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Fatigue Crack Growth Analysis with Extended Finite Element for 3D Linear Elastic Material

Yahya Ali Fageehi

2021Metals19 citationsDOIOpen Access PDF

Abstract

This paper presents computational modeling of a crack growth path under mixed-mode loadings in linear elastic materials and investigates the influence of a hole on both fatigue crack propagation and fatigue life when subjected to constant amplitude loading conditions. Though the crack propagation is inevitable, the simulation specified the crack propagation path such that the critical structure domain was not exceeded. ANSYS Mechanical APDL 19.2 was introduced with the aid of a new feature in ANSYS: Smart Crack growth technology. It predicts the propagation direction and subsequent fatigue life for structural components using the extended finite element method (XFEM). The Paris law model was used to evaluate the mixed-mode fatigue life for both a modified four-point bending beam and a cracked plate with three holes under the linear elastic fracture mechanics (LEFM) assumption. Precise estimates of the stress intensity factors (SIFs), the trajectory of crack growth, and the fatigue life by an incremental crack propagation analysis were recorded. The findings of this analysis are confirmed in published works in terms of crack propagation trajectories under mixed-mode loading conditions.

Topics & Concepts

Paris' lawFracture mechanicsStructural engineeringFinite element methodCrack closureStress intensity factorLinear elasticityMaterials scienceCrack growth resistance curveExtended finite element methodVibration fatigueBendingMechanicsEngineeringPhysicsFatigue and fracture mechanicsNumerical methods in engineeringUltrasonics and Acoustic Wave Propagation
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