Měření koncentrací skleníkových plynů / Measurement of greenhouse gas concentrations

Dohnal, Jan

January 2017

This master thesis deals with the greenhouse effect, various gases and methods of measurement. On the greenhouse effect is viewed from its historical dating, despite changes in atmospheric composition. It contains a theoretical analysis of the individual gases. It focuses on the most harmful greenhouse gases such as water vapor, carbon dioxide, nitrous oxide, methane, ozone, chlorofluorocarbons and halons. Analysis methods for detection of gaseous substances. Part of this work is focus on the detection of nitrogen dioxide, chloro-fluorocarbon and methane. The data is processed using a ATmega’s microcontroller and then sent to an Internet server thingspeak.com. If the device proves successful, will be used as a laboratory exercise in the course Ecology in electronics.

Water Vapor Movement in Freezing Aggregate Base Materials

Rogers, Maile Anne

18 December 2013

The objectives of this research were to 1) measure the extent to which water vapor movement results in water accumulation in freezing base materials; 2) evaluate the effect of soil stabilization on water vapor movement in freezing base materials; 3) determine if the corresponding changes in water content are sufficient to cause frost heave during winter; 4) determine if the corresponding changes in water content are sufficient to cause reductions in stiffness during spring; 5) evaluate relationships between selected material properties, freezing conditions, and the occurrence and impact of water vapor movement; and 6) numerically simulate heat and water movement in selected pavement design scenarios. The research involved extensive laboratory and field testing, statistical analyses, and numerical modeling. The results of the laboratory testing, which included gradations, Atterberg limits, soil classifications, specific gravity and absorption values, electrical conductivity values, moisture-density relationships, soil-water characteristic curves, moisture-stiffness curves, hydraulic conductivity values, and frost susceptibility assessments, were used to characterize each material and enable subsequent statistical analyses. Testing of both treated and untreated materials enabled investigation of a wide variety of material properties. The results of the field testing, which included temperature, moisture content, water potential, elevation, and stiffness data over time, provided the basis for comparing pavement sections with and without capillary barriers and established the framework for numerical modeling. In a pavement section with a capillary barrier underlying the base layer, water vapor movement from the subgrade through the capillary barrier may be expected to increase the water content of the base layer by 1 to 3 percent during a typical winter season in northern Utah for base materials similar to those studied in this research. During winter, cold temperatures create an ideal environment for water vapor to travel upward from the warm subgrade soil below the frost line, through the capillary barrier, and into the base material. Soil stabilization can lead to increased or decreased amounts of water vapor movement in freezing base materials depending on the properties of the stabilized soil, which may be affected by gradation, mineralogy, and stabilizer type and concentration. Accumulation of water from long-term water vapor movement into frost-susceptible base materials underlain by a capillary barrier can lead to frost heave of the base layer as it approaches saturation, as water available in the layer can be redistributed upwards to create ice lenses upon freezing. However, the incremental increase in total water content that may occur exclusively from water vapor movement during a single winter season in northern Utah would not be expected to cause measurable increases in thaw weakening of the base layer during spring. Because water in a base layer overlying a capillary barrier cannot drain until nearly reaching positive pore pressures, the base layer will remain indefinitely saturated or nearly saturated as demonstrated in this research. For materials similar to those studied in this research, potentially important material properties related to the occurrence of water vapor movement during freezing include dry density, percent of material finer than the No. 200 sieve, percent of material finer than 0.02 mm, apparent specific gravity, absorption, initial water content, porosity, degree of saturation, hydraulic conductivity, and electrical conductivity. The rate at which water vapor movement occurs is also dependent on the thermal gradient within the given material, where higher thermal gradients are associated with higher amounts of water vapor movement. The numerical modeling supported the field observations that the capillary barrier effectively trapped moisture in the overlying base material, causing it to remain saturated or nearly saturated throughout the monitoring period. Only non-frost-susceptible aggregate base materials should be specified for use in cold climates in conjunction with capillary barriers, and the base material in this case should be assumed to remain in a saturated or nearly saturated condition during the entire service life of the pavement. Further study is recommended on water vapor movement in freezing aggregate base materials.

aggregate base material

capillary barrier

cement treatment

water vapor

freezing

frost heave

pavement

SHAW model

soil stabilization

soil-water characteristic curve

Civil and Environmental Engineering

Vybrané jevy při přenosu tepla vzduchotechnikou / Selected heat transfer phenomena in air conditioning

Vojkůvková, Petra

January 2014

Numerical simulation is a scientific method used to describe characteristics of examined system by means of experiments on its mathematical model. This thesis uses this method to elucidate the processes taking place in two different systems. Firstly it deals with the design of air conditioning systems for buildings, focusing on the mixing chambers. It focuses on the formation of condensation of water vapor in mixing chambers under conditions where the final temperature of the mixture does not drop below the saturation curve. Second prepared topic falls within the field of thermodynamics applied in food production. In order to assess the sufficiency of air-cooling method examines the thermal field in the product and evaluates the application of air-cooling assembly line in practice.

