Ecoulements confinés à haut et bas Reynolds : génération millifluidique de mousse et drainage de films minces de copolymères / Confined flow at high and low Reynolds : Millifluidic foaming and drainage of thin copolymer films

Gaillard, Thibaut

03 November 2016

La mousse est un matériau fascinant nous accompagnant au quotidien depuis des siècles, mais sa complexité fait qu’il est difficile de comprendre et contrôler ses propriétés. L’objet de cette thèse expérimentale est de montrer par deux exemples que si l’on contrôle les écoulements ayant lieu lors de la génération de la mousse et pendant sa vie on peut alors avoir un très bon contrôle de ses propriétés structurelles et sa stabilité. Dans la première partie j’étudie la génération de mousse constituée de bulles micrométriques par un écoulement diphasique cyclique dans un tuyau connectant deux seringues. Cette technique permet de varier la fraction liquide sans affecter les distributions de tailles de bulle. Je montre que ces distributions sont essentiellement contrôlées par la présence de constrictions dans le tuyau connectant les seringues et par les propriétés physico-chimiques de la solution moussante. Mes résultats montrent que ce n’est pas le vieillissement de la mousse mais bien les instabilités hydrodynamiques qui contrôlent la taille caractéristique des bulles. Avec diverses expériences modèles de millifluidique en régime inertiel je mets en évidence ce qui semble être un nouveau processus de fragmentation de bulles. L’accélération et la décélération des bulles lors de leur passage dans une constriction seraient le moteur de cette fragmentation. Le lien précis reste à quantifier dans de futurs travaux. Dans un second temps je montre qu’il est possible de faire des films minces, libres et d’une grande stabilité avec un fondu de copolymère en peigne de PDMS-g-PEG-PPG à température ambiante, sans ajout d’agents stabilisants. Les expériences de caractérisation indiquent que c’est un liquide newtonien ayant une faible tension de surface ne présentant pas de transition de phase à température ambiante. J’ai étudié de manière approfondie le drainage de films verticaux et horizontaux, qui se fait par un écoulement laminaire du liquide confiné entre les deux interfaces liquide/air. A l’aide d’une balance à film mince microfluidique développée pour l’étude des liquides visqueux je rapporte l’apparition de stratifications dans les films très minces. Celles-ci ont la même taille que la longueur caractéristique du fondu, lié soit à la taille du polymère, soit à une micro-séparation de phase. Le drainage et la stabilité sont donc potentiellement contrôlés par cet écoulement stratifié, mais il reste à comprendre si la stratification est la conséquence d’un simple effet de confinement ou d’une micro-séparation de phase près de l’interface. / Foam is a fascinating matter which has been broadly used for centuries, but its complexity makes it difficult to understand and control its properties. The subject of this experimental thesis is to show through two examples that by controlling the flows during the generation and lifetime of the foam its stability and structural properties may be better controlled. In the first part I study the generation of foams made of microscopic bubbles by a cyclic diphasic flow in a tube connecting two syringes. With this technique one can vary the liquid fractions without changing the bubble size distributions. I show that these distributions are mainly controlled by the presence of constrictions in the tubing connecting the syringes and by the physico-chemical properties of the foaming solution. My results show that the characteristic bubble size is not fixed by foam ageing effects but by hydrodynamic instabilities. With various millifluidic model experiments in the inertial regime I highlight what seems to be a new mechanism of bubble fragmentation. The acceleration and deceleration of the bubbles when going through a constriction would be the driving effect of this process. The precise link still has to be established. In the second part I show that it is possible to make highly stable free-standing films made of a comb-copolymer melt of PDMS-g-PEG-PPG, at room temperature, and without stabilising agents. The characterisation of this melt reveals that it is a newtonian liquid with a low surface tension and not subject to phase transitions at room temperature. I studied intensively the drainage of vertical and horizontal films, which is a laminar flow of the liquid confined between its two liquid/air interfaces. Using a millifluidic thin film pressure balance, developed for the study of viscous liquids, I report the formation of stratifications in very thin films. Theses stratifications have the same step hight than the characteristic length of the melt which we measured for the bulk, linked either to the size of the macromolecules or to micro-phase separation. The drainage and stability might be controlled by this stratified flow, but we still have to understand if it results from a simple confinement effect or from an interfacially driven micro-phase separation.

Moussage

Millifluidique

Distributions de taille de bulles

Instabilités hydrodynamiques

Fondu de copolymères en peigne

Stabilité de films minces libres

Foaming

Millifluidic

Bubbles size distributions

Hydrodynamic instabilities

Comb-Like copolymer melt

Ultralehké betony s vysokými užitnými vlastnostmi / Ultralight concrete with high utility properties

Popelková, Adéla

January 2018

This diploma thesis deals with the technology of production of ultralight concretes using direct lighten cementing compound and at the same time indirect lighten using lightweight aggregate. Further work deals with the choice of suitable raw materials for these concretes. The practical part consists of a proposal of several different recipes, experimental verification and by comparing their properties in a fresh or hardened state.

Engineered carbon-based scaffolds for hard and soft tissue repair, reconstruction or regeneration

Czarnecki, Jarema S.

January 2013

No description available.

Materials Science

Medicine

Mechanical Engineering

Biomedical Engineering

biomaterials

graft

tissue engineering

bioengineering

carbon

nanotechnology

bone

tendon

skin

transplant

organ

tissue scaffold

implant

tissue repair

regeneration

carbon fiber

composite

foaming

molding

biodegradable

bioresorbable

Rsn-2-mediated directed foam enrichment of β-lactamase

Krause, Thomas, Keshavarzi, Behnam, Dressel, Jannes, Heitkam, Sascha, Ansorge-Schumacher, Marion B.

