 232 ◽

Cited By ~ 9

Author(s):

Chang Tang ◽

Keqing Li ◽

Wen Ni ◽

Duncheng Fan

Keyword(s):

Magnetic Separation ◽

Iron Ore ◽

Direct Reduction ◽

Mineral Admixtures ◽

Iron Recovery ◽

Slag Powder ◽

Highly Active ◽

Iron Ore Tailings ◽

High Silica ◽

Iron ore tailings (IOTs) are a form of solid waste produced during the beneficiation process of iron ore concentrate. In this paper, iron recovery from IOTs was studied at different points during a process involving pre-concentration followed by direct reduction and magnetic separation. Then, slag-tailing concrete composite admixtures were prepared from high-silica residues. Based on the analyses of the chemical composition and crystalline phases, a pre-concentration test was developed, and a pre-concentrated concentrate (PC) with an iron grade of 36.58 wt % and a total iron recovery of 83.86 wt % was obtained from a feed iron grade of 12.61 wt %. Furthermore, the influences of various parameters on iron recovery from PC through direct reduction and magnetic separation were investigated. The optimal parameters were found to be as follows: A roasting temperature of 1250 °C, a roasting time of 50 min, and a 17.5:7.5:12.5:100 ratio of bitumite/sodium carbonate/lime/PC. Under these conditions, the iron grade of the reduced iron powder was 92.30 wt %, and the iron recovery rate was 93.96 wt %. With respect to the original IOTs, the iron recovery was 78.79 wt %. Then, highly active slag-tailing concrete composite admixtures were prepared using the high-silica residues and S75 blast furnace slag powder. When the amount of high-silica residues replacing slag was 20%, the strength of cement mortar blocks at 7 days and 28 days was 33.11 MPa and 50 MPa, respectively, whereas the activity indices were 89 and 108, respectively. Meanwhile, the fluidity rate was appropriately 109. When the content of high-silica residues replacing slag was not more than 30%, the quality of mineral admixtures was not reduced. Last but not least, reusing the high-silica residues during iron recovery enabled the complete utilization of the IOTs.

Characterization of Band-E Narges magnetite iron ore for mineral processing

Earth Sciences Research Journal ◽

10.15446/esrj.v22n2.73438 ◽

2018 ◽

Vol 22 (2) ◽

pp. 145-148

Author(s):

Amir Pazoki ◽

Reza Rashidi-Khabir ◽

Reza Jahanian ◽

Ali Pourbahaadini

Keyword(s):

Magnetic Separation ◽

Sulfur Content ◽

Iron Ore ◽

Iron Recovery ◽

Experimental Conditions ◽

Isfahan Province ◽

Initial Content ◽

Iron Grade ◽

The City

The Band-e Narges deposit is located about 70 km northeast of the city of Badrud, northern Isfahan province. Band-E Narges ore deposit is mining for magnetite. To release valuable minerals, crushing and grinding implemented for separation ore from the gangue. Magnetic separation and flotation methods for upgrading magnetite iron ore were carried out in different experimental conditions with varied parameters. The particle size of the initial content was 74 microns for flotation, and 150 microns for magnetic separation. The initial samples, with the iron grade of 43.4% and sulfur of 1.9%, are individually subjected to upgrading by floatation and magnetic separation during which the affecting parameters for each method were optimized. The improvement in the optimal condition for magnetic separation culminated in 60.85% for the iron grade, 85.21% iron for recovery and 1.08% for sulfur content. The upgrading by floatation in the optimal mode produced 60.02% iron grade, 80.41% iron recovery and 0.95% sulfur content. To determine the best method for the pre-concentration stage of ore, the content gained from each technique passed reclining for grad improvement. The final content obtained from the magnetic separation of was undergone the floatation test yielded to a content with 64.3% iron grade, 77.15% iron recovery and 0.7% sulfur content. The use of magnetic separation as a pre-concentration stage for floatation method is proposed as an economical method for improving the grade of the iron and reduce the sulfur content and to avoid the high cost of grinding, which is costly part of processing procedures.

