A micro-CT investigation of density changes in pressboard due to compression

Stjärnesund, Johan

January 2018

Pressboard, a high-density cellulose-based product, is used both as load bearing structures and dielectric insulation in oil-filled power transformers. During transformer operation, mechanical forces and vibrations are applied on the material. In particular, this investigation focuses on pressboard sheets placed between the turns of transformer windings, called the spacers, which during short circuit are subjected to high compressive forces of impulse nature. As a result of these forces, remaining deformations are created in the components. One step to reduce the negative consequences that come from the deformations is to understand how the fiber structure of the material changes by these forces, thus finding the week link. Understanding these changes could lead to future modification of the material to better withstand short circuits. To see the fiber structure and its changes in the material, pressboard has been investigated with a micro-CT at the Division of Applied Mechanics at Uppsala University. The scanned images have been reconstructed and analyzed in NRecon, CTAnalyser, and Matlab to investigate the density distribution changes and to identify the densification patterns. The study shows that pressboard initially has an inhomogeneous density distribution through the thickness and after mechanical indentations, the densification tends to begin in the more porous parts of the material. The project also included a prediction of the densification pattern, performed by finite element analysis (FEA) using a simplified material model. The results show that a material model with varying Young’s modulus through the thickness, based on a stiffness and porosity relationship, can produce similar densification patterns as in the experiments.

Micro computed tomography

μCT

pressboard

density

densification

Materials Engineering

Materialteknik

A µCT Investigation of the Electrical Breakdown Mechanisms in Mica/Epoxy Machine Insulation / Undersökning av de elektriska nebrytningsmekanismerna i glimmer/epoxi-isolation

Saxén, Carl

January 2017

Mica/Epoxy machine insulation is a composite material of the mineral mica, fibre-glass mesh and epoxy resin. The material is used in motors and generators rated for high voltage, where the material must withstand multiple stresses such as elevated temperatures, mechanical and electrical stresses. This is a novel investigation that focuses on the breakdown mechanisms related to electrical stress of the insulation. These include partial discharges and electrical treeing. The micro Computed Tomography (μCT) uses a series of X-ray images to visualise the interior. This provides a method for non-invasively examination of the insulation for any signs of material degradation caused by high electrical fields. The following thesis presents an initial study on how this material system interacts with the μCT, the production of 16 samples capable of being electrically aged and scanned in the μCT, with minimal interference, sample preparation and an analysis of the images produced from the μCT. The samples produced are electrically aged at different voltages after which they are scanned with the μCT. The images produced are then analysed for signs of material degradation using different software. Some of the samples did have a complete electrical breakdown and an attempt of correlating these breakdowns to the amount of folds in the insulation is done. It is found that samples with an aluminium core are suitable for μCT imaging. The visualisation of defects such as voids, resin rich parts or folds in insulation is also possible. The detection of material degradation due to electrical aging is not clear enough to draw any conclusions although some possible signs are found. For samples that had an electrical breakdown the result is much clearer. It shows the breakdown channels path inside the insulation, moving in between the mica tape layers. The samples with a complete breakdown also had tendencies that the breakdown channels followed the resin rich part in the sample. Even if no signs of electrical treeing can be seen in the samples during aging, the breakdown channels visualised still show what path the final treeing did take and how it did so by moving around the mica tape.

Breakdown

composite

computed tomography

epoxy

mica

resin

winding

x-ray

μCT

Materials Engineering

Materialteknik

μCT-Untersuchung sowie histologische Auswertung zur Knochendichte- und -dickenmessung der subchondralen Kompakta bei Osteoarthrose des Menschen / μCT based and histological examination of bone thickness and density in human subchondral compact bone under osteoarthritic conditions

Gödeke, Linus

18 December 2017

No description available.

