A Third-Order Moving Mesh Cell-Centered Scheme for One-Dimensional Elastic-Plastic Flows

TL;DR

This paper introduces a third-order moving mesh cell-centered scheme for one-dimensional elastic-plastic flows that adaptively concentrates mesh points around waves, achieving high accuracy without remapping of variables.

Contribution

It develops a novel third-order moving mesh scheme combining Lagrangian and MMPDE methods, improving wave resolution and avoiding mesh tangling in elastic-plastic flow simulations.

Findings

Demonstrates third-order convergence of the scheme.

Shows improved accuracy over existing Lagrangian schemes.

Successfully resolves shock and rarefaction waves with adaptive mesh.

Abstract

A third-order moving mesh cell-centered scheme without the remapping of physical variables is developed for the numerical solution of one-dimensional elastic-plastic flows with the Mie-Gr\"{u}neisen equation of state, the Wilkins constitutive model, and the von Mises yielding criterion. The scheme combines the Lagrangian method with the MMPDE moving mesh method and adaptively moves the mesh to better resolve shock and other types of waves while preventing the mesh from crossing and tangling. It can be viewed as a direct arbitrarily Lagrangian-Eulerian method but can also be degenerated to a purely Lagrangian scheme. It treats the relative velocity of the fluid with respect to the mesh as constant in time between time steps, which allows high-order approximation of free boundaries. A time dependent scaling is used in the monitor function to avoid possible sudden movement of the mesh points due to the creation or diminishing of shock and rarefaction waves or the steepening of those waves. A two-rarefaction Riemann solver with elastic waves is employed to compute the Godunov values of the density, pressure, velocity, and deviatoric stress at cell interfaces. Numerical results are presented for three examples. The third-order convergence of the scheme and its ability to concentrate mesh points around shock and elastic rarefaction waves are demonstrated. The obtained numerical results are in good agreement with those in literature. The new scheme is also shown to be more accurate in resolving shock and rarefaction waves than an existing third-order cell-centered Lagrangian scheme.