Authors: Z. Y. Jiang, H. B. Tibar, A. Aljabri

Abstract:

Optimisation of the physical and mechanical properties of cold rolled thin strips is achieved by controlling the rolling parameters. In this paper, the factors affecting the asymmetrical cold rolling of thin low carbon steel strip have been studied at a speed ratio of 1.1 without lubricant applied. The effect of rolling parameters on the resulting microstructure was also investigated. It was found that under dry condition, work roll shifting and work roll cross angle can improve the strip profile, and the result is more significant with an increase of work roll cross angle rather than that of work roll shifting. However, there was no obvious change in microstructure. In addition, effects of rolling parameters on strip profile and microstructure have also been discussed.

Keywords: Reduction ratio, rolling speed ratio, strip shape, work rolls cross angle, work roll shifting.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1339097

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1299

References:

[1] Groover, M.P., Fundamentals of Modern Manufacturing Material, Process and systems. 2nd ed. 2002, New York: John Wiley & Sons.
[2] Roberts, W.L., Cold Rolling of Steel. 1978, New York: Marcel Decker. 19.
[3] Rawsthorne, D., Mechanics of Thin Strip Rolling. 2007, University of Wollongong.
[4] Jiang, Z., D. Wei, and A. Tieu, Analysis of cold rolling of ultra thin strip. Journal of Materials Processing Technology, 2009. 209(9): p. 4584-4589.
[5] Jiang, Z. Y., Zhu, H. T., Tieu, A.K. and Sun, W.H., Modelling of work roll edge contact in thin strip rolling. Journal of materials processing technology, 2004. 155: p. 1280-1285.
[6] Jiang, Z.Y., Tieu, A. K., Zhang, X.M., Lu, C. and Sun, W.H., Finite element simulation of cold rolling of thin strip. Journal of Materials Processing Technology, 2003. 140: pp. 542-547.
[7] Montmitonnet, P., Massoni, E., Vacance, M., Sola, G. and Gratacos, P., Modelling for geometrical control in cold and hot rolling, Ironmaking & Steelmaking 1993. 20: pp. 254-60.
[8] Jiang, Z.Y., Jiang, Z., Tieu, A. K. and Wei, D., An approach to analyse the special rolling of thin strip. Journal of Material Processing Technology, 2006. 177: pp. 130-133.
[9] Guo, R.M., Optimal profile and shape control of flat sheet metal using multiple control devices. IEEE Transactions on Industry Applications 1996. 32 (2): pp. 449 – 457.
[10] Morita, Z. and Toshihiko, An introduction to iron and steel processing. The Foundation, 1997.
[11] Dieter, G.E., Mechanical Metallurgy. 1988, McGraw-Hill Publishing, New York.
[12] Malik, A.S. and Grandhi, R.V., A computational method to predict strip profile in rolling mills. Journal of materials processing technology, 2008. 206(1): p. 263-274.
[13] Robert, W. L., Strip Shape: Its measurement and control" in cold rolling steel. Marcel Dekker: New York, 1978.
[14] Jiang, Z.Y, Xiong, S. W., Tieu, A. K. and Wang, Q. J., Modelling of the effect of friction on cold strip rolling. Journal of Materials Processing Technology, 2008. 201(1): p. 85-90.
[15] McConnell, C. and J. Lenard, Friction in cold rolling of a low carbon steel with lubricants. Journal of Materials Processing Technology, 2000. 99(1): p. 86-93.
[16] Jiang, Z.Y., Du, X. Z., Du, Y. B., Wei, D.B. and Hay, M, Strip shape analysis of asymmetrical cold rolling of thin strip. Advanced Material Research, 2010. 97-101: pp. 81-84.
[17] Ginzburg, V.B., High-Quality Steel Rolling: Theory and Practice. 1993, New York: Marcel Dekker Inc.
[18] Nakanishi, T., T. Sugiyama, Y. Lida and T. Hashimoto, Application of work roll shift mill (HCWmill) to hot strip and plate. Hitachi review, 1985. 34(4): p. 153-160.