Numerical Simulation of Electromagnetic Field in a Round Bloom Continuous Casting Mould with Eccentric Electromagnetic Stirring

doi:10.12068/j.issn.1005-3026.2016.06.013

Journal of Northeastern University Natural Science ›› 2016, Vol. 37 ›› Issue (6): 820-824.DOI: 10.12068/j.issn.1005-3026.2016.06.013

• Materials & Metallurgy • Previous Articles Next Articles

Numerical Simulation of Electromagnetic Field in a Round Bloom Continuous Casting Mould with Eccentric Electromagnetic Stirring

REN Bing-zhi¹， CHEN Deng-fu¹， WANG Hong-dan^{1, 2}， QI Rui³

1. College of Materials Science and Engineering， Chongqing University， Chongqing 400044， China; 2. School of Metallurgy and Material Engineering， Chongqing University of Science and Technology， Chongqing 401331， China; 3. Department of Continuous Casting， CISDI Engineering Co.， Ltd.， Chongqing 400013， China.

Received:2014-10-27 Revised:2014-10-27 Online:2016-06-15 Published:2016-06-08
Contact: CHEN Deng-fu
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Abstract

Abstract: A three-dimensional mathematical model was developed to study the electromagnetic field in a round bloom continuous casting mould with electromagnetic stirring (M-EMS). The simulation results of electromagnetic field were validated by the measured data from the experiments. The effects of stirring current intensity and frequency on magnetic flux density and electromagnetic force were investigated， and the electromagnetic field characteristics were also discussed after applying eccentric M-EMS. The results show that both magnetic flux density and electromagnetic force increase with increasing current intensity. When the stirring current frequency increases， the magnetic flux density decreases and the electromagnetic force increases first and then decreases with the maxima at 2.5Hz. Under the conditions of eccentric M-EMS， the electromagnetic force still appears to be circumferential distribution on the planes transverse to the strand. However， the magnitudes of both magnetic flux density and electromagnetic force show asymmetrical distribution， which are much larger at the side near the external arc of the continuous caster.

Key words: continuous casting, electromagnetic stirring, round bloom, eccentric stirring, electromagnetic field

CLC Number:

TF777

REN Bing-zhi， CHEN Deng-fu， WANG Hong-dan ， QI Rui. Numerical Simulation of Electromagnetic Field in a Round Bloom Continuous Casting Mould with Eccentric Electromagnetic Stirring[J]. Journal of Northeastern University Natural Science, 2016, 37(6): 820-824.

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Numerical Simulation of Electromagnetic Field in a Round Bloom Continuous Casting Mould with Eccentric Electromagnetic Stirring

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