Evaporation model for keyhole dynamics during additive manufacturing of metal

Abstract: The molten-pool flow, particularly the keyhole effect, plays a critical role in the formation of defects in additive-manufacturing and welding processes. In this study, we derive an evaporation model for metal alloys considering the gas-flow structure and material composition and implement it in a multiphysics thermal-fluid flow model, which utilizes the volume of fluid (VOF) in the finite volume method (FVM) to capture free surfaces and the ray-tracing method to track multireflections of laser within the keyhole. The current derived evaporation model is validated against in situ x-ray imaging results via multiple cases: (1) stationary laser melting of a Ti−6Al−4V base plate under 1-atm ambient pressure, (2) stationary laser melting of a 304L stainless-steel base plate under 0.0002-atm ambient pressure, (3) laser scanning of a Ti−6Al−4V base plate under 1-atm ambient pressure. The simulation results indicate that our evaporation model is applicable for both common and near-vacuum environment, while Anisimov’s evaporation model, which is widely used in keyhole simulation, is unsuitable in near-vacuum keyhole simulation. Moreover, the absorbed energy distribution, recoil pressure, z-direction recoil force and keyhole growth are analyzed in the simulations.

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Recommended citation: Wang, Lu, Yanming Zhang, and Wentao Yan. “Evaporation model for keyhole dynamics during additive manufacturing of metal.” Physical Review Applied 14.6 (2020): 064039.