Abstract
Among various off-equilibrium microstructures of additively manufactured Ti-6Al-4V alloy, electron beam powder bed fusion, in which three dimensional metallic objects are fabricated by melting the ingredient powder materials layer by layer on a pre-heated bed, results in a specimen that is nearly free of the preferred orientation of the α-Ti phase as well as a low beta phase fraction of ∼1 wt%. However, when further heat treatment of up to 1050 ∘C was applied to the material in our previous study, a strong texture aligning the hexagonal basal plane of α phase with the build direction and about 6% β phase appeared at room temperature. In this study, to understand the mechanism of this heat treatment, the grain level microstructure of the additively manufactured Ti-6Al-4V was investigated using in situ high temperature EBSD up to 1000 ∘C, which allows the tracking of individual grains during a heat cycle. As a result, we found a random texture originating from the fine grains in the initial material and observed a significant suppression of α phase nucleation in the slow cooling after heating to 950 ∘C within the α and β dual phase regime but close to the the β-transus temperature at ∼980 ∘C, which led to a coarse microstructure. Furthermore, the texture resulting from phase transformation of the additively manufactured Ti-6Al-4V assuming nucleation at the grain boundaries was modeled, using the double Burgers orientation relationship for the first time. The model successfully reproduced the measured texture, suggesting that the texture enhancement of the α phase by the additional heat treatment derives also from the variant selection during the phase transformation and nucleation on grain boundaries.
Highlights
Titanium alloy Ti-6Al-4V offers excellent formability, fatigue and creep strength, originating from the balanced α and β-Ti crystallographic phases and is widely used in the aerospace industry [1,2]
Each powder layer was pre-heated in order to attain a temperature between 550 ◦C and 700 ◦C (∼0.5 Tm, and Tm is the temperature of the melting point in Kelvin) by using a de-focused electron beam
It is almost zero before heat treatment, which is reasonable in light of thermodynamic equilibrium (Figure 1), the β-phase remains about 6% at room temperature after the heating and cooling cycle
Summary
Titanium alloy Ti-6Al-4V (wt.%) offers excellent formability, fatigue and creep strength, originating from the balanced α and β-Ti crystallographic phases and is widely used in the aerospace industry [1,2]. Since the phase balance is critical to the mechanical properties of the Ti-6Al-4V, the mechanism of the β phase suppression needs to be clarified to control the material properties. With this motivation, our previous neutron diffraction study [13] was expanded to an in situ high temperature environment up to 1050 ◦C using a heating chamber, where the microstructure was characterized as a function of temperature, including the α to β to α transformation. Katzarov [20] successfully modeled that a high cooling rate results in a large amount of α phase and a suppressed rate of nucleation of the α phase depending on the diffusion of vanadium in the material
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