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contributor authorBusse, Christian
contributor authorGustafsson, David
contributor authorRasmusson, Patrik
contributor authorSjأ¶din, Bjأ¶rn
contributor authorMoverare, Johan J.
contributor authorSimonsson, Kjell
contributor authorLeidermark, Daniel
date accessioned2017-05-09T01:28:21Z
date available2017-05-09T01:28:21Z
date issued2016
identifier issn1528-8919
identifier othergtp_138_04_042506.pdf
identifier urihttp://yetl.yabesh.ir/yetl/handle/yetl/161059
description abstractIn this paper, the possibility to use linear elastic fracture mechanics (LEFM), with and without a superimposed residual stress field, to predict fatigue crack propagation in the gas turbine disk material Inconel 718 has been studied. A temperature of 400 آ°C and applied strain ranges corresponding to component near conditions have been considered. A threedimensional crack propagation software was used for determining the stress intensity factors (SIFs) along the crack path. In the first approach, a linear elastic material behavior was used when analyzing the material response. The second approach extracts the residual stresses from an uncracked model with perfectly plastic material behavior after one loading cycle. As a benchmark, the investigated methods are compared to experimental tests, where the cyclic lifetimes were calculated by an integration of Paris' law. When comparing the results, it can be concluded that the investigated approaches give good results, at least for longer cracks, even though plastic flow was taking place in the specimen. The pure linear elastic simulation overestimates the crack growth for all crack lengths and gives conservative results over all considered crack lengths. Noteworthy with this work is that the 3Dcrack propagation could be predicted with the two considered methods in an LEFM context, although plastic flow was present in the specimens during the experiments.
publisherThe American Society of Mechanical Engineers (ASME)
titleThree Dimensional LEFM Prediction of Fatigue Crack Propagation in a Gas Turbine Disk Material at Component Near Conditions
typeJournal Paper
journal volume138
journal issue4
journal titleJournal of Engineering for Gas Turbines and Power
identifier doi10.1115/1.4031526
journal fristpage42506
journal lastpage42506
identifier eissn0742-4795
treeJournal of Engineering for Gas Turbines and Power:;2016:;volume( 138 ):;issue: 004
contenttypeFulltext


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