Abstract
The hot deformation behaviors of a new Ti-6Al-2Nb-2Zr-0.4B titanium alloy in the strain rate range 0.01–10.0 s−1 and temperature range 850–1060 °C were evaluated using hot compressing testing on a Gleeble-3800 simulator at 60% of deformation degree. The flow stress characteristics of the alloy were analyzed according to the true stress–strain curve. The constitutive equation was established to describe the change of deformation temperature and flow stress with strain rate. The thermal deformation activation energy Q was equal to 551.7 kJ/mol. The constitutive equation was On the basis of the dynamic material model and the instability criterion, the processing maps were established at the strain of 0.5. The experimental results revealed that in the (α + β) region deformation, the power dissipation rate reached 53% in the range of 0.01–0.05 s−1 and temperature range of 920–980 °C, and the deformation mechanism was dynamic recovery. In the β region deformation, the power dissipation rate reached 48% in the range of 0.01–0.1 s−1 and temperature range of 1010–1040 °C, and the deformation mechanism involved dynamic recovery and dynamic recrystallization.
Highlights
Titanium alloys are important structural materials in ship and aerospace due to hightemperature resistance, the high specific strength, weldability, corrosion resistance, and other excellent characteristics [1,2,3,4]
An urgent need to reduce the weight of structural materials in aerospace is observed
Ti-6Al-2Nb-2Zr-0.4B alloy is a new type of high elasticity modulus titanium alloy, developed according to the design theory of aluminum and molybdenum equivalents, and molecular orbital calculation of the electronic structure and β-phase stability coefficient
Summary
Titanium alloys are important structural materials in ship and aerospace due to hightemperature resistance, the high specific strength, weldability, corrosion resistance, and other excellent characteristics [1,2,3,4]. Ti-6Al-2Nb-2Zr-0.4B alloy is a new type of high elasticity modulus titanium alloy, developed according to the design theory of aluminum and molybdenum equivalents, and molecular orbital calculation of the electronic structure and β-phase stability coefficient. This alloy exhibited high elastic modulus and strength, good plasticity and toughness, and excellent comprehensive properties. Tohbetadineefodr,manatdiotnhelatwheorfmthalewalolorkyiantghdigiahgtreammpweraastuorbetsawinaesd abnyalsyuzpeedrpaonsdintghethseutiwtaobldeiapgroracmesss.inTghetedcehfnoormloagtyiownalaswobotfatihneeda,llporyoavtidhiinggh atetmhpeoerreattiucraels bwasaiss afonraltyhzeehdoatnpdrotcheesssuinigtatbelcehpnroolcoegsysifnogrmteuchlantioolnog. y was obtained, providing a theoretical basis for the hot processing technology formulation
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