论文信息 - Clogging resistant submerged entry nozzle design through mathematical modelling

Clogging resistant submerged entry nozzle design through mathematical modelling

Abstract Submerged entry nozzle (SEN) clogging is caused by deposition of solid microinclusions present in the liquid steel and aided by stagnation and swirling velocity regimes near the bottom wall. A mathematical model has been developed to investigate steel flow within the SEN and the results obtained with k–ϵ and Reynolds stress model (RSM) turbulence models have been compared. The existing flat SEN bottom causes stagnation of the steel flow within the nozzle and the absence of shear stress prevents the removal of inclusions. The jet from the port is narrow and focused and has two high turbulent swirls near the walls. As a remedy, a parabolic curve shaped bottom has been designed to guide the liquid steel flow and has resulted in a better flow profile and exit jet characteristics. Stagnation is absent and the jet characteristics have improved with the average jet turbulence being reduced by 33%. The study on the sufficiency of the shear stress magnitudes to remove clogging has shown that the curve bottom performs better compared with the flat bottom. The effect of casting speed variation has also been studied on these two bottom configurations. The preliminary plant trials show encouraging results.

R. Sambasivam

[1] Brian G. Thomas,et al. Turbulent flow through bifurcated nozzles , 1993 .

[2] Hua Bai,et al. Turbulent flow of liquid steel and argon bubbles in slide-gate tundish nozzles: Part II. Effect of operation conditions and nozzle design , 2001 .

[3] Tetsuya Fujii,et al. Numerical analysis of fluid flow in the continuous casting mold by a bubble dispersion model , 1991 .

[4] Brian G. Thomas,et al. Simulation of Argon Gas Flow Effects in a Continuous Slab Caster , 1994 .

[5] W. White,et al. The oxide handbook , 1983 .

[6] Masaki Nitta,et al. FILTRATION MECHANISM OF NON-METALLIC INCLUSIONS IN STEEL BY CERAMIC LOOP FILTER , 1992 .

[7] G. Bergeles,et al. Three-dimensional modeling of the flow and the interface surface in a continuous casting mold model , 1999 .

[8] D. Gupta,et al. Water modelling study of the jet characteristics in a continuous casting mould , 1992 .

[9] Brian G. Thomas,et al. Numerical study of steady turbulent flow through bifurcated nozzles in continuous casting , 1995 .

[10] Hua Bai,et al. Turbulent flow of liquid steel and argon bubbles in slide-gate tundish nozzles: Part I. model development and validation , 2001 .