Litcius/Paper detail

Transient dynamics and stability of keyhole at threshold in laser powder bed fusion regime investigated by finite element modeling

Yaasin Mayi, Morgan Dal, Patrice Peyre, Michel Bellet, Charlotte Metton, Clara Moriconi, R. Fabbro

2020Journal of Laser Applications21 citationsDOIOpen Access PDF

Abstract

A Finite element model is developed with a commercial code to investigate the keyhole dynamics and stability at keyhole threshold, a fusion regime characteristic to laser microwelding or to Laser Powder Bed Fusion. The model includes relevant physics to treat the hydrodynamic problems—surface tension, Marangoni stress, and recoil pressure—as well as a self-consistent ray-tracing algorithm to account for the “beam-trapping” effect. Implemented in both static and scanning laser configurations, the model successfully reproduces some key features that most recent x-ray images have exhibited. The dynamics of the liquid/gas interface is analyzed, in line with the distribution of the absorbed intensity as well as with the increase of the keyhole energy coupling. Based on these results, new elements are provided to discuss our current understanding of the keyhole formation and stability at threshold.

Topics & Concepts

KeyholeMarangoni effectMaterials scienceFinite element methodMechanicsLaserSurface tensionTransient (computer programming)FusionRay tracing (physics)OpticsComposite materialThermodynamicsPhysicsWeldingPhilosophyOperating systemComputer scienceLinguisticsAdditive Manufacturing Materials and ProcessesLaser Material Processing TechniquesWelding Techniques and Residual Stresses