Journal
OPTICS AND LASER TECHNOLOGY
Volume 111, Issue -, Pages 664-670Publisher
ELSEVIER SCI LTD
DOI: 10.1016/j.optlastec.2018.08.052
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Funding
- Australian Research Council (ARC) through ARC [DP150104719]
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Additively manufactured Ti-6Al-4V implants represent a premier application of metal additive manufacturing (AM) since 2007. Microstructural inhomogeneity can noticeably affect one or more aspects of their mechanical or biomedical performance. This paper investigates the microstructural inhomogeneity in selective laser melting (SLM)-fabricated Ti-6Al-4V using micro X-ray diffraction (mu-XRD) and the consequent changes in elastic modulus (concerns are trivial with other mechanical properties of SLM Ti-6A1-4V implants). Cylindrical specimens of 4)12 mm x 20 mm (few Ti-6Al-4V implants are thicker than 20 mm) were manufactured by SLM for detailed charaterization. mu-XRD (beam size: 500 mu m) was applied to 40 uniformly spaced regions at different build heights, assisted with microscopic examination. The distribution of lattice parameters for each phase was mapped out based on a detailed analysis of the mu-XRD two-dimensional (2D) diffraction data (ring patterns). The bottom half of the cylindrical specimen consisted of essentially alpha and beta while alpha'-martensite was prominent above the mid-height, with the top 3.5-mm thick region being fully martensitic. In relation to this, the elastic modulus was found to decrease almost linearly from the mid-build height to the top. It is further shown that the mu-XRD 2D ring patterns offered an improved approach to characterising the beta-phase in SLM Ti-6Al-4V. The implications of these findings are discussed explicitly.
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