Paper Titles

Interfacial Criteria for Producing Metal Matrix Composites and Ceramic Particle Stabilized Metallic Foams
p.419

Principal Outcomes of the EC Thematic Network on Modelling Tools for the Forging Industry
p.425

Variability of Diffusion Coefficients in the Analysis of Heterogeneous Welded Joints
p.431

Finite Element Simulation of Multi-Pass Equal Channel Angular Pressing
p.439

Modelling of Heat Transfer in Continuous Casting
p.445

The 'In Situ' Investigation of Solidification
p.455

Characterizing the Inner Structure of Continuously Cast Sections by Using a Heat Transfer Model
p.461

Topological Characterization of 2D Finite Cellular Systems
p.471

Numerical Simulation of Dendrite Arm Coarsening in the Case of Ternary Al Alloys
p.483

HomeMaterials Science ForumMaterials Science Forum Vols. 414-415Modelling of Heat Transfer in Continuous Casting

Modelling of Heat Transfer in Continuous Casting

Article Preview

Abstract:

You might also be interested in these eBooks

Materials Science, Testing and Informatics I

Info:

Periodical:

Materials Science Forum (Volumes 414-415)

Pages:

445-454

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.414-415.445

Citation:

Cite this paper

Online since:

January 2003

Authors:

Seppo Louhenkilpi

Keywords:

Continuous Casting, Heat Transfer, Material Property, Modeling

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2003 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

[1] A. Chatterjee, S. Chattopadhyay, R. Dutta, and P.K. Mukhopadhyay: Heat transfer during solidification of continuously cast slabs - mathematical modelling work at Tata Steel. In Proc. 10th Process Technology Conference- Second Internal Symposium on Modeling in the Iron and Steel Industry, Toronto, Ontario, Canada, 1992, April 5-8, pp.325-331.

[2] K. Thompson and M. Wolf: The Concast heat transfer model. A proven tool for optimized slab caster design and operation. Concast Technol. News. Vol. 27 (1988), p.6.

[3] M. Bamberger and B. Prinz: Mathematical modeling of the temperature field in continuous casting. Z. Metall. Vol. 77 (1986), No. 4, pp.234-38.

[4] P.J. Flint: A three-dimensional finite difference model of heat transfer, fluid flow and solidification in the continuous slab caster. In. Proc. of 9th Process Technology, 73rd Steelmaking Conf., Detroit, MI, 1990.

[5] M.R. Aboutalebi, M. Hasan, R.I.L. Guthrie: Thermal modelling and stress analysis in the continuous casting of arbitrary sections. Steel Research. Vol. 65 (1994), No. 6, pp.225-33.

DOI: 10.1002/srin.199401062

[6] C.R. Swaminathan and V.R. Voller: A general enthalpy method for modeling solidification processes. Metall. Trans B. Vol. 23B (1992), October, pp.651-64.

[7] G. Funk, J. Böhmer, F. Fett and R. Hentrich: Coupled thermal and stress-strain models for the continuous casting of steels. Steel Research. Vol. 64 (1993), No. 5, pp.246-54.

DOI: 10.1002/srin.199301017

[8] S.K. Choudhary, D. Mazumdar and A. Ghosh: Mathematical modelling of heat transfer phenomena in continuous casting of steel. ISIJ Int. Vol. 33 (1993), No. 7, pp.764-74.

DOI: 10.2355/isijinternational.33.764

[9] S. Barozzi, P. Fontana and P. Pragliola: Computer control and optimization of secondary cooling during continuous casting. Iron and Steel Engineer. Vol. 63 (1986), November, pp.21-26.

[10] K.-H. Spitzer, K. Harste, B. Weber, P. Monheim and K. Schwerdtfeger: Mathematical model for thermal tracking and on-line control in continuous casting. ISIJ International. Vol. 32 (1992), No. 7, pp.848-56

DOI: 10.2355/isijinternational.32.848

[11] S. Louhenkilpi: Simulation and Control of Heat Transfer in Continuous Casting of Steel, Doctoral Thesis, Helsinki University of Technology, Finland, 1995.

[12] H. Kytönen, M. Tolvanen, S. Louhenkilpi, L. Holappa: Experimental and numerical determination of crater end in continuous casting of steel, Modelling of Welding, Casting and Advanced Solidification Processes VIII, San Diego, June 7-12, 1998, pp.631-638.

[13] J. Miettinen, H. Kytönen, S. Louhenkilpi, L. Holappa: IDS, TEMPSIMU, CASIM - Three Windows Applications for Continuous Casting of Steels, 12th IAS Steelmaking Seminar, Novenber 2-5, 1999, Buenos Aires.

[14] S. Louhenkilpi, E. Laitinen, R. Nieminen: Real-Time Simulation of Heat Transfer in Continuous Casting. Met. Trans. B. Vol. 24B (1993), August, pp.685-693.

DOI: 10.1007/bf02673184

[15] S. Louhenkilpi: Study of Heat Transfer in a Continuous Billet Casting Machine. Scand. J. Metallurgy. Vol. 23 (1994), pp.9-17.

[16] S. Louhenkilpi, R. Nieminen, M. Rekkilä: TEMPSIMU- Heat transfer model for continuous casting, User manual, Windows version 1.5, Laboratory of Metallurgy, Helsinki University of Technology and Department of Mathematics, Jyväskylä University (1997).

[17] S. Wang, S. Louhenkilpi, M. Päätalo, L. Holappa: Free Surface Flow Simulation of Steel in Continuous Casting Moulds, 6th Japan-Nordic Countries Joint Symposium, Nov. 29-30, 2000, Nagoya, Japan.

[18] J. Miettinen, S. Louhenkilpi, J. Laine: IDS - Solidification analysis package, User manual, Windows version 1.3.1, Internal Report, Laboratory of Metallurgy, Helsinki University of Technology, Espoo (1997).

[19] J. Miettinen, S. Louhenkilpi: Calculation of Thermophysical Properties of Carbon and Low Alloyed Steels for Modeling of Solidification Processes. Met. Trans. B. Vol. 25B (1994), December, pp.909-916.

DOI: 10.1007/bf02662773

[20] J. Miettinen: Calculation of Solidification-Related Thermophysical Properties for Steels, Met. Trans. B. Vol. 28B (1997), April, pp.281-297.