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This article is cited in 2 scientific papers (total in 2 papers)
Thermophysical Properties of Materials
Physical modelling of $\rm Ti$–$6\rm Al$–$4\rm V$ alloy above $\beta$ transus at high temperatures $(1010$–$1150^{\circ}$C$)$ and high strain rates using Garofalo and Hensel–Spittel laws
Mohamed Ghata, A. Mohamedbc, Ahmed S. Afifyd a Department of Industrial Engineering and Mathematical Sciences (DIISM), Università Politecnica delle Marche, Ancona, 60131 Italy
b Chemistry Department, College of Science, Taibah University, Al-Madinah Al-Munawarah, 41477 Saudi Arabia
c The Higher Institute of Optics Technology (HIOT), Heliopolis, Cairo, 17361 Egypt
d Department of Basic Sciences, The Higher Institute for Engineering, Automotive Technology and Energy, New Heliopolis, Egypt
Abstract:
A phenomenological model based on the combination of the Garofalo and Hensel–Spittel equations is used to obtain a quite accurate description of the flow curves of $\rm Ti$–$6\rm Al$–$4\rm V$ alloy for processing temperatures between $1010$ and $1150^{\circ}$C and strain rates of $100{,}~50{,}~10{,}~1{,}~0.1{,}~0.001$ s$^{-1}$. The hot deformation is achieved by dynamic recovery in the $\beta$ phase by subgrain formation. The activation energy of the dynamic recovery $Q_{HW}$ is determined as $202$ kJ/mol and the stress exponent $n$ is $3.92$. The analysis of the experimental data by constitutive model shows an excellent result of describing the flow curves.
Received: 09.07.2020 Revised: 10.03.2021 Accepted: 19.05.2021
Citation:
Mohamed Ghat, A. Mohamed, Ahmed S. Afify, “Physical modelling of $\rm Ti$–$6\rm Al$–$4\rm V$ alloy above $\beta$ transus at high temperatures $(1010$–$1150^{\circ}$C$)$ and high strain rates using Garofalo and Hensel–Spittel laws”, TVT, 60:4 (2022), 529–534; High Temperature, 60:4 (2022), 479–484
Linking options:
https://www.mathnet.ru/eng/tvt11486 https://www.mathnet.ru/eng/tvt/v60/i4/p529
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