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A conservation law consistent updated Lagrangian material point method for dynamic analysis

Giuliano Pretti, William M. Coombs, Charles E. Augarde, Bradley Sims, Marc Marchena Puigvert, José Antonio Reyna Gutiérrez

2023Journal of Computational Physics16 citationsDOIOpen Access PDF

Abstract

The Material Point Method (MPM) is well suited to modelling dynamic solid mechanics problems undergoing large deformations with non-linear, history dependent material behaviour. However, the vast majority of existing material point method implementations do not inherit conservation properties (momenta and energy) from their continuum formulations. This paper provides, for the first time, a dynamic updated Lagrangian material point method for elasto-plastic materials undergoing large deformation that guarantees momenta and energy conservation. Sources of energy dissipation during point-to-grid and grid-to-point mappings for FLuid Implicit Particle (FLIP) and Particle In Cell (PIC) approaches are clarified and a novel time-stepping approach is proposed based on an efficient approximation of the Courant-Friedrich-Lewy (CFL) condition. The formulation provided in this paper offers a platform for understanding the energy conservation nature of future/existing features of material point methods, such as contact approaches.

Topics & Concepts

Material point methodConservation lawConservation of energyEnergy conservationDissipationPoint (geometry)GridPoint particleApplied mathematicsLagrangianComputer scienceContinuum mechanicsMaterial propertiesMathematical optimizationClassical mechanicsMathematicsPhysicsMathematical analysisFinite element methodEngineeringGeometryStructural engineeringThermodynamicsQuantum mechanicsElectrical engineeringFluid Dynamics Simulations and InteractionsLattice Boltzmann Simulation StudiesFluid Dynamics and Heat Transfer
A conservation law consistent updated Lagrangian material point method for dynamic analysis | Litcius