Título

MULTIPHASE MODELING OF THE FLUIDYNAMICS OF BOTTOM ARGON BUBBLING DURING LADLE OPERATIONS

MULTIPHASE MODELING OF THE FLUIDYNAMICS OF BOTTOM ARGON BUBBLING DURING LADLE OPERATIONS1

Autoria

Llanos, Carlos. A.; Garcia-Hernandez, Saúl; Ramos-Banderas, J. Ángel; Barreto, José de J.; Solorio-Diaz, Gildardo

DOI

10.5151/2594-5300-16817

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Resumo

The objective of the present study is the optimization of the ladle stirring operation through a multiphase mathematical model and an analogue physical model. Four cases were considered using one and two argon injection inlets with different configuration, where the multiphase steel/slag/argon system was simulated numerically in Three-Dimensional Unsteady State conditions and a water/oil/air system for the physical model was considered. The Volume of Fluid (VOF) model was employed to simulate numerically the interaction among the phases considering the surface tensions. The simulation results were evaluated by a fluidynamics analysis of the systems and by a numerical prediction of three important operation parameters: mixing time, lining refractory wear and slag opening. The implementation of two argon inlets did not reduce the mixing time; however, the slag layer opening was decreased in a 30%, and the refractory wear in terms of the skin friction coefficient value was also decreased in a 63%. These results confirm that it is imperative to consider, for numerical simulation, the three phases present during ladle operations.

 

The objective of the present study is the optimization of the ladle stirring operation through a multiphase mathematical model and an analogue physical model. Four cases were considered using one and two argon injection inlets with different configuration, where the multiphase steel/slag/argon system was simulated numerically in Three-Dimensional Unsteady State conditions and a water/oil/air system for the physical model was considered. The Volume of Fluid (VOF) model was employed to simulate numerically the interaction among the phases considering the surface tensions. The simulation results were evaluated by a fluidynamics analysis of the systems and by a numerical prediction of three important operation parameters: mixing time, lining refractory wear and slag opening. The implementation of two argon inlets did not reduce the mixing time; however, the slag layer opening was decreased in a 30%, and the refractory wear in terms of the skin friction coefficient value was also decreased in a 63%. These results confirm that it is imperative to consider, for numerical simulation, the three phases present during ladle operations.

Palavras-chave

Ladle metallurgy; Multiphase systems; Physical modeling; Mathematical simulation.

Ladle metallurgy; Multiphase systems; Physical modeling; Mathematical simulation.