Litcius/Paper detail

Study of fatigue crack propagation on modified CT specimens under variable amplitude loadings using machine learning

B. Santos, V. Infante, T. Barros, Ricardo Baptista

2024International Journal of Fatigue24 citationsDOIOpen Access PDF

Abstract

This study focuses on predicting fatigue crack paths and fatigue life in modified compact tension specimens, under mixed mode and variable amplitude loading conditions, using Machine Learning techniques. Mixed-mode conditions were induced by using specimens that incorporated holes with different radii and center coordinates. Initially, multiple Finite Element Method (FEM) simulations were conducted to determine the fatigue crack path for different configurations. Subsequently, several configurations were selected for experimental fatigue testing, in which the fatigue crack path was monitored and recorded. The final phase of the study involved Machine Learning (ML) techniques, specifically Artificial Neural Networks (ANN) and k-Nearest Neighbors (kNN), to predict fatigue crack propagation. The models were trained using different numerical and experimental data. Predicted results were then compared with experimentally tested data, and the behavior and accuracy of the models were evaluated. Overall, the implemented models demonstrated the ability to predict fatigue crack path with average deviations (ANN – 1.19 mm; kNN – 1.10 mm) closely resembling results obtained through Finite Element simulations (1.65 mm). The models were also able to predict fatigue life with average errors of 10.1 % (ANN) and 16.7 % (kNN), all achieved with a reduction of computational costs greater than 90 %.

Topics & Concepts

Finite element methodStructural engineeringArtificial neural networkAmplitudeMaterials scienceFracture mechanicsPath (computing)Paris' lawEngineeringComputer scienceCrack closureArtificial intelligencePhysicsQuantum mechanicsProgramming languageFatigue and fracture mechanicsNon-Destructive Testing TechniquesStructural Health Monitoring Techniques