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Experimentally validated meso-scale fracture modelling of mortar using output from micromechanical models

Hongzhi Zhang, Yading Xu, Yidong Gan, Erik Schlangen, Branko Šavija

2020Cement and Concrete Composites43 citationsDOIOpen Access PDF

Abstract

This paper presents a validation process of the developed multi-scale modelling scheme on mortar composites. Special attention was paid to make the material structure of real and virtual mortar specimens comparable at the meso-scale. The input mechanical parameters of cement paste (both bulk cement paste and interfacial transition zone) at the meso-scale were derived from results of micromechanical modelling through a volume averaging approach. Two constitutive relations for local elements were assumed and tested. By comparing with the experiments, the model using linear-elastic constitutive relation showed to be capable to reproduce the experimental load-displacement response satisfactorily in terms of the elastic stage and peak load. However, in the non-elastic stage a more realistic load-displacement curve can be simulated by considering the softening of cement paste using a step-wise approach. More importantly, the proposed multi-scale modelling scheme is validated by the experimental measurements. The proposed development offers the opportunity for the meso-scale model to become fully predictive.

Topics & Concepts

MortarMaterials scienceSofteningConstitutive equationDisplacement (psychology)Scale (ratio)Fracture (geology)MechanicsMacroscopic scaleStructural engineeringComposite materialGeotechnical engineeringGeologyEngineeringFinite element methodPhysicsQuantum mechanicsPsychotherapistPsychologyRock Mechanics and ModelingComposite Material MechanicsNumerical methods in engineering
Experimentally validated meso-scale fracture modelling of mortar using output from micromechanical models | Litcius