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Abstract

In twin-roll casting, as heat is transferred from melt to rolls, the melt is cooled, solidified and finally rolled to a specific thickness. Therefore, an efficient cooling system for the roll is very important for a stable operation of the process. In the present study, a composite roll with internal cooling channels was designed for twin-roll casting of magnesium alloy AZ31 by considering steady-state heat transfer between objects. The roll consisting of a steel core and a copper alloy sleeve was proposed to be assembled by thermal-shrinkage fitting. The fitting strength was examined by a series of stress analyses at stages of assembly as well as operation. The number of cooling channels and their cross sections were modified accordingly.

Keywords

Twin-roll casting roll cooling thermal shrinkage Mg-AZ31

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References

Sanders

Jr . Continuous casting for aluminum sheet: a product perspective. JOM 2012; 64: 291–301.

Liang

Cowley

. The twin-roll strip casting of magnesium. JOM 2004; 56: 26–28.

Das

Barekar

Fakir

. Effect of melt conditioning on heat treatment and mechanical properties of AZ31 alloy strips produced by twin roll casting. Mat Sci Eng A 2015; 620: 223–232.

U. S. Patent. Roll cooling structure for twin roll continuous caster. Patent Number 5,887,644, 30 March 1999.

Japan Patent. Cooling roll for twin roll type strip continuous casting. Publication number 05-253649, 5 October 1993.

Japan Patent. Device for controlling roll shape in twin roll type continuous caster. Publication number 05-285607, 2 November 1993.

Japan Patent. Cooling roll in metal strip continuous casting apparatus. Publication number 06-297108, 25 October 1994.

Park

Kang

Park

. Optimal design of strip casting roll. Trans KSME A 2002; 26: 2466–2473.

Hugenschutt

Kolbeck

Wobker

. Copper shells for twin roll casting. Proc Light Metal 2006; 2006: 859–863.

10.

Spathis

Tsiros

Arvanitis

. The use of copper shells by twin roll strip casters. Proc Light Metal 2010; 2010: 747–751.

11.

Badowski

Garate

Armendariz

. Influence of the cooling water temperature on productivity and product quality in twin roll casting with copper shells. Proc Light Metal 2010; 2010: 741–756.

12.

Takuda

Hatta

Fujimoto

. Thermal calculation in twin-roll thin strip casting of high-silicon steel. J Jpn Soc Technol Plast 1991; 32: 222–227.

13.

Tavares

Guthrie

RIL

. Computational fluid dynamics applied to twin-roll casting. Can Metall Quart 1998; 37: 241–250.

14.

Guthrie

RIL

Tavares

. Mathematical and physical modeling of steel flow and solidification in twin-roll/horizontal belt thin-strip casting machines. Appl Math Model 1998; 22: 851–872.

15.

Santos

Spim

Jr Garcia

. Modeling of solidification in twin-roll casting. J Mat Process Tech 2000; 102: 33–39.

16.

Cruchaga

Celentano

Lewis

. Modelling of twin-roll strip casting processes. Commun Numer Meth En 2003; 19: 623–635.

17.

Bae

Kang

. Mathematical model for the twin roll type strip continuous casting of magnesium alloy considering thermal flow phenomena. J Mat Process Tech 2007; 191: 251–255.

18.

Zeng

Koitzsch

Pfeifer

. Numerical simulation of the twin-roll casting process of magnesium alloy strip. J Mat Process Tech 2009; 209: 2321–2328.

19.

Zhang

Jiang

Wei

. Study on casting roll during twin-roll casting of thin strip. Mat Sci Forum 2010; 654–656: 1602–1605.

20.

Park

. 2-D mathematical analysis of vertical twin-roll casting for magnesium alloys. Proc MAG-2012 2012; 2012: 1027–1030.

Design of a composite roll for twin-roll casting of Mg-AZ31

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