Moist Rayleigh Benard Convection

Prabhakaran, Prasanth

16 October 2018

No description available.

530

Physik (PPN621336750)

Convection

nucleation

secondary nucleation

clouds

pattern formation

Leidenfrost effect

flow visualization

drop fragmentation

Impacts de gouttes sur coussins d'air : surfaces super-hydrophobes, chaudes ou mobiles / Drop impacts on air cushions : super-hydrophobic, hot or moving surfaces

Lastakowski, Henri

17 December 2013

Cette thèse concerne l'étude de la dynamique d'impacts de gouttes, dans des situations de friction réduite entre le substrat solide et la goutte liquide. Cette diminution de friction s'est faite au moyen d'un film d'air inséré entre le liquide et le solide. Il existe plusieurs stratégies permettant l'existence de ce film d'air : la première est d'utiliser le phénomène de caléfaction, ou effet Leidenfrost : un liquide approché d'une surface chauffée au delà d'une température critique s'évapore suffisamment rapidement pour pouvoir léviter sur sa propre vapeur, et ainsi être isolé de la surface solide. Dans certaines conditions, les surfaces super-hydrophobes micro-texturées permettent au liquide de rester dans un état "fakir", c'est à dire de n'être en contact qu'avec le sommet de micro-piliers, le reste du liquide demeurant au dessus d'un coussin d'air. Enfin, il a également été constaté que l'écoulement d'air engendré par le mouvement d'une surface solide peut induire une force de portance sur une goutte, et ainsi lui permettre de léviter au dessus de cette surface / In this thesis we study the dynamic of drop impacts, in situations of low friction between the liquid and the solid surface. This low friction can be obtained thanks to an air cushion trapped between the liquid and the solid, which can be achieved by several ways. The first one is the Leidenfrost effect : when a liquid is moved close to a hot surface, the evaparation rate can be sufficient make liquid levitate on its own vapour. In certain conditions, onto micro-patterned super-hydrophobic surfaces, a drop can be in a "fakir" state, which means that the contact is limited to the top of micro-pillars, the rest of the liquid is at the top of an air cushion. Finally, we also observed that the air flow due to a moving surface can generate a lift force which can permit the levitation of the drop

Gouttes

Impacts

Friction

Écoulements aux interfaces

Caléfaction

Surfaces super-hydrophobes

Drops

Impacts

Friction

Interfacial flows

Leidenfrost effect

Superhydrophobic surfaces

532

Vývoj metod in-line tepelného zpracování / Developement of In-Line Heat Treatment Methods

Hnízdil, Milan

January 2012

In-line heat treatment is a part of technological process uses a phase and structure changes to obtain required mechanical properties. Heat treatment of rolled products offers a reduction of steel making costs and a creation of new steel products. For example the TRIP steel is a part of modern steels which is used in the automobile industry for higher safety of passengers. The heat treatment is often described in the literature. But the authors are often focused on the method how to get the required structure and mechanical properties for different metallic materials. Nevertheless just few articles are focused on the technical observing of temperature regimes and which parameter is necessary to consider during designing the cooling section. Eight parameters were tested by the experimental way to examine their influence on the cooling intensity. They were: gravity (orientation of the cooled surface), coolant pressure, amount of coolant spraying on the surface (the flow rate), rolling velocity, nozzle configuration, kind of nozzles (full cone or flat fan nozzle), coolant temperature and the surface quality (surface roughness and scales). All these parameters have an influence the heat transfer coefficient. Based on knowledge gained in this work was created the cooling section, which comply with the required cooling temperature regimes.

REACTION ACCELERATION AT INTERFACES STUDIED BY MASS SPECTROMETRY

Yangjie Li (10971108)

