Superplastic deformation behaviour and microstructure evolution of near-α Ti-Al-Mn alloy
Materials Science and Engineering: A • 2017
معلومات البحث
المؤلفون
AV Mikhaylovskaya, AO Mosleh, AD Kotov, JS Kwame, T Pourcelot, IS Golovin, VK Portnoy
الكلمات المفتاحية
SuperplasticityTitanium alloysMicrosize grain structureDislocation structure
المجلة العلمية
Materials Science and Engineering: A
الناشر
Elsevier
المجلد
708
العدد
Not Available
الصفحات
469-477
publication.type
International
رابط البحث
Open Link
المواد المرفقة
Not Available
الملخص
Superplastic deformation behaviour of conventional sheets of a near-α titanium alloy (Ti-2.5
Al-1.8 Mn) was studied by a step-by-step decrease of the strain rate and constant strain rate
tests in a temperature range of 790–915° C. The research found that superplastic
deformation is possible in a temperature range of 815–890° С and a constant strain rate
range of 2× 10− 4 to 1× 10− 3 s− 1 with elongation above 300% and m-index above 0.4.
Also, the research identified the optimum superplastic temperature range of 815–850° C and
constant strain rate of 4× 10− 4 s− 1 which provide a maximum elongation of 600–650%.
Strain hardening is accelerated by dynamic grain growth at high temperatures of 865 and
890° С. High dislocation activity is observed at superplastic flow in α-phase. Constitutive
modelling of superplastic deformation behaviour is performed, and possible deformation
Al-1.8 Mn) was studied by a step-by-step decrease of the strain rate and constant strain rate
tests in a temperature range of 790–915° C. The research found that superplastic
deformation is possible in a temperature range of 815–890° С and a constant strain rate
range of 2× 10− 4 to 1× 10− 3 s− 1 with elongation above 300% and m-index above 0.4.
Also, the research identified the optimum superplastic temperature range of 815–850° C and
constant strain rate of 4× 10− 4 s− 1 which provide a maximum elongation of 600–650%.
Strain hardening is accelerated by dynamic grain growth at high temperatures of 865 and
890° С. High dislocation activity is observed at superplastic flow in α-phase. Constitutive
modelling of superplastic deformation behaviour is performed, and possible deformation
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