Abstract
A deep beam is a beam with a small ratio of its shear span to its effective depth. Deep beams at failure under shear mechanism behave as brittle in contrast to the normal beams which become ductile under the flexural mechanism. The shear failure of deeps beams can be prevented by providing a sufficient amount of web shear reinforcements. Providing horizontal web reinforcement to the RC deep beams is a way to increase their capacity to shear. Testing of the studied deep beams was performed by Finite Element Method (FEM) modeling with the aid of ANSYS software. To obtain valid parameters for modeling RC deep beams in FEM modeling, calibrating test have to be done through verification and validation processes. The study results of all studied RC deep beams show that by closing up the spacing between the horizontal web reinforcement results in increment in the ultimate load, while the ultimate deflection and the curvature ductility were found to be decreasing. For RC deep beams, the placing configuration of horizontal web reinforcement at 0.5h-0.7h was found to be efficient for gaining higher values of ultimate deflection and curvature ductility compared to the placing configuration at 0.3h-0.5h with similar values of ultimate load. It was also found that all the specimens’ crack patterns at the first crack state were caused by flexural-tension while at the ultimate state, they were caused by the shear mechanism.
Highlights
A deep beam is a beam with a small ratio of shear span to effective depth
Studies related to the horizontal web reinforcement of RC deep beams with the configuration by its space and its amount have been conducted by observations of its effect to increased shear strength [1, 2, 611]
Closing up the spacing or enlarging the area of horizontal web reinforcement may lead to increase of the ultimate load and decrease of the ultimate deflection and curvature ductility of RC deep beams
Summary
A deep beam is a beam with a small ratio of shear span to effective depth. At failure, under shear, deep beams become brittle while normal beams, under flexural mechanism, become ductile. Studies related to the horizontal web reinforcement of RC deep beams with the configuration by its space and its amount have been conducted by observations of its effect to increased shear strength [1, 2, 611]. This study attempts to investigate the effect of spacing and positioning configuration of horizontal web reinforcement of deep beams by monitoring capacity and curvature ductility. From the verification process [12,13,14] it is known that the element types for concrete, reinforcement steel model, and for the loading and the supporting plate are SOLID65, LINK8, and SOLID45 respectively. Series BT1 are deep beams with the spacing configuration of the horizontal web reinforcement and are in turn divided into three series (BT1-1, BT1-2, and BT1-3). Horizontal web reinforcement 2D6 (0.3h-0.5h) 2D10 (0.3h-0.5h) 2D13 (0.3h-0.5h) 2D6 (0.5h-0.7h) 2D10 (0.5h-0.7h) 2D13 (0.5h-0.7h) www.etasr.com
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