30 May 2024

Today, the availability of methods for the activity-preserving and cost-efficient downstream processing of enzymes forms a major bottleneck to the use of these valuable tools in technical processes. A promising technology appears to be foam fractionation, which utilizes the adsorption of proteins at a gas–liquid interface. However, the employment of surfactants and the dependency of the applicability on individual properties of the target molecules are considerable drawbacks. Here, we demonstrate that a reversible fusion of the large, surface-active protein Ranaspumin-2 (Rsn-2) to a β-lactamase (Bla) enabled both surfactant-free formation of a stable foam and directed enrichment of the enzyme by the foaming. At the same time, Bla maintained 70% of its catalytic activity, which was in stark contrast to the enzyme without fusion to Rsn-2. Rsn-2 predominantly mediated adsorption. Comparable results were obtained after fusion to the structurally more complex penicillin G acylase (PGA) as the target enzyme. The results indicate that using a surface-active protein as a fusion tag might be the clue to the establishment of foam fractionation as a general method for enzyme downstream processing.

info:eu-repo/classification/ddc/570

ddc:570

Využití pěnoasfaltu v asfaltových směsích / Usage of foam bitumens in asphalt mixtures

Venclíková, Michaela

January 2018

In this diploma thesis there are described the issues use of foamed bitumen as binder in asphalt mixtures. The thesis is divided into two parts, theoretical and practical. The aim of theoretical part was to elaborate an overview of technologies, which allow to reduce the temperature during the production and laying of asphalt mixtures. The aim of the practical part was to compare the selected empirical and functional parameters of two types of asphalt mixtures produced in two variants, with hot bitumen and foamed bitumen. Attention was paid mainly to stiffness and low temperature parameters.

Effect of the presence of a dispersed phase (solid particles, gas bubbles) on the viscosity of slag

Albertsson, Galina

January 2009

The viscosities of a set of silicone oils containing different size ranges of charcoal or paraffin particles as well as the viscosities of silicone oil foams were measured at room temperature in order to determine the effect of dispersed phase on the viscosity of a liquid and its effect on foaming ability. The effective viscosity of the samples increased with volume fraction of the second phase. The foaming ability was improved by the presence of the particles. The improved foaming effect was for the most part not a result of the increased viscosity. No connection between the particle size and the effective viscosity could be determined. On the other hand particle morphology and the particle size distribution had effect on the effective viscosity. The viscosity data were compared with a number of existing equations for the estimation of effective viscosity. Einstein-Roscoe equation is suitable for two-phase mixtures containing globular particles with narrow particle size distribution and low interfacial tension. New mathematical models are required for effective viscosity prediction, where the suspending phase viscosity, effect of the interfacial tension, as well as the particle morphology should be taken in consideration.

Mathematical modelling

Physical modelling

Slag viscosity

Slag foaming.

вязкость шлака

вспенивания шлака

Matematisk modellering

fysisk modellering

slaggviskositet

slaggskumning

Metallurgy and Metallic Materials

Metallurgi och metalliska material

New methodologies of Silk Proteins processing for advanced applications

Bucciarelli, Alessio

29 October 2019

Silk fibroin is a widely studied material in the context of tissue engineering. Thanks to its versatility and impressive properties, the fields where silk fibroin is used have grown. In particular, silk fibroin has proved to be useful in all the cases when an interface with living tissues is needed (e.g. biophotonics, bioelectronics). As a consequence of this increasing interest, a wide range of protocols have been developed to prepare different materials starting from cocoons. The aim of this thesis is to investigate new strategies to fabricate silk fibroin-based materials, either improving previously developed protocols or proposing new methodologies both with the purpose to overcome certain limitations of current approaches and to propose new areas of application. We choose to work on three topics: the production of patterns using photolithography on a fibroin photoresist films (fibroin photocrosslinkable photoresist, FPP), the production of sponges made from a chemically modified version of the native protein (Methacrylated fibroin, Sil-MA), and the production of a solid bulk resin made starting from the regenerated protein. In the case of the FPP (and its counterpart made of sericine, SPP) the fabrication of films and pattern was restricted to the use of harsh chemicals. In addition, the resulting material had a roughness that limits its use in optical applications, making the determination of the refractive index (RI) not possible. The novelty of our work consisted in the modification of the original protocol to make it environmentally sustainable and to decrease the roughness in order to use ellipsometry to determine the RI dispersion. The broadly used silk-based sponges can be prepared by several protocols but they all suffer of the same limitations: the sponges are stabilized only by physical crosslinking (the change from the random to the crystalline secondary structure), and there are no clear models that correlate the sponge properties to their composition. We produced a new sponge, chemically crosslinked, whose stability was ensured by the creation, of chemical bonds between the protein chains during an UV curing. This task was accomplished using a simple protocol and a statistical method to model the composition-properties relations. The possibility to obtain a bulk, non-porous solid monolith from fibroin (solid-fibroin) has been received attention only in the last few years. This material is produced by a transition from solution to solid through solvent evaporation, a very slow process that takes weeks to be completed. The advantage of this transition is that it occurs at room temperature, allowing the addition of thermally degradable molecules (e.g. enzymes). We were able to optimize a procedure to produce the same material by compression of a silk sponge at high pressure and low temperature. The advantage of this method is the lower amount of time required to produce the material, minutes instead of days.