610

Osteoarthrose

Knie

Knochen

Mensch

Kompakta

Subchondraler Knochen

Osteoarthritis

Knee

Bone

Subchondral

Human

μCT

Compact Bone

Medizin (PPN619874732)

An experimental-analytical scale-linking study on the crack-bridging mechanisms in different types of SHCC in dependence on fiber orientation

Curosu, Iurie, Muja, Erjon, Ismailov, Mansur, Hamza Ahmed, Ameer, Liebscher, Marco, Mechtcherine, Viktor

04 March 2023

A scale-linking, experimental study complemented by an analytical model was carried out to investigate the influence of fiber orientation on the crack-opening behavior of strain-hardening cement-based composites (SHCC). Three SHCC compositions were investigated with polyvinyl alcohol (PVA) and ultra-high molecular weight polyethylene (UHMWPE) fibers in combination with normal- and high-strength matrices. The micromechanical experiments with fiber inclinations of 0◦, 30◦, 45◦, and 60◦ involved fiber embedment in plain and fiber-reinforced specimens. The experimentally derived micromechanical parameters were input into an analytical crack-bridging model to assess the upscaling accuracy of the micromechanical results by comparing the predicted crack-bridging laws to the single-crack opening behavior of equivalent miniature SHCC specimens with controlled fiber orientation. This study yields new insights into the effect of fiber orientation on the crackbridging properties of different types of SHCC, assesses the link between micromechanical and composite scale properties, offers a solid experimental basis for refining the analytical models, and developing anisotropic materials models for SHCC in dependence on fiber orientation.

info:eu-repo/classification/ddc/690

ddc:690

La micro-architecture de l'os trabéculaire en croissance : variabilité tridimensionnelle normale et pathologique analysée par microtomodensitométrie / Trabecular bone microarchitecture during growth : three-dimensional normal and pathological variability analyzed by μCT-scan

Colombo, Antony

15 December 2014

L’imagerie médicale et la 3D, en pleine expansion dans le champ de l'anthropologie biologique, permettent d’explorer les structures internes tout en les préservant. L’étude de la micro-architecture osseuse trabéculaire permet d’appréhender la variabilité de l'os humain à une échelle jusqu'à présent peu explorée. Dans le cadre de cette recherche, cette variabilité est analysée et caractérisée en termes de croissance et de maturation, en fonction des critères individuels d’âge et de sexe, ainsi que dans des contextes pathologiques variés. Les images microtomodensitométriques des métaphyses humérales proximales de 43 sujets immatures (provenant de 3 collections ostéologiques de référence et couvrant l’ensemble des âges du développement) et celles de 8 cas paléopathologiques (représentant 5 étiologies différentes) ont été analysées pour quantifier la micro-architecture osseuse trabéculaire. Nos résultats montrent que cette micro-architecture varie pendant et entre les différentes phases de la croissance. Des corrélations avec l’âge sont mises en évidence, si elles n’expliquent pas suffisamment la variabilité observée pour en faire des estimateurs d'âge précis, il apparaît néanmoins que les variations relevées entre les différents volumes d’intérêt pourraient caractériser différentes périodes de la croissance. Les variables mesurées présentent des différences sexuelles significatives pendant l’adolescence, mais ne peuvent pas en l'état être utilisées pour la diagnose sexuelle. L'étude de la microarchitecture trabéculaire osseuse des sujets pathologiques atteste d’un développement anormal de l’os et donc du statut pathologique de l’individu observé. / Medical imaging and 3D reconstructions are used increasingly by anthropologists; they allow both investigating and preserving internal structures. Study of trabecular bone microarchitecture allows understanding variability of human skeleton at a smaller scale. This variability is observed and characterized in terms of normal growth and maturation according to age and sex, and for several pathological conditions. μCT scans of proximal metaphysis of humerus from 43 immature individuals (coming from 3 identified skeletons collections and representing all periods of age development) and 8 paleopathological cases (corresponding to 5 different etiologies) have been analyzed to quantify bone microarchitecture. Our results show that this microarchitecture varies during and between different phases of growth. Correlations with age are highlighted, even if they do not sufficiently explain the observed variability in order to represent specific age estimators; it nevertheless appears that the variations observed between the different volumes of interest could characterize different periods of growth. The measured variables showed significant sex differences only during the adolescence period, but they cannot be used, in the present state, for sex determination. The study of the trabecular bone microarchitecture of pathological individuals attests of the abnormal development of bone and therefore of their pathological status.

Microtomodensitométrie

Os trabéculaire

Micro-architecture

Croissance et maturation

Auxologie

Enfants

Paléopathologie

Humérus

, μCT-scan

Trabecular bon e

Microarchitecture,

Human growth and maturation

Auxology

Children

Paleopathology

Humerus