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Laser powder bed fusion of WC-reinforced Hastelloy-X composite: Microstructure and mechanical properties

Han, Quanquan; Gu, Yuchen; Gu, Heng; Yin, Yingyue; Song, Jun; Zhang, Zhenhua; Soe, Shwe

Laser powder bed fusion of WC-reinforced Hastelloy-X composite: Microstructure and mechanical properties Thumbnail


Authors

Quanquan Han

Yuchen Gu

Heng Gu

Yingyue Yin

Jun Song

Zhenhua Zhang

Profile image of Shwe Soe

Dr Shwe Soe Shwe.Soe@uwe.ac.uk
Associate Professor in Digital Manufacturing



Abstract

Nickel-based superalloys such as Hastelloy X (HX) are widely used in gas turbine engines for their exceptional oxidation resistance and high-temperature strength. The addition of ceramic reinforcement further enhances these superalloys’ mechanical performance and high-temperature properties. For this reason, this paper investigates the microstructure and mechanical property of laser powder bed fusion (LPBF) additively manufactured HX–1 wt% WC (tungsten carbide) composite specimens. The results demonstrate that the LPBF-fabricated composite was observed to have several pores and microcracks, whilst only pores were detected in the as-fabricated pure HX. Compared to the fabricated pure HX, the tensile yield strength of such HX composite parts was increased by 13% without undue sacrifices to ductility, suggesting that the very limited number of microcracks were not sufficient to degrade the mechanical performance. The significantly increased dislocations were considered to be the primary contributor for the mechanical performance enhancement in the LPBF-fabricated composite material. The findings offer a promising pathway to employ LPBF process to fabricate advanced microcrack-free composites with high-strength through a careful selection of ceramic reinforcement materials.

Journal Article Type Article
Acceptance Date Sep 4, 2020
Online Publication Date Sep 21, 2020
Publication Date 2021
Deposit Date Oct 12, 2020
Publicly Available Date Sep 22, 2021
Journal Journal of Materials Science
Print ISSN 0022-2461
Electronic ISSN 1573-4803
Publisher Springer Verlag
Peer Reviewed Peer Reviewed
Volume 56
Pages 1768-1782
DOI https://doi.org/10.1007/s10853-020-05327-6
Keywords Mechanical Engineering; General Materials Science; Mechanics of Materials
Public URL https://uwe-repository.worktribe.com/output/6706608
Additional Information Received: 14 June 2020; Accepted: 3 September 2020; First Online: 21 September 2020; : ; : The paper has no conflict of interest in any person or organisation.

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