Spatial Poisson processes for fatigue crack initiation
Abstract
In this work we propose a stochastic model for estimating the occurrence of crack initiations on the surface of metallic specimens in fatigue problems that can be applied to a general class of geometries. The stochastic model is based on spatial Poisson processes with intensity function that combines stress-life (S-N) curves with averaged effective stress, , which is computed after solving numerically the linear elasticity equations on the specimen domains using finite element methods. Here, is a parameter that characterizes the size of the neighbors covering the domain boundary. The averaged effective stress, parameterized by , maps the stress tensor to a scalar field upon the specimen domain. Data from fatigue experiments on notched and unnotched sheet specimens of 75S-T6 aluminum alloys are used to calibrate the model parameters for the individual data sets and for their combination. Bayesian and classical approaches are applied to estimate the survival-probability function for any specimen tested under a prescribed fatigue experimental setup. Our proposed model can predict the initiation of cracks in specimens made from the same material with new geometries.
Cite
@article{arxiv.1805.03433,
title = {Spatial Poisson processes for fatigue crack initiation},
author = {Ivo Babuska and Zaid Sawlan and Marco Scavino and Barna Szabó and Raúl Tempone},
journal= {arXiv preprint arXiv:1805.03433},
year = {2018}
}