Analytical Study of Reinforced Concrete Beams Strengthened by FRP Bars Subjected to Impact Loading Conditions

TL;DR

This study develops and validates an analytical finite element model to predict the behavior of reinforced concrete beams strengthened with FRP under impact loading, demonstrating improved dynamic performance and damage mitigation.

Contribution

A new analytical model using ABAQUS for impact-loaded FRP-retrofitted concrete beams, validated against experimental data, enhancing prediction accuracy of their dynamic response.

Findings

FRP retrofitting improves impact resistance of RC beams.

The model accurately predicts beam behavior under impact loads.

FRP strengthening slows damage progression.

Abstract

In this research, a new analytical model is developed to analyze structural members strengthened with FRP systems and subjected to impact loading conditions. ABAQUS based finite element code was used to develop the proposed model. The model was validated against nine beams built and tested with various configurations and loading conditions. Three sets of beams were prepared and tested under quasistatic and impact loadings by applying various impact height and Dynamic Explicit loading conditions. The first set consisted of two beams, where one of the beams was reinforced with steel bars and the other was externally reinforced with GFRP sheet. The second set consisted of six beams, with five of the beams were reinforced with steel bars and one of them wrapped by GFRP sheet. The last set was tested to validate the response of concrete beams reinforced by FRP bar. In addition, beams were reinforced with glass and carbon fiber composite bars tested under Quasi-Static and Impact loading conditions. The impact load was simulated by the concept of a drop of a solid hammer from various heights. The numerical results showed that the developed model can be an effective tool to predict the performance of retrofitted beams under dynamic loading condition. Furthermore, the model showed that FRP retrofitting of RC beams subjected to repetitive impact loads can effectively improve their dynamic performance and can slow the progress of damage.