Title: Finite Element Modeling of Shear Deficient RC Beams Strengthened with NSM CFRP Rods Under Cyclic Loading
Author(s): R. Hawileh, J. A. Abdalla , M. Z. Naser , and M. Tanarslan
Publication: Symposium Paper
Appears on pages(s): 1-18
Keywords: shear failure, reinforced concrete beams, computational modeling, fiber-reinforced polymers (FRP), strengthening, near-surface mounted (NSM), cyclic loading.
This paper presents Finite Element (FE) model to predict and analyze the cyclic loading response of reinforced concrete (RC) beams strengthened in shear with Carbon Fiber Reinforced-Polymer (CFRP) and Near-Surface Mounted (NSM) reinforcement. Four FE models were developed based on experimental tests conducted in a previous study. The first specimen was unstrengthened to serve as a control beam while the other two beams were strengthened with NSM CFRP bars with different spacing arrangements. The last beam specimen was strengthened with larger diameter CFRP bars. The developed FE models employed different nonlinear constitutive material modeling laws and techniques such as concrete cracking, steel yielding, bondslip between CFRP bars and epoxy resin, and debonding between the epoxy resin and concrete surfaces. The predicted and measured load-deflection response envelop curves along with the associated hysteresis loops for each specimen were used as platforms to validate the accuracy of the developed models. The results indicate that there is a good match between the predicted results and measured data. It is concluded that the developed FE model is a suitable tool to predict the behavior of such strengthening systems when subjected to cyclic loading and could be used in lieu of expensive experimental testing especially in design-oriented parametric studies.