Show simple item record

contributor authorMichael P. Enright
contributor authorPatrick J. Golden
contributor authorRamesh Chandra
contributor authorAlan C. Pentz
contributor authorKwai S. Chan
contributor authorJonathan P. Moody
date accessioned2017-05-09T00:37:37Z
date available2017-05-09T00:37:37Z
date copyrightJuly, 2010
date issued2010
identifier issn1528-8919
identifier otherJETPEZ-27121#072502_1.pdf
identifier urihttp://yetl.yabesh.ir/yetl/handle/yetl/143154
description abstractFretting fatigue is a random process that continues to be a major source of damage associated with the failure of aircraft gas turbine engine components. Fretting fatigue is dominated by the fatigue crack growth phase and is strongly dependent on the magnitude of the stress values in the contact region. These stress values often have the most influence on small cracks where traditional long-crack fracture mechanics may not apply. A number of random variables can be used to model the uncertainty associated with the fatigue crack growth process. However, these variables can often be reduced to a few primary random variables related to the size and location of the initial crack, variability associated with applied stress and crack growth life models, and uncertainty in the quality and frequency of nondeterministic inspections. In this paper, an approach is presented for estimating the risk reduction associated with the nondestructive inspection of aircraft engine components subjected to fretting fatigue. Contact stress values in the blade attachment region are estimated using a fine mesh finite element model coupled with a singular integral equation solver and combined with bulk stress values to obtain the total stress gradient at the edge of contact. This stress gradient is applied to the crack growth life prediction of a mode I fretting fatigue crack. A probabilistic model of the fretting process is formulated and calibrated using failure data from an existing engine fleet. The resulting calibrated model is used to quantify the influence of inspection on the probability of fracture of an actual military engine disk under real life loading conditions. The results can be applied to quantitative risk predictions of gas turbine engine components subjected to fretting fatigue.
publisherThe American Society of Mechanical Engineers (ASME)
titleProbabilistic Fretting Fatigue Assessment of Aircraft Engine Disks
typeJournal Paper
journal volume132
journal issue7
journal titleJournal of Engineering for Gas Turbines and Power
identifier doi10.1115/1.4000130
journal fristpage72502
identifier eissn0742-4795
keywordsFatigue
keywordsStress
keywordsFracture (Process)
keywordsDisks
keywordsFinite element model
keywordsAircraft engines
keywordsBlades
keywordsForce
keywordsFracture (Materials) AND Inspection
treeJournal of Engineering for Gas Turbines and Power:;2010:;volume( 132 ):;issue: 007
contenttypeFulltext


Files in this item

Thumbnail

This item appears in the following Collection(s)

Show simple item record