Research on the Middlings from Dong Anshan Iron Ore by Roasting-Magnetic Dressing

10.4028/www.scientific.net/amr.826.102 ◽

2013 ◽

Vol 826 ◽

pp. 102-105

Author(s):

Ji Wei Lu ◽

Nai Ling Wang ◽

Wan Zhong Yin ◽

Rui Chao Zhao ◽

Chuang Yuan

Keyword(s):

Magnetic Separation ◽

Iron Ore ◽

Reduction Roasting ◽

Iron Recovery ◽

Flotation Process ◽

Iron Concentrate ◽

For the middlings (containing siderite) separated from Dong Anshan carbonaceous iron ore which was dressed by a two-step flotation process, using roasting-magnetic and regrinding-magnetic separation, the iron concentrate with iron grade and iron recovery of 60.31%, 87.49% was obtained. Mechanism of reduction-roasting was studied by means of XRD in the end.

Experimental Research of Low-Grade Tin-Iron Ore Separation

10.4028/www.scientific.net/amr.641-642.377 ◽

2013 ◽

Vol 641-642 ◽

pp. 377-380

Author(s):

Yi Miao Nie ◽

Qi Hui Dai ◽

Xiao Long Lu

Keyword(s):

Magnetic Separation ◽

Concentration Ratio ◽

Iron Ore ◽

Shaking Table ◽

Low Grade ◽

Gravity Concentration ◽

Iron Concentrate ◽

Stage Separation ◽

Concentrate Grade ◽

Iron ore and tin mineral are the mainly recovered minerals of the low-grade ore, which could be effectively separated by a strong magnetic separation-gravity concentration process, with ore iron grade of 20.3%, tin grade 0.18%. Stage grinding and stage separation was used, getting the grade of iron concentrate and the recovery rate of tin separation index, the feeder of tin was magnetic separation tailing, by shaking table re-election, obtained tin concentrate grade was 10%, production was 0.34% (compared to the original ore, tin dressing) .Tin concentration ratio reached more than 330.

Improvement of the technology for processing siderite ore from the Bakal deposit

Transbaikal State University Journal ◽

10.21209/2227-9245-2021-27-4-6-12 ◽

2021 ◽

Vol 27 (4) ◽

pp. 6-12

Author(s):

Е. Degodya ◽

◽

N. Sedinkina ◽

О. Shavakuleva ◽

N. Gmyzina ◽

...

Keyword(s):

Magnetic Field ◽

Magnesium Oxide ◽

Magnetic Separation ◽

Mass Fraction ◽

Iron Ore ◽

Raw Material ◽

Magnetic Fraction ◽

Suspended State ◽

Dry Magnetic Separation ◽

Siderite Ore

The Urals is one of the unique iron ore provinces of the world, including all the variety of iron ores. Siderite ores are represented by the Bakal group of deposits, in which siderite in mineralogical terms is not a chemically pure iron carbonate, but has an isomorphic admixture of magnesium and calcium, forming sideroplesite and pistomesite. The main iron ore mineral of the siderite ore of this deposit is an isomorphic mixture of iron, magnesium and manganese carbonates, which occur in different quantitative ratios. A scheme for ore dressing is proposed, which includes crushing to a size of 10-0 mm and dry magnetic separation in a suspended state at a magnetic field strength of 52 k/m. The study of dry magnetic separation of siderite ore was carried out on a suspended separator with a constant magnetic field and on an electromagnetic separator 138T-SEM. The resulting magnetic fraction is sent to the baking, subsequent crushing to a size of 2-0 mm and dry magnetic separation in the suspended state. To increase the mass fraction of iron and reduce the mass fraction of magnesium oxide, the magnetic fraction is sent for grinding and wet magnetic separation. The results of the experiments have showed that the enrichment using high-intensity dry magnetic separation of siderite ore from various sections of the deposit, the mass fraction of MgO decreased from 9.4-12.3% to 8.0-10.1%, and the mass fraction of iron increased from 28.8-33.4% to 31.4-40.8%. As a result, a product with a mass fraction of iron 59.3-60.1% and magnesium oxide 10.0-11.3% has been obtained. The developed enrichment technology allows us to obtain conditioned raw materials, which can serve as a promising raw material for PJSC Magnitogorsk Iron and Steel Works (PJSC MMK)

