Litcius/Paper detail

Punching Shear Strength of FRP-Reinforced Concrete Slabs without Shear Reinforcements: A Reliability Assessment

Soliman Alkhatib, Ahmed Farouk Deifalla

2022Polymers28 citationsDOIOpen Access PDF

Abstract

The recent failure of buildings because of punching shear has alerted researchers to assess the reliability of the punching shear design models. However, most of the current research studies focus on model uncertainty compared to experimentally measured strength, while very limited studies consider the variability of the basic variables included in the model and the experimental measurements. This paper discusses the reliability of FRP-reinforced concrete slabs' existing punching shear models. First, more than 180 specimens were gathered. Second, available design codes and simplified models were selected and used in the calculation. Third, several reliability methods were conducted; therefore, three methods were implemented, including the mean-value first-order second moment (MVFOSM) method, the first-order second moment (FOSM) method, and the second-order reliability method (SORM). A comparison between the three methods showed that the reliability index calculated using the FOSM is quite similar to that using SORM. However, FOSM is simpler than SORM. Finally, the reliability and sensitivity of the existing strength models were assessed. At the same design point, the reliability index varied significantly. For example, the most reliable was the JSCE, with a reliability index value of 4.78, while the Elgendy-a was the least reliable, with a reliability index of 1.03. The model accuracy is the most significant parameter compared to other parameters, where the sensitivity factor varied between 67% and 80%. On the other hand, the column dimension and flexure reinforcement are the least significant parameters compared to other parameters where the sensitivity factor was 0.4% and 0.3%, respectively.

Topics & Concepts

Structural engineeringReliability (semiconductor)PunchingFirst-order reliability methodShear strength (soil)ReinforcementSensitivity (control systems)Geotechnical engineeringMaterials scienceMathematicsEngineeringStatisticsComposite materialGeologyRandom variablePower (physics)Soil waterQuantum mechanicsPhysicsElectronic engineeringSoil scienceStructural Behavior of Reinforced ConcreteProbabilistic and Robust Engineering DesignStructural Response to Dynamic Loads