CONSTANTIN, Loic; KRAIEM, Nada; WU, Zhipeng; CUI, Bai; BATTAGLIA, Jean-Luc; GARNIER, Christian; SILVAIN, Jean-François; LU, Yong Feng

doi:10.1016/j.addma.2021.101927

Metadata

License

CONSTANTIN, Loic
Institut de Chimie de la Matière Condensée de Bordeaux [ICMCB]
Department of Electrical and Computer Engineering

KRAIEM, Nada
Institut de Chimie de la Matière Condensée de Bordeaux [ICMCB]
Department of Electrical and Computer Engineering

WU, Zhipeng
Department of Electrical and Computer Engineering

Language

Article de revue

This item was published in

Additive Manufacturing. 2021-02-01, vol. 40, p. 101927 (9 p.)

Elsevier

English Abstract

Manufacturing complex metal matrix composite (MMC) structures by laser powder-bed fusion (LPBF) could unleash their full potential but is difficult due to the presence of reinforcement. Unmelted particles negatively affect the pool dynamics, cause critical spatter ejections, and form printing defects. In this work, by taking copper (Cu) / diamond (D) composite as an example for its prospective thermal management applications and machinability limitations; we discovered that adding steps to LPBF enables the fabrication of high-quality materials and structures. We demonstrated that adding a recoating step improves the composite quality compared to structures manufactured by conventional LPBF. Adding a remelting step enabled further improvement by limiting the generation of spatter and printing defects, leading to 3D laser print dense (97%), highly thermally conductive (349 W/m K) and complex Cu/5 vol% D structures. Therefore, pursuing research into nonconventional LPBF could open new avenues for manufacturing MMCs.Read less <

English Keywords

Additive manufacturing

Copper

Diamond

Selective laser melting

Metal matrix composites

Metadata

License

Manufacturing of complex diamond-based composite structures via laser powder-bed fusion

Language

This item was published in

English Abstract

English Keywords

DOI

Origin

Collections