Powiadomienia systemowe
- Sesja wygasła!
Tytuł artykułu
Autorzy
Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
Purpose: The aim of the paper is to determine the influence of the isothermal holding conditions in a range of bainitic transformation on the mechanical stability of retained austenite for medium-carbon TRIP-aided steel. Design/methodology/approach: The examinations were carried out on medium-carbon steel containing 0.55%C and 1.35%Si. The conditions of heat treatment consisted of isothermal quenching of the specimens to a temperature range of 250 to 550°C, where they were held for 600 and 1800 s. Tensile deformation of steel to the given strain equal 0.25, 0.5 and 0.75 of total elongation of samples was conducted in order to determine the kinetics of retained austenite transformation into martensite. The retained fraction of the γ phase was determined by the use of the quantitative X-ray phase analysis. Findings: Increasing the carbon concentration to 0.55% in TRIP-type steels makes possible to obtain very high strength properties without a deterioration of the ductility. The retained austenite of the 19% volume fraction can be obtained after the isothermal quenching of the steel to a temperature of 250°C. In these conditions, the matrix of the steel is the ferritic bainite. The size of regular grains of retained austenite is equal up to 3μm, while the rest of γ phase is present in a form of thin films between individual laths of bainite. Diversification of retained austenite form has a reflection in its mechanical stability, connected with two-stage kinetics of martensitic transformation of γ phase. Research limitations/implications: To determine with more detail the stability of retained austenite the knowledge of lattice parameter changes with an isothermal holding temperature is needed. Practical implications: The proposed heat treatment can be useful for manufacturing reinforced structural elements characterized by high strength and ductile properties in the automobile industry. Originality/value: The developed conditions of the heat treatment concern the medium-carbon TRIP-type bainitic steel, offering higher product of UTS UEl compared with usually investigated TRIP-type ferritic-bainitic steels.
Wydawca
Rocznik
Tom
Strony
5--12
Opis fizyczny
Bibliogr. 25 poz.
Twórcy
autor
- Division of Constructional and Special Materials, Institute of Engineering Materials and Biomaterials, Silesian University of Technology, ul. Konarskiego 18a, 44-100 Gliwice, Poland, adam.grajcar@polsl.pl
Bibliografia
- [1] J. Adamczyk, Engineering of Metallic Materials, The Silesian University of Technology Publishers, Gliwice, 2004 (in Polish).
- [2] T. Gladman, The Physical Metallurgy of Microalloyed Steels, The University Press, Cambridge, 1997.
- [3] B. Ehrhardt, T. Berger, H. Hofmann, T.W. Schaumann, Property related design of advanced cold rolled steels with induced plasticity, Steel Grips 2 (2004) 247-255.
- [4] A.K. Lis, B. Gajda, Modeling of the DP and TRIP microstructure in the CMnAlSi automotive steel, Proceedings of the 11th International Scientific Conference “Contemporary Achievements in Mechanics, Manufacturing and Materials Science”, CAM3S’2005, Gliwice – Zakopane, 2005, 585-591.
- [5] A. Basuki, E. Aernoudt, Influence of rolling of TRIP steel in the intercritical region on the stability of retained austenite, Journal of Materials Processing Technology 89-90 (1999) 37-43.
- [6] K. Sugimoto, T. Iida, J. Sakaguchi, T. Kashima, Retained austenite characteristics and tensile properties in a TRIP type bainitic sheet steel, ISIJ International 9 (2000) 902-908.
- [7] J. Adamczyk, A. Grajcar, Structure and mechanical properties of DP-type and TRIP-type sheets, Journal of Materials Processing Technology 162-163 (2005) 267-274.
- [8] A. Grajcar, Effect of hot-working in the γ+ α range on a retained austenite fraction in TRIP-aided steel, Journal of Achievements in Materials and Manufacturing Engineering 22/2 (2007) 79-82.
- [9] A. Grajcar, Hot-working in the γ+ α; region of TRIP-aided microalloyed steel, Archives of Materials Science and Engineering 28/12 (2007) 743-750.
- [10] A. Grajcar, Determination of the stability of retained austenite in TRIP-aided bainitic steel, Journal of Achievements in Materials and Manufacturing Engineering 20 (2007) 111-114.
- [11] B. Gajda, A.K. Lis, Thermal processing of CMnAlSi steel at ((α+γ) temperature range, Journal of Achievements in Materials and Manufacturing Engineering 18 (2006) 355-358.
- [12] N. Apostolos, A. Vasilakos, K. Papamantellos, G. Haidemenopoulos, W. Bleck, Experimental determination of the stability of retained austenite in low alloy TRIP steels, Steel Research 11 (1999) 466-471.
- [13] K. Eberle, P. Cantinieaux, P. Harlet, M. Vande Populiere, New thermomechanical strategies for the realization of multiphase steels showing a transformation induced plasticity effect, Iron and Steelmaker 26/2 (1999) 23-27.
- [14] A. Wasilkowska, P. Tispouridis, A. Werner, A. Pichler, S. Traint, Microstructure and tensile behaviour of cold-rolled TRIP-aided steels, Proceedings of the 11th Scientific International Conference “Achievements in Mechanical and Materials Engineering” AMME’2002, Gliwice–Zakopane, 2002, 605-610.
- [15] K. Sugimoto, R. Kikuchi, S. Hashimoto, Development of high strength low alloy TRIP-aided steels with annealed martensite, Steel Research 73 (2002) 253-258.
- [16] K.W. Andrews, Hardenability of steels, Journal of the Iron and Steel Institute 7 (1965) 721-727.
- [17] E. Girault, P. Jacques, Ph. Harlet, K. Mols, J. Van Humbeeck, E. Aernoudt, F. Delannay, Metallographic methods for revealing the multiphase microstructure of TRIP-assisted steels, Materials Characterization 40 (1998) 111-118.
- [18] B. Averbach, M. Cohen, X-ray phase analysis, Trans. AIME 176 (1948) 60-70.
- [19] J. Adamczyk, A. Grajcar, Heat treatment of TRIP-aided bainitic steel, Proceedings of the 11th International Scientific Conference “Contemporary Achievements in Mechanics, Manufacturing and Materials Science”, CAM3S’2005, Gliwice - Zakopane, 2005, 1-6.
- [20] J. Pietrzyk, W. Osuch, G. Michta, The isothermal decomposition of the austenite obtained at a temperature between A3-A1 in a steel containing 0.2%C, 1.5%Mn and 1.5%Si, Materials Engineering 19 (1998) 18-23 (in Polish).
- [21] S.K. Liu, L. Yang, D.G. Zhu, J. Zhang, The influence of the alloying elements upon the transformation kinetics and morphologies of ferrite plates in alloy steels, Metallurgical and Materials Transactions 25A (1994) 1991-1996.
- [22] Y. Tomita, K. Morioka, Effect of microstructure on transformation-induced plasticity of silicon-containing low-alloy steel, Materials Characterization 38 (1997) 243-250.
- [23] J. Pietrzyk, G. Michta, W. Osuch, A. Kruk, Low-carbon steels with the TRIP effect, Materials Engineering 24 (2002) 154-156 (in Polish).
- [24] A. Barbarki, E. Mikołajki, M. Popławski, The application of austempering in the formation of microstructure and mechanical properties of medium carbon constructional steels, Archives of Machine Technology and Automatization 24 (2004) 9-16 (in Polish).
- [25] H.K.D.H. Bhadeshia, Bainite in Steels, Transformations, Microstructure and Properties, Second Edition, The University Press, Cambridge, 2001.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BSL7-0033-0001