A growing library of three-dimensional cohesive elements for use in ABAQUS

•We develop a set of three-dimensional cohesive elements for use in ABAQUS.•The cohesive elements follow a very adaptable nonlinear traction–separation relation.•We present a series of modifications to make the elements more useful to the user.•We present examples which undergo both small- and large...

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Bibliographic Details
Published in:Engineering fracture mechanics 2014-08, Vol.126, p.190-216
Main Authors: Spring, Daniel W., Paulino, Glaucio H.
Format: Article
Language:English
Subjects:
3D cohesive elements
ABAQUS
Cohesion
Computer simulation
Deformation
Finite deformation
Finite element method
Libraries
Mathematical analysis
Mathematical models
PPR Cohesive model
Three dimensional
UEL
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Summary:•We develop a set of three-dimensional cohesive elements for use in ABAQUS.•The cohesive elements follow a very adaptable nonlinear traction–separation relation.•We present a series of modifications to make the elements more useful to the user.•We present examples which undergo both small- and large-deformation.•The paper is written from an educational perspective. In this paper, we present the implementation of a small library of three-dimensional cohesive elements. The elements are formatted as user-defined elements, for compatibility with the commercial finite element software ABAQUS. The PPR, potential-based traction–separation relation is chosen to describe the element’s constitutive model. The intrinsic cohesive formulation is outlined due to its compatibility with the standard, implicit finite element framework present in ABAQUS. The implementation of the cohesive elements is described, along with instructions on how to incorporate the elements into a finite element mesh. Specific areas of the user-defined elements, in which the user may wish to modify the code to meet specific research needs, are highlighted. Numerical examples are provided which display the capabilities of the elements in both small deformation and finite deformation regimes. A sample element source code is provided in an appendix, and the source codes of the elements are supplied through the website of the research group of the authors.
ISSN:0013-7944
1873-7315
DOI:10.1016/j.engfracmech.2014.04.004