Analysis of three-dimensional vortexes below the free surface in a continuous casting mold

Cesar A. Real-Ramirez; Jesus I. Gonzalez-Trejo

doi:10.1007/s12613-011-0453-6

International Journal of Minerals, Metallurgy, and Materials ›› 2011, Vol. 18 ›› Issue (4) : 397 -407. DOI: 10.1007/s12613-011-0453-6

Article

Analysis of three-dimensional vortexes below the free surface in a continuous casting mold

Cesar A. Real-Ramirez ¹^,^a
, Jesus I. Gonzalez-Trejo ¹

Author information +

History +

PDF

Abstract

To study fluctuations of the free surface of liquid steel in the mold, two different models with the same casting conditions but different thicknesses were employed to analyze the hydrodynamic behavior at the top of the mold. The first model was a standard thickness slab, and the second had a thickness three times wider. It is found with the second model that above the plane formed by the steel jets, it is possible to observe four three-dimensional vortexes that interact with the submerged entry nozzle (SEN) and mold walls. By using a biphasic model to simulate the interface between the liquid and air inside the mold, the flow asymmetry and the fluctuations of the free surface can be clearly observed.

Keywords

continuous casting / molds / flow patterns / three dimensional vortes / mathematical models / computer simulation

Cite this article

Download citation ▾

Cesar A. Real-Ramirez, Jesus I. Gonzalez-Trejo. Analysis of three-dimensional vortexes below the free surface in a continuous casting mold. International Journal of Minerals, Metallurgy, and Materials, 2011, 18(4): 397-407 DOI:10.1007/s12613-011-0453-6

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Real C., Miranda R., Vilchis C., et al. Transient internal flow characterization of a bifurcated submerged entry nozzle. ISIJ Int., 2006, 46, 1183.

[2]	Zhao B., Thomas B.G., Vanka S.P., et al. Transient fluid flow and superheat transport in continuous casting of steel slabs. Metall. Mater. Trans. B, 2005, 36(6): 801.

[3]	Ramos-Banderas A., Morales R.D., Sánchez-Pérez R., et al. Dynamics of two-phase downwards flows in submerged entry nozzles and its influence on the two-phase flow in the mold. Int. J. Multiphase Flow, 2005, 31(5): 643.

[4]	Sengupta J., Thomas B.G., Shin H.J., et al. A new mechanism of hook formation during continuous casting of ultra-low-carbon steel slabs. Metall. Mater. Trans. A, 2006, 37(5): 1597.

[5]	Mazumdar S., Ray S. K. Solidification control in continuous casting of steel. Sadhana, 2001, 26(1–2): 179.

[6]	Real-Ramirez C. Submerged Entry Nozzle Geometry Influence on the Oscillations Generation in the Liquid Surface in a Continuous Casting Mold: Numerical and Experimental Analysis [Dissertation], 2008 Mexico, Universidad Autónoma Metropolitana Unidad Azcapotzalco, 125.

[7]	Badri A., Natarajan T.T., Snyder C.C., et al. A mold simulator for the continuous casting of steel: Part I. the development of a simulator. Metall. Mater. Trans. B, 2005, 36(3): 355.

[8]	Zhang L.F., Yang S.B., Cai K.K., et al. Investigation of fluid flow and steel cleanliness in the continuous casting strand. Metall. Mater. Trans. B, 2007, 38(1): 63.

[9]	J. Alexander, C. Real-Ramirez, M. Palomar-Pardave, et al., Influence of the submerged entry nozzle geometry on the heat transfer inside the continuous casting mold, [in] TMS 2009 Annual Meeting and Exhibition, San Francisco, 2009, p.591.

[10]	C. Real, L. Hoyos, F. Cervantes, et al., Sensitivity analysis of the three dimensional flow dynamics in the continuous casting submerged entry nozzle, [in] Proceeding of the XVI Congreso Sobre Métodos Numéricos y sus Aplicaciones, Córdoba, 2007, p.302.

[11]	Zhang L.F., Aoki J., Thomas B.G. Inclusion removal by bubble flotation in a continuous casting mold. Metall. Mater. Trans. B, 2006, 37(3): 361.