Thermodynamic Study on the Sulfidation-Magnetic Roasting of the Hematite Type of Tin-Bearing Iron Ore

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.472.596 ◽

2014 ◽

Vol 472 ◽

pp. 596-602

Author(s):

Bin Liao ◽

Lei LI ◽

Hua Wang ◽

Xiu Li Sang

Keyword(s):

Magnetic Separation ◽

Iron Ore ◽

Thermodynamic Study ◽

New Method ◽

Thermodynamics Analysis ◽

Roasting Process ◽

Co Concentration ◽

Iron Phase

Sulfidation-magnetic roasting process was used to treat tin-bearing iron ore of hematite to recovery iron resources. The results of thermodynamics analysis of the roasting reaction trait showed that, when CO concentration was lower than 11.43% at temperature higher than 873K, SnO2 and Fe2O3 could be selectively reduced to SnO and Fe3O4, respectively. FeS2 would be decomposed into FeS and S2 during the roasting process, and the S2 sulfidation effect was stronger than FeS. After roasting, the main iron phase of the minerals was changed into magnetite from hematite and then the iron could be recovered through the magnetic separation. This method provides a new method for the recovery of iron from tin-bearing iron ore of hematite.

Increasing Iron and Reducing Phosphorus Grades of Magnetic-Roasted High-Phosphorus Oolitic Iron Ore by Low-Intensity Magnetic Separation–Reverse Flotation

Processes ◽

10.3390/pr7060388 ◽

2019 ◽

Vol 7 (6) ◽

pp. 388 ◽

Cited By ~ 8

Author(s):

Xiao ◽

Zhou

Keyword(s):

Magnetic Separation ◽

Iron Ore ◽

Phosphorus Content ◽

Reverse Flotation ◽

Low Intensity ◽

High Phosphorus ◽

Oolitic Iron Ore ◽

Phosphorus Reduction ◽

Iron Grade ◽

Iron Ore Concentrate

High-phosphorus oolitic iron ore, treated by suspended flash magnetic roasting, contained 42.73% iron (mainly present as magnetite) and 0.93% phosphorus (present as collophane). Low-intensity magnetic separation (LIMS) was combined with reverse flotation to increase the iron and reduce the phosphorus contents of the roasted product. The results showed that an optimized iron ore concentrate with an iron grade of 67.54%, phosphorus content of 0.11%, and iron recovery of 78.99% were obtained under LIMS conditions that employed a grind of 95% −0.038 mm and a magnetic field of 0.10 T. Optimized rougher reverse-flotation conditions used a pulp pH of 9 and dosages of toluenesulfonamide, starch, and pine alcohol oil of 800 g/t, 1000 g/t, and 40 g/t, respectively; optimized scavenging conditions used a pulp pH of 9 and dosages of toluenesulfonamide, starch, and pine alcohol oil of 400 g/t, 500 g/t, and 20 g/t, respectively. Study of the mechanism of phosphorus reduction showed that the toluenesulfonamide could be adsorbed on the surface of quartz after the action of starch, but adsorption was significantly weakened. The starch inhibitor negatively affected adsorption on quartz, but positively influenced adsorption of phosphorus minerals.