Měření koncentrací skleníkových plynů / Measurement of greenhouse gas concentrations

Dohnal, Jan

January 2016

This semester thesis deals with the greenhouse effect, various gases and methods of measurement. On the greenhouse effect is viewed from its historical dating, despite changes in atmospheric composition and reactions of individual institutions. It contains a theoretical analysis of the individual gases. It focuses on the most harmful greenhouse gases such as water vapor, carbon dioxide, nitrous oxide, methane, ozone, chlorofluorocarbons and halons. Analysis methods for detection of gaseous substances. Part of this work is focus on the detection of nitrogen dioxide and chloro-fluorocarbon. The data is processed using a microcontroller and then sent to an Internet server thingspeak.com. If the device proves successful, will be used as a laboratory exercise in the course Ecology in electronics.

Droplet Heat and Mass Exchange with the Ambient During Dropwise Condensation and Freezing

Julian Castillo (9466352)

16 December 2020

<div> <p>The distribution of local water vapor in the surrounding air has been shown to be the driving mechanism for several phase change phenomena during dropwise condensation and condensation frosting. This thesis uses reduced-order modeling approaches, which account for the effects of the vapor distribution to predict the droplet growth dynamics during dropwise condensation in systems of many droplets. High-fidelity modeling techniques are used to further probe and quantify the heat and mass transport mechanisms that govern the local interactions between a freezing droplet and its surrounding ambient, including neighboring droplets. The relative significance of these transport mechanisms in the propagation of frost are investigated. A reduced-order analytical method is first developed to calculate the condensation rate of each individual droplet within a group of droplets on a surface by resolving the vapor concentration field in the surrounding air. A point sink superposition method is used to account for the interaction between all droplets without requiring solution of the diffusion equation for a full three-dimensional domain. For a simplified scenario containing two neighboring condensing droplets, the rates of growth are studied as a function of the inter-droplet distance and the relative droplet size. Interactions between the pair of droplets are discussed in terms of changes in the vapor concentration field in the air domain around the droplets. For representative systems of condensing droplets on a surface, the total condensation rates predicted by the reduced-order model match numerical simulations to within 15%. The results show that assuming droplets grow as an equivalent film or in a completely isolated manner can severely overpredict condensation rates.</p> <p>The point superposition model is then used to predict the condensation rates measured during condensation experiments. The results indicate that it is critical to consider a large number of interacting droplets to accurately predict the condensation behavior. Even though the intensity of the interaction between droplets decreases sharply with their separation distance, droplets located relatively far away from a given droplet must be considered to accurately predict the condensation rate, due to the large aggregate effect of all such far away droplets. By considering an appropriate number of interacting droplets in a system, the point sink superposition method is able to predict experimental condensation rates to within 5%. The model was also capable of predicting the time-varying condensation rates of individual droplets tracked over time. These results confirm that diffusion-based models that neglect the interactions of droplets located far away, or approximate droplet growth as an equivalent film, overpredict condensation rates.</p> <p>In dropwise condensation from humid air, a full description of the interactions between droplets can be determined by solving the vapor concentration field while neglecting heat transfer across the droplets. In contrast, the latent heat released during condensation freezing processes cause droplet-to-ambient as well as droplet-to-droplet interactions via coupled heat and mas transfer processes that are not well understood, and their relative significance has not been quantified. As a first step in understanding these mechanisms, high-fidelity modeling of the solidification process, along with high-resolution infrared (IR) thermography measurements of the surface of a freezing droplet, are used to quantify the pathways for latent heat dissipation to the ambient surroundings of a droplet. The IR measurements are used to show that the crystallization dynamics are related to the size of the droplet, as the freezing front moves slower in larger droplets. Numerical simulations of the solidification process are performed using the IR temperature data at the contact line of the droplet as a boundary condition. These simulations, which have good agreement with experimentally measured freezing times, reveal that the heat transferred to the substrate through the base contact area of the droplet is best described by a time-dependent temperature boundary condition, contrary to the constant values of base temperature and rates of heat transfer assumed in previous numerical simulations reported in the literature. In further contrast to the highly simplified descriptions of the interaction between a droplet and its surrounding used in previous models, the model developed in the current work accounts for heat conduction, convection, and evaporative cooling at the droplet-air interface. The simulation results indicate that only a small fraction of heat is lost through the droplet-air interface via conduction and evaporative cooling. The heat transfer rate to the substrate of the droplet is shown to be at least one order of magnitude greater than the heat transferred to the ambient air.</p> <p>Subsequently, the droplet-to-droplet interactions via heat and mass exchange between a freezing droplet and a neighboring droplet, for which asymmetries are observed in the final shape of the frozen droplet, are investigated. Side-view infrared (IR) thermography measurements of the surface temperature for a pair of freezing droplets, along with three-dimensional numerical simulations of the solidification process, are used to quantify the intensity and nature of these interactions. Two droplet-to-droplet interaction mechanisms causing asymmetric freezing are identified: (1) non-uniform evaporative cooling on the surface of the freezing droplet caused by vapor starvation in the air between the droplets; and (2) a non-uniform thermal resistance at the contact area of the freezing droplet caused by the heat conduction within the neighboring droplet. The combined experimental and numerical results show that the size of the freezing droplet relative to its neighbor can significantly impact the intensity of the interaction between the droplets and, therefore, the degree of asymmetry. A small droplet freezing in the presence of a large droplet, which blocks vapor from freely diffusing to the surface of the small droplet, causes substantial asymmetry in the solidification process. The droplet-to-droplet interactions investigated in thesis provide insights into the role of heat dissipation in the evaporation of neighboring droplets and ice bridging, and open new avenues for extending this understanding to a system-level description for the propagation of frost.</p> </div> <br>

