Effect of Changes in Sulfur and Oxygen Concentration on Change in Nitrogen Concentration in Liquid Steel during CaO^|^ndash;CaSi Powder Blowing under Reduced Pressure

Numata, Mitsuhiro; Higuchi, Yoshihiko

doi:10.2355/isijinternational.52.2019

Cited by 6 publications

(2 citation statements)

References 24 publications

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“…Most studies of the hot metal powder desulfurization process have focused on top injection metallurgy technology [10][11][12][13][14][15], while the study of multiphase behavior in the process of ladle bottom powder injection with electric field is few. In addition, it is extremely hard or impossible to measure experimentally the particle trajectories in metallurgical systems, so mathematical simulation become an important method to understand this process [16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulation of Multiphase Flow Behavior in Hot Metal Ladle Desulfurization with Bottom Powder Injection and Electric Field

Feng

Liao

Liu

et al. 2019

Mathematical Problems in Engineering

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A computation fluid-coupled discrete phase model (CFD-DPM) was used to predict the motion characteristics of gas, particle, and liquid phases in the hot metal ladle. The influence of different voltage loading modes, voltage values, and powder injection speeds on the particle motion trail was investigated, while the effects on the particle concentration maximum difference in the stagnation region were discussed. The optimal injection and voltage parameters were proposed. The results are shown as follows: the loading voltage before injection is beneficial to the diffusion of particles in the molten pool. With the increase of voltage and injection speed, the distribution of particles in the upper part of the molten iron tends to be uniform. The bottom of the ladle is the stagnation region. Optimum voltage and injection speed were determined. Under the optimum conditions, particles are evenly dispersed and the particle concentration difference in the stagnation region is small. This research work will benefit greatly to the hot metal ladle desulfurization technology.

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Section: Introductionmentioning

confidence: 99%

Numerical Simulation of Multiphase Flow Behavior in Hot Metal Ladle Desulfurization with Bottom Powder Injection and Electric Field

Feng

Liao

Liu

et al. 2019

Mathematical Problems in Engineering

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“…Both of the authors reported an equation for estimation of the chemical reaction rate constant to quantify the speed of chemical reaction of nitrogen removal at the interface based on their experimental results and moreover, they found that the denitrogenation can be described as a reaction of second order that indicates that the reaction rate is proportional to the square of concentration. To account for the variation in the content of surface‐active element, Numata et al carried out extensive experiments by blowing calcium and aluminum compound flux powder to create a time‐dependent ambient of oxygen and sulfur content under reduced pressure. The results showed that the rate of nitrogen desorption increases as the contents of oxygen and sulfur in liquid steel decrease.…”

Section: Introductionmentioning

confidence: 99%

Modeling Study of Nitrogen Removal from the Vacuum Tank Degasser

Miettinen

Louhenkilpi

2014

steel research int.

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Low nitrogen content in liquid steel is required for most of the steelmaking companies, where vacuum degassing of liquid steel is usually carried out to remove nitrogen as well as other impurity elements during ladle treatment. This paper presents an integrated computational fluid dynamics (CFD) model for simulating the nitrogen removal in an industrial vacuum tank degasser (VTD). In the CFD model, oxygen and sulfur are considered as surface-active elements decreasing the denitrogenation rate at the gas-steel interface. An activity coefficient and a desulfurization sub-model are implemented to compute the effective activity coefficients of the related elements and the evolution of sulfur content in liquid steel during the process, respectively. The effect of various elements on denitrogenation rate in the VTD is studied with the developed model. For the used steel compositions the denitrogenation rate decreases with an increase in the content of [S] [Al]. The model is validated by comparing final nitrogen contents measured from the industrial plant with the ones predicted by the model and good agreements were found. The model has proven to be a useful and accurate tool for predicting final nitrogen content of liquid steel in the plant.

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Theoretical Analysis and Experiment of Liquid Metal Penetration into Slot Plug Applied for Refining Ladles

Cheng

Zhu

2014

Metall Mater Trans B

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Effect of Changes in Sulfur and Oxygen Concentration on Change in Nitrogen Concentration in Liquid Steel during CaO^|^ndash;CaSi Powder Blowing under Reduced Pressure

Cited by 6 publications

References 24 publications

Numerical Simulation of Multiphase Flow Behavior in Hot Metal Ladle Desulfurization with Bottom Powder Injection and Electric Field

Numerical Simulation of Multiphase Flow Behavior in Hot Metal Ladle Desulfurization with Bottom Powder Injection and Electric Field

Modeling Study of Nitrogen Removal from the Vacuum Tank Degasser

Theoretical Analysis and Experiment of Liquid Metal Penetration into Slot Plug Applied for Refining Ladles

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