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Konferencja
12th International Scientific Conference CAM3S'2006, 27-30th November 2006, Gliwice-Zakopane
Języki publikacji
Abstrakty
Purpose: Investigations of microstructure after hot deformation was presented in this work. The non-metallic inclusion influence on the microstructure and type of crack mechanism was shown. The hot ductility investigations were carried out on the low carbon-manganese steel with addition of boron. Design/methodology/approach: The ductility of the steel was measured by reduction of area during the extension test in the temperature range from 700 to 1200 degrees centigrade. The test was carried out with two different strain rates 0.01 s to the -1 and 6.5 s to the -1. The first one is characteristic for the continuous casting process and the second one for rolling of heavy plates and billets. The deformation microstructures of investigated steel after the hot extension tests were characterized by optical microscopy and scanning electron microscopy. The chemical composition of non-metallic inclusion was established by EDX analyses. Findings: The received - 30% ductility minimum of investigated steel with 0.01 s to the -1 strain rate, was found in the temperature range from 900 to 1000 degrees centigrade and these temperatures are connected with band straightening in the continuous casting process. The minimum of hot ductility for fast strain rate 6.5 s to the -1 reached -65% reduction of area value. The ferrite-bainite and ferrite-pearlite microstructures after air cooling were observed. The inclusions in different size from 0.6 to 4 micrometres and different shape (spherical and elongated) were observed. There were MnS and SiO2 inclusions with some other elements like Al2O3 and MnO. Practical implications: Low carbon steel with addition of boron is produced by continuous casting process where straightening of the strand is taken place close to 900 degrees centigrade. This temperature corresponds with hot ductility minimum for investigated steel. Originality/value: Available literature concerns investigations of low carbon steels but without boron addition, which expect to have strong influence on the position of the hot ductility minimum.
Wydawca
Rocznik
Tom
Strony
291--294
Opis fizyczny
Bibliogr. 17 poz., fot., rys., tab.
Twórcy
autor
autor
autor
- Institute of Materials Engineering, Faculty of Materials Processing Technology and Applied Physics, Częstochowa University of Technology, Armii Krajowej 19, 42-200 Częstochowa, Poland, npiwek@mim.pcz.czest.pl
Bibliografia
- [1] A. Cowley, R. Abushosha, B. Mintz, Influence of Ar3 and Ae3 temperatures on hot ductility of steel, Materials Science and Technology, 14 November (1998) 1145-1153.
- [2] B. Mintz, Importance of Ar3 temperature in сontrolling ductility and width of hot ductility trough in steels and its relationship to transverse cracking, Materials Science and Technology 12 February (1996) 132-138.
- [3] B. Mintz, A. Cowley, R. Abushosha, Importance of columnar grains in dictating hot ductility of steels, Materials Science and Technology 16 (2000) 1-5.
- [4] B. Mintz, The influence of composition on the hot ductility of steels and to the problem of transverse cracking, ISIJ International 39 (1999) 833-855.
- [5] CM. Chimani, K. Morwald, Micromechanical investigation of the hot ductility behavior of steel, ISIJ International 39 (1999) 1194-1197.
- [6] M. Carsi, M.T. Larrea, F. Panalba, Characterization of medium carbon microalloyed steels with boron, AMTT, Zakopane, (1995) 95-100.
- [7] R. Nowosielski, P. Sakiewicz, P. Gramatyka, The effect of ductility minimum temperature in CuNi25 alloy, AMME 2005, Gliwice-Wisła, Poland, 487-492.
- [8] H.K.D.H. Bhadeshia, Bainite in steels, The University Press, Cambridge, London, 2001.
- [9] R. Nowosielski, P. Sakiewicz, J. Mazurkiewicz, Ductility Minimum Temperature phenomenon in as cast CuNi25 alloy, Journal of Achievements in Materials and Manufacturing Engineering 17 (2006) 193-196.
- [10] W. Ozgowicz, The relationship between hot ductility and intergranular fracture in an CuSn6P alloy and elevated temperatures, AMME 2005, Gliwice-Wisła, Poland, 503-508.
- [11] S.M. Pytel, Hot ductility of continuous cast structural steels, AMTT, Zakopane, 1995, 403-411.
- [12] J.Sojka, P. Betakova, L. Hyspecka, L. Cizek, M. Sozańska, A. Hernas, Role of non-metallic inclusion shape in hydrogen embitterment tested Rusing slow strain rate test, AMME 2003, Gliwice-Zakopane, Poland, 821 -824.
- [13] J. Shim, Y. Oh, J. Suh, Y. Cho, J. Shim, J. Byun, D.Lee, Ferrite nucleation potency of non-metallic inclusions in medium carbon steels, Acta Materialia 49 (2001) 2115-2122.
- [14] J.H. Shim, Y.W. Cho, S.H. Chung, J.D. Shim, D.N. Lee, Nucleation of intragranular ferrite at Ti203 particle in low carbon steel, Acta Materialia 47 (1999) 2751 -2760.
- [15] R. Kiessling, N. Lange, Non metallic inclusion in steel. Second edition, The Institute of Materials, London, 1997.
- [16] B. Garbarz, J. Marcisz, J. Wojtas, ТЕМ analysis of fine sulphides dissolution and precipitation in steel, Materials Chemistry and Physics 81 (2003) 486-489.
- [17] L.A. Dobrzański, The engineering materials and materials design, WNT, Warszawa, 2006.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BOS5-0018-0062