A meshfree computational framework for the numerical simulation of the solid -state additive manufacturing process, additive friction stir-deposition (AFS- D)

In this work, a fully coupled thermo-mechanical meshfree approach is developed for the first time to simulate a solid-state layer-by-layer additive manufacturing process, Additive Friction Stir-Deposition (AFS-D). The meshfree method in this present work uses a Lagrangian reference frame, which permits tracking of material point history. A solid mechanics formulation is used, allowing the resolution of both elastic and plastic strains. An explicit dynamics time stepping scheme is used to ensure that the code is robust for the large level of non-linearity native to the AFS-D process. In this present work, a description of the meshfree method will first be described. Then a new thermo-mechanical joining contact algorithm will be introduced. Following that, a de-scription of the experimental setup for the AFS-D model calibration experimental one layer deposition cases is explained. Subsequently, the simulation model and results for three different parameter sets will be detailed and compared against the experimental results. Finally, temperature and strain rate gradients are revealed across the entire deposition elucidating spatial-temporal flow phenomena in the AFS-D process. ? 2021 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http:// creativecommons.org/licenses/by-nc-nd/4.0/).

Automated summary

In this work, a fully coupled thermo-mechanical meshfree approach is developed for simulating the solid-state layer-by-layer additive manufacturing process AFS-D. The method uses a Lagrangian reference frame and solid mechanics formulation to resolve elastic and plastic strains. The simulation results are compared against experimental results for calibration, revealing temperature and strain rate gradients in the AFS-D process.