Meso-scale modeling of irradiated concrete in test reactor

•A meso-scale finite element model for irradiated concrete is developed.•Neutron radiation-induced volumetric expansion is a predominant degradation mode.•Confrontation with expansion and damage obtained from experiments is successful.•Effects of paste shrinkage, creep and ductility are discussed. A...

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Published inNuclear engineering and design Vol. 295; pp. 59 - 73
Main Authors Giorla, A., Vaitová, M., Le Pape, Y., Štemberk, P.
Format Journal Article
LanguageEnglish
Published United States Elsevier B.V 15.12.2015
Elsevier
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Summary:•A meso-scale finite element model for irradiated concrete is developed.•Neutron radiation-induced volumetric expansion is a predominant degradation mode.•Confrontation with expansion and damage obtained from experiments is successful.•Effects of paste shrinkage, creep and ductility are discussed. A numerical model accounting for the effects of neutron irradiation on concrete at the mesoscale is detailed in this paper. Irradiation experiments in test reactor (Elleuch et al., 1972), i.e., in accelerated conditions, are simulated. Concrete is considered as a two-phase material made of elastic inclusions (aggregate) subjected to thermal and irradiation-induced swelling and embedded in a cementitious matrix subjected to shrinkage and thermal expansion. The role of the hardened cement paste in the post-peak regime (brittle-ductile transition with decreasing loading rate), and creep effects are investigated. Radiation-induced volumetric expansion (RIVE) of the aggregate cause the development and propagation of damage around the aggregate which further develops in bridging cracks across the hardened cement paste between the individual aggregate particles. The development of damage is aggravated when shrinkage occurs simultaneously with RIVE during the irradiation experiment. The post-irradiation expansion derived from the simulation is well correlated with the experimental data and, the obtained damage levels are fully consistent with previous estimations based on a micromechanical interpretation of the experimental post-irradiation elastic properties (Le Pape et al., 2015). The proposed modeling opens new perspectives for the interpretation of test reactor experiments in regards to the actual operation of light water reactors.
Bibliography:USDOE
AC05-00OR22725
ISSN:0029-5493
1872-759X
DOI:10.1016/j.nucengdes.2015.08.027