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Closure of three-dimensional fatigue cracksAlizadeh, Hassan January 2005 (has links)
No description available.
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Factors affecting the failure of cracked components at elevated temperatureYatomi, Masataka January 2003 (has links)
No description available.
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Localised corrosion and stress cracking of aluminium-magnesium alloysYuan, Yudie January 2006 (has links)
No description available.
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Effects of cyclic loading on fibre reinforced titanium metal matrix compositesZamperini, Silvia January 2002 (has links)
No description available.
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Prediction of the fatigue of metal matrix composites using theory of cellsFleming, William January 2006 (has links)
Discontinuous and particulate metal matrix composites have emerged as a set of materials which has found increasing niche areas of use. They are now widely used in both diesel and petrol internal combustion engines, as well as in sports bicycles and other areas where their combination of unique properties can be exploited to advantage. The inclusion of fibres into a base matrix produces a complex material both in its make up and mechanical properties and it would be an advantage to be able to predict a candidate metal matrix composite material's mechanical and thermal properties prior to that material's development. One such approach, the so called Theory of Cells, is a micromechanical approach which uses the analysis of repeating cells within the composite to make prediction of the composite's mechanical properties. In the present study, this approach has been employed to predict the fatigue life of a series of different metal matrix composites at ambient temperature. These composites include some materials with SiC fibres and some with Al203 fibres. Using data obtained from the monolithic matrix material and the individual fibres theoretical S/N and Strain/N curves were produced. This was possible by assuming that the matrix material in the composite fails at the same fatigue stress level as does the monolithic matrix material or, if fibres fail, this will be at the failure level of the individual fibres. These curves were then compared to experimental data for all metal matrix composites and good agreement was obtained for all but the low cycle fatigue regime. A finite element programme was employed to predict fatigue life in the low cycle fatigue regime and the results were compared to the predictions made by the Theory of Cells. It was found that the finite element was no better at predicting the fatigue life of the composite than the Theory of Cells. Both systems however predicted an area of high stress in front of the fibre in the direction of loading. Fatigue tests were carried out on one particular material at both 200°C and 300°C and the fatigue life was compared to that predicted by the Theory of Cells. It was found that the predictions became increasingly inaccurate with increasing temperature.
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Analyse des hétérogénéités de microstructure et de microtexture héritées par transformation de phase β→α dans des pièces massives en alliage Ti-10V-2Fe-3Al : influence sur la dispersion des propriétés mécaniques / Analysis of microstructure and microtexture heterogeneities inherited by beta to alpha phase transformation in massive Ti-10V-2Fe-3Al alloy parts / influence on the dispersion of mechanical propertiesChini, Maria Rita 07 September 2018 (has links)
Les alliages de titane β-métastables comme le Ti-10V-2Fe-3Al se substituent progressivement aux alliages α/β dans les applications aéronautiques du fait de leur résistance spécifique améliorée. Leurs microstructures d'emploi sont cependant complexes et multi-échelles, constituées d'une matrice β (de grains millimétriques) partiellement transformée en nodules primaires αp (micrométriques) et en lamelles secondaires αs (sub-micrométriques). Les propriétés finales peuvent être très sensibles aux variations locales de microstructures et sont souvent non maîtrisées lors du forgeage de pièces massives. De plus la matrice β qui représente ~40% du volume et qui a un comportement élastique et plastique fortement anisotrope, comme la phase α, complique la compréhension des mécanismes de déformation en jeu. Le premier objectif de cette thèse est de mettre en œuvre des techniques de caractérisation multi-échelles (la diffraction des neutrons, l'imagerie électronique couplée à l'analyse d'image et l'EBSD, la reconstruction des microtextures de haute température β/αp) pour analyser efficacement la microstructure/texture des constituants β/αp/αs et caractériser leurs hétérogénéités au sein de demi-produits et de pièces obtenues par matriçage. Les résultats permettent d'analyser la fragmentation des grains β en sous-grains, les macrozones αp, le maintien de relation d'orientation entre β/αp et l'organisation des lamelles αs en colonies ou paniers tressés, en pointant les différences de taille de domaines révélés par la cristallographie et l'imagerie standard. Le second objectif est d'appliquer cette méthodologie à l'analyse de facies de rupture d'éprouvettes présentant un comportement singulier (en traction ou en fatigue) pour caractériser les configurations microstructurales à l'origine de l'amorçage de fissures. Cette analyse a principalement été réalisée par polissage manuel du faciès couplé à des acquisitions EBSD mais également en exploitant le potentiel de l'imagerie 3D par MEB-FIB (Focus Ion Beam) et la technique TKD (Transmission Kikuchi Diffraction) sur lame mince prélevée au niveau d'un site d'amorçage par FIB. Enfin, cette étude expérimentale a été complétée par une première approche en simulation micromécanique sur une microstructure modèle 100% β. L'objectif était d'évaluer l'influence de l’anisotropie élastique de la phase β sur la genèse de contraintes d'incompatibilités dans les régimes élastique et élasto-plastique. L'ensemble des résultats contribue à une meilleure compréhension des variations de propriétés mécaniques en lien avec la microstructure locale / The β-metastable titanium alloys such as Ti-10V-2Fe-3Al are gradually replacing α/β alloys in aeronautical applications thanks to their improved specific strength. However, their microstructures are complex and multi-scale, consisting of a β matrix (of millimetric grains) partially transformed into primary αp nodules (micrometric) and secondary αs lamellae (sub-micrometric). The final mechanical properties are very sensitive to local variations of the microstructure, which are not always fully controlled during forging of massive parts. Moreover, the β matrix, which represent 40% of the volume and whose elastic and plastic behavior is strongly anisotropic (like the α phase) complicates the understanding of the mechanisms of deformation. The first objective of this thesis was to efficiently characterize the microstructure/texture of the different constituents (β/αp/αs) and their heterogeneities within half-finished products and forged parts by using techniques of multi-scale characterization (neutron diffraction, electronic imaging coupled with image analysis and EBSD, reconstruction of high temperature microtextures β/αp). As a result the fragmentation of the β grains into subgrains, the αp macrozones, the destruction of the orientation relation between β/αp and the organization of the αs lamellae in colonies or basket weave was quantified and the differences in size of domains revealed by crystallography and by standard imaging were pointed out. The second objective is to apply this methodology to the analysis of fracture surfaces of samples exhibiting singular behavior (in tension or in fatigue) in order to characterize the microstructural configurations leading to early cracking. This analysis was mainly performed by manual polishing coupled with EBSD acquisitions but also by using 3D imaging by SEM-FIB (Focus Ion Beam) and TKD (Transmission Kikuchi Diffraction) technique on a thin foil FIB-extracted from the crack initiation site. Finally, this experimental study was completed by a micromechanical simulation on a 100% β model microstructure. The objective was to evaluate the influence of the elastic anisotropy of the β phase on the genesis of incompatibility stresses in the elastic and elasto-plastic regimes. The overall results contribute to a better understanding of the variations of mechanical properties related to the local microstructure
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