Změny antikorozního systému nemrznoucích teplonosných kapalin / Changes anticorrosive system non - freezing heat transfer liquid

Pexa, Michal

January 2008

This diploma thesis is focused on proposition of non-freezing heat transfer fluid for solar systems. Fluid will be based on mixture of new available compound propane-1,3-diol with water and modern corrosion inhibitors. Then will be investigate, if this new compound is competetive to common used liquids like ethylene glycol or propylene glycol.

Kapalné elektrolyty pro lithno-iontové akumulátory / Liquid electrolytes for lithium-ion accumulators

Štichová, Zuzana

January 2011

The aim of this master´s thesis was the measurement of electrical conductivity and dynamic viscosity of the electrolytes. Based on these measurements to verify Walden theorem between measured variables. Electrolytes were used on sulfolane base in combination with propylene carbonate and salt. The thesis also deals with the measuring method of dielectric properties of electrical and optical method with a refractometer. The freezing point of combination of sulfolan and propylene carbonate were determined by cryoscopy.

Analýza reologických vlastností teplonosných kapalin / Rheological properties analysis of heat transfer fluids

Neradil, Petr

January 2016

This master thesis deals with the issue of heat transfer fluids for solar thermal system. It discusses the different types of solar systems and their use. It also describes the different types of heat-transfer fluids for solar thermal systems and analyzes the basic chemical composition of commercially available heat-transfer fluids. There are described the properties of these fluids and methods for measuring certain properties. The practical part deals with measuring the temperature dependence of density and dynamic viscosity of alternative and commercially available heat-transfer fluids, determining the freezing point and compares the results.

Ekologické rozdíly mezi bylinami a dřevinami a evoluce bylinnosti / Ecological differences between herbs and woody plants, and evolution of the herbaceous habit

Klimeš, Adam

January 2020

Ecological differences between herbs and woody plants, and evolution of the herbaceous habit Adam Klimeš, doctoral thesis Abstract Flowering plants (angiosperms), which make up most present-day vegetation, were originally woody. While flowering plants have repeatedly given rise to herbaceous lineages since their first appearance, we lack a clear explanation for these common evolutionary events. Freezing temperatures and drought periods have been proposed as factors which had caused huge success of the younger growth form but the evidence is very limited and not in favour of these hypotheses. In this thesis, we aimed to build the foundations of research on the evolution of herbs. We outlined new potential drivers of the evolution of herbs, suggested solutions to some methodological challenges and provided evidence about differences between herbs and woody plants relevant to the hypotheses on herb evolution. To this end, we used common garden experiments with young plants of both growth forms and global trait data from public databases which we evaluated using phylogenetic comparative techniques. Annuality of aboveground biomass and fast life-strategy of herbs are characteristics which differentiate them from woody plants and which in some conditions are expected to be behind their success. Apart from the...

Coal fly ash: How sample properties and methodology influence immersion freezing results

