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Experimental and Numerical Investigations on High Performance SFRC: Cyclic Tensile Loading and Fatigue
Authors:Niklas Schä  fer,Vladislav Gudž  ulić  ,Rolf Breitenbü  cher,Gü  nther Meschke
Affiliation:1.Institute for Building Materials Technology, Ruhr-University Bochum, 44801 Bochum, Germany;2.Institute for Structural Mechanics, Ruhr-University Bochum, 44801 Bochum, Germany; (V.G.); (G.M.)
Abstract:In the present study, the capability of high-strength short steel fibers to control the degradation in high-performance concrete was experimentally examined and numerically simulated. To this end, notched prismatic high-performance concrete specimens with (HPSFRC) and without (HPC) short steel fibers were subjected to static and cyclic tensile tests up to 100,000 cycles. The cyclic tests showed that the rate of strain increase was lower for HPSFRC specimens and that the strain stagnated after around 10,000 cycles, which was not the case with HPC specimens. The microscopic examinations showed that in HPSFRC, a larger number of microcracks developed, but they had a smaller total surface area than the microcracks in the HPC. To further investigate the influence of fibers on the behavior of HPSFRC in the cracked state, displacement-controlled crack opening tests, as well as numerical simulations thereof, were carried out. Experiments have shown, and the numerical simulations have confirmed, that the inclusion of short steel fibers did not significantly affect the ultimate strength; however, it notably increased the post-cracking ductility of the material. Finally, the unloading/reloading behavior was examined, and it was observed that the unloading stiffness was stable even for significant crack openings; however, the hysteresis loops due to unloading/reloading were very small.
Keywords:SFRC   fatigue   tensile stress   controlled crack opening test   cohesive zone model   discrete fibers   crack closure model
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