Influence of Different Asymmetric Rolling Processes on Shear Strain
Authors: A. Pesin, D. Pustovoytov, M. Sverdlik
Abstract:
Materials with ultrafine-grained structure and unique physical and mechanical properties can be obtained by methods of severe plastic deformation, which include processes of asymmetric rolling (AR). Asymmetric rolling is a very effective way to create ultrafine-grained structures of metals and alloys. Since the asymmetric rolling is a continuous process, it has great potential for industrial production of ultrafine-grained structure sheets. Basic principles of asymmetric rolling are described in detail in scientific literature. In this work finite element modeling of asymmetric rolling and metal forming processes in multiroll gauge was performed. Parameters of the processes which allow achieving significant values of shear strain were defined. The results of the study will be useful for the research of the evolution of ultra-fine metal structure in asymmetric rolling.
Keywords: Asymmetric rolling, equivalent strain, FEM, multiroll gauge, profile, severe plastic deformation, shear strain, sheet.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1092878
Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2721References:
[1] Y.H. Ji, J.J. Park. Development of severe plastic deformation by various asymmetric rolling processes // Materials Science and Engineering: A, Vol. 499, Issues 1-2, 2009, P. 14-17
[2] Pesin А.М. Modeling and development of the processes of asymmetric deformation to improve sheet rolling: thesis. Magnitogorsk, 2003. 395 p.
[3] Li Y.H., Park J.J., Kim W.J. Finite element analysis of severe deformation in Mg–3Al–1Zn sheets through differential-speed rolling with a high speed ratio. Mater. Sci. Eng. Vol. A, 2007. P.454-455
[4] Pesin A.M., Salganik V.M., Pustovoitov D.O, Dyja H. Asymmetric rolling: Theory and Technology / HUTNIK-WIADOMOSCI HUTNICZE. 2012. No 5. P. 358-363.
[5] Zhiming Li, Liming Fu, Bin Fu, Aidang Shan. Effects of annealing on microstructure and mechanical properties of nano-grained titanium produced by combination of asymmetric and symmetric rolling // Materials Science and Engineering: A, Vol. 558, 2012, P. 309-318
[6] Jianhua Jiang, Yi Ding, Fangqing Zuo, Aidang Shan. Mechanical properties and microstructures of ultrafine-grained pure aluminum by asymmetric rolling // Scripta Materialia, Vol. 60, Issue 10, 2009, P. 905-908
[7] Sverdlik M., Pesin A., Pustovoytov D. Theoretical basis and technology development of the combined process of asymmetric rolling and plastic bending // Advanced Materials Research. 2012. Т. 586. С. 259-264.
[8] Pesin A.M. Scientific school of asymmetric rolling in Magnitogorsk // Вестник Магнитогорского государственного технического университета им. Г.И. Носова. 2013. №5 (45). С. 23-28.
[9] Pesin A., Salganik V., Trahtengertz E., Drigun E. Development of the asymmetric rolling theory and technology / Proceedings of the 8-th International Conference on Metal Forming. Krakow / Poland / 3-7 September 2000. Metal Forming 2000. P. 311-314.
[10] Dyja H., Salganik W.M., Piesin A.M., Kawalek A. Asymetryczne walcowanie blach cienkich: teoria, technologia I nowe rozwiazania. Seria monografie, nr 137. – Czestochowa: 2008, 345 p.
[11] Sverdlik M., Pesin A., Pustovoytov D., Perekhozhikh A. Numerical research of shear strain in an extreme case of asymmetric rolling // Advanced Materials Research. 2013. Т. 742. С. 476-481.
[12] Zuo F., Jiang J., Shan A. Shear deformation and grain refinement in pure Al by asymmetric rolling // Transactions of Nonferrous Metals Society of China. Vol. 18, Issue 4, 2008, P. 774-777
[13] Cui Q, Ohori K. Grain refinement of high purity aluminum by asymmetric rolling. Materials Science and Technology, 2000, 16, P.1095-1101.