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Multi-Scale Modeling of Residual Stresses Evolution in Laser Powder Bed Fusion of Inconel 625

Mohamed Balbaa, M.A. Elbestawi

2021Journal of Manufacturing and Materials Processing22 citationsDOIOpen Access PDF

Abstract

Laser powder bed fusion exhibits many advantages for manufacturing complex geometries from hard to machine alloys such as IN625. However, a major drawback is the formation of high tensile residual stresses, and the complex relationship between the process parameters and the residual stresses has not been fully investigated. The current study presents multi-scale models to examine the variation of process parameters on melt pool dimensions, cyclic temperature evolutions, cooling rate, and cyclic stress generation and how they affect the stress end state. In addition, the effect of the same energy density, which is often overlooked, on the generated residual stresses is investigated. Multi-level validation is performed based on melt pool dimensions, temperature measurements with a two-color pyrometer, and finally, in-depth residual stress measurement. The results show that scan speed has the strongest effect on residual stresses, followed by laser power and hatch spacing. The results are explained in light of the non-linear temperature evolution, temperature gradient, and cooling rate during laser exposure, cooling time, and the rate during recoating time.

Topics & Concepts

Residual stressMaterials scienceInconel 625FusionLaserResidualPyrometerComposite materialUltimate tensile strengthStress (linguistics)MetallurgyTemperature measurementOpticsMicrostructureThermodynamicsAlgorithmPhilosophyComputer scienceLinguisticsPhysicsAdditive Manufacturing Materials and ProcessesAdditive Manufacturing and 3D Printing TechnologiesWelding Techniques and Residual Stresses
Multi-Scale Modeling of Residual Stresses Evolution in Laser Powder Bed Fusion of Inconel 625 | Litcius