Grawe, Sarah

24 July 2019

Aufgrund ihrer speziellen Eigenschaften können sogenannte eisnukleierende Partikel die Bildung von Eis in Wolken katalysieren. Laboruntersuchungen zum Gefrierverhalten dieser Partikel haben sich als wertvoll erwiesen, wenn es um das Verständnis zugrunde liegender Prinzipien und Mechanismen geht. Eine Spezies, die in früheren Untersuchungen vernachlässigt wurde, ist Flugasche aus Kohleverbrennung. Kohle-Flugasche (KFA) wird aufgrund ineffizienter Filterung submikroner Partikel über die Schornsteine von Kraftwerken emittiert und kann, in Abhängigkeit der meteorologischen Bedingungen, die Vereisung von Wolken in der Nähe der Quelle und darüber hinaus beeinflussen. In dieser Arbeit wurde das Immersionsgefrierverhalten, d.h. der Einfluss eingeschlossener Partikel auf das Gefrieren unterkühlter Tropfen, für vier verschiedene KFA-Proben aus deutschen Kohlekraftwerken untersucht. Dabei wurden einerseits Tropfen untersucht, die ein einzelnes submikrones Partikel enthielten. Andererseits wurde das Gefrierverhalten von Suspensionstropfen, die eine Vielzahl verschieden großer Partikel beinhalteten, quantifiziert. Zusätzlich wurden die Proben, sowohl in ihrer Gesamtheit als auch in Form einzelner submikroner Partikel, bezüglich ihrer chemischen Zusammensetzung, Morphologie und Kristallographie analysiert. Es wurde festgestellt, dass die Gefriereffizienz der Proben innerhalb von Minuten abnimmt, sobald diese in Berührung mit Wasser kommen. Immersionsgefriermessungen mit purem Anhydrit (CaSO4 ), das in den Proben nachgewiesen wurde, zeigten einen ähnlichen Trend, d.h. eine abnehmende Effizienz mit zunehmender Suspensionszeit. Diese Beobachtung, und die Übereinstimmung von Messungen mit KFA-Suspensionspartikeln und Gips (CaSO 4 * 2H2O, ein Hydrat des Anhydrits), weisen darauf hin, dass Hydratation die Ursache für die Abnahme der Gefriereffizienz sein könnte. Dieser Einfluss von Probeneigenschaften und Methodologie auf das Immersionsgefrierverhalten von KFA-Partikeln muss bei der Abschätzung der Relevanz der Partikel für die atmosphärische Eisnukleation unbedingt berücksichtigt werden.:1. Introduction 2. Fundamentals 2.1 Ice nucleation theory 2.2 Properties of CFA particles 3. Materials and Methods 3.1 Materials 3.2 Methods 4. Results 4.1 Physicochemical sample characterization 4.2 Immersion freezing behavior of CFA 5. Discussion 5.1 Comparison to literature results 5.2 Physicochemical particle properties and immersion freezing behavior 5.3 Atmospheric implications 6. Summary and Conclusions 7. Outlook / Due to their specific properties, atmospheric ice-nucleating particles are able to catalyze ice formation in clouds. Laboratory studies investigating the freezing behavior of these particles have proven to be of unmatched value when attempting to understand underlying principles and mechanisms. One species that has almost entirely been neglected in previous ice nucleation studies is fly ash from coal combustion (CFA: coal fly ash). Emitted through the stacks of power plants due to inefficient filtering of submicron particles, CFA has the potential to influence cloud glaciation in source regions and beyond, depending on the meteorological conditions. In this thesis, the immersion freezing behavior, i.e., the influence of particles immersed in supercooled cloud droplets on ice nucleation, of four samples from German power plants was determined with the help of several single particle and bulk instruments. In parallel, single particles and bulk CFA were investigated with respect to their chemical composition, morphology, and crystallography. It was found that the immersion freezing efficiency of the CFA particles decreases in contact with water on the time scale of minutes. Hydration products, that were found in both single particles and in the bulk after suspension, could be responsible for this unique behavior. Immersion freezing measurements with pure anhydrite (anhydrous CaSO4 ), which is known to occur at the surface of CFA particles, showed the same qualitative trend, i.e., a decreasing efficiency with increasing suspension time. This observation, and the agreement between measurements with suspended CFA particles and gypsum (CaSO4 * 2H2O, a hydrate of anhydrite), support the hypothesis that hydration causes the observed decrease in immersion freezing efficiency. This influence of sample properties and methodology on the immersion freezing behavior of CFA must be taken into consideration when assessing the relevance of these particles for atmospheric ice nucleation.:1. Introduction 2. Fundamentals 2.1 Ice nucleation theory 2.2 Properties of CFA particles 3. Materials and Methods 3.1 Materials 3.2 Methods 4. Results 4.1 Physicochemical sample characterization 4.2 Immersion freezing behavior of CFA 5. Discussion 5.1 Comparison to literature results 5.2 Physicochemical particle properties and immersion freezing behavior 5.3 Atmospheric implications 6. Summary and Conclusions 7. Outlook

info:eu-repo/classification/ddc/550

ddc:550

Design of multifunctional materials with controlled wetting and adhesion properties

Chanda, Jagannath

24 March 2016

Ice accretion on various surfaces can cause destructive effect of our lives, from cars, aircrafts, to infrastructure, power line, cooling and transportation systems. There are plenty of methods to overcome the icing problems including electrical, thermal and mechanical process to remove already accumulated ice on the surfaces and to reduce the risk of further operation. But all these process required substantial amount of energy and high cost of operation. To save the global energy and to improvement the safety issue in many infrastructure and transportation systems we have to introduce some passive anti-icing coating known as ice-phobic coating to reduce the ice-formation and ice adhesion onto the surface. Ice-phobic coatings mostly devoted to utilizing lotus-leaf-inspired superhydrophobic coatings. These surfaces show promising behavior due to the low contact area between the impacting water droplets and the surface. In this present study we investigate systematically the influence of chemical composition and functionality as well as structure of surfaces on wetting properties and later on icing behavior of surfaces. Robust anti-icing coating has been prepared by using modified silica particles as a particles film. Polymer brushes were synthesized on flat, particle surfaces by using Surface initiated ATRP. We have also investigated the effect of anti-icing behavior on the surfaces by varying surface chemistry and textures by using different sizes of particles. This approach is based on the reducing ice accumulation on the surfaces by reducing contact angle hysteresis. This is achieved by introducing nano to micro structured rough surfaces with varying surface chemistry on different substrates. Freezing and melting dynamics of water has been investigated on different surfaces by water vapour condensation in a high humidity (80%) condition ranging from super hydrophilic to super hydrophobic surfaces below the freezing point of water. Kinetics of frost formation and ice adhesion strength measurements were also performed for all samples. All these experiments were carried out in a custom humidity and temperature controlled chamber. We prepared a superhydrophobic surface by using Poly dimethyl siloxane (PDMS) modified fumed silica which display very low ice-adhesion strength almost 10 times lower than the unmodified surface. Also it has self-cleaning behavior after melting of ice since whole ice layer was folded out from the surface to remove the ice during melting. Systematic investigation of the effect of three parameters as surface energy, surface textures (structure, geometry and roughness) and mechanical properties of polymers (soft and stiff) on icing behavior has also been reported.

