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Metal Additive Manufacturing using complex beam shaping

T. U. Tumkur, Gabe Guss, John D. Roehling, Saad A. Khairallah, Manyalibo J. Matthews

2022Procedia CIRP20 citationsDOIOpen Access PDF

Abstract

Large thermal gradients, complex melt pool instabilities and poor absorptivity are application-limiting detriments in laser powder bed fusion-enabled metal additive manufacturing (AM), ultimately resulting in poor mechanical properties. Current approaches to improving the mechanical robustness of structures printed using metal additive manufacturing (AM) come at the expense of print reliability, consistency cost and integrability. Here, we employ laser beams shaped in amplitude, phase and polarization, to deliver controlled optothermal profiles on the powder bed. Unique optical properties of such beams (such as non-diffractive propagation) result in an improved combination of reduced porosity, increased part density, lower surface roughness and robust tensile properties across a broad scan parameter range, compared to conventional beams. We employ Multiphysics simulations and highspeed imaging for feedback and validation for printing SS 316L.

Topics & Concepts

Materials scienceMultiphysicsLaserPorositySurface roughnessRobustness (evolution)ThermalFusionSurface finishSelective laser meltingComposite materialOpticsMicrostructureFinite element methodStructural engineeringEngineeringPhysicsChemistryBiochemistryPhilosophyGeneLinguisticsMeteorologyAdditive Manufacturing Materials and ProcessesLaser Material Processing TechniquesAdditive Manufacturing and 3D Printing Technologies
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