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Kleijn, Chris
Delft University of Technology
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (6/6 displayed)
- 2021The Effects of Process Parameters on Melt-pool Oscillatory Behaviour in Gas Tungsten Arc Weldingcitations
- 2021A simulation-based approach to characterise melt-pool oscillations during gas tungsten arc weldingcitations
- 2021Modeling of a continuous physical vapor deposition processcitations
- 2021The Effect of Groove Shape on Molten Metal Flow Behaviour in Gas Metal Arc Weldingcitations
- 2018Revealing internal flow behaviour in arc welding and additive manufacturing of metalscitations
- 2016Marangoni driven turbulence in high energy surface melting processescitations
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article
Marangoni driven turbulence in high energy surface melting processes
Abstract
<p>Experimental observations of high-energy surface melting processes, such as laser welding, have revealed unsteady, often violent, motion of the free surface of the melt pool. Surprisingly, no similar observations have been reported in numerical simulation studies of such flows. Moreover, the published simulation results fail to predict the post-solidification pool shape without adapting non-physical values for input parameters, suggesting the neglect of significant physics in the models employed. The experimentally observed violent flow surface instabilities, scaling analyses for the occurrence of turbulence in Marangoni driven flows, and the fact that in simulations transport coefficients generally have to be increased by an order of magnitude to match experimentally observed pool shapes, suggest the common assumption of laminar flow in the pool may not hold, and that the flow is actually turbulent. Here, we use direct numerical simulations (DNS) to investigate the role of turbulence in laser melting of a steel alloy with surface active elements. Our results reveal the presence of two competing vortices driven by thermocapillary forces towards a local surface tension maximum. The jet away from this location at the free surface, separating the two vortices, is found to be unstable and highly oscillatory, indeed leading to turbulence-like flow in the pool. The resulting additional heat transport, however, is insufficient to account for the observed differences in pool shapes between experiment and simulations.</p>