Study on Deep Reduction and Efficient Separation of Lingyang Iron Ore

10.4028/www.scientific.net/amr.454.310 ◽

2012 ◽

Vol 454 ◽

pp. 310-314 ◽

Cited By ~ 1

Author(s):

Yan Jun Li ◽

Jie Liu ◽

Yue Xin Han ◽

Shu Min Zhang

Keyword(s):

Iron Powder ◽

Magnetic Separation ◽

Iron Ore ◽

Mineral Processing ◽

Reduction Temperature ◽

Optimum Conditions ◽

Fine Grinding ◽

Efficient Separation ◽

Iron Grade ◽

Temperature Time

The test for deep reduction and efficient separation of Lingyang iron ore from Linjiang that cannot be separated and utilized by any conventional mineral processing technology was conducted in the Laboratory, and the research results showed that iron from Lingyang iron ore was recovered effectively. In this paper, the effect of reduction temperature, time and coal content on reduction was analyzed, and the process of deep reduction and efficient magnetic separation was investigated. Furthermore, on such optimum conditions of deep reduction as reduction temperature 1275°C, time 50min, and coal content 40%, the reduction products were separated in the flowsheets of magnetic separation after fine grinding and the iron powder products with iron grade 79.58% and recovery 62.77% were obtained.

Experimental Study on a Low Grade Sulfide-Oxidized Mixed Copper-Iron Ore in Anhui

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.543-547.3785 ◽

2014 ◽

Vol 543-547 ◽

pp. 3785-3788

Author(s):

Zhi Guo Zhang ◽

Quan Jun Liu ◽

Hong Xiao ◽

Jin Cheng Ran

Keyword(s):

Experimental Study ◽

Copper Oxide ◽

Magnetic Separation ◽

Technological Process ◽

High Intensity ◽

Copper Sulfide ◽

Iron Ore ◽

Low Grade ◽

Flow Sheet ◽

The copper-iron ore has grades of 0.58% Cu and 42.14% Fe in Anhui. According to test on raw ore, it has the characteristics of close intergrowth and fine dissemination size, which belongs to a refractory ore. The copper oxide distributes mainly at the perimeter of copper sulfide. According to the characteristics of the structure, a flow sheet of rough grinding and flotation of inter-locked particles is taken. This process can recover copper effectively, leading to the recovery of Cu increase to 70.05%.A combined technological process of high intensity magnetic separation-gravity separation is used to hematite, which achieves an iron grade of 62.34% in the final concentrate and a recovery of 65.49%.

Concentration on Limonitic Iron Ore by Multi-Grade Magnetic Roasting-Low Intensity Magnetic Separation

10.4028/www.scientific.net/amr.933.125 ◽

2014 ◽

Vol 933 ◽

pp. 125-131 ◽

Cited By ~ 1

Author(s):

Han Quan Zhang

Keyword(s):

Magnetic Separation ◽

Iron Ore ◽

Volume Fraction ◽

Dynamic State ◽

Iron Recovery ◽

Remarkable Effect ◽

Oxidized Iron ◽

Atmosphere Temperature ◽

Iron Grade ◽

Magnetizing Roasting

Magnetizing roasting followed by magnetic separation is a compound technique for the beneficiation optimization of Huangmei refractory limonite. The natural limonite samples are obtained from Huangmei, Hubei province. The samples are characterized by TG-DTG-DSC. The content of major components is analyzed by SEM-XRAY, which is found that the sample iron mainly occurs in the form of limonite, with impurities including quartz, kaolinite, and barite. The feasibility of oxidized iron ore magnetic roasting limonite by multi-grade dynamic state magnetizing roasting is investigated. The effects of operation parameters such as roasting atmosphere, temperature and roasting duration are analyzed. The results show that: in the condition of the volume fraction of CO is 2% to 5%, the temperature is 700-780°C, and the roasting duration is 20 to 30 minutes. By multi-grade dynamic state magnetizing roasting, the grade of roasting limonite is nearly 33%, and the feasibility of separation is effective. A good index is created through simple mineral processing, the iron grade of concentrate reaches to 60% and the iron recovery rate reaches to 83.94%. It reveals that the multi-grade dynamic state magnetizing roasting device has a remarkable effect on roasting limonite.