Vliv fyzikálních vlastností paliva na tvorbu směsi

Honzírek, Jiří

January 2012

No description available.

Modellierung der Verdunstung realer Kraftstoffe zur Simulation der Gemischbildung bei Benzindirekteinspritzung /

Gartung, Kai.

January 2008

Diss--Universität Bayreuth.

Modellierung der Verdunstung realer Kraftstoffe zur Simulation der Gemischbildung bei Benzindirekteinspritzung

Gartung, Kai

January 2007

Zugl.: Bayreuth, Univ., Diss., 2007

Essays in industrial organization /

Aydemir, Zava.

January 2003

Univ., Diss.--Zürich, 2002.

Fyzikální vlastnosti kapalných paliv a biopaliv pro zážehové motory

Beránek, Lukáš

January 2016

The theoretical part of this thesis Physical properties of liquid fuels and biofuels for petrol engines describes fuels for petrol engines, it deals with properties this fuels and their production. It deals with nature of density, dynamic viscosity and measuring this parameters. Experimental part of this thesis is focused on measuring temperature depen-dence dynamic viscosity and density of gasoline, bioethanol and their mixtures. Results of the measuring are registred in tables and they are typified in graphs. Mathematical functions were found, which can be used for a convenient predicti-ons of physical properties of gasoline, biofuels and their mixtures.

Vliv biosložky na fyzikální vlastnosti automobilového benzinu

Beer, Erik

January 2018

The theoretical part of the diploma thesis with the topic "Effect of bio-component on the automotive gasoline properties" contains a summary of basic fuels for spark ignition engines, their basic properties, and the legislative requirements. This part also deals with the theory of measurement of density, viscosity and shear stress. In the experimental part of thesis are described the measurement of the physical and mechanical properties of petrol, buthanol and their blend sand determination of their temperature dependences. The results are presented in the tables and are shown in the charts. Obtained results are discussed with the thematic scientific contributions.

CO-H2-Synthesegaserzeugung durch Benzinreformierung und Benzin-Reformat-Mischbetrieb von Otto-Motoren

Maus, Felix

January 2008

Zugl.: Stuttgart, Univ., Diss., 2008

Hodnocení paliv pro spalovací motory ve vztahu k životnímu prostředí

Vančatová, Šárka

January 2019

The name of this diploma thesis is „Evaluation of combustion engine fuel and its influence on the environment”. At the beginning there is a brief history of fuels. After that there is a chapter which divides fuels according to their state thus they are separate to three main types (solid state, gaseous state and liquid state). There are described main characteristics in the next part of this thesis which are heat of combustion, bulk density, dosage, volatility, resistance to detonation burning and mainly octane and cetane number. There are described currently used fuels for combustion engines right after the characteristic of fuels. These fuels are divided to fuels made of petroleum (gasoline, diesel, and LPG), fuels made of natural gas (CNG, and LNG), biofuels (bioethanol, biomethanol, vegetable oils – FAME and synthetic diesel fuel) and there is also an independent group of hydrogen. Thereafter are described European emission standards. The practical part of the thesis is focused on an analysis of previously mentioned fuels and there is a biggest focus on production of carbon dioxide. Other emissions are evaluated as well such as carbon monoxide, hydrocarbons and NOx gases. The analysis is done on classical fuels like gasoline and diesel and also on alternative fuels such as CNG, LPG, E85, FAME and hydrogen. In the end there are tables and graphs which contains production of flue gases.

Development and application of optical diagnostic techniques for assessing the effects of preferential evaporation of multi-component fuels under engine-relevant conditions / Développement et exploitation de techniques de diagnostics optiques pour la compréhension de l'évaporation de carburants mufti-composants dans les moteurs essence

