Application of Damage Tolerant Design in Mechanical Engineering

Research output: ThesisDoctoral Thesis

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Application of Damage Tolerant Design in Mechanical Engineering. / Jan, Miraj Muhammad.
2008. 103 p.

Research output: ThesisDoctoral Thesis

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@phdthesis{ca74702d0d004e2599a1d261efea1888,
title = "Application of Damage Tolerant Design in Mechanical Engineering",
abstract = "In this thesis, the three primary fatigue design approaches stress-life, strain-life, and DTD are used to analyse fatigue damage with special focus on investigating flaws typically encountered in structural parts. The fatigue limit of undamaged and damaged specimens is assessed experimentally as well as theoretically. An effort is made to combine the existing concepts and to re-interpret the results obtained by the DTD and strain-life approaches in the framework of the conventional stress-life method. For a material containing defects, the idea of net section yielding is exploited to transform the S/N curve of an undamaged material to a damaged one. Finally, a method is proposed for obtaining an estimate of the fatigue lifetime of a component with and without defects using the static tensile properties in combination with the fatigue crack growth properties of the material. A guideline for obtaining a first estimate of fatigue data useful for purposes of preliminary design is developed and verified experimentally for a wrought aluminium alloy typically used for cryogenic applications. As a practical design application, the fatigue response of thin-walled tubular specimens is considered. A special rig having the capability of testing various materials such as aluminium and steel alloys under arbitrary combinations of static and/or periodic internal pressure and axial loading has been designed. First promising results for aluminium tubes under static internal pressure and axial fatigue loading are presented.",
keywords = "fatigue life prediction, fatigue crack growth, S/N curve, HCF, LCF, damage tolerant design, aluminium alloy, Betriebsfestigkeit, Erm{\"u}dungsrisswachstum, W{\"o}hlerlinie, HCF, LCF, schadenstolerante Auslegung, Aluminium",
author = "Jan, {Miraj Muhammad}",
note = "no embargo",
year = "2008",
language = "English",

}

RIS (suitable for import to EndNote) - Download

TY - BOOK

T1 - Application of Damage Tolerant Design in Mechanical Engineering

AU - Jan, Miraj Muhammad

N1 - no embargo

PY - 2008

Y1 - 2008

N2 - In this thesis, the three primary fatigue design approaches stress-life, strain-life, and DTD are used to analyse fatigue damage with special focus on investigating flaws typically encountered in structural parts. The fatigue limit of undamaged and damaged specimens is assessed experimentally as well as theoretically. An effort is made to combine the existing concepts and to re-interpret the results obtained by the DTD and strain-life approaches in the framework of the conventional stress-life method. For a material containing defects, the idea of net section yielding is exploited to transform the S/N curve of an undamaged material to a damaged one. Finally, a method is proposed for obtaining an estimate of the fatigue lifetime of a component with and without defects using the static tensile properties in combination with the fatigue crack growth properties of the material. A guideline for obtaining a first estimate of fatigue data useful for purposes of preliminary design is developed and verified experimentally for a wrought aluminium alloy typically used for cryogenic applications. As a practical design application, the fatigue response of thin-walled tubular specimens is considered. A special rig having the capability of testing various materials such as aluminium and steel alloys under arbitrary combinations of static and/or periodic internal pressure and axial loading has been designed. First promising results for aluminium tubes under static internal pressure and axial fatigue loading are presented.

AB - In this thesis, the three primary fatigue design approaches stress-life, strain-life, and DTD are used to analyse fatigue damage with special focus on investigating flaws typically encountered in structural parts. The fatigue limit of undamaged and damaged specimens is assessed experimentally as well as theoretically. An effort is made to combine the existing concepts and to re-interpret the results obtained by the DTD and strain-life approaches in the framework of the conventional stress-life method. For a material containing defects, the idea of net section yielding is exploited to transform the S/N curve of an undamaged material to a damaged one. Finally, a method is proposed for obtaining an estimate of the fatigue lifetime of a component with and without defects using the static tensile properties in combination with the fatigue crack growth properties of the material. A guideline for obtaining a first estimate of fatigue data useful for purposes of preliminary design is developed and verified experimentally for a wrought aluminium alloy typically used for cryogenic applications. As a practical design application, the fatigue response of thin-walled tubular specimens is considered. A special rig having the capability of testing various materials such as aluminium and steel alloys under arbitrary combinations of static and/or periodic internal pressure and axial loading has been designed. First promising results for aluminium tubes under static internal pressure and axial fatigue loading are presented.

KW - fatigue life prediction

KW - fatigue crack growth

KW - S/N curve

KW - HCF

KW - LCF

KW - damage tolerant design

KW - aluminium alloy

KW - Betriebsfestigkeit

KW - Ermüdungsrisswachstum

KW - Wöhlerlinie

KW - HCF

KW - LCF

KW - schadenstolerante Auslegung

KW - Aluminium

M3 - Doctoral Thesis

ER -