Structural performance of concrete sandwich panels under fire

This paper investigates the structural performance of load-bearing precast concrete sandwich panels subjected to one-sided fire. It focuses on panels made with FRP diagonal-bar connectors. Heat transfer analysis is conducted for characterizing the temperature gradient within the panel and a structur...

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Bibliographic Details
Published in:Fire safety journal 2021-05, Vol.121, p.103293, Article 103293
Main Authors: Chen, Jun, Hamed, Ehab, Gilbert, R. Ian
Format: Article
Language:English
Subjects:
Buckling
Compression
Concrete
Concrete sandwich panels
Connectors
Creep (materials)
Diameters
Differential equations
Eccentric loading
Fire
Fire resistance
Geometric nonlinearity
Heat transfer
Insulation
Iterative methods
Load bearing elements
Mathematical analysis
Mathematical models
Modelling
Nonlinear systems
Plastic deformation
Precast concrete
Reinforced concrete
Reinforcing steels
Sandwich panels
Stiffening
Structural behavior
Structural models
Temperature gradients
Tension stiffening
Thickness
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Summary:This paper investigates the structural performance of load-bearing precast concrete sandwich panels subjected to one-sided fire. It focuses on panels made with FRP diagonal-bar connectors. Heat transfer analysis is conducted for characterizing the temperature gradient within the panel and a structural model is developed. The model considers the composite action between the reinforced concrete (RC) wythes, the transient creep of concrete under fire, strain softening in compression, cracking and tension stiffening, yielding of the steel reinforcement and geometric nonlinearity. The heat transfer analysis is conducted using a finite element approximation, and the governing differential equations of the structural model are solved using the nonlinear shooting method following an iterative procedure. The model is validated through comparisons with test results and other models in the literature. A numerical example and a parametric study that show the capabilities of the proposed model and clarify the structural behavior are presented. The results reveal progressive failures of the FRP-bar connectors and buckling failures of the panels under fire. It is revealed that the load eccentricity of the applied load greatly affects both the structural performance and the fire resistance of the panels. The diameter of FRP bars, the thickness of insulation layer and the load level are also found to play key roles in the fire resistance of the panels.
ISSN:0379-7112
1873-7226
DOI:10.1016/j.firesaf.2021.103293