Abstract

A number of numerical and experimental studies have been reported in recent literature to investigate the effects of infill walls on the seismic response of RC infilled frames. Many experimental studies used CFRP sheets as an external bracing system for retrofitting the infilled RC frames. It has been found that the common mode of failure of such retrofitted frames is the debonding of the CFRP-concrete adhesive material. In the current study, the behaviour of CFRP retrofitted infilled RC frames was investigated with a finite element micro model. In that model, a four-node shell element was used for modeling the concrete, infill panel and CFRP sheets. The interaction between concrete frame and infill panel was modelled using contact surfaces to allow the occurrence of separation and prevent penetration. Nonlinearities of the concrete, infill panel, steel and CFRP sheets were considered. To allow the occurrence of debonding mode of failure, the adhesive layer was modelled using cohesive surface-to-surface interaction model, which assumes that the failure of cohesive bond is characterized by progressive degradation of the cohesive stiffness, which is driven by a damage process based on the fracture energy. The proposed model was verified using experimental results from the literature. Results indicated that the cohesive model could capture the debonding mode of failure which has been observed experimentally. The validated micro model was used to investigate the effects of the strip end area, the anchor location and partial bonding of the CFRP sheet to the infill panel surface on the behaviour of infilled frames. The results of parametric study showed that, to get the highest efficiency of the CFRP retrofitted infilled frame, bonding about 25% only of the diagonal length from each end is sufficient to get the same behaviour of the totally bonded sheet.

Highlights

  • Retrofitting of constructions vulnerable to lateral loads is a current problem of great political and social relevance

  • Experiments have shown that under lateral forces, the concrete frame tends to separate from the infill near windward lower and leeward upper corners of the infill panels, causing compressive contact stresses to develop between the frame and the infill at the other diagonally opposite corners, in addition to the transverse component which represent the shear stress

  • The full bond model overestimates the stiffness at the intermediate loading stage, and the ultimate load of the retrofitted infilled frame compared to cohesive models

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Summary

Introduction

Retrofitting of constructions vulnerable to lateral loads is a current problem of great political and social relevance. Sinan et al [6] investigated the strengthening of masonry infilled RC frames using diagonal CFRP strips under cyclic loads They investigated the effects of CFRP strips’ width and arrangement type on specimens’ behavior, strength, stiffness and story drifts of the test specimens. Nwofor [19] constructed a numerical model using explicit finite element method to study the behavior of masonry infilled reinforced concrete frames. He compared obtained results against results from experimental test to ensure the ability of his model to stimulate the shear strength response of masonry infill panel. This interaction model assumes that the failure of cohesive bond is characterized by progressive degradation of the cohesive stiffness, which is driven by a damage process based on the fracture energy

Finite Element Analysis
Constitutive models
Interaction between Concrete Frame and Infill Panel
Interface between CFRP strips and the infilled frame surface
Elements and Meshing
Verification of the Model with Previous Work
Material Properties and Applied Loads
Cross Braced CFRP Retrofitted Infilled Frame
Parametric Study
Partial bonding of the CFRP Sheet to the Infill Panel surface
Proposed Location of Anchors to Delay the Debonding
Findings
Conclusion

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