Simulation of moisture variations in concrete during prolonged alternate wetting and drying cycles using 3D discrete network model

The precise prediction of moisture variations within concrete is of great significance because various deterioration phenomena spanning corrosion to carbonation are induced by mass transfer facilitated by the presence of moisture. Under actual environmental conditions, concrete is exposed to numerou...

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Bibliographic Details
Published inCase Studies in Construction Materials Vol. 19; p. e02553
Main Authors Waghmare, Dheeraj, Ren, Dawei, Jiradilok, Punyawut, Nagai, Kohei
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.12.2023
Elsevier
Subjects
Capillary action
Diffusion
Discrete element method
Mass transport
Meso-scale
Moisture profiles
Wetting and drying
Capillary action
Wetting and drying
Moisture profiles
Mass transport
Discrete element method
Diffusion
Meso-scale
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Summary:The precise prediction of moisture variations within concrete is of great significance because various deterioration phenomena spanning corrosion to carbonation are induced by mass transfer facilitated by the presence of moisture. Under actual environmental conditions, concrete is exposed to numerous wetting and drying cycles. Thus, to accurately predict moisture variations it is essential to consider the effect of these conditions. This study investigates the effect of alternate wetting and drying cycles on moisture penetration through concrete at the mesoscale using a 3D discrete network model based on a Rigid Body Spring Model (RBSM). For modeling moisture transport during wetting, the non-linear diffusion equation is used and the effects of capillary suction in moisture transport are also considered. On the other hand, moisture transport during drying is modeled as an evaporation-diffusion process. The simulation results obtained using this discrete network model are validated against the available experimental outcomes. During the wetting cycle, the moisture content in regions close to the exposed surface rapidly increases and approaches the maximum saturation. The effect of subsequent drying is seen only until a certain depth below the exposed surface, known as the influential depth. It is also observed that moisture continues to penetrate deeper into a specimen even during a drying cycle.
ISSN:2214-5095
2214-5095
DOI:10.1016/j.cscm.2023.e02553