3D short fatigue crack investigation in beta titanium alloys using phase and diffraction contrast tomography

Herbig, Michael

26 January 2011

X-Ray Diffraction Contrast Tomography (DCT) is a recently developed, non-destructive synchrotron imaging technique which characterizes microstructure and grain orientation in polycrystalline materials in three dimensions (3D). By combining it with propagation based phase contrast tomography (PCT) it is for the first lime possible to observe in situ the 3D propagation behavior of short fatigue cracks (SFCs) within a set of fully characterized grains (orientation and shape). The combined approach, termed 3D X-ray Tomography of short cracks and Microstructure (3DXTSM), has been developed on the metastable beta titanium alloy "Beta21S". A large part of this work deals with the development of the 3DXTSM methodology. In the combined dataset, each point on the 3D fracture surface can be associated with a multidimensional data structure containing variables describing the grain orientation, the local fracture surface normal and the propagation history. The method uses a surface mesh composed of triangles that describes the crack (in other words: the fracture surface) in the last propagation state measured. Grain orientations, crack fronts, local growth rates and grain boundaries can be visualized by assigning colors to this mesh. The data structure can be interrogated in a number of different ways. Tools for extracting pole figures and pole density distribution functions have been implemented. An algorithm was developed that is capable of measuring the 3D local growth rate of a crack containing branches. The accuracy of the grain boundaries as reconstructed with OCT was evaluated and the elastic constants of Beta21S were determined.

[SPI:OTHER] Engineering Sciences/Other

NDT - Non destructive testing

Cracking

Short crack

Diffraction contrast tomography

Phase contrast tomography

3D Imaging

Titanium

Characterisation of the deformation mechanisms in HCP metals by combined use of X-ray imaging and diffraction techniques

Nervo, Laura

January 2015

We envisage a fundamental study of the physical mechanisms (dislocation slip versus deformation twinning) involved in plastic deformation of hexagonal close-packed (HCP) metals like titanium and magnesium. A novel combination of X-ray imaging and diffraction techniques, termed X-ray diffraction contrast tomography (DCT), will be used to investigate details of the deformation process in the bulk of polycrystalline specimen. DCT provides access to the position, 3D shape, (average) orientation and elastic strain tensor of grains in polycrystalline sample volumes containing up to 1000 grains and more. Ultimately, an extension of the X-ray DCT technique is associated with a section topography methodology on the same instrument. This combination enables the measurement of local orientation and elastic strain tensors inside selected bulk grains. A very preliminary study of this approach is carried out on a magnesium alloy, underlying the current limitations and possible improvements of such approach. In this thesis, the data acquisition and analysis procedures required for this type of combined characterisation approach have been developed. The work is supported by the use of neutron diffraction, for an in-situ loading experiments, and two-dimensional electron backscatter diffraction (EBSD), for the initial microstructure of the materials and cross-validation of the results obtained with the X-ray DCT technique.

539.7

3D short fatigue crack investigation in beta titanium alloys using phase and diffraction contrast tomography / Caractérisation tridimensionnelle des fissures de fatigue courtes dans les alliages de titane métastable (béta) par tomographie en contraste de phase et de diffraction

Herbig, Michael

26 January 2011

La tomographie en contraste de diffraction est une nouvelle technique non destructive d'imagerie synchrotron qui caractérise la microstructure et l'orientation des grains dans les matériaux polycristallins en trois dimensions (3D). En la combinant avec la tomographe par contraste de phase. Il est pour la première fois possible d'observer in situ la propagation 3D des fissures de fatigue courtes au sein d'un ensemble de grains entièrement caractérisé (orientation et forme). L'approche combinée, appelée « tomographie tri-dimensionnelle par rayons X des fissures courtes et de la microstructure »(T3DXFM), a été développée sur l’alliage de titane métastable "Beta21S". Une grande partie de ce travail porte sur le développement de la méthodologie T3DXFM. Dans le jeu de données combinées, chaque point de la surface de rupture 3D peut être associé à une structure de données multidimensionnelle contenant des variables décrivant l'orientation des grains, l'orientation locale de la surface de rupture ainsi que l'histoire de la propagation. La méthode utilise un maillage de surface composé de triangles qui décrit la fissure (en d'autres termes: la surface de rupture) dans l'état de propagation mesuré au dernier cycle de fatigue réalisé. Les orientations des grains, les différents fronts de la fissure, les vitesses de croissance locales ainsi que les joints de grains peuvent être visualisés en attribuant des couleurs à ce maillage. Des outils d'extraction des figures de pôle ont été créés et mis en œuvre. Un algorithme a été développé qui est capable de mesurer la vitesse de propagation locale 30 d'une fissure contenant des branchements. / X-Ray Diffraction Contrast Tomography (DCT) is a recently developed, non-destructive synchrotron imaging technique which characterizes microstructure and grain orientation in polycrystalline materials in three dimensions (3D). By combining it with propagation based phase contrast tomography (PCT) it is for the first lime possible to observe in situ the 3D propagation behavior of short fatigue cracks (SFCs) within a set of fully characterized grains (orientation and shape). The combined approach, termed 3D X-ray Tomography of short cracks and Microstructure (3DXTSM), has been developed on the metastable beta titanium alloy "Beta21S". A large part of this work deals with the development of the 3DXTSM methodology. In the combined dataset, each point on the 3D fracture surface can be associated with a multidimensional data structure containing variables describing the grain orientation, the local fracture surface normal and the propagation history. The method uses a surface mesh composed of triangles that describes the crack (in other words: the fracture surface) in the last propagation state measured. Grain orientations, crack fronts, local growth rates and grain boundaries can be visualized by assigning colors to this mesh. The data structure can be interrogated in a number of different ways. Tools for extracting pole figures and pole density distribution functions have been implemented. An algorithm was developed that is capable of measuring the 3D local growth rate of a crack containing branches. The accuracy of the grain boundaries as reconstructed with OCT was evaluated and the elastic constants of Beta21S were determined.

CND - Contrôle non destructif

Fissuration

Fissure courte

Tomographie en contraste de diffraction

Tomographie par contraste de phase

Imagerie 3D

Titane

NDT - Non destructive testing

Cracking

Short crack

Diffraction contrast tomography

Phase contrast tomography

3D Imaging

Titanium

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