Hot deformation behavior of Ti–5.0Al–2.40Sn–2.02Zr–3.86Mo–3.91Cr alloy with an initial lamellar microstructure in the α+β phase field

▶ Deformation behavior of Ti-alloy with an initial lamellar microstructure in the α+β phase field has been studied, and it will provide a basis for optimization of the cogging process. ▶ The globularization process represents a moderate η value and contributes to grain refinement. ▶ In order to obta...

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Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2011-01, Vol.528 (3), p.1812-1818
Main Authors: Ning, Yongquan, Fu, M.W., Hou, Hongyu, Yao, Zekun, Guo, Hongzhen
Format: Article
Language:English
Subjects:
Applied sciences
Constitutive modeling
Deformation
Deformation behavior
Elasticity. Plasticity
Exact sciences and technology
Grain refinement
Grains
Instability
Mechanical properties and methods of testing. Rheology. Fracture mechanics. Tribology
Metals. Metallurgy
Microstructure
Optimization
Processing maps
Stability
Strain rate
Titanium base alloys
Ti–5.0Al–2.40Sn–2.02Zr–3.86Mo–3.91Cr
α + β phase field
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Summary:▶ Deformation behavior of Ti-alloy with an initial lamellar microstructure in the α+β phase field has been studied, and it will provide a basis for optimization of the cogging process. ▶ The globularization process represents a moderate η value and contributes to grain refinement. ▶ In order to obtain homogeneous microstructure with fine grains, hot deformation process should be carried out under the condition of Td: 1130K, ε˙:0.001 s−1. Hot deformation behavior of Ti–5.0Al–2.40Sn–2.02Zr–3.86Mo–3.91Cr alloy with an initial lamellar microstructure in the α+β phase field was investigated at the temperatures of 1050–1130K (all below the β-transus temperature) and the strain rates of 0.001–10.0s−1 using processing maps. The apparent activation energy of deformation was calculated to be 313kJmol−1, and a constitutive equation by which the flow stress is represented as a function of strain rate and deformation temperature was developed. A processing map was constructed based on the experimental data for evaluation of the efficiency of power dissipation (η), identification of the instability regions and optimization of the α+β forging process parameters. It is found that the hot deformation at low temperature has high η value, and the microstructure obtained at high temperature is more homogeneous. The globularization process represents the moderate η value and contributes to the grain refinement. In order to obtain the homogeneous microstructure with fine grain, hot deformation should be carried out under the condition of (Topi: 1130K, ε˙opi:0.001 s−1). Flow instability is expected to occur at a single region with a higher strain rate (ε˙≥3.0 s−1) across the temperature range (Td: 1050–1130K) due to the possible occurrence of adiabatic shear banding or/and flow localization.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2010.11.019