Abstract
As the technique of fiber-reinforced polymer (FRP) composite material strengthened reinforced concrete structures is widely used in the field of civil engineering, durability of the strengthened structures has attracted more attention in recent years. Hygrothermal environment has an adverse effect on the bond behavior of the interface between FRP and concrete. This paper focuses on the bond durability of carbon fiber laminate- (CFL-) concrete interface in hygrothermal condition which simulates the climate characteristic in South China. Twenty 100 mm × 100 mm × 720 mm specimens were divided into 6 groups based on different temperature and humidity. After pretreatment in hygrothermal environment, the specimens were tested using double shear method. Strain gauges bonded along the CFL surface and linear variation displacement transducers (LVDTs) were used to measure longitudinal strains and slip of the interface. Failure mode, ultimate capacity, load-deflection relationship, and relative slip were analyzed. The bond behavior of FRP-concrete interface under hygrothermal environment was studied. Results show that the ultimate bearing capacity of the interface reduced after exposure to hygrothermal environments. The decreasing ranges were up to 27.9% after exposure at high temperature and humidity (60°C, 95% RH). The maximum strains (εmax) of the specimens pretreated decreased obviously which indicated decay of the bond behavior after exposure to the hygrothermal environment.
Highlights
External bonding of fiber-reinforced polymer (EB-FRP) composite material is a popular technique for strengthening concrete structures [1,2,3]
It was found that hydrothermal ageing caused a significant reduction in the capacity strength of the bonded interfaces for specimens strengthened with CFS and CFRP compared to the unstrengthened concrete slabs
This study experimentally investigated the bond-slip behavior of the carbon fiber laminate- (CFL-)concrete bond subjected to static load after hygrothermal environment exposure
Summary
External bonding of fiber-reinforced polymer (EB-FRP) composite material is a popular technique for strengthening concrete structures [1,2,3]. In this method, the adhesively bonded joint plays a crucial role which provides effective stress transferring from concrete to FRP to secure the integrity and durability of the strengthened structures [4,5,6]. Benzarti et al [13] designed 4 different composite systems to study the CFRP-to-concrete bond durability under constant hydrothermal ageing conditions (40∘C and 95% relative humidity). The chemical compositions reports explained that moisture diffusion from the superficial layer of concrete towards the adhesive joint is possibly the key reason causing the degradation process during hydrothermal
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