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Purpose: Purpose of this paper was to give information about low temperature strength and impact CharpyV toughness of low carbon microalloyed 5%Ni bainitic steel after thermomechanical rolling (TMR) or thermomechanical controlled processing (TMCP) and ageing at different temperatures: 580°C/2 h, 640°C/1h and 680°C/1h. Design/methodology/approach: The tensile strength tests were performed at -196, -60 and 20°C and Charpy V samples were broken at -100, -80, -60, -40, -20 and 20°C temperatures. The tensile strength TS, yield strength YS, elongation A5 and reduction of area RA were established from tensile experiments. After TMCP 16 mm steel plate had YS = 730MPa, TS = 950 MPa, A5 = 22,5% and RA = 61% and impact energy > 50 J at -196°C. Findings: The best combination of mechanical properties; yield strength and Charpy V toughness was achieved for steel after TMR and ageing 580°C/ 2h; YS = 800MPa, TS = 900 MPa, A5 = 22.5%, at -1000C KVmin.= 110 J. Research limitations/implications: The precise methodology for retained austenite identification and its amount content determination in the investigated microstructures is still metallographic problem which needs to be resolved. Practical implications: The best combination of yield strength and Charpy V toughness was achieved for steel after TMR and ageing 580°C/ 2h. At liquid nitrogen temperature ultrahigh strength properties were: YS = 1140 MPa, TS = 1280 MPa, A5 = 26%, RA = 55% and KV 122 J at -100°C. Originality/value: The detailed microstructure examination of the steel with optical and mainly scanning transmission electron microscopy was needed to explain its good properties at very low temperature. TRIP effect was observed due to the presence of highly alloyed retained austenite in the microstructure. That type of steel may be used for contemporary military and structural applications working at low temperatures.
Wydawca
Rocznik
Tom
Strony
37--42
Opis fizyczny
Bibliogr. 22 poz., rys., tab., wykr.
Twórcy
autor
- Division of, Institute of Materials Engineering, Częstochowa University of Technology, 19 Armii Krajowej, 42-200 Częstochowa, Poland
autor
- Division of, Institute of Materials Engineering, Częstochowa University of Technology, 19 Armii Krajowej, 42-200 Częstochowa, Poland
Bibliografia
- [1] C.I. Garcia, A.J. DeArdo, E. Raykin, J.D. Defilippi, Proc. Int. Symp. on ‘High performance steels for structural applications’, Clevland, OH, TMS,1995, 155-160.
- [2] M. Mujahid, A. Lis, C.I. Garcia, A.J. Deardo, Structure - property studies of Cu-containing HSLA 100 steels, Journal of Materials Engineering Performance 7 (1998) 247-259.
- [3] A. Lis, J. Lis, L. Jeziorski, Advanced ultra-low carbon steels with high toughness, Journal of Materials Processing Technology, 64 (1997) 255-265.
- [4] A. Ghosh, S. Das, S. Chatterjee, Ultrahigh strength hot rolled microalloyed steel: microstructure and properties, Materials Science and Technology 21 (2005) no 3, 325-333.
- [5] W.M. Garrison, J.L. Maloney, A.L. Wojcieszyński, High toughness of HY 180 steel, Key Engineering Materials 84-85 (1993) 282-293.
- [6] E.J. Czyrca, Mechanical properties of low-carbon HY 130 steel, Key Engineering Materials 84-85 (1993) 491-520.
- [7] A. Lis, L. Jeziorski, J. Lis, The CCT diagrams of ultra low caron bainitic steels and their impact toughness properties, Materials Engineering 3 (1998) 273-242. (in Polish and English)
- [8] A.K. Lis, J. Lis, Effect of hot deformation and cooling rate on phase transformations in low carbon bainitic steel, Proceedings 11th Int. Sci. Conf. on Contemporary Achievements in Mechanics, Manufacturing and Materials Science CAM3S’2005, Gliwice-Zakopane, 2005, 592-596.
- [9] J. Lis, A.K. Lis, C. Kolan, Processing and properties of C-Mn steel with dual-phase microstructure, Proceedings 13th Int. Sci. Conf. on Achievements in Mechanical and Materials Engineering AMME’2005, Gliwice-Wisła, 2005, 393-398.
- [10] A. Lis, W. Gliński, J. Lis, Modelling of microstructure development for thermomechanical rolling in D+J temperature range, Proc.12th Int. Sci. Conf. Achievements in Mechanical and Materials Engineering AMME 2003, Gliwice- Zakopane, 609-612.
- [11] J. Lis, A.K. Lis, C. Kolan, Processing and properties of C-Mn steel with dual-phase microstructure, Journal of Materials Processing Technology 162-163 (2005) 350-354.
- [12] J.Lis, Microsegregation of manganese in low carbon steels during intercritical heat treatments, Materials Engineering No. 7, Scientific Works of Faculty of Processing and Materials Engineering and Applied Physics, Częstochowa University of Technology, Częstochowa, 2005 ( in Polish).
- [13] W. Schütz, F. Schröter, Materials Science & Engineering 21 (2005) No. 5, 590-596.
- [14] F. Schröter, W. Schütz, Application of heavy plates in civil engineering, STEEL GRIPS 3 (2005) No. 425-432.
- [15] CEN: Eurocode 3 Part 1-10: Selection of Materials for fracture toughness and through-thickness properties, Draft December 2001.
- [16] De Vito, Recenta developpements technologiques dans la production de plaques a haute limite d’ elasticite 80 a Tarente, Rev. Metall. Cit. T 83 (1986) Nr.4 343-348.
- [17] J. Mikuáa, L. Wojnar, Application of anlytical methods in determining weldability of steels, Edt. Fotobit, Kraków, 1996.
- [18] A.K. Lis, J. Lis, Dual-phase ULCB steels thermomechanically processed, Materials Engineering (InĪynieria Materiaáowa) 123 (2001) No.4, 548-550
- [19] J. Lis, A.K. Lis, Structure and mechanical properties of low carbon bainitic steel after heat treatment from (D+J) range, Materials Engineering 137 (2003) No.6 329-331 (in Polish)
- [20] J. Lis, A.K. Lis, Formation of the microstructure of HN5MVNb steel after rolling annealed in (D+J) temperature range and fast cooled, Materials Engineering 130 (2002) no.5 498-502 (in Polish).
- [21] J. Lis, B. Gajda, A. Lis, CCT diagram of HN5MVNb steel after intercritical annealing, Proceedings 12th Int. Sci. Conf. AMME’2003, Achievements in Mechanical and Materials Engineering, Gliwice-Zakopane, 2003, 605-608.
- [22] J. Lis, Processing of HSLA-Ni steel by intercritical annealing after water quenching or thermomechanical rolling, Materials Engineering, 140 (2004) No.3 159-162.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-511a301a-e232-4436-838e-d3ea5c0394d6