Version 2.0 — LaserbeamFoam: Laser ray-tracing and thermally induced state transition simulation toolkit

Version 2.0 — LaserbeamFoam: Laser ray-tracing and thermally induced state transition simulation toolkit

In this update to the laserbeamFoam toolbox, a multi-component version of the solver is included with pair-wise Fickian Diffusion between selected component pairs. This new solver, multiComponentlaserbeamFoam, captures the multi-component nature of mixing between alloys, and as-such could be used to...

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Bibliographic Details
Main Authors: Thomas F. Flint, Joseph D. Robson, Parsa Esmati, Nicolò Grilli, Gowthaman Parivendhan, Philip Cardiff
Format: Article
Language:English
Published: Elsevier 2024-02-01
Series:SoftwareX
Subjects:
Thermal-fluid-dynamics
Multi-component
Laser-deposition
Online Access:http://www.sciencedirect.com/science/article/pii/S2352711023003084
Description
Summary:In this update to the laserbeamFoam toolbox, a multi-component version of the solver is included with pair-wise Fickian Diffusion between selected component pairs. This new solver, multiComponentlaserbeamFoam, captures the multi-component nature of mixing between alloys, and as-such could be used to simulate dissimilar laser joining processes, and dissimilar laser-powder-bed additive manufacturing, among others. Additionally a multi-laser version of the original laserbeamFoam solver is included (arraylaserbeamFoam) that can simulate N incident laser sources on a metallic substrate, where the direction, velocity, and other laser characteristics can be specified independently. In both these solvers, as in the original laserbeamFoam solver, the phenomenological recoil pressure treatment is used, as opposed to the full volumetric dilation treatment, for computational tractability.
ISSN:2352-7110

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