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Metal science and metallography
Название Hot plastic deformation of heat-resistant austenitic AISI 310S steel. Part 2. Tensile torsional fracture simulation
Автор A. Yu. Churyumov, A. V. Pozdnyakov, T. A. Churyumova, V. V. Cheverikin
Информация об авторе

National University of Science and Technology “MISiS” (Moscow, Russia):

A. Yu. Churyumov, Cand. Eng., Associate Prof., Dept. of Non-ferrous Metallurgy, e-mail: churyumov@misis.ru
A. V. Pozdnyakov, Cand. Eng., Associate Prof., Dept. of Non-ferrous Metallurgy
V. V. Cheverikin, Cand. Eng., Leading Resarcher

 

A. A. Bochvar High-technology Scientific Research Institute for Inorganic Materials (Moscow, Russia):
T. A. Churyumova, Researcher

Реферат

Finite element simulation and experimental investigation of heat-resistant AISI 310S steel under high-temperature tensile and torsion with tension conditions was carried out using thermomechanical simulator Gleeble 3800. The tensile fracture of steel is preceded by significant plastic deformation, as evidenced by the developed fracture surface, charac terized by microdimples. The true deformation to failure, determined by the relative reduction of cross-section area in the strain localization zone, is mainly determined by the tension temperature and increases from 2.1–2.2 to 3.2–3.6 with increasing temperature from 900 to 1100 °C. It was shown that the critical values of the AISI 310S steel failure criterion during hot plastic deformation increase with decreasing of the Zener-Hollomon parameter. Verification of the constructed fracture model showed its high predictive ability and the potential possibility for application for the development of industrial technologies for plastic deformation of the AISI 310S steel using the finite element method.
This work was financially supported by the Russian Science Foundation (project No. 18-79-10153).

Ключевые слова Hot deformation, fracture, microstructure, AISI 310 steel, modelling, finite element approach
Библиографический список

