Continuous separation of Fe–Al–Zn dross phase from hot dip galvanised melt using alternating magnetic field

Dong, Anping; Shu, Da; Wang, J.; Cai, Xueling; Sun, Baode; Cui, Juan; Shen, J. G.; Ren, Y. S.; Yin, X. D.

doi:10.1179/174328407x248514

Cited by 18 publications

(3 citation statements)

References 9 publications

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“…The dissolution rate of iron will increase from 0.8 to 1.8 g/(m 2 •s) as the content of Al rises from 20 to 30 wt % and the dissolution rate of steel is 2.3 g/(m 2 •s) when the content of Al rises to 55 wt % [5]. Fe 2 Al 5 , τ 5 (Al 8 Fe 2 Si), and τ 6 (Al 5 FeSi) phases will be generated and form in the top, floating, and bottom dross in the high Al content condition, once the iron content exceeds its solubility in the zinc bath [6]. The floating dross in the molten bath mainly includes oxide such as zinc oxide and alumina.…”

Section: Introductionmentioning

confidence: 99%

The Evaluation on Corrosion Resistance and Dross Formation of Zn–23 wt % Al–0.3 wt % Si–x wt % Mg Alloy

Peng

Lü

et al. 2019

Coatings

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: A comparative study of the corrosive resistance and dross formation of 55Al–Zn–1.6Si (wt%) (55AZS) and 23Al–Zn–0.3Si–xMg (wt%) (23AZS–xMg, x = 0, 1.5, 3) alloys are performed using immersion corrosion and dross formation test, respectively. The result of immersion corrosion testing shows that corrosive rate of the 23AZS alloy is lower than that of 55AZS alloy in the latter stage of immersion and 23AZS–1.5Mg alloy shows the optimal corrosive resistance compared to other alloys relatively. The result of dross formation test shows that the number of bottom dross particle formed in 23AZS–xMg (x = 0, 1.5, 3) alloy is less than that in 55AZS alloy. Moreover, the thermodynamic calculation is performed to reveal the solubility of Fe in the alloys, the result shows the solubility of Fe reduces as a decrease of Al content in the alloy, and the number of dross particle (Fe4Al13 and 6 (Al9Fe2Si2) phase) generated in 23AZS alloy is more than that in 55AZS alloy. In general, 23AZS–1.5Mg alloy has an advantage of less dross and a certain corrosion resistance and it is expected to be applied for the hot stamping process of coating.

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Section: Introductionmentioning

confidence: 99%

The Evaluation on Corrosion Resistance and Dross Formation of Zn–23 wt % Al–0.3 wt % Si–x wt % Mg Alloy

Peng

Lü

et al. 2019

Coatings

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“…3(b)) due to the lower density of the dross particles than the alloy matrix. 12) As shown in Fig. 3(c), after super-gravity separation, the dross particles were intercepted by the filter and gathered in the residue.…”

Section: Resultsmentioning

confidence: 99%

Recovery of Zinc from Zn–Al–Fe Melt by Super-gravity Separation

et al. 2018

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The removal of iron-containing dross particles and recovery of zinc from galvanizing dross by super-gravity separation was investigated using a model Zn-Fe-Al alloy. After super-gravity separation, the high purity molten zinc went through the filter, while the residue mainly consisting of dross particles was intercepted by the filter and separated from the molten zinc. The effects of gravity coefficient and separating temperature on zinc recovery and iron removal were investigated. The preliminary results show the supergravity separation is a promising method of recovering zinc from galvanizing dross.

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“…[24] Studies to remove inclusions from molten aluminum, copper, zinc, and silicon using AC magnetic field have been well reported and attained satisfying results, such as the studies reported by El-kaddah and Taniguchi, [7,8,[25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40][41][42] as shown in Table II. However, there were very few studies on the purification of steel using high frequency EM separation. The possible reason for this lack is that the EM purification experiment for steel is difficult due to its high melting temperature compared to that of aluminum and copper.…”

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confidence: 97%

Separation of Non-metallic Inclusions from Molten Steel Using High Frequency Electromagnetic Fields

Wang

Zhang

Tian

et al. 2014

Metall Mater Trans B

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The current work is to investigate the removal of non-metallic inclusions from molten steel using electromagnetic separation under high frequency magnetic fields. A certain amount of aluminum nuggets were added to the molten steel to generate alumina inclusions in the current experiments. A layer of alumina clusters close to the wall of the crucible was observed. Models for the entrapment of inclusions by EM fields were developed, indicating that over 91 pct inclusions were captured within the skin depth (2.31 mm from the wall) and the calculation agreed well with the experimental observation. The fluid flow, solidification of the steel and the motion and entrapment of inclusions were studied by three-dimensional mathematical modeling. The separation mechanism of inclusions from molten steel by EM fields was discussed. Both the experiments and the simulation show that EM separation is a feasible and high-efficient method to remove inclusions from the molten steel.

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Continuous separation of Fe–Al–Zn dross phase from hot dip galvanised melt using alternating magnetic field

Cited by 18 publications

References 9 publications

The Evaluation on Corrosion Resistance and Dross Formation of Zn–23 wt % Al–0.3 wt % Si–x wt % Mg Alloy

The Evaluation on Corrosion Resistance and Dross Formation of Zn–23 wt % Al–0.3 wt % Si–x wt % Mg Alloy

Recovery of Zinc from Zn–Al–Fe Melt by Super-gravity Separation

Separation of Non-metallic Inclusions from Molten Steel Using High Frequency Electromagnetic Fields

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