Itani, Lama

14 December 2015

Dans le cadre de cette thèse, une technique de diagnostic optique a été développée pour mesurer simultanément l’évaporation différentielle, la distribution de température, et la concentration massique de fuel dans un jet multi-composant. Cette technique a été examinée dans les conditions d’un moteurs essence. La technique de mesure est basée sur l’utilisation des deux traceurs excités par une seule longueur d’onde.Pour pouvoir examiner l’évaporation différentielle d’un carburant multi-composant, deux traceurs ont été sélectionnés : le p-difluorobenzène et le 1-methylnaphtalène. Ces traceurs reproduisent deux types de volatilité : faible et moyenne à élevée. Les traceurs choisis fluorescent dans deux régions spectrales distinctes ce qui rend l’application de cette technique possible. Une étude photophysique a été menée pour caractériser les deux traceurs, indépendamment puis en mélange, pour différentes conditions de pression, température, et composition du bain gazeux. L’étude photophysique est essentielle pour pouvoir mesurer quantitativement l’évaporation différentielle. Les résultats photophysiques montrent que le spectre du 1-methylnaphthalène est sensible à la température. Cette caractéristique permet de mesurer la distribution en température dans le jet.Les essais ont été réalisés dans une cellule haute pression / haute température, ca-pable de simuler les conditions d’un moteur thermique. Des sprays générés par un injecteur ECN Spray G et un piézo-électrique d’une ouverture annulaire ont été étudiés. Des mesures initiales ont été menées avec chaque traceur pour pouvoir fixer la proportion de mélange des traceurs. La précision de la méthode de mesure a été calculée suivant une configuration de filtres identiques. Ensuite, les champs de tempé-rature calculés par la LIF et ceux déterminés depuis les champs de concentration massique, ont été comparés. Les résultats démontrent que la température est homo-gène ce qui signifie que les mesures d’évaporation différentielle n’ont pas influencé par la distribution de température dans le jet.Les images obtenues en détectant les signaux depuis le mélange de traceurs ont permis de localiser l’évaporation différentielle. Une variation en distribution spatiale des composants est observée 550–600 K. Cet effet disparaît en augmentant la température, ce qui explique que l’évaporation est plus rapide à haute température. La localisation de l’évaporation différentielle varie avec le type d’injecteur. La géométrie du nez ainsi que la structure du jet a donc un impact sur la formation du mélange. / A non-intrusive quantitative laser-induced fluorescence (LIF) technique capable of simultaneously measuring preferential evaporation, temperature distribution, and fuel-mass concentration across a multi-component vaporized spray has been developed and investigated under engine-relevant conditions. The measurement technique is based on two-tracer LIF with single wavelength excitation.To assess preferential evaporation, a tracer pair with suitable co-evaporation and spectral properties was selected based on vapor-liquid equilibrium calculations repre-sentative for gasoline fuels. Evaporation studies have shown that one tracer (p-difluoro-benzene) co-evaporates with the high-to-medium-volatility end of the multi-component fuel while the other (1-methylnaphthalene) co-evaporates with the low-volatility end. For quantitative measurements the photophysical properties of both tracers (each tracer separately and the combined tracers) were determined under a wide range of pressure, temperature, and bath-gas composition conditions. 1-methylnaphthalene LIF shows a strong red-shift with temperature which enables measurements of the temperature distribution across the spray.Spray evaporation and vapor mixing experiments were performed in a high-pressure high-temperature vessel capable of simulating in-cylinder conditions. An ECN Spray-G and a piezo-electric outward opening injector were used in this study. Initial measure-ments were carried out with each tracer added separately to the fuel to assess signal cross-talk and to determine the best tracer concentrations. Once the proportions were determined, accuracy and precision of the method were determined from the LIF-signal ratio of spray images within identical spectral bands. Temperature fields, obtained by two-color 1-methylnaphthalene LIF and derived from fuel concentration maps based on the assumption of adiabatic evaporation, were examined for inhomogeneities in the area of interest since fluctuations potentially influence the two-color method. It was shown that the temperature is homogeneous in the measurement volume.To localize preferential evaporation, two-color two-tracer LIF images were evaluated. Taking into account the measurement accuracy and precision, variations in the spatial distribution of the fuel volatility classes were observed for 550–600 K. At higher tem-peratures, the effect is less pronounced, which is consistent with the fact that evapora-tion is faster. The localization of preferential evaporation varied with each injector used indicating the impact of injector nozzle geometry and jet structure on mixture formation. / Eine berührungsfreies quantitatives Verfahren auf Basis von laserinduzierter Fluoreszenz (LIF) wurde entwickelt, um simultan präferenzielle Verdampfung, Temperaturverteilung und Kraftstoffkonzentration im verdampften Bereich eines Mehrkomponenten-Kraftstoffsprays unter motorrelevanten Bedingungen zu messen. Verfahren beruht auf Zwei-tracer-LIF mit Anregungmit einem Laser.Es wurde ein Tracer-Paar mit geeigneten Verdampfungs- und spektralen Eigenschaften auf Basis von Dampf-Flüssigkeits-Gleichgewichtsrechnungen für Otto-Kraftstoffe ausgewählt. Verdampfungsmessungen haben gezeigt, dass ein Tracer (p-Difluorbenzol) gleichzeitig mit dem mittel- und höherflüchtigen Siedeklassen verdampft, während der andere (1-Methylnaphthalin) den schwerflüchtigen Komponentenfolgt. Für quantitative Messungen wurden die photophysikalischen Eigenschaften beider Tracer (einzeln und als Kombination) in einem weiten Bereich von Druck, Temperatur und Gaszusammensetzung bestimmt. 1-Methylnaphthalin-LIF zeigt eine starke Rotverschiebung mit der Temperatur, die Messungen der Temperaturverteilung ermöglicht. Es wurde ein Tracer-Paar mit geeigneten Verdampfungs- und spektralen Eigenschaften auf Basis von Dampf-Flüssigkeits-Gleichgewichtsrechnungen für Otto-Kraftstoffe ausgewählt. Verdampfungsmessungen haben gezeigt, dass ein Tracer (p-Difluorbenzol) gleichzeitig mit dem mittel- und höherflüchtigen Siedeklassen verdampft, während der andere (1-Methylnaphthalin) den schwerflüchtigen Komponentenfolgt. Für quantitative Messungen wurden die photophysikalischen Eigenschaften beider Tracer (einzeln und als Kombination) in einem weiten Bereich von Druck, Temperatur und Gaszusammensetzung bestimmt. 1-Methylnaphthalin-LIF zeigt eine starke Rotverschiebungmit der Temperatur, die Messungen der Temperaturverteilung ermöglicht.

Multi-Composant

Jet

Essence

Laser-induced fluorescence (LIF)

Éaporation

Multi-Component

Jet

Gasoline

Laser-induced fluorescence (LIF)

Evaporation

Multikomponenten

Strahl

Benzin

Laser-induced fluorescence (LIF)

Verdampfung

Stanovení emisí a škodlivých částic výfukových plynů u CNG, benzinových a naftových vozidel / Determination of emissions and harmful particles of exhaust gases of CNG, petrol and diesel vehicles

Rozsíval, Adam

January 2019

The thesis deals with an analyses of emission and harmful particles of exhaust fumes of automobiles with an environmental impact. More precisely, it describes the basic characteristics of current fuel types and emission produced by internal combustion engines. Next, it deals with the measures and possibilities of decreasing car traffic emission with respect to environmental impact. It also describes the current European standards for emission and the systems of the cars that are able to decrease emission. The work also deals with the measuring of emission and the methods that are used. According to the measuring methods, the analysis of exhalation is done and it is based on the data of the real car fleet. Values of the emission analyses are compared. The financial aspect is a part of the analyses.