[12]	Sengupta J., Thomas B.G., Wells M.A. The use of water cooling during the continuous casting of steel and aluminum alloys. Metall. Mater. Trans. A, 2005, 36(1): 187.

[13]	Zhang L.F., Wang Y.F., Zuo X.J. Flow transport and inclusion motion in steel continuous-casting mold under submerged entry nozzle clogging condition. Metall. Mater. Trans. B, 2008, 39(4): 534.

[14]	Jeon Y.J., Sung H.J., Lee S. Flow oscillations and meniscus fluctuations in a funnel-type water mold model. Metall. Mater. Trans. B, 2010, 41(1): 121.

[15]	Torres-Alonso E., Morales R.D., Demedices L.G., et al. Flow dynamics in thin slab molds driven by sustainable oscillating jets from the feeding SEN. ISIJ Int., 2007, 47(5): 679.

[16]	Kamal M., Sahai Y. A simple innovation in continuous casting mold technology for fluid flow and surface standing waves control. ISIJ Int., 2006, 46(12): 1823.

[17]	Li B.K., Tsukihashi F. Effects of electromagnetic brake on vortex flows in thin slab continuous casting mold. ISIJ Int., 2006, 46, 1833.

[18]	Ramos-Banderas A., Sánchez-Pérez R., Morales R.D., et al. Mathematical simulation and physical modeling of unsteady fluid flows in a water model of a slab mold. Metall. Mater. Trans. B, 2004, 35(3): 449.

[19]	Lemanowicz I., Gorissen R., Odenthal H.J., et al. Validation of CFD-calculations for the submerged entry nozzle-mould system using the digital particle image velocimetry. Stahl Eisen, 2000, 120(9): 85.

[20]	Nakiboglu G., Gorlé C., Horváth I., et al. Stack gas dispersion measurements with large scale-PIV, aspiration probes and light scattering techniques and comparison with CFD. Atmos. Environ., 2009, 43(21): 3396.

[21]	Kantoush S.A., Schleiss A.J. Large-scale piv surface flow measurements in shallow basins with different geometries. J. Vis., 2009, 12(4): 361.

[22]	Weitbrecht V., Kühn G., Jirka G.H. Large scale PIVmeasurements at the surface of shallow water flows. Flow Meas. Instrum., 2002, 13(5–6): 237.

[23]	Launder B.E. Comments on “Improved form of low reynolds-number κ ≈ ɛ turbulence model“. Phys. Fluids, 1976, 19(5): 765.

[24]	Ng K.H., Spalding D.B. Predictions of two-dimensional boundary layers on smooth walls with a two-equation model of turbulence. Int. J. Heat Mass Transfer, 1976, 19(10): 1161.

[25]	Ansys Inc., ANSYS FLUENT 12.0 Theory Guide, 2009.

[26]	Evans J.W., Xu D., Jones W.K.Jr. Physical and mathematical modeling of metal flow in the continuous casting of steel and aluminum. Met. Mater. Int., 1998, 4(6): 1111.

[27]	Chaudhary R., Lee G.G., Thomas B.G., et al. Transient mold fluid flow with well- and mountain-bottom nozzles in continuous casting of steel. Metall. Mater. Trans. B, 2008, 39(6): 870.

[28]	Zhang X.G., Zhang W.X., Jin J.Z., et al. Flow of steel in mold region during continuous casting. J. Iron Steel Res. Int., 2007, 14(2): 30.

[29]	Ha M.Y., Lee H.G., Seong S.H. Numerical simulation of three-dimensional flow, heat transfer, and solidification of steel in continuous casting mold with electromagnetic brake. J. Mater. Process. Technol., 2003, 133(3): 322.

[30]	Li B., Tsukihashi F. Vortexing flow patterns in a water model of slab continuous casting mold. ISIJ Int., 2005, 45(1): 30.

[31]	Thomas B.G., Yuan Q., Sivaramakrishnan S., et al. Comparison of four methods to evaluate fluid velocities in a continuous slab casting mold. ISIJ Int., 2001, 41(10): 1262.