1. Nahshon K., Hutchinson J. W. Modification of the Gurson Model for shear failure. European Journal of Mechanics A. 2008. Vol. 27. pp. 1–17.
2. Said L. B., Mars J., Wali M., Dammak F. Numerical prediction of the ductile damage in single point incremental forming process. International Journal of Mechanical Sciences. 2017. Vol. 131–132. pp. 546–558.
3. Kolmogorov V. L. Stresses. Deformations. Fracture. Moscow: Metallurgiya, 1970. 229 p.
4. Johnson G. R., Cook W. H. Fracture characteristics of three metals subjected to various strains, strain rates, temperatures and pressures. Engineering Fracture Mechanics. 1985. Vol. 21. No. 1. pp. 31–48.
5. Murugesan M., Jung D. W., Cook J. Material and Failure Model Parameters Estimation of AISI-1045 Medium Carbon Steel for Metal Forming Applications. Materials. 2019. Vol. 12, Iss. 4. 609.
6. Bao Y., Wierzbicki T. On fracture locus in the equivalent strain and stress triaxiality space. International Journal of Mechanical Sciences. 2004. Vol. 46, Iss. 1. pp. 81–98.
7. Hu Q., Li X., Han X., Chen J. A new shear and tension based ductile fracture criterion: modeling and validation. European Journal of Mechanics A - Solids. 2017. Vol. 66. pp. 370–386.
8. Rice J. R., Tracey D. M. On the ductile enlargement of voids in triaxial stress fields. Journal of the Mechanics and Physics of Solids. 1969. Vol. 17, Iss. 3. pp. 201–217.
9. Oyane M. Criteria of ductile fracture strain. Bulletin of the JSME. 1972. Vol. 15, Iss. 90. pp. 1507–1513.
10. Norris D. M., Reaugh J. E., Moran B. A plastic-strain, mean-stress criterion for ductile fracture. Journal of Engineering Materials and Technology. 1978. Vol. 100, Iss. 3. pp. 279–286.
11. Churyumov A. Yu. Deformation and Fracture of 13CrMoNbV Ferritic-Martensitic Steel at Elevated Temperature. Physics of Metals and Metallography. 2019. Vol. 120, Iss. 12. pp. 1228–1232.
12. Shaikh A. A., Churyumov A. Yu., Pozdniakov A. V., Churyumova T. A. Simulation of the Hot Deformation and Fracture Behavior of Reduced Activation Ferritic/Martensitic 13CrMoNbV Steel. Applied Science. 2020. Vol. 10, Iss. 2. 530.
13. Nioi M., Pinna C., Celotto S., Swart E., Farrugia D. et al. Finite element modelling of surface defect evolution during hot rolling of silicon steel. Journal of Materials Processing Technology. 2019. Vol. 268. pp. 181–191.
14. Gorbunova Yu. D., Orlov G. А. Simulation of hot stamping of elliptical steel bottoms. Chernye Metally. 2019. No. 10. pp. 58–62.
15. Lemmens B., Springer H., Peeters M., De Graeve I., De Strycker J. et al. Deformation induced degradation of hot-dip aluminized steel. Materials Science and Engineering: A. 2018. Vol. 710. pp. 385–391.
16. Dwivedi S., Rana R. S., Rana A., Rajpurohit S., Purohit R. Investigation of Damage in Small Deformation in Hot Rolling Process Using FEM. Materials Today: Proceedings. 2017. Vol. 4. Part A. Iss. 2. pp. 2360–2372.
17. Hubert C., Dubar L., Dubar M., Dubois A. Experimental simulation of strip edge cracking in steel rolling sequences. Journal of Materials Processing Technology. 2010. Vol. 210. pp. 1587–1597.
18. Wang C., Liu X., Gui J., Xu Z., Guo B. Infl uence of inclusions on matrix deformation and fracture behavior based on Gurson – Tvergaard – Needleman damage model. Materials Science and Engineering: A. 2019. Vol. 756 A. pp. 405–416.
19. Marashi J., Yakushina E., Xirouchakis PP., Zante R., Foster J. An evaluation of H13 tool steel deformation in hot forging conditions. Journal of Materials Processing Technology. 2017. Vol. 246. pp. 276–284.
20. Farrugia D. C. J. Prediction and avoidance of high temperature damage in long product hot rolling. Journal of Materials Processing Technology. 2006. Vol. 177, Iss. 1–3. pp. 486–492.
21. Lisunets N. L. Improving the efficiency of the processes of billets manufacture from rolled metal via shift cutting based on simulation. Chernye Metally. 2018. No. 6. pp. 31–35.
22. Liu G., Yang S., Ding J., Han W., Zhou L. et al. Formation and evolution of layered structure in dissimilar welded joints between ferritic-martensitic steel and 316L stainless steel with fillers. Journal of Materials Science & Technology. 2019. Vol. 35, Iss. 11. pp. 2665–2681.
23. Wei Y., Shen Z., Zhang W., Tang R., Long Y. et al. Microstructure evolution of modified 310S austenitic stainless steels under argon ion irradiation at different temperatures. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms. 2019. Vol. 459. pp. 7–14.
24. Behnamian Y., Mostafaei A., Kohandehghan A., Amirkhiz B.S., Serate D. et al. Characterization of oxide scales grown on alloy 310S stainless steel after long term exposure to supercritical water at 500 °C. Materials Characterization. 2016. Vol. 120. pp. 273–284.
25. Churyumov А. Yu., Pozdnyakov А. V, Churyumova Т. А., Cheverikin V. V. Hot plastic deformation of heat-resistant austenitic steel AISI 310S. Part 1. Simulation of flow stress and dynamic recrystallization. Chernye Metally. No. 8. pp. 48-55.
26. Zhu Y., Zeng W., Zhang F., Zhao Y., Zhang X. et al. A new methodology for prediction of fracture initiation in hot compression of Ti40 titanium alloy. Materials Science and Engineering A. 2012. Vol. 553. pp. 112–118.

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