Mechanical Engineering

Computational Heat Transfer

Droplet freezing

dropwise condensation

solidificatoin

recalescence

water vapor transport

evaporative cooling

frost

condensation freezing

ice bridging

droplet evaporation

Utilisation du caséinate de sodium pour la fabrication de films actifs pour l’emballage alimentaire : étude des propriétés barrières aux gaz, de l’activité antimicrobienne et de la biodégradabilité / Fabrication of sodium caseinate edible films for active food packaging : study of gas barrier properties, antimicrobial activity and biodegradability

Colak, Basak Yilin

14 November 2014

La mondialisation des marchés, les changements d’habitudes de consommation et les préoccupations croissantes concernant la sécurité alimentaire et l’environnement sont des éléments moteurs pour le développement des films d’emballage comestibles/biodégradables antimicrobiens. Une utilisation en masse de ce type de film est dépendante principalement des verrous technologiques car le mode de fabrication actuellement utilisé pour ce genre de film consiste à utiliser un procédé (voie solvant) qui n’est pas toujours adapté à une production importante et continue. L’étude présentée ici permet de montrer la possibilité d’obtenir des films comestibles antimicrobiens à partir de caséinate de sodium en utilisant les procédés traditionnels de la plasturgie : extrusion bi-vis et extrusion-gonflage. Grâce aux optimisations des paramètres d’élaboration tels que la température de transformation, le taux de cisaillement et le taux de plastifiant, les matériaux contenant un agent actif naturel : le lysozyme, la nisine ou la natamycine ont gardé en partie leurs activités antimicrobiennes. Par des caractérisations mécaniques et physico-chimiques des films thermoplastiques, il a été démontré que ces films ont des propriétés mécaniques et barrières similaires à ceux fabriqués par voie solvant. Ces propriétés dépendent principalement du taux de plastifiant. Ainsi, il est possible de fabriquer des films comestibles antimicrobiens de caséinate de sodium avec de bonnes propriétés mécaniques et barrières qui ne sont pas affectées par la transformation thermomécanique et qui peuvent être adaptées en fonctions des applications en variant le taux de plastifiant / Because food market becomes international, consumers are changing their habits and they are more concerned about food security and environmental issues, there are driving forces for the development of edible/biodegradable antimicrobial packaging films. However, fabrication process (solution-casting) of these kinds of films isn’t always suitable for a continuous industrial big production. The present study demonstrates the suitability of sodium caseinate based edible antimicrobial films to be fabricated by some conventional plastic transformation processes: twinscrew extrusion and blown-film extrusion. Thanks to the optimizations of elaboration parameters such as extrusion temperature, shear and plasticizer ratio, the materials incorporated with one of the following active agents: lysozyme, nisin or natamycin, partially kept their antimicrobial activity. Physical-chemical film characterization of films emphasized that the type of transformation process doesn’t have any influence on tensile or gas barrier properties. These properties are mainly affected by plasticizer type and content. Thus, sodium caseinate based edible antimicrobial films can be produced successfully by thermo-mechanical processes without losing good mechanical and gas barrier properties

Caséinate de sodium

Extrusion

Films antimicrobiens

Films comestibles

Biodégradable

Perméabilité à l’oxygène

Perméabilité à la vapeur d’eau

Sodium caseinate

Extrusion

Antimicrobial films

Edible films

Biodegradable

Oxygen permeability

Water vapor permeability

Tropospheric Delay Modeling using GNSS Observations from Continuously Operating Reference Stations (CORS)

alojaiman, shahad N M A A

January 2019

No description available.

