A crack growth equation is used for calculating the size of a fatigue crack growing from cyclic loads. The growth of fatigue cracks can result in catastrophic failure, particularly in the case of aircraft. A crack growth equation can be used to ensure safety, both in the design phase and during operation, by predicting the size of cracks. In critical structure, loads can be recorded and used to predict the size of cracks to ensure maintenance or retirement occurs prior to any of the cracks failing.
Fatigue life can be divided into an initiation period and a crack growth period. Crack growth equations are used to predict the crack size starting from a given initial flaw and are typically based on experimental data obtained from constant amplitude fatigue tests.
One of the earliest crack growth equations based on the stress intensity factor range of a load cycle () is the Paris–Erdogan equation
where is the crack length and is the fatigue crack growth for a single load cycle . A variety of crack growth equations similar to the Paris–Erdogan equation have been developed to include factors that affect the crack growth rate such as stress ratio, overloads and load history effects.
The stress intensity range can be calculated from the maximum and minimum stress intensity for a cycle
A geometry factor is used to relate the far field stress to the crack tip stress intensity using
There are standard references containing the geometry factors for many different configurations.
Many crack propagation equations have been proposed over the years to improve prediction accuracy and incorporate a variety of effects. The works of Head, Frost and Dugdale, McEvily and Illg, and Liu on fatigue crack-growth behaviour laid the foundation in this topic. The general form of these crack propagation equations may be expressed as
where, the crack length is denoted by , the number of cycles of load applied is given by , the stress range by , and the material parameters by .
Cette page est générée automatiquement et peut contenir des informations qui ne sont pas correctes, complètes, à jour ou pertinentes par rapport à votre recherche. Il en va de même pour toutes les autres pages de ce site. Veillez à vérifier les informations auprès des sources officielles de l'EPFL.
vignette|Photomicrographie de la progression des fissures dans un matériau dues à la fatigue. Image tirée de . La fatigue est l'endommagement local d'une pièce sous l'effet d'efforts variables : forces appliquées, vibrations, rafales de vent Alors que la pièce est conçue pour résister à des efforts donnés, la variation de l'effort, même à des niveaux bien plus faibles que ceux pouvant provoquer sa rupture, peut à la longue provoquer sa rupture. Les essais de fatigue permettent de déterminer la résistance des matériaux à de telles faibles charges répétées.
This course covers principles of snow physics, snow hydrology, snow-atmosphere interaction and snow modeling. It transmits sound understanding of physical processes within the snow and at its interfac
This course covers elementary fracture mechanics and its application to the fracture of engineering materials.
Explique la fracture, la ténacité et la propagation des fissures dans les matériaux, en soulignant la différence entre les matériaux ductiles et cassants.
Explore la mécanique de la neige, en se concentrant sur les mécanismes de libération des avalanches et de propagation des fissures, y compris la redistribution des contraintes et les considérations de sécurité.
Explore la mécanique de la neige et la dynamique des avalanches, couvrant la propagation des fissures, la rupture de la rupture de la dalle et la friction dans la libération de la dalle.