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Ti-6Al-4V hollow-strut lattice materials by laser powder bed fusion

Jordan Noronha, Jason Rogers, Martin Leary, E. Kyriakou, S. B. Inverarity, Raj Das, Milan Brandt, Ma Qian

2023Additive manufacturing52 citationsDOIOpen Access PDF

Abstract

Hollow-strut metal lattices are an emerging class of cellular metallic materials. However, their mechanical properties at relative densities (ρRD) higher than 10% are largely unknown because conventional manufacturing methods are ill-equipped to fabricate them. In this study, face-centered cubic (FCC) and FCC with Z-struts (FCCZ) Ti‐6Al‐4V hollow-strut lattices with ρRD = 8–16% were fabricated using laser powder bed fusion (LPBF) additive manufacturing (AM). Both lattice topologies exhibited yield strength (σ*) and elastic modulus (E*) at the upper empirical limits for solid-strut metal lattices with similar ρRD values. Furthermore, the difference in σ* or E* between hollow-strut FCC and FCCZ lattices is much smaller than that between solid-strut FCC and FCCZ lattices. The deformation behaviours and failure modes of the LPBF-manufactured Ti‐6Al‐4V hollow-strut FCC and FCCZ lattices were investigated by uniaxial compression and finite element modelling (FEM). In addition to the lattice topology, the fine (∼20 µm) prior-β grains in the Ti‐6Al‐4V hollow-strut thin walls contribute positively to the superior mechanical properties, compared with the coarse grains in Ti‐6Al‐4V solid-strut lattices. Finally, the manufacturability established in this work provides a reliable pathway for LPBF-AM of Ti‐6Al‐4V hollow-strut lattices. The findings of this work are expected to apply to other hollow-strut lattice topologies.

Topics & Concepts

Materials scienceLattice (music)FusionTitanium alloyFinite element methodComposite materialDesign for manufacturabilitySelective laser meltingModulusStructural engineeringMicrostructureAlloyMechanical engineeringPhilosophyEngineeringPhysicsLinguisticsAcousticsCellular and Composite StructuresAdditive Manufacturing and 3D Printing TechnologiesAdditive Manufacturing Materials and Processes