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Magnetic Damping of Liquid Steel Flows in Horizontal Single Belt Casting (HSBC)

A preliminary computational fluid flow model has been developed to simulate the magnetic braking of liquid steel on a water-cooled, rapidly moving, horizontal belt. The liquid steel issuing from the proposed vertical slot-nozzle should ideally move isokinetically with the belt during freezing. In th...

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Published in:	Journal for Manufacturing Science and Production 2015-03, Vol.15 (1), p.141-149
Main Authors:	Mahdi Aboutalebi, M., Isac, Mihaiela, Guthrie, Roderick I. L.
Format:	Article
Language:	English
Subjects:	Analysis Casting Collaboration Energy consumption Flow control horizontal single belt caster [HSBC] Laboratories Magnetic fields magnetic flow control Mathematical models metal delivery system Metals modeling Steel Steel production Studies Turbulent flow vertical slot-nozzle
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container_title	Journal for Manufacturing Science and Production
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creator	Mahdi Aboutalebi, M. Isac, Mihaiela Guthrie, Roderick I. L.
description	A preliminary computational fluid flow model has been developed to simulate the magnetic braking of liquid steel on a water-cooled, rapidly moving, horizontal belt. The liquid steel issuing from the proposed vertical slot-nozzle should ideally move isokinetically with the belt during freezing. In this study, ANSYS Fluent 14.5 software was used to model the 3-D turbulent flow of liquid steel. A 288 core High Performance Computer cluster located at the McGill Metals Processing Centre was used for high-speed computation. The standard model was used to simulate the turbulence. Similarly, the magnetic induction method was used to calculate the induced heterogeneous magnetic field, from which the current density and electromagnetic forces produced were computed. The behavior of the proposed magnetic flow control was first validated against previous experimental work and was then applied to predict the performance of the proposed slot nozzle. The predicted results show that by applying a DC Magnetic brake to the proposed metal delivery system, near isokinetic conditions can be rapidly established.
doi_str_mv	10.1515/jmsp-2014-0051
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subjects	Analysis Casting Collaboration Energy consumption Flow control horizontal single belt caster [HSBC] Laboratories Magnetic fields magnetic flow control Mathematical models metal delivery system Metals modeling Steel Steel production Studies Turbulent flow vertical slot-nozzle
title	Magnetic Damping of Liquid Steel Flows in Horizontal Single Belt Casting (HSBC)
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