Modeling of concrete cracking—A hybrid technique of using displacement discontinuity element method and direct boundary element method

This paper presents a new approach by making use of a hybrid method of using the displacement discontinuity element method and direct boundary element method to model concrete cracking by incorporating fictitious crack model. Fracture mechanics approach is followed using the Hillerborg's fictit...

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Bibliographic Details
Published in:Engineering analysis with boundary elements 2011-09, Vol.35 (9), p.1054-1059
Main Authors: Ameen, Mohammed, Raghu Prasad, B.K., Gopalakrishnan, A.R.
Format: Article
Language:English
Subjects:
Applied sciences
Boundary element method
Building structure
Buildings. Public works
Concrete structure
Concretes
Construction (buildings and works)
Cracking (fracturing)
Discontinuity
Displacement
Exact sciences and technology
Fracture mechanics
Fracture mechanics (crack, fatigue, damage...)
Fundamental areas of phenomenology (including applications)
Mathematical analysis
Mathematical models
Physics
Solid mechanics
Structural and continuum mechanics
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Summary:This paper presents a new approach by making use of a hybrid method of using the displacement discontinuity element method and direct boundary element method to model concrete cracking by incorporating fictitious crack model. Fracture mechanics approach is followed using the Hillerborg's fictitious crack model. A boundary element based substructure method and a hybrid technique of using displacement discontinuity element method and direct boundary element method are compared in this paper. In order to represent the process zone ahead of the crack, closing forces are assumed to act in such a way that they obey a linear normal stress-crack opening displacement law. Plain concrete beams with and without initial crack under three-point loading were analyzed by both the methods. The numerical results obtained were shown to agree well with the results from existing finite element method. The model is capable of reproducing the whole range of load–deflection response including strain-softening and snap-back behavior as illustrated in the numerical examples.
ISSN:0955-7997
1873-197X
DOI:10.1016/j.enganabound.2011.03.009