Numerical and Experimental Investigation of a Modified Twin Roll Strip Casting Process for the Production of Clad Steel Strips

Michele Vidoni; Markus Daamen; Gerhard Hirt

doi:10.4028/www.scientific.net/KEM.651-653.689

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HomeKey Engineering MaterialsKey Engineering Materials Vols. 651-653Numerical and Experimental Investigation of a...

Numerical and Experimental Investigation of a Modified Twin Roll Strip Casting Process for the Production of Clad Steel Strips

Abstract:

A process for the production of clad steel strips by means of vertical twin-roll strip casting is under investigation at the Institute of Metal Forming (IBF). This production concept is based on the introduction of a solid strip in the casting pool in order to join it with the solidifying melt. The advantages of this concept are a shorter process chain and a higher energy efficiency compared to the existing cladding methods. The contact time and the thickness ratio between solid strip and solidifying melt, their relative position and the alloy combination are fundamental parameters to be considered in the design of this cladding process. A numerical model is used to predict the temperature increase in the solid strip and the solidification of the melt for the material combinations 1.4301/C75 and C75/Cu, and for two process configurations. Carbon steel and copper strips were introduced in the melting pool during casting experiments. Both carbon steel and copper strips could be clad without melting when positioned on the casting roll surface. This indicates that the surface temperature of the copper strip did not rise over 1084°C. Both the copper and the carbon steel strips show partial melting when introduced in a central position.

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Periodical:

Key Engineering Materials (Volumes 651-653)

Pages:

689-694

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.651-653.689

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Online since:

July 2015

Authors:

Michele Vidoni*, Markus Daamen, Gerhard Hirt

Keywords:

Clad Strip, New Processes, Numerical Simulation, Twin-Roll Strip Casting

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* - Corresponding Author

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