Analysis of Strip Temperature in Hot Rolling Process by Finite Element Method

The program was developed by finite element method to calculate the temperature distribution in hot strip rolling process. The heat transfer coefficients of air cooling, water cooling and thermal resistance between work roll and strip were analyzed, A new heat generation rate model was proposed acco...

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Veröffentlicht in:	Journal of iron and steel research, international international, 2010-02, Vol.17 (2), p.17-21
Hauptverfasser:	MEI, Rui-bin, LI, Chang-sheng, LIU, Xiang-hua, HAN, Bin
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied and Technical Physics Engineering Finite element method Hot rolling Induction heating Iron and steel industry Machines Manufacturing Materials Engineering Materials Science Mathematical analysis Mathematical models Metallic Materials Physical Chemistry Processes skin depth Strip Surface temperature temperature distribution 感应加热有限元方法有限元法温度分布温度过程热轧带钢表面温度
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container_title	Journal of iron and steel research, international
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creator	MEI, Rui-bin LI, Chang-sheng LIU, Xiang-hua HAN, Bin
description	The program was developed by finite element method to calculate the temperature distribution in hot strip rolling process. The heat transfer coefficients of air cooling, water cooling and thermal resistance between work roll and strip were analyzed, A new heat generation rate model was proposed according to the influence of source current density, work frequency, air gap and distance to edge on induction heating by finite element method （FEM）. The heat generation rate was considered in the thermal analysis to predict the temperature distribution in the induction heating. The influence of induction heating on the strip temperature was investigated for different slab thicknesses. The temperature difference became more and more obvious with the increase of thickness. The strip could be heated quickly by the induction heating both in surface and center because of the thermal conductivity and skin effect. The heat loss of radiation has important influence on the surface temperature. The surface temperature could be heated quickly by high frequency when the strip is thicker.
doi_str_mv	10.1016/S1006-706X(10)60052-0
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Iron Steel Res. Int</addtitle><addtitle>Journal of Iron and Steel Research</addtitle><description>The program was developed by finite element method to calculate the temperature distribution in hot strip rolling process. The heat transfer coefficients of air cooling, water cooling and thermal resistance between work roll and strip were analyzed, A new heat generation rate model was proposed according to the influence of source current density, work frequency, air gap and distance to edge on induction heating by finite element method （FEM）. The heat generation rate was considered in the thermal analysis to predict the temperature distribution in the induction heating. The influence of induction heating on the strip temperature was investigated for different slab thicknesses. The temperature difference became more and more obvious with the increase of thickness. The strip could be heated quickly by the induction heating both in surface and center because of the thermal conductivity and skin effect. The heat loss of radiation has important influence on the surface temperature. 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subjects	Applied and Technical Physics Engineering Finite element method Hot rolling Induction heating Iron and steel industry Machines Manufacturing Materials Engineering Materials Science Mathematical analysis Mathematical models Metallic Materials Physical Chemistry Processes skin depth Strip Surface temperature temperature distribution 感应加热有限元方法有限元法温度分布温度过程热轧带钢表面温度
title	Analysis of Strip Temperature in Hot Rolling Process by Finite Element Method
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