Influence of process parameters of dry high intensity magnetic separators on separation of hematite

Tripathy, Sunil Kumar; Singh, Veerendra; Murthy, Y. Rama; Banerjee, P. K.; Suresh, N.

doi:10.1016/j.minpro.2017.01.007

Cited by 61 publications

(18 citation statements)

References 21 publications

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“…The saturation magnetization (Ms) of copper ore tailings, roasted slag (1,200°C for 30 min, airflow 5 L min −1 ), and magnetic concentrate at above optimum conditions were studied in VSM, and the results are shown in Figure 12. It was obvious that Ms of copper ore tailings increases from 4.85 to 11.55 emu/g after magnetizing roasting, which indicated that the magnetic properties may vary more or less under different roasting conditions [30]. Moreover, the maximum Ms of the magnetic concentrate was 12.94 emu/g.…”

Section: Magnetic Propertymentioning

confidence: 95%

Recovery of γ-Fe₂O₃ from copper ore tailings by magnetization roasting and magnetic separation

2021

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To comprehensively reuse copper ore tailings, the recovery of γ-Fe2O3 from magnetic roasted slag after sulfur release from copper ore tailings followed by magnetic separation is performed. In this work, after analysis of chemical composition and mineralogical phase composition, the effects of parameters in both magnetization roasting and magnetic separation process with respect to roasting temperature, residence time, airflow, particle size distribution, magnetic field intensity, and the ratio of sodium dodecyl sulfonate to roasted slag were investigated. Under optimum parameters, a great number of γ-Fe2O3 is recycled with a grade of 66.86% and a yield rate of 67.21%. Meanwhile, the microstructure, phase transformation and magnetic property of copper ore tailings, roasted slag, and magnetic concentrate are carried out.

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Section: Magnetic Propertymentioning

confidence: 95%

Recovery of γ-Fe₂O₃ from copper ore tailings by magnetization roasting and magnetic separation

2021

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“…Besides the redox activity and surface charge properties (Abdel Maksoud et al 2020 ), low-cost synthesis and non-toxicity (Leone et al 2018 ), high selectivity (Song et al 2018 ; Asadi et al 2020 ; Nisola et al 2020 ; Wang et al 2020c , 2021 ; He et al 2021 ; Luan et al 2021 ), binding specificity (Vishnu and Dhandapani 2021 ), and excellent reusability (D’Cruz et al 2020 ; Hu et al 2020 ; Li et al 2020 ; Ahmad et al 2020b ; Vu and Wu 2020 ; Wang et al 2020c ; Nkinahamira et al 2020 ; Tabatabaiee Bafrooee et al 2021 ), a key feature of magnetic nanoadsorbents is that they can be separated in situ from adsorption-remediated waters in the form of a magnetic nanoadsorbent(s)–adsorbate(s) sludge by applying a strong enough magnetic field (Ambashta and Sillanpää 2010 ; Zaidi et al 2014 ; Simeonidis et al 2015 ; Moharramzadeh and Baghdadi 2016 ; Wanna et al 2016 ; Tripathy et al 2017 ; Mirshahghassemi et al 2017 ; Yeap et al 2017 ; Augusto et al 2019 ; Kheshti et al 2019a ; Mashile et al 2020 ; Brião et al 2020 ; Balbino et al 2020 ).…”

Section: Magnetic Nanoadsorbentsmentioning

confidence: 99%

Magnetic nanoadsorbents for micropollutant removal in real water treatment: a review

Mudhoo

Sillanpää

2021

Environ Chem Lett

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Pure water will become a golden resource in the context of the rising pollution, climate change and the recycling economy, calling for advanced purification methods such as the use of nanostructured adsorbents. However, coming up with an ideal nanoadsorbent for micropollutant removal is a real challenge because nanoadsorbents, which demonstrate very good performances at laboratory scale, do not necessarily have suitable properties in in full-scale water purification and wastewater treatment systems. Here, magnetic nanoadsorbents appear promising because they can be easily separated from the slurry phase into a denser sludge phase by applying a magnetic field. Yet, there are only few examples of large-scale use of magnetic adsorbents for water purification and wastewater treatment. Here, we review magnetic nanoadsorbents for the removal of micropollutants, and we explain the integration of magnetic separation in the existing treatment plants. We found that the use of magnetic nanoadsorbents is an effective option in water treatment, but lacks maturity in full-scale water treatment facilities. The concentrations of magnetic nanoadsorbents in final effluents can be controlled by using magnetic separation, thus minimizing the ecotoxicicological impact. Academia and the water industry should better collaborate to integrate magnetic separation in full-scale water purification and wastewater treatment plants.

