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Predicting fiber‐reinforced polymer–concrete bond strength using artificial neural networks: A comparative analysis study

Rami H. Haddad, M. A. Haddad

2020Structural Concrete72 citationsDOI

Abstract

Abstract The repair efficiency of fiber‐reinforced polymer (FRP) is crucially linked to bond strength between FRP and concrete. Artificial neural networks (ANNs) technique is employed for the prediction of FRP–concrete bond strength based on more than 440 data points collected from literature work for training and testing of the proposed ANNs model. Such a model facilitates investigating the effect of various key parameters in controlling the bond. These are concrete compressive strength, maximum aggregate size, FRP thickness and modulus of elasticity, FRP‐to‐concrete length and width ratios, and adhesive tensile strength. The proposed ANNs model shows high fitting and prediction capability of training and testing data, respectively, with low mean square errors. Its accuracy of prediction far exceeds that of literature empirical models. Furthermore, the present comparative and sensitivity study of the predicted bond strength promotes the understanding of the impact of the above key parameters.

Topics & Concepts

Fibre-reinforced plasticUltimate tensile strengthMaterials scienceArtificial neural networkStructural engineeringBond strengthCompressive strengthAggregate (composite)AdhesiveTest dataComposite materialComputer scienceEngineeringMachine learningProgramming languageLayer (electronics)Structural Behavior of Reinforced ConcreteConcrete Corrosion and DurabilityInnovative concrete reinforcement materials