Coupled Numerical Simulation on Heat, Flow and Solution Transport in Double-Stream-Pouring Continuous Casting

Wei Wen Zhang; Hai Dong Zhao; Ji Xiang Gao; Yuan Yuan Li

doi:10.4028/www.scientific.net/MSF.575-578.121

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Numerical Simulation on the Dendritic Spacing and Microporosity in A356 Alloy Ingot
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Coupled Numerical Simulation on Heat, Flow and Solution Transport in Double-Stream-Pouring Continuous Casting
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The Simulation of Thermal Field in Induction Melting with Cold-Crucible and Dual Frequencies
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Control of Liquid Level in Tundish of Strip Caster with Automatic Pouring System
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HomeMaterials Science ForumMaterials Science Forum Vols. 575-578Coupled Numerical Simulation on Heat, Flow and...

Coupled Numerical Simulation on Heat, Flow and Solution Transport in Double-Stream-Pouring Continuous Casting

Abstract:

Double-stream-pouring continuous casting (DSPCC) is a novel technique to prepare gradient composites. In this paper, a two-dimensional steady mathematical model coupled flow, heat and solution transport in the solidification zone of DSPCC has been established based on the standard k-ε turbulent model. The variation of thermo-physical properties of the alloys against the temperature is also considered. The effects of casting speed on the temperature field, velocity field and composition of the researched composite are analyzed based on the proposed mathematical model. An experimental 2024/3003 aluminum composite was prepared by using a laboratory-made DSPCC facility. Selected results of experiment are in a good agreement with that of numerical simulation.