Litcius/Paper detail

An extended/generalized phase‐field finite element method for crack growth with global‐local enrichment

Rudy Geelen, Julia Plews, Michael Tupek, John E. Dolbow

2020International Journal for Numerical Methods in Engineering45 citationsDOIOpen Access PDF

Abstract

Summary An extended/generalized finite element method (XFEM/GFEM) for simulating quasistatic crack growth based on a phase‐field method is presented. The method relies on approximations to solutions associated with two different scales: a global scale, that is, structural and discretized with a coarse mesh, and a local scale encapsulating the fractured region, that is, discretized with a fine mesh. A stable XFEM/GFEM is employed to embed the displacement and damage fields at the global scale. The proposed method accommodates approximation spaces that evolve between load steps, while preserving a fixed background mesh for the structural problem. In addition, a prediction‐correction algorithm is employed to facilitate the dynamic evolution of the confined crack regions within a load step. Several numerical examples of benchmark problems in two‐ and three‐dimensional quasistatic fracture are provided to demonstrate the approach.

Topics & Concepts

Quasistatic processDiscretizationExtended finite element methodFinite element methodBenchmark (surveying)Displacement fieldApplied mathematicsDisplacement (psychology)MathematicsField (mathematics)Structural engineeringMathematical optimizationComputer scienceMathematical analysisEngineeringPhysicsGeologyQuantum mechanicsPsychotherapistPsychologyPure mathematicsGeodesyNumerical methods in engineeringAdvanced Numerical Methods in Computational MathematicsComposite Material Mechanics
An extended/generalized phase‐field finite element method for crack growth with global‐local enrichment | Litcius