Additively manufactured β-Ti5553 with laser powder bed fusion: Microstructures and mechanical properties of bulk and lattice parts
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Ti5553 paper - Final.pdf
Embargo:
2026-02-27
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12.40Mb
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Final Accepted Manuscript
Author
Wu, MargaretLinne, Marissa
Forien, Jean-Baptiste
Barton, Nathan R.
Ye, Jianchao
Hazeli, Kavan
Perron, Aurelien
Bertsch, Kaila
Wang, Y. Morris
Voisin, Thomas
Affiliation
University of ArizonaIssue Date
2024-02-27
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Elsevier BVCitation
Wu, M., Linne, M., Forien, J. B., Barton, N. R., Ye, J., Hazeli, K., ... & Voisin, T. (2024). Additively manufactured β-Ti5553 with laser powder bed fusion: microstructures and mechanical properties of bulk and lattice parts. Journal of Materials Processing Technology, 118354.Rights
© 2024 Elsevier B.V. All rights reserved.Collection Information
This item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu.Abstract
Ti5553 (Ti-5Al-5Mo-5V-3Cr wt%) is a titanium alloy widely used for its high strength-to-weight ratio and good formability at elevated temperatures. Unlike Ti-6Al-4V, Ti5553 does not undergo martensitic transformation, preventing cracking of brittle martensite upon rapid cooling. This makes it a strong candidate for additive manufacturing (AM), particularly laser powder bed fusion (L-PBF). L-PBF offers the unique opportunity to make fine lattice structures to reduce component weight. Despite the growing field of AM, there have been limited studies on L-PBF Ti5553 lattices and how their properties differ from the bulk. The present work addresses this knowledge gap by investigating microstructures and properties of L-PBF bulk and lattice parts and the effect of post L-PBF heat treatments. Electron microscopy and mechanical testing show that the high dislocation density formed during L-PBF increases bulk part's yield strength by approximately 100 MPa compared to the conventional alloy. Digital image correlation during compression testing of octet truss lattices reveals a layer-by-layer failure mode. Compared to the bulk, the lattice contains copious ω nanoprecipitation, weaker <001> texture, smaller average grain sizes, and larger content of high-angle grain boundaries. These features elicit differences in Taylor factor distributions for the lattice depending on load direction, underlining challenges in predicting lattice mechanical response based on bulk properties. By examining the processing-structure-property relationships in the bulk and lattice, the present results delineate their microstructural and mechanical differences and establish a benchmark for the future design applications of L-PBF Ti5553.Note
24 month embargo; first published 27 February 2024ISSN
0924-0136Version
Final accepted manuscriptSponsors
Office of Scienceae974a485f413a2113503eed53cd6c53
10.1016/j.jmatprotec.2024.118354