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A semi-Lagrangian reproducing kernel particle method with particle-based shock algorithm for explosive welding simulation

Jonghyuk Baek, Jiun‐Shyan Chen, Guohua Zhou, Kevin Arnett, Michael Hillman, G. A. Hegemier, Scott Hardesty

2021Computational Mechanics20 citationsDOIOpen Access PDF

Abstract

Abstract The explosive welding process is an extreme-deformation problem that involves shock waves, large plastic deformation, and fragmentation around the collision point, which are extremely challenging features to model for the traditional mesh-based methods. In this work, a particle-based Godunov shock algorithm under a semi-Lagrangian reproducing kernel particle method (SL-RKPM) is introduced into the volumetric strain energy to accurately embed the key shock physics in the absence of a mesh or grid, which is shown to also ensure the conservation of linear momentum. For kernel stability, a deformation-dependent anisotropic kernel support update algorithm is proposed, which is shown to capture excessive plastic flow and material separation. A quasi-conforming nodal integration is adopted to avoid the need of updating conforming cells which is tedious in extreme deformations. It is shown that the proposed formulation effectively captures shocks, jet formation, and smooth-to-wavy interface morphology transition with good agreement with experimental results.

Topics & Concepts

Explosion weldingShock (circulatory)MechanicsParticle methodKernel (algebra)AlgorithmShock waveExplosive materialComputer scienceMathematicsClassical mechanicsApplied mathematicsPhysicsMathematical analysisWeldingMechanical engineeringEngineeringBoundary value problemArc weldingOrganic chemistryChemistryCombinatoricsInternal medicineFiller metalMedicineNumerical methods in engineeringFluid Dynamics Simulations and InteractionsHigh-Velocity Impact and Material Behavior