A new fatigue frictional contact crack propagation model with the coupled X-FEM/LATIN method
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Publication:1033244
DOI10.1016/j.cma.2007.03.004zbMath1173.74385OpenAlexW2015688105MaRDI QIDQ1033244
R. Ribeaucourt, Anthony Gravouil, Marie-Christine Baietto
Publication date: 6 November 2009
Published in: Computer Methods in Applied Mechanics and Engineering (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.cma.2007.03.004
Friction in solid mechanics (74M10) Contact in solid mechanics (74M15) Brittle fracture (74R10) Finite element methods applied to problems in solid mechanics (74S05)
Related Items (22)
Large deformation frictional contact analysis with immersed boundary method ⋮ Stabilized global-local X-FEM for 3D non-planar frictional crack using relevant meshes ⋮ An enrichment-based approach for the simulation of fretting problems ⋮ Extended finite element method for fretting fatigue crack propagation ⋮ CutFEM Method for Stefan--Signorini Problems with Application in Pulsed Laser Ablation ⋮ Development of X-FEM methodology and study on mixed-mode crack propagation ⋮ A weighted Nitsche stabilized method for small-sliding contact on frictional surfaces ⋮ Toward an optimal a priori reduced basis strategy for frictional contact problems with LATIN solver ⋮ A multiscale large time increment/FAS algorithm with time-space model reduction for frictional contact problems ⋮ Crack face contact for a hexahedral-based XFEM formulation ⋮ A computational framework for crack propagation along contact interfaces and surfaces under load ⋮ A stochastic LATIN method for stochastic and parameterized elastoplastic analysis ⋮ A two-scale extended finite element method for modelling 3D crack growth with interfacial contact ⋮ A novel constrained LArge Time INcrement method for modelling quasi-brittle failure ⋮ A PGD-based homogenization technique for the resolution of nonlinear multiscale problems ⋮ A node-to-node scheme for three-dimensional contact problems using the scaled boundary finite element method ⋮ Crack face contact in X-FEM using a segment-to-segment approach ⋮ A contact algorithm for frictional crack propagation with the extended finite element method ⋮ A multi-model X-FEM strategy dedicated to frictional crack growth under cyclic fretting fatigue loadings ⋮ A local multigrid X-FEM strategy for 3-D crack propagation ⋮ A state-of-the-art review of the X-FEM for computational fracture mechanics ⋮ A finite element framework for modeling internal frictional contact in three-dimensional fractured media using unstructured tetrahedral meshes
Cites Work
- Unnamed Item
- Unnamed Item
- Domain integral formulation for stress intensity factor computation along curved three-dimensional interface cracks
- Modelling of growth of three-dimensional cracks by a continuous distribution of dislocation loops
- The partition of unity finite element method: basic theory and applications
- Appropriate extended functions for X-FEM simulation of plastic fracture mechanics
- An energy-conserving scheme for dynamic crack growth using the eXtended finite element method
- Level set X-FEM non-matching meshes: application to dynamic crack propagation in elastic–plastic media
- A mixed augmented Lagrangian-extended finite element method for modelling elastic–plastic fatigue crack growth with unilateral contact
- A Mixed-Mode Crack Analysis of Isotropic Solids Using Conservation Laws of Elasticity
- Elastic crack growth in finite elements with minimal remeshing
- Extended finite element method for three-dimensional crack modelling
- Arbitrary branched and intersecting cracks with the extended finite element method
- Non-planar 3D crack growth by the extended finite element and level sets-Part I: Mechanical model
- A finite element method for crack growth without remeshing
- The growth of slip surfaces in the progressive failure of over-consolidated clay
- An extended finite element method for modeling crack growth with frictional contact.
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