info:eu-repo/classification/ddc/540

ddc:540

Evaluation of heat pump concepts in ice rinks / Utvärdering av värmepumpskoncepts i ishallar

Gummesson, Patrik

January 2014

In Sweden there are about 350 ice rinks in operation today which consume approximately 300 GWh per year. The average energy consumption for a Swedish ice rink is approximately 1000 MWh per year. Ice rink dose not only consume energy it also rejects heat. The rejected heat comes from the refrigeration system that cools down the ice floor. The refrigeration system rejects heat around 700 to 1000 MWh per season. The reason for this study is because of the rejected heat which leads to the question how the rejected heat can be used.The object is to find a heat pump concept that can use the rejected heat or another heat source in an ice rink. Three different heat pump concepts were evaluated. The first heat pump concept use the ice floor as a heat source (called BHP), the second concept use the rejected heat as a heat source (called CHP) and the third concept use the rejected heat to charge an energy storage (called GHP).To accomplish the objective a heat analysis of two ice rinks were made to be able to simulate the heat pump concepts. With the simulation results a life cycle cost was made for a better evaluation. The results from the heat analysis were used for simulating the heat pump concepts. The two ice rinks that were analyzed were Järfälla ice rink and Älta ice rink. The main heat source the two ice rinks uses today is district heating and electricity. Järfälla only use district heating (DH) as a heat source and Älta ice rink use recovery heat, electricity and district heating.The heat analysis of the two the ice rinks showed that the highest district heating consumer was the domestic hot water at 47% of the DH followed by the dehumidifier at 32% of the DH and last the space heating at 22% of the DH. This shows how the heat is used in a general ice rink in Sweden. The temperature levels for the dehumidifier is around 65 °C (only DH part), the domestic hot water at 55 °C and last the space heating at 20 °C. However the heat demand for the ice rinks resulted in 443 MWh for Järfälla and 192 MWh for Älta. To know the size of the heat pump used for the heat pump concepts a heat profile for the ice rinks were made. The result of heat profiles lead to a heat pump size of 105 kW in Järfälla and 45 kW in Älta. The rejected heat for one season in Järfälla is 1000 MWh and 780 MWh in Älta.With the results from the heat analysis the evaluation the heat pump concepts was possible. The COP1 for the CHP resulted at 3,8 and the COP1 for the GHP was assumed to be the same as for the CHP. The COP1 calculations for the BHP concept resulted at 2,5. COP was calculated with collected data from the respective ice rinks refrigeration system. The simulations results were that the BHP and the CHP concept could fulfill the heat demand up to around 79% and the GHP up to around 84% in both ice rinks. The rest of the heat demand is heated with supplementary heat. The life cycle cost (LCC) showed that the CHP concept had the lowest cost followed by the GHP concept. The BHP concept had the highest LCC, because of the low COP. The LCC model dos not include the running cost, the maintenance cost and the energy tariffs for the district heating.The recommended solution is the GHP concept. This is because it is a good investment for the future since other buildings can be connected to the energy storage. The GHP concept is also the solution that fulfills the heat demand best and has the lowest annual energy cost.

Energy

ice rink

heat pump

COP

energy storage

LCC

heat demand

humidity

ice resurfacing

freezing time

Energy Engineering

Energiteknik

Multiphysics Simulation and Innovative Characterization of Freezing Soils

Liu, Zhen

08 March 2013

No description available.

Civil Engineering

Freezing Soil

Multiphysics

Simulation

Porous Materials

Pavement

Buried Pipes

Frost Action

Thermo-TDR

Soil Water Characteristic Curve

Wireless Body Area Network in Real-time Monitoring Application

Chakraborty, Suryadip

January 2013

No description available.

Computer Science

Wireless Body Area Network

Parkinsons Diseases

Freezing of Gait

Real time monitoring

Squat Exercise

Athletic Monitoring

Study of storm water treatment with multi-chamber pipe-final phase and laboratory study of freezing point depression on pavement samples

Guo, Ting

January 2004

No description available.

Engineering, Civil

Storm Water Treatment

Multi-Chamber Phase

Pipe-Final Phase

Laboratory Study

Freezing Point Depression

Pavement