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Fracture modelling of plain concrete using non-local fracture mechanics and a graph-based computational framework

P. Thamburaja, K. Sarah, Arun R. Srinivasa, J. N. Reddy

2021Proceedings of the Royal Society A Mathematical Physical and Engineering Sciences19 citationsDOIOpen Access PDF

Abstract

In this article, we developed a thermodynamically consistent non-local microcracking model for quasi-brittle materials with application to concrete. The model is implemented using a novel graph-based finite element analysis (GraFEA) approach that allows for (i) the probabilistic modeling of the growth and coalescence of microcracks, (ii) the modeling of crack closure using a kinematics-based approach, and (iii) the modeling of rate effects on microcracking. The developed theoretical model and its computational framework is also implemented into the dynamics-based Abaqus/Explicit finite element program through a vectorized user-material subroutine interface. We further demonstrate the procedure for obtaining the parameters (including the non-local intrinsic material length scale, which governs the fracture process) and consequently validate the simulations with independent experimental results.

Topics & Concepts

SubroutineFinite element methodCoalescence (physics)Computer scienceBrittlenessKinematicsFracture mechanicsProbabilistic logicStructural engineeringAlgorithmMaterials scienceEngineeringComposite materialPhysicsArtificial intelligenceProgramming languageClassical mechanicsAstrobiologyNumerical methods in engineeringRock Mechanics and ModelingGeotechnical Engineering and Underground Structures
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