Prediction of the wear profile of a roll groove in rod rolling using an incremental form of wear model

Abstract

A model for predicting the wear profile of the ductile cast iron roll during rod (or bar) rolling is proposed using Archard's wear equation. Archard's wear equation was reformulated as an incremental form and the hardness of the roll was expressed as a function of rolling time under a high temperature. The wear profile of the roll is calculated at each deformation step by consideration of relative sliding velocity and normal roll pressure at contact area. The coefficients required in the proposed wear model have been obtained using the high-temperature wear tester of pin-on-disc type.

A three-dimensional finite element analysis coupled with the proposed wear model has been carried out for the oval-round pass rolling sequence widely used in present continuous rod (or bar) rolling mills. To describe the deformation behaviour of material at the roll/material interface better, a contact-searching algorithm that can be applied efficiently to the finite element mesh was also suggested.

The results showed that, for an oval groove, the maximum wear occurs at the centre part of the roll and, for a round groove, at the shoulder area of the roll. The wear profiles moves to the spread direction of workpiece (i.e. roll axis direction) as well as the direction of roll centre as the production (tonnage) increases. The proposed wear model might be used for adjusting the gap (pass height) of rolls to set up a suitable rolling schedule for keeping dimensional tolerance of the product and avoid catastrophic failure of rolls after rolling a characteristic tonnage.

Keywords

wear profile thermal softening hot rod (or bar) rolling finite element analysis ductile cast iron (DCI) roll round pass oval pass

References

Holm

Electric Contacts, 1946, p. 203 (Almqvist and Wiksells, Stockholm).

Archard

J. F.

Contacts and rubbing of flat surface. J. Appl. Phys., 1953, 24, 981.

Liou

M. J.

Hasio

H. S.

Prediction of die wear in high speed hot upset forging. ERC/NSDM Report 99-33, OSU, 1989.

Hansen

P. H.

Bay

P. H.

A flexible computer based system for prediction of wear distribution in forming rolls. Advd Technol. Plasticity, 1990, 1, 19–26.

Kim

T. H.

Kim

B. M.

Choi

J. C.

Prediction of die wear in the wire drawing process. J. Mater. Processing Technol., 1997, 65, 11–17.

Sachs

Roll wear in finishing trains of hot strip mills. Iron Steel Engr, 1961, 38, 71–92.

Williams

R. V.

Boxall

G. M.

Roll surface deterioration in hot strip mills. J. Iron Steel Inst., April 1965, 369–377.

Ohnuki

Wear and deterioration of rolling roll and procedure of anti-wear. J. Japan Soc. Lubric. Engng, 1987, 32, 621–626.

Lundberg

S. E.

A new high-temperature test rig for optimization of materials for hot-rolling rolls. J. Mater. Processing Technol., 1993, 36, 273–301.

10.

Park

J. W.

Lee

H. C.

Lee

Composition, micro-structure, hardness, and wear properties of high-speed steel rolls. Metall. Mater. Trans. A, 1999, 30, 399–409.

11.

Tronel

Chenot

J. L.

Prediction of tool wear using finite element software for the three-dimensional simulation of the hot-forging process. J. Mater. Processing Technol., 1992, 31, 255–263.

12.

Minami

Saiki

Effect of surface hardening by nitriding on thermal softening and deterioration of dies in warm and hot forging. Advd Technol. Plasticity, 1996, 389–392.

13.

Altan

S. H.

Gegel

H. L.

Metal Forming: Fundamentals and Forming, 1983 (American Society for Metals, Metals Park, Ohio).

14.

Shida

Empirical formula of flow-stress of carbon steels—resistance to deformation of carbon steels. J. JSTP, 1969, 10(103), 610–617.

15.

Lee

Choi

Kim

Y. H.

Mathematical model and experimental validation of surface profile of a workplace in round-oval-round pass sequence. J. Mater. Processing Technol., 2000, 81, 87–96.