An efficient FE–SBFE coupled method for mesoscale cohesive fracture modelling of concrete

This study develops a method coupling the finite element method (FEM) and the scaled boundary finite element method (SBFEM) for efficient meso-scale fracture modelling of concrete for the first time. In this method, the aggregates are modelled by SBFE polygons with boundaries discretised only, while...

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Bibliographic Details
Published in:Computational mechanics 2016-10, Vol.58 (4), p.635-655
Main Authors: Huang, Y. J., Yang, Z. J., Liu, G. H., Chen, X. W.
Format: Article
Language:English
Subjects:
Classical and Continuum Physics
Computational Science and Engineering
Computed tomography
Computing time
Concrete
Concrete aggregates
Engineering
Finite element analysis
Finite element method
Laws, regulations and rules
Mesoscale phenomena
Methods
Modelling
Mortars (material)
Original Paper
Theoretical and Applied Mechanics
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Summary:This study develops a method coupling the finite element method (FEM) and the scaled boundary finite element method (SBFEM) for efficient meso-scale fracture modelling of concrete for the first time. In this method, the aggregates are modelled by SBFE polygons with boundaries discretised only, while the mortar matrix is modelled by conventional finite elements. The semi-analytical SBFEM is implemented in ABAQUS by a user-defined element subroutine for the first time. Nonlinear cohesive interface elements with normal and shear traction-separation constitutive laws are pre-inserted within the mortar and on the aggregate-mortar interfaces to simulate potential cracks. Various meso-structures generated from both random aggregates and X-ray computed tomography images are modelled. The results demonstrate that the coupled method leads to considerable reductions in degrees of freedom and computational time against the conventional FEM, and these reductions become more significant when the aggregate volume fraction increases. The modelled crack paths and load-carrying capacities of a three-point bending beam and an L-shaped panel are in excellent agreement with the experimental data.
ISSN:0178-7675
1432-0924
DOI:10.1007/s00466-016-1309-8