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111	Zážehový motor s Millerovým cyklem optimalizace provozu turbodmychadla / SI engine with Miller cycle turbocharger operation optimization Novotný, Pavel January 2021 (has links) The diploma thesis deals with the calculation of thermodynamic parameters of a turbocharged petrol engine with Miller cycle. A drive unit from Volkswagen, the EA211EVO model line, was chosen as the engine. The engine has a displacement of 1498 cm3 and engine power reaches 110kW at 5000 to 6000 RPM. In this work, a basic description of the thermodynamics of cycles of spark ignition engines is performed, then the problem of turbocharging and methods of its control are presented. The following are the created engine models in GTSuite environment in variants with WasteGate and Variable Turbine Geometry. Finally, operation optimizations with various valve timing changes are presented. The individual variants are the compared.
112	Šroubový spoj turbodmychadla a hlavy válců / Bolted joint of turbocharger and cylinder head Kolivošková, Veronika January 2017 (has links) The subject of this diploma thesis is the theoretical basis of the screw connection theory and the subsequent application to the specific screw connection problem. Mentioned connection is part of the turbo charged combustion engine, specifically directly between the cylinder head and the turbocharger. The diploma thesis is divided into several parts. The first part dealing with selected chapters of the screw connections and the combustion engines theory, whose knowledge is important for further chapters of this diploma thesis. The next part shows method of creating the geometric and computational model, on which were performed the appropriate sensory analyses with respect to determine the cause of the nut and bolt loose in the given connection. On the basis of the gained knowledge and their evaluation has been created a separate calculation methodology in the last part of this thesis, which describing parameters that have an impact on this undesirable phenomenon, and which should be included in analyses for similar issues. The diploma thesis was realized in cooperation with ŠKODA Auto a.s., tř. Václav Klementa 869, Mladá Boleslav, and AUDI AG, Union-Straße 1, Ingolstadt.
113	Návrh oběžného kola radiální turbíny se sníženým momentem setrvačnosti / Radial turbine runner design with reduced moment of inertia Votava, Ondřej January 2020 (has links) This master’s thesis deals with topological optimization of the impeller of a radial turbocharger turbine. It focuses on reducing the moment of inertia with unchanged aerodynamic properties. The optimization was carried out using CFD, thermal and structural analysis. The computational modeling was performed using the finite element analysis in ANSYS. The work proposes models of the impeller with the topological modification of the internal structure. Based on the values of moment of inertia, the stress and the strain the most suitable model was selected.
114	Vícestupňové přeplňování vznětového motoru / Multistage turbocharging of diesel engine Vichr, Tomáš January 2021 (has links) This master thesis summarizes the basic knowledge in the field of turbocharging of internal combustion piston engines. It also focuses on the analysis of some properties of multistage turbocharging, especially for diesel engines. Using analytical relationships, a model in the form of a web application has been created, which describes the cooperation of a turbocharger or turbochargers with an internal combustion engine. With the help of this model, some two-stage supercharging options for the selected engine have been then proposed.
115	Zvýšení výkonových parametrů motoru AR67203 / Increasing AR67203 Engine Performance Smilek, Lukáš January 2012 (has links) The aim of this diploma thesis is supercharging of SI engines and design influence on performance. The main objective of this thesis is to propose appropriate modifications on AR67203 engine of Alfa Romeo 155Q4 personal vehicle in order to achieve significantly better performance parameters and a constant torque in the widest possible speed range. That is why I analyze design and modifications that affect the overall engine performance and their appropriate application to the selected engine. An important point of this thesis is the right choice of turbocharger, in order to have an effective cooperation with a modified engine. The calculation study and the simulation in Lotus Engine Simulation software serve this purpose. I also give information about ECU programming. The results, as well as a practical output in the form of measured performance parameters of modified engine, are evaluated at the end.
