Investigation of Flow Characteristics in a Six‐Strand CC Tundish Combining Plant Measurements, Physical and Mathematical Modeling

The tundish plays a major role in the continuous casting process. The flow in a tundish has a very substantial effect on the quality of the final product and on efficient casting conditions. Efforts are being made worldwide to obtain the most favourable shape of tundish interior by using dams, weirs and gas curtains. The aim of these flow control devices is to reduce the dead zone areas and improve the conditions for the separation of non-metallicinclusions. Numerousmodelstudiesare being carried outto explainthe effect of the tundishworking spaceshapeand steel flowconditions on the inclusionsfloating processes. The presented article shows the results of investigations performed to obtain the mass exchange characteristics in the investigated tundish. The measurements were done directly at the steel plant during normal working conditions. By controlling the changing content of manganese in steel, the residence time distribution (RTD) characteristics were acquired. The RTD characteristics are also obtained with a water model of the tundish with dimensional scale of 1:3. Parallel to the water model, numerical simulation based on mathematical modelling of fluid flow, relying on the system of differential equations, is employed in the research work. Numerical simulations were carried out with the finite-volume commercial code FLUENTusing the standard k-e turbulence model. The primary purpose of the investigations carried out is to present the characteristics describing the transitory zone in a six-strand tundish. It is shown that the F-curve, describing the transitory zone, can be obtained by using different measurement techniques. Tracer concentration characteristicsfor the model of tundish obtained from both modelling techniques - physical as well as numerical - are very similar.

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