04 August 2021

<p>Various organic reactions, including important synthetic reactions involving C–C, C–N, and C–O bond formation as well as reactions of biomolecules, are known to be accelerated when the reagents are present in confined volumes such as sprayed or levitated microdroplets or thin films. This phenomenon of reaction acceleration and the key role of interfaces played in it are of intrinsic interest and potentially of practical value as a simple, rapid method of performing small-scale synthesis. This dissertation has three focusing subtopics in the field of reaction acceleration: (1) application of reaction acceleration in levitated droplets and mass spectrometry to accelerate the reaction-analysis workflow of forced degradation of pharmaceuticals at small scale; (2) fundamental understanding of mechanisms of accelerated reactions at air/solution interfaces; (3) discovery the use of glass particles as a `green' heterogeneous catalysts in solutions and systematical study of solid(glass)/solution interfacial reaction acceleration as a superbase for synthesis and degradation using high-throughput screening.</p><p><br></p><p>Reaction acceleration in confined volumes could enhance analytical methods in industrial chemistry. Forced degradation is critical to probe the stabilities and chemical reactivities of therapeutics. Typically performed in bulk followed by LC-MS analysis, this traditional workflow of reaction/analysis sequence usually requires several days to form and measure desirable amount of degradants. I developed a new method to study chemical degradation in a shorter time frame in order to speed up both drug discovery and the drug development process. Using the Leidenfrost effect, I was able to study, over the course of seconds, degradation in levitated microdroplets over a metal dice. This two-minute reaction/analysis workflow allows major degradation pathways of both small molecules and therapeutic peptides to be studied. The reactions studied include deamidation, disulfide bond cleavage, ether cleavage, dehydration, hydrolysis, and oxidation. The method uses microdroplets as nano-reactors and only require a minimal amount of therapeutics per stress condition and the desirable amount of degradant can be readily generated in seconds by adjusting the droplet levitation time, which is highly advantageous both in the discovery and development phase. Built on my research, microdroplets can potentially be applied in therapeutics discovery and development to rapidly screen stability of therapeutics and to screen the effects of excipients in enhancing formulation stabilities.</p><p><br></p><p>My research also advanced the fundamental understanding of reaction acceleration by disentangles the factors controlling reaction rates in microdroplet reactions using constant-volume levitated droplets and Katritzky transamination as a model. The large surface-to-volume ratios of these systems results in a major contribution from reactions at the air/solution interface where reaction rates are increased. Systems with higher surface-active reactants are subject to greater acceleration, particularly at lower concentrations and higher surface-to-volume ratios. These results highlight the key role that air/solution air/solution interfaces play in Katritzky reaction acceleration. They are also consistent with the view that reaction increased rate constant is at least in part due to limited solvation of reagents at the interface.</p><p><br></p><p><br></p><p>While reaction acceleration at air/solution interfaces has been well known in microdroplets, reaction acceleration at solid/solution interfaces appears to be a new phenomenon. The Katritzky reaction in bulk solution at room temperature is accelerated significantly by the surface of a glass container compared to a plastic container. Remarkably, the reaction rate is increased by more than two orders of magnitude upon the addition of glass particles with the rate increasing linearly with increasing amounts of glass. A similar phenomenon is observed when glass particles are added to levitated droplets, where large acceleration factors are seen. Evidence shows that glass acts as a ‘green’ heterogeneous catalyst: it participates as a base in the deprotonation step and is recovered unchanged from the reaction mixture. </p><p><br></p><p>Subsequent to this study, we have systematically explored the solid/solution interfacial acceleration phenomena using our latest generation of a high-throughput screening system which is capable of screening thousands of organic reactions in a single day. Using desorption electrospray ionization mass spectrometry (DESI-MS) for automated analysis, we have found that glass promotes not only organic reactions without organic catalysts but also reactions of biomolecules without enzymes. Such reactions include Knoevenagel condensation, imine formation, elimination of hydrogen halide, ester hydrolysis and/or transesterification of acetylcholine and phospholipids, as well as oxidation of glutathione. Glass has been used as a general `green' and powerful heterogeneous catalyst.</p>

Organic Chemistry

Catalysis and Mechanisms of Reactions

Reaction Kinetics and Dynamics

mass spectrometry

reaction acceleration

Leidenfrost effect

forced degradation

heterogeneous catalysis

glass

high-throughput screening

Vývoj metod in-line tepelného zpracování / Developement of In-Line Heat Treatment Methods

Hnízdil, Milan

January 2012

In-line heat treatment is a part of technological process uses a phase and structure changes to obtain required mechanical properties. Heat treatment of rolled products offers a reduction of steel making costs and a creation of new steel products. For example the TRIP steel is a part of modern steels which is used in the automobile industry for higher safety of passengers. The heat treatment is often described in the literature. But the authors are often focused on the method how to get the required structure and mechanical properties for different metallic materials. Nevertheless just few articles are focused on the technical observing of temperature regimes and which parameter is necessary to consider during designing the cooling section. Eight parameters were tested by the experimental way to examine their influence on the cooling intensity. They were: gravity (orientation of the cooled surface), coolant pressure, amount of coolant spraying on the surface (the flow rate), rolling velocity, nozzle configuration, kind of nozzles (full cone or flat fan nozzle), coolant temperature and the surface quality (surface roughness and scales). All these parameters have an influence the heat transfer coefficient. Based on knowledge gained in this work was created the cooling section, which comply with the required cooling temperature regimes.