Your search keyword '"Chitalu, Floyd M."' showing total 2 results

1. Simulating Brittle Fracture with Material Points.

Author

Fan, Linxu, Chitalu, Floyd M., and Komura, Taku

Subjects

BRITTLE material fracture, CONTINUUM damage mechanics, BRITTLE fractures, SURFACE cracks, CRACK propagation (Fracture mechanics)

Abstract

Large-scale topological changes play a key role in capturing the fine debris of fracturing virtual brittle material. Real-world, tough brittle fractures have dynamic branching behaviour but numerical simulation of this phenomena is notoriously challenging. In order to robustly capture these visual characteristics, we simulate brittle fracture by combining elastodynamic continuum mechanical models with rigid-body methods: A continuum damage mechanics (CDM) problem is solved, following rigid-body impact, to simulate crack propagation by tracking a damage field. We combine the result of this elastostatic continuum model with a novel technique to approximate cracks as a non-manifold mid-surface, which enables accurate and robust modelling of material fragment volumes to compliment fast-and-rigid shatter effects. For enhanced realism, we add fracture detail, incorporating particle damage-time to inform localised perturbation of the crack surface with artistic control. We evaluate our method with numerous examples and comparisons, showing that it produces a breadth of brittle material fracture effects and with low simulation resolution to require much less time compared to fully elastodynamic simulations. [ABSTRACT FROM AUTHOR]

Published

2022

2. Displacement‐Correlated XFEM for Simulating Brittle Fracture.

Author

Chitalu, Floyd M., Miao, Qinghai, Subr, Kartic, and Komura, Taku

Subjects

*BRITTLE fractures, *LINEAR elastic fracture mechanics, *ALGORITHMS, *SURFACE cracks, *FINITE element method, *LAGRANGIAN functions, *DEFORMATION of surfaces

Abstract

We present a remeshing‐free brittle fracture simulation method under the assumption of quasi‐static linear elastic fracture mechanics (LEFM). To achieve this, we devise two algorithms. First, we develop an approximate volumetric simulation, based on the extended Finite Element Method (XFEM), to initialize and propagate Lagrangian crack‐fronts. We model the geometry of fracture explicitly as a surface mesh, which allows us to generate high‐resolution crack surfaces that are decoupled from the resolution of the deformation mesh. Our second contribution is a mesh cutting algorithm, which produces fragments of the input mesh using the fracture surface. We do this by directly operating on the half‐edge data structures of two surface meshes, which enables us to cut general surface meshes including those of concave polyhedra and meshes with abutting concave polygons. Since we avoid triangulation for cutting, the connectivity of the resulting fragments is identical to the (uncut) input mesh except at edges introduced by the cut. We evaluate our simulation and cutting algorithms and show that they outperform state‐of‐the‐art approaches both qualitatively and quantitatively. [ABSTRACT FROM AUTHOR]

Published

2020