A multiresolution investigation on fatigue damage of aluminum alloys at micrometer level

A multiresolution investigation on fatigue damage of aluminum alloys at micrometer level

Fatigue damage is a form of material degradation under repeated mechanical and/or thermal loading. A new multiresolution fatigue damage analysis is formulated and used to estimate low-cycle fatigue damage. The progressive fatigue damage is measured based on the X-ray computed tomography. Then, the m...

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Veröffentlicht in:International journal of damage mechanics 2017-03, Vol.26 (2), p.192-209
Hauptverfasser: Chen, H, Shi, X, He, Q, Mao, JH, Liu, Y, Kang, H, Shen, J
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container_issue 2
container_start_page 192
container_title International journal of damage mechanics
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creator Chen, H
Shi, X
He, Q
Mao, JH
Liu, Y
Kang, H
Shen, J
description Fatigue damage is a form of material degradation under repeated mechanical and/or thermal loading. A new multiresolution fatigue damage analysis is formulated and used to estimate low-cycle fatigue damage. The progressive fatigue damage is measured based on the X-ray computed tomography. Then, the measured microcracks and microvoids are transformed to mesoscale and macro-scale damage variables. The entire transformation process is achieved analytically by means of 3D finite element analysis and specially formulated super representative volume elements. The estimated macro-scale damage variables in terms of effective Young’s moduli are compared with those measured experimentally and found to be in agreement. Some lessons learned in this study are provided for the direction of future research.
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title A multiresolution investigation on fatigue damage of aluminum alloys at micrometer level
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