Numerical Modeling of Liquid–Liquid Mass Transfer and the Influence of Mixing in Gas-Stirred Ladles

Hoang, Quynh N.; Ramírez-Argáez, Marco A.; Conejo, Alberto N.; Blanpain, Bart; Dutta, Abhishek

doi:10.1007/s11837-018-3056-0

Cited by 23 publications

(16 citation statements)

References 40 publications

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“…Nevertheless, the rising bubbles form a turbulent bubble plume, and the resulting slag eye causes the reoxidation of liquid steel. Intense interactions occur between the slag and molten steel because the overlying slag is pushed to the side . It is widely known that the bubble size and its motion affect momentum, heat, and mass transfer in gas–liquid bubble flow .…”

Section: Introductionmentioning

confidence: 99%

Physical Modeling Evaluation on Refining Effects of Ladle with Different Purging Plug Designs

Tan

Jin

et al. 2020

steel research int.

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Circular slits are introduced in purging plugs for alleviating the stress concentration to prolong their service life. Herein, the effects of slits with different geometries on the mixing time, inclusion removal rate, and slag eye area are studied by water model method. Experimental results show that the inclusion removal rate decreases with increasing slit angle for the gas flow rate of less than 6.02 NL min À1 . Moreover, with slit diameter increases, the mixing time and inclusion removal rate decrease when a gas flow rate is less than 5.26 NL min À1 . The slag eye area increases with increasing slit diameter, and the slit angle has a positive influence on the formation of the slag eye. Finally, the optimization of the mixing time and inclusion removal rate for less consumption of stirring energy and less slag entrapment indicates that the smaller the slag eye area is, the better the refining effect is.

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Section: Introductionmentioning

confidence: 99%

Physical Modeling Evaluation on Refining Effects of Ladle with Different Purging Plug Designs

Tan

Jin

et al. 2020

steel research int.

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“…Mixing time is a parameter that measures the mixing efficiency of the primary phase (liquid steel) in a bath. Mathematically, it is defined as the time at which there is a chemical homogeneity of 95% in the steel [5]. Mixing time helps to quantify the degree of agitation needed to homogenize the liquid contents after a step change in the composition inside a ladle.…”

Section: Introductionmentioning

confidence: 99%

Numerical Modeling of Equal and Differentiated Gas Injection in Ladles: Effect on Mixing Time and Slag Eye

et al. 2020

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Ladle refining plays a crucial role in the steelmaking process, in which a gas stream is bubbled through molten steel to improve the rate of removal of impurities and enhance the transport phenomena that occur in a metallurgical reactor. In this study, the effect of dual gas injection using equal (50%:50%) and differentiated (75%:25%) flows was studied through numerical modeling, using computational fluid dynamics (CFD). The effect of gas flow rate and slag thickness on mixing time and slag eye area were studied numerically and compared with the physical model. The numerical model agrees with the physical model, showing that for optimal performance the ladle must be operated using differentiated flows. Although the numerical model can predict well the hydrodynamic behavior (velocity and turbulent kinetic energy) of the ladle, there is a deviation from the experimental mixing time when using both equal and differentiated gas injection at a high gas flow rate and a high slag thickness. This is probably due to the insufficient capture of the velocity field near the water–oil (steel–slag) interface and slag emulsification by the numerical model, as well as the complicated nature of correctly simulating the interaction between both gas plumes.

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“…Therefore, if mixing time is of interest, a dynamic treatment for the free surface is required. Recently, Hoang et al [15] studied mixing time in ladle to observe its influence on mass transfer. They observed that mixing is accomplished in a much shorter time than interphase mass transfer, specifically by two orders of magnitude, which indicated that mass transfer is the rate-limiting step.…”

Section: Introductionmentioning

confidence: 99%

A Novel Multiphase Methodology Simulating Three Phase Flows in a Steel Ladle

et al. 2019

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Mixing phenomena in metallurgical steel ladles by bottom gas injection involves three phases namely, liquid molten steel, liquid slag and gaseous argon. In order to numerically solve this three-phase fluid flow system, a new approach is proposed which considers the physical nature of the gas being a dispersed phase in the liquid, while the two liquids namely, molten steel and slag are continuous phases initially separated by a sharp interface. The model was developed with the combination of two algorithms namely, IPSA (inter phase slip algorithm) where the gas bubbles are given a Eulerian approach since are considered as an interpenetrating phase in the two liquids and VOF (volume of fluid) in which the liquid is divided into two separate liquids but depending on the physical properties of each liquid they are assigned a mass fraction of each liquid. This implies that both the liquid phases (steel and slag) and the gas phase (argon) were solved for the mass balance. The Navier–Stokes conservation equations and the gas-phase turbulence in the liquid phases were solved in combination with the standard k-ε turbulence model. The mathematical model was successfully validated against flow patterns obtained experimentally using particle image velocimetry (PIV) and by the calculation of the area of the slag eye formed in a 1/17th water–oil physical model. The model was applied to an industrial ladle to describe in detail the turbulent flow structure of the multiphase system.

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Numerical Modeling of Liquid–Liquid Mass Transfer and the Influence of Mixing in Gas-Stirred Ladles

Cited by 23 publications

References 40 publications

Physical Modeling Evaluation on Refining Effects of Ladle with Different Purging Plug Designs

Physical Modeling Evaluation on Refining Effects of Ladle with Different Purging Plug Designs

Numerical Modeling of Equal and Differentiated Gas Injection in Ladles: Effect on Mixing Time and Slag Eye

A Novel Multiphase Methodology Simulating Three Phase Flows in a Steel Ladle

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