Effects of Adhesive Connection on Composite Action between FRP Bridge Deck and Steel Girder

Xu Jiang,Frans Bijlaard,Xuhong Qiang,Henk Kolstein,Chengwei Luo

doi:10.1155/2017/6218949

Xu Jiang, Frans Bijlaard + Show 3 more

Open Access

https://doi.org/10.1155/2017/6218949

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Abstract

The FRP-steel girder composite bridge system is increasingly used in new constructions of bridges as well as rehabilitation of old bridges. However, the understanding of composite action between FRP decks and steel girders is limited and needs to be systematically investigated. In this paper, depending on the experimental investigations of FRP to steel girder system, the Finite Element (FE) models on experiments were developed and analyzed. Comparison between experiments and FE results indicated that the FE models were much stiffer for in-plane shear stiffness of the FRP deck panel. To modify the FE models, rotational spring elements were added between webs and flanges of FRP decks, to simulate the semirigid connections. Numerical analyses were also conducted on four-point bending experiments of FRP-steel composite girders. Good agreement between experimental results and FE analysis was achieved by comparing the load-deflection curves at midspan and contribution of composite action from FRP decks. With the validated FE models, the parametric studies were conducted on adhesively bonded connection between FRP decks and steel girders, which indicated that the loading transfer capacity of adhesive connection was not simply dependent on the shear modulus or thickness of adhesive layer but dominated by the in-plane shear stiffness K.

Highlights

Fiber-reinforced polymer (FRP) materials are increasingly being used in civil infrastructure applications
Comparison with experimental results indicated that the Finite Element (FE) models were much stiffer for in-plane shear stiffness of the FRP deck panel
To modify the FE models, rotational spring elements were added between webs and flanges of FRP decks, to simulate the semirigid connections

Summary

Introduction

Fiber-reinforced polymer (FRP) materials are increasingly being used in civil infrastructure applications. Due to the light weight of FRP bridge decks (about 10–20% of a reinforced concrete deck), the dead load can be substantially reduced, which leads to a significant saving for the structure and foundations. To compete with concrete decks, in addition to the transverse load-carrying function, FRP bridge decks should contribute as part of the top chords of the main girders in the longitudinal axis of the bridge. In the case of concrete deck replacement for rehabilitation of old bridges, FRP decks must be capable of maintaining the longitudinal top chord function; otherwise the main girders must be strengthened. Parametric studies on the loading transferring capacity of adhesively bonded connection were conducted by varying the modulus and thickness of the adhesive layer between FRP decks and steel girder

Numerical Modelling

Experiment FEM

Parametric Study

Conclusions