General cracked-hinge model for simulation of low-cycle damage in cemented beams on soil

•The cracked-hinge model adequately describe the low-cyclic behaviour of concrete.•Implementation of the hinge into a beam element is straightforward.•The proposed hinge comply well with the cohesive zone model.•The soil foundation has significant influence on the structural response. The need for m...

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Bibliographic Details
Published in:Engineering fracture mechanics 2017-04, Vol.175, p.324-338
Main Authors: Skar, Asmus, Poulsen, Peter Noe, Olesen, John Forbes
Format: Article
Language:English
Subjects:
Cement constituents
Cemented materials
Cementing
Cohesive crack
Computer simulation
Constitutive models
Crack propagation
Cracks
Fracture mechanics
Linear analysis
Low-cyclic fatigue
Mathematical models
Non-linear FEM
Nonlinear analysis
Pavement analysis
Soils
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Summary:•The cracked-hinge model adequately describe the low-cyclic behaviour of concrete.•Implementation of the hinge into a beam element is straightforward.•The proposed hinge comply well with the cohesive zone model.•The soil foundation has significant influence on the structural response. The need for mechanistic constitutive models to evaluate the complex interaction between concrete crack propagation, geometry and soil foundation in concrete- and composite pavement systems has been recognized. Several models developed are either too complex or designed to solve relatively simple problems, e.g. limited to one type of load configuration or test set-up. In order to develop a general and mechanistic modeling framework for non-linear analysis of low-cycle damage in cemented materials, this paper presents a cracked-hinge model aimed at the analysis of the bending fracture of the cemented material. The model is based on the fracture mechanics concepts of the fictitious crack model. The proposed hinge is described in a general and consistent format, allowing for any type of stress-crack opening relationship and unloading- reloading formulation. The functionality of the proposed hinge model is compared to numerical- and experimental results. The proposed hinge shows good performance and seems promising for the description of low-cycle fracture behavior in cemented materials.
ISSN:0013-7944
1873-7315
DOI:10.1016/j.engfracmech.2017.01.016