Journals →  CIS Iron and Steel Review →  2020 →  #1 →  Back

Rolling and Metal Forming
ArticleName Variations of the rheological properties of steel in the plate rolling process conditions
DOI 10.17580/cisisr.2020.01.08
ArticleAuthor A. Kawałek, H. Dyja, K. V. Ozhmegov
ArticleAuthorData

Czestochowa University of Technology, Institute of Metal Forming and Safety Engineering (Czestochowa, Poland):

A. Kawaek, Prof, Dr. hab., Eng., Head of the Department of Plastic Working and Safety Engineering, E-mail: kawalek.anna@wip.pcz.pl
K. V. Ozhmegov, Dr. Eng.

 

Metal Forming Institute (Poznan, Poland):

H. Dyja, Prof, Dr. hab., Eng.

Abstract

The article presents the results of investigation into of the rheological properties of steel S355J2+N, while considering the influence of deformation, temperature and strain rate. Tests were carried out using a metallurgical process simulator Gleeble 3800. Based on the plastometric tests, stress–strain diagrams for the steel were developed and the coefficients of the flow stress function were selected. The obtained rheological testing results were used in computer simulations of the asymmetric plate rolling in the 3600 Plate Rolling Mill.

keywords Plastometric tests, rheological properties, steel S355J2 + N, stress–strain diagrams, computer simulations, asymmetric rolling process.
References

1. Nikolaev V. A., Vasilyev A. A. Strip bending and other parameters of asymmetric rolling. Stal. 2013. No. 7. pp. 42–49.
2. Aboutorabi A., Assempour A., Afrasiab H. Analytical approach for calculating the sheet output curvature in asymmetrical rolling: In the case of roll axis displacement as a new asymmetry factor. International journal of mechanical sciences. 2016. Vol. 105. pp. 11–22.
3. Kawalek A., Dyja H., Markowski J. Effect of asymmetrical rolling on broadening of the product line of rolled sheets. Metalurgija. 2003. Vol. 42, Issue 3. pp. 207–211.
4. Yan Tao, Qin Na, Zhao Shuo, et al. Deformation analysis of asymmetric break-down rolli ng of hollow steel. World journal of engineering. 2017. Vol. 14. Issue 6. Pp. 483–488.
5. Tian Yong, Guo Yan-hui, Wang Zhao-dong et al. Analysis of Rolling Pressure in Asymmetrical Rolling Process by Slab Method. Journal of iron and steel research international. 2009. Vol. 16. Issue 4. pp. 22–30.
6. Kawalek A. The theoretical and experimental analysis of the effect of asymmetrical rolling on the value of unit pressure. Journal of materials processing technology. 2004. Vol. 157. pp. 531–535.
7. Dyja H., Gakin A., Knapiski M. Reologia metali odksztacanych plastycznie. Wydawnictwo Politechniki Czstochowskiej. 2010. p. 371.
8. Tsay K., Arbuz, A., Gusseynov N., Nemkaeva R et al. Refinement of the microstructure of steel by cross rolling. Journal of chemical technology and metallurgy. 2016. Vol. 51. Iss. 4. pp. 385–392.
9. Kern A., Walter P., Pfeiffer E., Tscherish H.-J. Complex for flat steel production in China. Chernye metally. 2017. No. 6. pp. 51–57.
10. Shkatov V. V., Mazur I. P., Knapinski M., Chetverikova T. S. Simulation of dynamic recrystallization and resistance to deformation of carbon and low-alloyed steels during hot forming. Chernye metally. 2018. No. 11. pp. 22–27.
11. Knapinski M., Dyja H., et al. Physical Simulations of the Controlled Rolling Process of Plate X100 with Accelerated Cooling. Solid State Phenomena. 2013. Vol. 199. pp. 484–489.
12. Chukin M. V., Pesin I. A. Development of machine parts production processes for a plate mill. Chernye metally. 2018. No. 12. pp. 6–9.
13. Gryc A., Bajor T., Dyja H., et al. Physical modelling of plastic deformation conditions for the rolling process of az31 bars in a three high skew rolling mill. Metalurgija. 2014. Vol. 53, Iss. 4. pp. 489–492.
14. Bajor T., Krakowiak M., Szota P. Numerical analysis of az61 magnesium alloy extrusion process by modified equal channel angular extrusion (ecae) method. Metalurgija. 2014. Vol. 53, Iss. 4. pp. 485–488.

Full content Variations of the rheological properties of steel in the plate rolling process conditions
Back