Struktura a mechanické vlastnosti nástřiku Ti-6Al-4V připraveného metodou Cold Spray / Strucure and mechnical properties of cold sprayed Ti-6Al-4V layer

Sabela, Jakub

January 2019

Diploma thesis deals in the first part with recent knowledge of cold spray, its mechanism and parameters of deposition, advanced coatings made by cold spray and their applications, knowledge of Ti-6Al-4V coatings and their heat treatment. Deposit of Ti- 6Al-4V powder was made by cold spray process. In experimental part, microstructure and mechanical properties of supplied and its heat treated material were observed and examined. Mechanical properties and microstructure remained unchanged by annealing at 600 °C as in the case of supplied material. Recrystallization occured in microstructure of and phases by annealing at 800 °C. Grains were emerged in microstructure and mechanical properties were decreased. Mechanical properties were improved by annealing at 900 °C due to quenching. Microstructure consists of and ’ phases. Mechanical properties were the worst for annealed material at 1000 °C because of coarsed grains. Material which was annealed at 800 °C, quenched and precipitation hardened had the best microstructure and mechanical properties.

Observations of energy transfer mechanisms associated with internal waves

Gomez Giraldo, Evelio Andres

January 2007

[Truncated abstract] Internal waves redistribute energy and momentum in stratified lakes and constitute the path through which the energy that is introduced at the lake scale is cascaded down to the turbulent scales where mixing and dissipation take place. This research, based on intensive field data complemented with numerical simulations, covers several aspects of the energy flux path ranging from basin-scale waves with periods of several hours to high frequency waves with periods of few minutes. It was found that, at the basin-scale level, the horizontal shape of the lake at the level of the metalimnion controls the period and modal structure of the basin-scale natural modes, conforming to the dispersion relationship of internal waves in circular basins. The sloping bottom, in turn, produces local intensification of the wave motion due to focusing of internal wave rays over near-critical slopes, providing hot spots for the degeneration of the basin-scale waves due to shear instabilities, nonlinear processes and dissipation. Different types of high-frequency phenomena were observed in a stratified lake under different forcing conditions. The identification of the generation mechanisms revealed how these waves extract energy from the mean flow and the basin-scale waves. The changes to the stratification show that such waves contribute to mixing in different ways . . . Detailed field observations were used to develop a comprehensive description of an undocumented energy flux mechanism in which shear-instabilities with significant amplitudes away from the generation level are produced in the surface layer due to the shear generated by the wind. The vertical structure of these instabilities is such that the growing wave-related fluctuations strain the density field in the metalimnion triggering secondary instabilities. These instabilities also transport energy vertically to the thermocline where they transfer energy back to the mean flow through interaction with the background shear.

Energy transfer

Stratified flow

Hydrodynamics

Water waves

Lakes

Internal waves

Internal waves

Physical limnology

Stratified lakes

Natural modes

Shear instability

Energy transfer

Modélisation numérique de la mise en suspension de sédiments cohésifs par instabilités de cisaillement / Numerical modeling of cohesive sediment suspension by shear instabilities

Harang, Alice

22 February 2013

Ce travail numérique porte sur le comportement de la lutocline (interface entre l'eau et la vase fluide) en écoulement cisaillé et vise à une meilleure compréhension des mécanismes de remise en suspension de sédiments cohésifs. La crème de vase, ou vase partiellement solidifiée, est modélisée par un fluide homogène équivalent miscible dans l'eau, de rhéologie newtonienne ou viscoplastique. Une étude de l'hydrodynamique de cet écoulement stratifié en densité ainsi qu'en viscosité est ensuite proposée. Considérant une crème de vase initialement non-turbulente, l'étude se focalise sur le développement des instabilités au niveau de la lutocline et de la transition vers une couche de mélange turbulente. La particularité de cet écoulement réside dans la forte viscosité de vase et son seuil de mise en mouvement lorsqu'elle présente un caractère viscoplastique. Une étude de stabilité linéaire permet d'évaluer l'influence des différents paramètres de l'écoulement, notamment les stratifications en densité et en viscosité. La stratification en viscosité augmente sensiblement le taux de croissance de l'instabilité pour des nombres de Reynolds intermédiaires. L'évolution non-linéaire de l'écoulement est ensuite étudiée en utilisant des simulations numériques directes, la stratification en viscosité entrainant un épaississement de la couche de mélange finale. Enfin, des simulations numériques directes basées sur un modèle de fluide de Bingham régularisé permettent d'étudier l'influence de la contrainte seuil sur le développement de l'instabilité. / This numerical study focuses on the behavior of the lutocline in a shear flow and aims to better understand the mechanism of resuspension of cohesive sediment. Mud flow, or mud partially consolidated, is modeled by an equivalent homogenous fluid miscible in water, with newtonian or viscoplastic rheology. A study of the hydrodynamics of this shear flow, stratified both in density and viscosity, is presented. Considering an initially laminar mud flow, the focus of the study is on the development of instabilities on the lutocline and the transition to a turbulent mixing layer. The specificity of this flow lies on the large viscosity of the mud and its threshold to be put in motion, when it presents a viscoplastic feature. A linear stability study assesses the influence of the various parameters of the flow, especially of density and viscosity stratification. The viscosity stratification slightly increases the growth rate of the instability for intermediate Reynolds numbers. Then, the non linear evolution of the flow is studied by using direct numerical simulations, viscous stratification leading to a thicker mixing layer. At last, direct numerical simulations based on a Bingham regularized model, permits to study the influence of the critical strain on the development of the instability.

Instabilité de cisaillement

Transition vers la turbulence

Écoulement stratifié

Écoulement géophysique

Estuaire

Mise en suspension

Shear instability

Transition to turbulence

Cohesive sediment (mud flow)

Mixing and dispersion

Statified flow

Geophysical flow

Estuary

Suspension