Numerical analysis of the thermomechanical behavior of rubber concrete at high temperatures

Insufficient research has been done on the mechanical and thermal properties of rubber concrete in the presence of fire. In this paper, we do detailed numerical modeling of the rubber concrete's thermomechanical behavior under dynamic conditions at high temperatures (800°C) using different perc...

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Bibliographic Details
Published inStructural concrete : journal of the FIB Vol. 24; no. 3; pp. 3236 - 3250
Main Authors Karim Serroukh, Hamza, El Marzak, Mounir, Benaicha, Mouhcine, Li, Wenlong, Zhu, Jianguo, Hafidi Alaoui, Adil
Format Journal Article
LanguageEnglish
Published Weinheim WILEY‐VCH Verlag GmbH & Co. KGaA 01.06.2023
Wiley Subscription Services, Inc
Subjects
Compressive properties
Compressive strength
Equations of motion
Finite difference method
High temperature
Impact loads
Impact prediction
mathematical model
Mathematical models
Modulus of elasticity
Numerical analysis
Numerical models
Parameters
post‐fire
Rubber
rubber concrete
Temperature profiles
Tensile strength
Thermal conductivity
Thermal expansion
Thermal strain
Thermodynamic properties
Thermomechanical analysis
thermomechanical behavior
Thermomechanical properties
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Summary:Insufficient research has been done on the mechanical and thermal properties of rubber concrete in the presence of fire. In this paper, we do detailed numerical modeling of the rubber concrete's thermomechanical behavior under dynamic conditions at high temperatures (800°C) using different percentages of rubber aggregate (0%, 10%, 20%, and 30%). The novelty of this work lies in its analysis of the temperature profiles over time in rubber concrete. This analysis is carried out using finite difference models developed with the MATLAB tool to predict thermomechanical parameters such as elastic modulus, thermal strain, tensile strength, and compressive strength. In addition, the dynamic behavior of the rubber concrete under impact loading was predicted, including stress and velocity change as a function of time at elevated temperatures. By the equations of motion and transient conduction, the mathematical model developed is based on density, thermal conductivity, heat capacity, and thermal expansion. The comparison between numerical and experimental results, and the analysis of the influence of the percentage of rubber aggregates on thermomechanical parameters, as well as the influence of temperature on the evolution of stress and velocity as a function of time, have shown the effectiveness of the mathematical and numerical model developed.
ISSN:1464-4177
1751-7648
DOI:10.1002/suco.202300150