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Use of Mixed-Mode Fracture Interfaces for the Modeling of Large-Scale FRP-Strengthened Beams |
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| Authors: | Jae Ha Lee Rose M. Chacko Maria M. Lopez |
| Affiliation: | 1Doctoral Candidate, Dept. of Civil and Environmental Engineering, Pennsylvania State Univ., 212 Sackett, University Park, PA 16801. 2Structural Engineer, WorleyParsons Group, Inc., 633 Chestnut St., Suite 400, Chattanooga, TN 37450. 3Associate Professor, Dept. of Civil and Environmental Engineering, Pennsylvania State Univ., 212 Sackett, University Park, PA 16801 (corresponding author). E-mail: mmlopez@engr.psu.edu |
| Abstract: | In this study, numerical models of fiber-reinforced polymer (FRP)-strengthened beams were developed using nonlinear fracture mechanics for the modeling of the concrete-FRP (longitudinal and U-wrap) interfaces. Mode 1, Mode 2, and mixed-mode interfacial behaviors were considered. Results from the finite-element models were compared with experimental tests of large-scale strengthened beams using FRP U-wraps as anchors. The numerical program assessed the effect of the interfacial modeling in the global and local responses. A parametric study was conducted to determine the effect of additional longitudinal FRP sheets in strengthened beams with and without FRP U-wraps. Results from this study indicate that the use of a mixed-mode concrete-FRP interface is a robust numerical approach for the prediction of the global and local responses of large-scale FRP-strengthened beams. The parametric study shows that the use of FRP U-wraps could improve the strength and ductility of the FRP-strengthened beams by changing their failure mode and deflection response. Appropriate modeling of the concrete-FRP interfaces is needed to successfully predict these effects. |
| Keywords: | Fiber reinforced polymer Anchors Finite element method Interfaces Cracking Reinforced concrete Beams |