Glass fibre-reinforced polymer (GFRP) has several advantages, including durability and corrosion resistance. However, there is some skepticism regarding the overall strength of GFRP-reinforced concrete elements when subjected to elevated temperatures, particularly regarding the degradation of bond strength between GFRP bars and concrete.
Four full-size GFRP-reinforced concrete beams with straight-end bar lap splices at their midspan, which were examined in two prior related experimental studies under standard fire exposure, have been modelled using the ABAQUS software. A thermal-mechanical numerical analysis was performed to study the performance of the beams under four-point bending in simulated standard fire conditions. In a subsequent stage, a parametric study was conducted to investigate the effects of the applied load ratio and the number of reinforcing GFRP bars.
Results show that increasing the load ratio slightly increased the beam mid-span deflections throughout most of the simulated duration of standard fire exposure. However, under higher load ratios (80%–100%), a significant increase in the beam mid-span deflection was observed immediately before failure, when the surface temperature of the reinforcing bars approached their glass transition temperature. Based on the outcomes of this new numerical study, using fewer but larger-diameter GFRP bars is recommended over using more bars of smaller diameter with the same total cross-sectional area for enhanced fire resistance.
The outcomes of this research can assist researchers and practitioners during the design stage of GFRP-reinforced concrete beams to determine the optimum number and diameter of GFRP bars to enhance their fire resistance. Additionally, the outcomes can be highly beneficial when rehabilitating fire-damaged concrete beams, as the maximum safe load that can be applied to GFRP-reinforced concrete beams in the event of a fire can be accurately determined.
