Electromagnetic Forces in Continuous Casting of Steel Slabs

This paper reviews the current state of the art in the application of electromagnetic forces to control fluid flow to improve quality in continuous casting of steel slabs. Many product defects are controlled by flow-related phenomena in the mold region, such as slag entrapment due to excessive surfa...

Full description

Bibliographic Details
Main Authors: Seong-Mook Cho, Brian G. Thomas
Format: Article
Language:English
Published: MDPI AG 2019-04-01
Series:Metals
Subjects:
Online Access:https://www.mdpi.com/2075-4701/9/4/471
id doaj-4f676a18a2f445ad89114a33d76caae6
record_format Article
spelling doaj-4f676a18a2f445ad89114a33d76caae62020-11-24T20:47:30ZengMDPI AGMetals2075-47012019-04-019447110.3390/met9040471met9040471Electromagnetic Forces in Continuous Casting of Steel SlabsSeong-Mook Cho0Brian G. Thomas1Department of Mechanical Engineering, Colorado School of Mines, 1610 Illinois Street, Golden, CO 80401, USADepartment of Mechanical Engineering, Colorado School of Mines, 1610 Illinois Street, Golden, CO 80401, USAThis paper reviews the current state of the art in the application of electromagnetic forces to control fluid flow to improve quality in continuous casting of steel slabs. Many product defects are controlled by flow-related phenomena in the mold region, such as slag entrapment due to excessive surface velocity and level fluctuations, meniscus hook defects due to insufficient transport of flow and superheat to the meniscus region, and particle entrapment into the solidification front, which depends on transverse flow across the dendritic interface. Fluid flow also affects heat transfer, solidification, and solute transport, which greatly affect grain structure and internal quality of final steel products. Various electromagnetic systems can affect flow, including static magnetic fields and traveling fields which actively accelerate, slow down, or stir the flow in the mold or strand regions. Optimal electromagnetic effects to control flow depends greatly on the caster geometry and other operating conditions. Previous works on how to operate electromagnetic systems to reduce defects are discussed based on results from plant experiments, validated computational models, and lab scale model experiments.https://www.mdpi.com/2075-4701/9/4/471magnetohydrodynamicsfluid flowbubblesinclusionsentrapmententrainmentheat transfersolidificationslab moldcontinuous casting
collection DOAJ
language English
format Article
sources DOAJ
author Seong-Mook Cho
Brian G. Thomas
spellingShingle Seong-Mook Cho
Brian G. Thomas
Electromagnetic Forces in Continuous Casting of Steel Slabs
Metals
magnetohydrodynamics
fluid flow
bubbles
inclusions
entrapment
entrainment
heat transfer
solidification
slab mold
continuous casting
author_facet Seong-Mook Cho
Brian G. Thomas
author_sort Seong-Mook Cho
title Electromagnetic Forces in Continuous Casting of Steel Slabs
title_short Electromagnetic Forces in Continuous Casting of Steel Slabs
title_full Electromagnetic Forces in Continuous Casting of Steel Slabs
title_fullStr Electromagnetic Forces in Continuous Casting of Steel Slabs
title_full_unstemmed Electromagnetic Forces in Continuous Casting of Steel Slabs
title_sort electromagnetic forces in continuous casting of steel slabs
publisher MDPI AG
series Metals
issn 2075-4701
publishDate 2019-04-01
description This paper reviews the current state of the art in the application of electromagnetic forces to control fluid flow to improve quality in continuous casting of steel slabs. Many product defects are controlled by flow-related phenomena in the mold region, such as slag entrapment due to excessive surface velocity and level fluctuations, meniscus hook defects due to insufficient transport of flow and superheat to the meniscus region, and particle entrapment into the solidification front, which depends on transverse flow across the dendritic interface. Fluid flow also affects heat transfer, solidification, and solute transport, which greatly affect grain structure and internal quality of final steel products. Various electromagnetic systems can affect flow, including static magnetic fields and traveling fields which actively accelerate, slow down, or stir the flow in the mold or strand regions. Optimal electromagnetic effects to control flow depends greatly on the caster geometry and other operating conditions. Previous works on how to operate electromagnetic systems to reduce defects are discussed based on results from plant experiments, validated computational models, and lab scale model experiments.
topic magnetohydrodynamics
fluid flow
bubbles
inclusions
entrapment
entrainment
heat transfer
solidification
slab mold
continuous casting
url https://www.mdpi.com/2075-4701/9/4/471
work_keys_str_mv AT seongmookcho electromagneticforcesincontinuouscastingofsteelslabs
AT briangthomas electromagneticforcesincontinuouscastingofsteelslabs
_version_ 1716809823908003840