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Purpose: The high-temperature plastic deformation is coupled with dynamic processes of recovery influencing the structure and properties of alloys. One of crucial issues is finding the interdependence between the hot plastic deformation process parameters, the structure and properties. Design/methodology/approach: Hot plastic deformation was carried out using a torsion plastometer in the temperature range of 900-1150°C at a strain rate of 0.04-4 s-1. The plastometric investigations enabled the determination of the influence of deformation parameters on technological plasticity. Investigations of the samples’ structures were carried out using a light and electron microscope, by a thin film method. A quantitative analysis of structural changes was performed using the „MetIlo” image analysis programme. Findings: Results of the investigations have been provided referring to the influence of the hot plastic deformation process on the microstructure and the substructure as well as technological plasticity of steels of an austenitic, ferritic and ferritic-austenitic structure. Mathematical models were developed which link the deformation process parameters to the grain size obtained after the deformation as well as the mechanical properties determined in a torsion test. Practical implications: The research carried out enabled the understanding of the phenomena taking place during deformation and annealing of the investigated alloy. The results will constitute the basis for modelling the structural changes. Originality/value: The results obtained are vital for designing an effective thermo - mechanical processing technology for the investigated steels.
Wydawca
Rocznik
Tom
Strony
154--161
Opis fizyczny
Bibliogr. 18 poz., rys., tabl.
Twórcy
autor
autor
- Faculty of Materials Science and Metallurgy, Silesian University of Technology, ul. Krasińskiego 8, 40-019, Katowice, Poland, dariusz.kuc@polsl.pl
Bibliografia
- [1] J. M. Cabrera, A. Mateo, L. Llanes, J.M. Prado, M. Anglada, Hot deformation of duplex stainless steels, Journal of Materials Processing Technology 143-144 (2003) 321-325.
- [2] S. Choi, Y. Lee, P.D. Hodgson, Feasibility study of partial recrystalliation in multi-pass hot deformation process and application to calculation of mean flow stress, Journal of Materials Processing Technology 125-126 (2002) 63-71.
- [3] R. D. Doherty, D.A. Hughes, Current issues in recrystallization, Materials Science and Engineering A 238 (1997) 219-274.
- [4] D. C. J. Farrugia, Prediction and avoidance of high temperature damage in long product hot rolling, Journal of Materials Processing Technology 177 (2006) 486-492.
- [5] M. Hetmańczyk, G. Niewielski, D. Kuc, Modelling of the structure changes during soaking to plastic deformation, Proceedings of the 8th Scientific International Conference „Achievements in Mechanical and Materials Engineering” AMME’1999, Gliwice-Rydzyna, 1999, 249-252.
- [6] A. Itman Filho, J.M.D.A. Rollo, R.V. Silva, G. Martinez, Alternative process to manufacture austenitic-ferritic stainless steel wires, Materials Letters 59 (2005) 1192-1194.
- [7] D. Kuc, G. Niewielski, E. Hadasik, K. Radwański, Structure and mechanical properties of hot deformed ferritic steel, Archives of Civil and Mechanical Engineering 3 (2004) 85-92.
- [8] D Kuc, G. Niewielski, K. Radawaski, The structure and plasticity changes in stainless steels after hot-deformation processes, Proceedings of the 11th International Scientific Conference “Contemporary Achievements in Mechanics, Manufacturing and Materials Science” CAM3S’2005, Gliwice - Zakopane, 2005 (CD-ROM).
- [9] H. J. McQueen, S. Yue, N. D. Ryan, E. Fry, Hot working characteristics of steels in austenitic state, Journal of Materials Processing Technology 53 (1995) 293-310.
- [10] G. Niewielski, D. Kuc, Structure and properties of high-alloy steels, Plasticity of Metallic Materials, Silesian University of Technology Press, Gliwice, 2004.
- [11] T. Sakai, Dynamic recrystallization microstructure under hot working conditions, Journal of Materials Processing Technology 53 (1995) 349-361.
- [12] I. Schindler, E. Hadasik, A new model describing the hot stress-strain curves of HSLA steel at high deformation, Journal of Materials Processing Technology 106 (2000) 131-135.
- [13] I. Schindler, J. Boruta, Utilization Potentialities of the Torsion Plastometer, Department of Metal Forming, Silesian Technical University Press, Katowice, 1998.
- [14] S.S.M. Tavares, M.R. da Silva, J.M. Pardal, H.F.G. Abreu, A.M. Gomes, Microstructural changes produced by plastic deformation in the UNS S31803 duplex stainless steel, Journal of Materials Processing Technology 180 (2006) 318-322.
- [15] H.L. Xing, C.W. Wang, K.F. Zhang, Z.R. Wang, Recent development in the mechanics of superplasticity and its applications, Journal of Materials Processing Technology 151 (2005) 196-202.
- [16] X.J. Zhang, P.D. Hodgson, P.F. Thomas, The effect of through - thickness strain distribution on the static recrystallization of hot rolled austenitic stainless steel strip, Journal of Materials Processing Technology 60 (1996) 615-619.
- [17] H.L. Xing, C.W. Wang, K.F. Zhang, Z.R. Wang, Recent development in the mechanics of superplasticity and its applications, Journal of Materials Processing Technology 151 (2005) 196-202.
- [18] X.J. Zhang, P.D. Hodgson, P.F. Thomas, The effect of through - thickness strain distribution on the static recrystallization of hot rolled austenitic stainless steel strip, Journal of Materials Processing Technology 60 (1996) 615-619.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BOS2-0019-0062