Civil Engineering

PPP

CORS

Tropospheric delay

GNSS

IGS

GPS

MGEX

Zenith total delay

Zenith wet delay

PWV

ZTD

ZWD

Precipitable Water Vapor

Influence of Oxygen Partial Pressure on the Droplet Shape of Stainless Steel Using Levitated Droplet Method

Hessling, Oscar

January 2016

An induction setup for levitation studies of molten metals was built. The setup was used to levitate and heat stainless steel samples of 2.00 g to 1600 °C and subject them to different atmospheres. Changes in shape and temperature were recorded by video and infrared thermocouple. Oxide films forming on the droplets during levitation were observed. It was possible to notice an immediate surface reaction when the reaction gas was introduced. This reaction is concluded to influence the surface and bulk composition, and therefore have an effect on the shape evolution of the droplet. A more oxidizing atmosphere resulted in a more conical droplet shape; this is thought to be an effect of lowered surface tension and the conically shaped volumetric force caused by the magnetic field. Changes in temperature after the sample is molten are thought to be an effect of changes in emissivity, caused by surface oxidization. Post mortem analysis show a difference in surface morphology for samples subjected to different gases, as well as a difference in amount of oxidization.

Levitated droplet method

magnetic levitation

levitation

stainless steel

steel

surface tension

oxygen partial pressure

water vapor

inert atmosphere

Metallurgy and Metallic Materials

Metallurgi och metalliska material

Untersuchung von Multilagenbarrieren für die Verkapselung organischer Bauelemente

Dollinger, Felix

11 December 2015

Elektronische Bauteile aus organischen Halbleitern stellen höchste Anforderungen an die Qualität der Verkapselung, die sie vor eindringenden Wasser- und Luftmolekülen schützt. Gleichzeitig soll diese preiswert und mechanisch flexibel sein. Diese Arbeit realisiert Aluminium-Mehrschichtsysteme als wirkungsvolle, biegsame und einfache Verkapselung. Es werden verschiedene Herstellungsmethoden und Zwischenschichtmaterialien untersucht, wobei die Barrierelamination als überlegenes Verfahren etabliert wird. Verkapselungssysteme werden mittels optischer Untersuchung und mit dem elektrischen Calciumtest auf ihre Güte geprüft, bevor sie in Solarzellenalterungsexperimenten unter realitätsnahen Bedingungen zur Anwendung kommen. Laminationsbarrieren aus Aluminiumdünnschichten zeigen reproduzierbar Wasserdampfdurchtrittsraten im unteren 10^(-4) g(H2O)/m^2/Tag-Bereich unter beschleunigten Permeationsbedingungen. Sie verlängern die T(50)-Lebensdauer von Solarzellen um einen Faktor 50 gegenüber unverkapselten Zellen auf Werte, die mit starrer Glas- oder zeitaufwendiger ALD-Verkapselung vergleichbar sind. / Organic electronic devices require excellent encapsulation to protect them from intruding water- and air-molecules. At the same time, the encapsulation has to be inexpensive and flexible. This work presents aluminum multilayer barriers as highly effective, flexible and low-cost encapsulation. Various production methods and interlayer materials are investigated and barrier-lamination is established as superior process. Encapsulation systems are evaluated optically and by means of the electrical calcium-test, before they are employed in realistic solar cell aging experiments. Lamination-barriers of thin aluminum films show reproducible water-vapor transmission rates in the low 10^(-4) g(H2O)/m^2/day-range under accelerated permeation conditions. They improve the T(50)-lifetime of solar cells by a factor of 50 compared to unencapsulated cells, reaching values on par with rigid glass encapsulation or time-consuming atomic layer deposition.

