Structural response of liquid-cooled GFRP slabs subjected to fire – Part II: Thermo-chemical and thermo-mechanical modeling

Structural response of liquid-cooled GFRP slabs subjected to fire – Part II: Thermo-chemical and thermo-mechanical modeling

Based on defined temperature-dependent material properties, thermo-chemical and thermo-mechanical models were developed to predict the temperature progression and endurance of full-scale slab components exposed to ISO 834 fire conditions on their underside. Important geometrical changes that occur o...

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Bibliographic Details
Published in:Composites. Part A, Applied science and manufacturing Vol. 37; no. 9; pp. 1296 - 1308
Main Authors: Keller, Thomas, Tracy, Craig, Zhou, Aixi
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 01-09-2006
Elsevier
Subjects:
A: Polymer–matrix composites
Application fields
Applied sciences
B: High-temperature properties
Buildings. Public works
E: Pultrusion
Exact sciences and technology
Forms of application and semi-finished materials
Laminates
Materials
Plastics
Polymer industry, paints, wood
Technology of polymers
Thermo-mechanical modeling
Thermo-mechanical modeling
E: Pultrusion
B: High-temperature properties
A: Polymer–matrix composites
Cell structure
Laminate
Mechanical model
Construction materials
Fiber reinforced material
Theoretical study
Polymer
Thermomechanical properties
Mineral fiber
Modeling
Composite material
Finite element method
Thermal properties
Fire resistance
Thermal conductivity
Numerical simulation
A: Polymer-matrix composites
Glass fiber
Application
Thermal degradation
Pultrusion
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Summary:Based on defined temperature-dependent material properties, thermo-chemical and thermo-mechanical models were developed to predict the temperature progression and endurance of full-scale slab components exposed to ISO 834 fire conditions on their underside. Important geometrical changes that occur over long fire exposures of FRP materials, such as the radiative shielding effect of delaminating fiber layers and loss of fiber layers, were considered. The predicted temperature progression in the liquid-cooled and non-cooled slab components from the 2-D thermo-chemical model corresponded well with measured values up to 120 min of exposure. The validated model allows the prediction of the hot face temperatures, which are very difficult to experimentally measure. The 3-D thermo-mechanical model accurately predicts the measured mid-span deflections and axial strains under serviceability loads in the liquid-cooled case during 120 min of fire exposure.
ISSN:1359-835X
1878-5840
DOI:10.1016/j.compositesa.2005.08.007