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“…Several researchers opted to apply the dry high intensity magnetic separation aiming to enrich low-grade iron ores [4,[8][9][10][11][12][13][14]16]. The results obtained by this method are satisfactory where a maximum product grade of 53.1% FeTotal is achievable with 19% yield as the magnetic product in lift roll magnetic separator (LRMS) at optimum conditions of variables.…”

Section: Introductionmentioning

confidence: 99%

“…The results obtained by this method are satisfactory where a maximum product grade of 53.1% FeTotal is achievable with 19% yield as the magnetic product in lift roll magnetic separator (LRMS) at optimum conditions of variables. Rare earth roll magnetic separator (RERMS) is also found to be efficient with a higher yield of 36.8% in the magnetic product grade of 49.5% FeTotal [9]. Further, magnetic separation studies of low-grade iron ore were carried out by using LRMS and found that a product of maximum of 51.2% FeTotal can be obtained from the low-grade ore assaying 35.9% FeTotal [17].…”

Section: Introductionmentioning

confidence: 99%

Application of dry high-intensity magnetic separation in upgrading low-grade iron ore of Rouina deposit, Algeria

Messai¹,

Idres²,

Menéndez-Aguado³

2020

J Min & Metal A Mining

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The recent developments of steel and iron industries generated a huge consumption of iron ores which has attracted much attention for utilizing low-grade iron resources to satisfy this increasing demand. The present study focuses on the characterization and enrichment of the low-grade iron ores from Rouina deposit-Ain Defla-. Currently, the ore is used in the cement industry because it is considered a low-grade iron ore. After the sampling process, a physico-chemical and mineralogical characterization was carried out and the results revealed that the sample consists of hematite, limonite and goethite as major opaque oxide minerals whereas silicates as well as clays form the gangue minerals in the sample. The average grade of FeTotal, SiO2 and Al2O3 contents in the raw material collected from the mine of the case study are 30.85%, 23.12% and 7.77% respectively. Processes involving combination of classification, washing and dry high-intensity magnetic separation were carried out to upgrade the low-grade iron ore sample to make it suitable as a marketable product. The sample was first ground and each closed size sieve fractions were subjected to washing followed by drying than dry high intensity magnetic separation and it was observed that limited upgradation is possible. As a result, it was possible to obtain a magnetic concentrate of 54.09% with a recovery degree of 89.30% and yield of 62.82% using a magnetic field intensity equal to 2.4 Tesla at the size fraction [-0.125 +0.063 mm].

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Influence of process parameters of dry high intensity magnetic separators on separation of hematite

Cited by 61 publications

References 21 publications

Recovery of γ-Fe₂O₃ from copper ore tailings by magnetization roasting and magnetic separation

Recovery of γ-Fe₂O₃ from copper ore tailings by magnetization roasting and magnetic separation

Magnetic nanoadsorbents for micropollutant removal in real water treatment: a review

Application of dry high-intensity magnetic separation in upgrading low-grade iron ore of Rouina deposit, Algeria

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Influence of process parameters of dry high intensity magnetic separators on separation of hematite

Cited by 61 publications

References 21 publications

Recovery of γ-Fe2O3 from copper ore tailings by magnetization roasting and magnetic separation

Recovery of γ-Fe2O3 from copper ore tailings by magnetization roasting and magnetic separation

Magnetic nanoadsorbents for micropollutant removal in real water treatment: a review

Application of dry high-intensity magnetic separation in upgrading low-grade iron ore of Rouina deposit, Algeria

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Recovery of γ-Fe₂O₃ from copper ore tailings by magnetization roasting and magnetic separation

Recovery of γ-Fe₂O₃ from copper ore tailings by magnetization roasting and magnetic separation