Verkapselung

Barrierelamination

Wasserdampf

Permeation

WVTR

Calcium Test

Organische Solarzelle

Organische Elektronik

encapsulation

barrier-lamination

water vapor

permeation

WVTR

calcium test

organic solar cell

organic electronics

ddc:621

rvk:ZN 5160

Wasserdampf

Verkapselung

Permeation

Solarzelle

Encapsulation and stability of organic devices upon water ingress / Verkapselung und Stabilität organischer Bauelemente bei Wassereintritt

Nehm, Frederik

06 April 2017

Organic electronic devices like organic solar cells and organic light-emitting diodes quickly degrade in ambient conditions if left unprotected. High susceptibility to moisture necessitates their encapsulation. The maximum water ingress acceptable to achieve reasonable lifetimes ranges several orders of magnitudes below industrial flexible barrier solutions. In this work, an electrical Ca-Test is used to optimize and investigate moisture barriers towards their application in device encapsulation. Aside from substantial improvement of the measurement system, atomic layer deposited, sputtered, and thermally evaporated barriers are screened and their water vapor transmission rates measured down to 2*10^(-5) g(H2O)/(m²*d) at 38 °C and 90% RH. Completely new encapsulation techniques are presented using novel molecular layer deposition interlayers or lamination of independently processed barriers. This way, simple Al layers become high-end moisture barriers. Furthermore, different single layer barriers are exposed to a wide variety of climates. An in-depth analysis of water permeation mechanics reveals sorption governed by Henry's law as well as dominance of interface diffusion below the barrier at late test stages. Investigated moisture barriers are applied to organic light-emitting diodes as well as solar cells and great improvements of lifetimes are observed. In addition, significant improvements in stability towards water ingress are witnessed upon the integration of adhesion layers at the cathode interface. Lastly, the great potential and applicability of this technology is showcased by the production and aging of fully flexible, highly efficient, stable organic solar cells. / Organische Elektronik-Bauteile wie organische Solarzellen und organische Leuchtdioden degradieren in kürzester Zeit, wenn sie ungeschützt feuchter Luft ausgesetzt sind. Ihre starke Anfälligkeit gegenüber Wasserdampf macht ihre Verkapselung notwendig. Der maximale Wassereintritt, der für sinnvolle Lebensdauern noch zulässig erscheint, liegt jedoch noch mehrere Größenordnungen unter dem, was mit existierenden Technologien erreicht werden kann. In der vorliegenden Arbeit wird ein elektrischer Kalzium-Korrosionstest benutzt, um Barrieresysteme auf ihre Anwendbarkeit als Verkapselung organischer Bauelemente hin zu untersuchen und zu optimieren. Abgesehen von signifikanten Verbesserungen am Messsystem werden Wasserdampfbarrieren aus Atomlagenabscheidungs-, Kathodenzerstäubungs- und Verdampfungsprozessen vermessen. Dabei werden außerordentlich niedrige Wasserdampfdurchtrittsraten von nur 2*10^(-5) g(H2O)/(m²*d) in einem Alterungsklima von 38 °C und 90% relativer Feuchte verzeichnet. Vollkommen neue Verkapselungstechniken werden realisiert, wie etwa die Integration von Zwischenschichten durch Molekularlagenabscheidung oder die Lamination zweier Barrieren, die unabhängig voneinander prozessiert werden. Dieser Prozess verwandelt einfache Al Schichten in qualitativ hochwertige Wasserdampfbarrieren. Des Weiteren werden verschiedene Einzelschicht-Barrieren einer breiten Klimavariation ausgesetzt. Dies ermöglicht die genaue Analyse der Permeationsmechanismen des Wassers. Es wird gezeigt, dass Sorption hier dem Henry'sche Gesetz folgt. Diffusion entlang der Grenzfläche unterhalb der Barriere dominiert die Permeation zu späten Testzeiten. Die untersuchten Wasserdampfbarrieren werden an organischen Leuchtdioden und Solarzellen erprobt und zeigen große Verbesserungen bezüglich ihrer Lebensdauern. Darüber hinaus zeigt sich eine stark verbesserte Resistenz gegenüber Wassereintritt, wenn eine zusätzliche Adhäsionsschicht unter der Kathodengrenzfläche integriert wird. Letztendlich zeigt sich das große Potential und die Anwendbarkeit der Ergebnisse in der hohen Effizienz und langen Lebensdauer vollflexibler, verkapselter organischer Solarzellen.

Verkapselung

organische Solarzellen

Photovoltaik

OLEDs

Stabilität

Wasserdampbarrieren

WVTR

ALD

Ca-Test

encapsulation

organic solar cells

photovoltaics

OLEDs

stability

water vapor barriers

WVTR

ALD

Ca-Test

ddc:530

rvk:VN 6057