Turbulent flow dynamics, heat transfer and mass exchange in the melt of induction furnaces-Reference-Cited by-同舟云学术

Turbulent flow dynamics, heat transfer and mass exchange in the melt of induction furnaces

Published:2003-03-01 Issue:1 Volume:22 Page:39-47
ISSN:0332-1649
Container-title:COMPEL - The international journal for computation and mathematics in electrical and electronic engineering
language:en
Short-container-title:

Author:

Baake E.,Nacke B.,Umbrashko A.,Jakovics A.

Abstract

Experimental investigations of the turbulent flow velocities measured in the melt of experimental induction furnaces show, that beside the intensive local turbulence pulsations, macroscopic low‐frequency oscillations of the recirculated toroidal main flow eddies play an important role in the heat and mass exchange processes. Traditional numerical calculations of the flow and transfer processes, based on wide spread commercial codes using various modifications of the k‐ε turbulence model show that these models do not take into account the low‐frequency oscillations of the melt flow and the calculated temperature and concentration distributions in the melt essentially differs from experimental results. Therefore, the melt flow dynamics in an induction crucible furnace was numerically simulated with help of transient three‐dimensional calculations using the large eddy simulation turbulence model. This leads to a good agreement between calculated and measured periods of low‐frequency oscillations and heat and mass transfer between the toroidal flow eddies.

Publisher

Emerald

Subject

Applied Mathematics,Electrical and Electronic Engineering,Computational Theory and Mathematics,Computer Science Applications

Reference7 articles.

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2. Baake, E., Mühlbauer, A. and Nacke, B. (1999), Heat and mass transfer in the turbulent melt flow of the crucible inductor furnace, International Colloquium on Modeling of Material Processing, Riga, Latvia, pp. 98‐103.

3. Baake, E., Mühlbauer, A., Jakovitsch, A. and Andree, W. (1994), “Extension of the k‐ε model for the numerical simulation of the melt flow in induction crucible furnaces”, Metallurgical and Material Transactions, Vol. 26B, pp. 529–35.

4. Baake, E., Nacke, B., Jakovics, A. and Umbrashko, A. (2000), Heat and mass transfer in turbulent flows with several recirculated flow eddies, Fourth International PAMIR Conference, Presquile de Giens, France, pp. 71‐6.

5. Bojarevics, V., Pericleous, K. and Cross, M. (2000), Modeling turbulent flow dynamics in AC magnetic field, The 3rd International Symposium on Electromagnetic Processing of Materials, Nagoya, Japan, pp. 85‐90.

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