Precipitation hardening of laser powder bed fusion Ti-6Al-4V

The laser powder bed fusion (PBF-L) additive manufacturing (AM) community has dedicated significant efforts into process optimization and control for defect-free Ti-6Al-4V. As defects become less of an issue for PBF-L Ti-6Al-4V, the processing-structure-properties (PSP) relationships between AM microstructures can now be explored to optimize mechanical properties. Lower temperature aging treatments around 550 degrees C in wrought Ti-6A-4V have been historically understood to precipitation harden the alpha phase with an ordered, hexagonal close packed (HCP) alpha 2 phase. The alpha 2 phase exists as nanoscale Ti3Al precipitates coherent with the parent alpha phase. The goal of the present investigation was to implement a vacuum heat treatment of 545 degrees C for 100 h on PBF-L Ti-6Al-4V. This vacuum heat treatment took place after an initial hot isostatic pressure (HIP) treatment that decomposed the as-built, martensitic microstructure. The vacuum aging successfully produced nanoscale precipitates of alpha 2 phase within alpha- laths, confirmed via atom probe tomography (APT). Microstructural-length scale and quasi-static mechanical properties were investigated by nanoindentation and uniaxial tensile tests of miniaturized test specimens. Given the sensitivity of Ti-6Al-4V mechanical properties to small changes in chemistry, all test specimens originated from the same build. The alpha 2 precipitation resulted insignificantly harder alpha- laths (approximate to 2 GPa) as measured via nanoindentation, as well as a relative yield and ultimate tensile strength increase of 60 MPa and 38 MPa, respectively. Analysis of Variance (ANOVA) of the datasets revealed no statistical differences in total elongation between the HIPed and HIPed + aged specimens, indicative of the aging treatment producing a net benefit of strength with no loss inductility.