116	Provoz a údržba vozidel s přeplňovanými motory turbodmychadly / Running and Maintenance of Vehicles with Supercharged Engine Vertaľ, Peter January 2010 (has links) The goal is to measure the temperature of the turbocharger after engine shutdown.Measurements wants to show the need to keep a car engine to cool after a heavier burden on the idle speed. It would also prevent possible disruptions turbocharger. The paper also deals with the problems, construction and basic principles of operation of the turbocharger
117	Variable Stator Nozzle Angle Control in a Turbocharger Inlet Carrasco Mora, Enrique January 2015 (has links) Turbochargers are becoming an essential device in internal combustion engines as they boost the intake air with more pressure in order to increase the power output. These devices are normally designed for a single steady design point but the pulsating flow delivered from the internal combustion engine is everything but steady. The efficiency drop experienced in the off-design points by the fixed geometry turbochargers have made some research groups to look into new variable geometry solutions for turbocharging. A nozzle ring is a device which normally achieves a higher performance under design conditions, but the efficiency rapidly drops at off-design conditions. In this paper, a variable angle nozzle ring is designed and implemented in the model of a radial turbine of a turbocharger in order to study its potential when working under real internal combustion engine cycles. To understand the profit margin the turbine performance is compared with two turbines with the same impeller geometry: one without nozzle ring and one with a nozzle ring with a fixed angle. The results show that the maximum efficiency angle function calculated for the variable angle nozzle ring achieves an improvement in the total efficiency of 5 % when comparing with a turbine with a fixed angle and 18 % when comparing with a vaneless turbine. The improved guidance achieved due to the variable blade angle leads to less turbine losses and therefore more mechanical energy can be extracted from the exhaust mass flow throughout all the combustion cycle but a further study should be made in order to match all the engine operations points. Notably, taking the pulsating boundary conditions into consideration, a remarkable improvement is achieved already for the fixed angle nozzle ring. Turbocharger Radial Turbine Blade Nozzle Engineering and Technology Teknik och teknologier Mechanical Engineering Maskinteknik Vehicle Engineering Farkostteknik Energy Engineering Energiteknik Fluid Mechanics and Acoustics Strömningsmekanik och akustik
118	Acoustic Characterization of Turbochargers and Pipe Terminations Tiikoja, Heiki January 2012 (has links) In search for quieter engines there is a need for a better understanding of the acoustic properties of engine intake and exhaust system components. Besides mufflers which have the purpose of reducing pressure pulses originating from the internal combustion (IC) engine, there are many components in a modern car exhaust and intake system, e.g., air-filters, coolers, catalytic converters, particulate filters - all having an effect on the pressure pulses or sound field in the system. In this work the focus is on the turbocharged IC-engine where both, sound scattering (reflection and transmission) and sound generation from automotive turbochargers are studied. In addition, sound reflection from an open ended pipe, such as the tailpipe of an IC-engine exhaust is investigated. Accurate and efficient methods to fully characterize turbochargers by measuring the acoustic two-port have been developed. Compared to earlier work, a number of modifications are suggested for improving the quality of the results. A study on three different automotive turbochargers is also presented, including data for sound scattering for both the compressor and turbine. The results for the transmission of sound, which is of interest for the ability of a turbocharger to reduce noise coming from the engine, is plotted for all tested cases against a dimensionless frequency scale (Helmholtz-number). This makes it possible to generalize the result in order to draw conclusions about the behavior for any turbocharger. The sound generation was also studied and three different methods to estimate the sound power are suggested. The methods were used to investigate sound generation at different operating points and identify source mechanisms for a turbocharger compressor. An accurate method for measuring the reflection of plane acoustic waves from a pipe termination in a duct with hot gas flow has been developed and tested. Representing the acoustical conditions at an exhaust tail-pipe, the data obtained is important for effective modeling of exhaust systems. The experimental results of the reflection coefficient were compared with Munt`s theory on flow duct openings. The measurements were carried out for air jet velocities up to Mach 0.4 and for flow temperatures up to 100°C in order to study temperature effects on the reflection properties. It was concluded, that the experimental results agree well with the Munt theory. acoustical two-port turbocharger transmission loss sound generation compressor turbine IC-engine inlet system exhaust system flow duct duct termination reflection coefficient Vehicle Engineering Farkostteknik
119	Systemsimulation eines elektrischen Turboladers für Brennstoffzellenanwendungen unter Berücksichtigung von Kondensationsphänomenen in der Radialturbine Lück, Sebastian, Wittmann, Tim, Göing, Jan, Bode, Christoph, Friedrichs, Jens 27 May 2022 (has links) Das Betriebsverhalten eines elektrischen Turboladers zur Bedruckung des Kathodengassystems eines automobilen Brennstoffzellensystems wird unter Berücksichtigung der feuchten Brennstoffzellenabluft untersucht. Basierend auf den Komponentenkennfeldern von Elektromotor, Leistungselektronik, Lagerung und Turbomaschinenkomponenten werden stationäre und transiente Betriebslinien berechnet, anhand derer eine Betriebspunktverschiebung gezeigt wird. Diese kann auf die Einflüsse der Gaszusammensetzung und Kondensation in der Turbine zurückgeführt werden. Anhand von drei stationären Betriebspunkten wird die Zusammensetzung der Verluste innerhalb der Maschine gezeigt. Die Verzögerung wird zudem als kritisches Manöver im transienten Betrieb durch signifikante Abnahme des Pumpgrenzabstands identifiziert. / The performance of an electric turbocharger for the cathode gas supply system of an automotive fuel cell system is investigated considering moist air off gasses. Based on the component performance maps of electric motor, power electronics, bearings and turbomachinery, steady state and transient operating lines are calculated and a shift of operating points is shown. These can be traced back to the influence of gas composition and condensation within the turbine. Based on three operating points, losses inside the machine are characterized. Furthermore, deceleration is identified as the most critical transient operating scenario due to a significant decrease of the surge margin. info:eu-repo/classification/ddc/620 ddc:620
120	Electric turbocharger for fuel cells - IHI´s contribution to sustainable mobility Filsinger, Dietmar, Ehrhard, Jan, Kuwata, Gen, Ikeya, Nobuyuki 27 May 2022 (has links) Towards a carbon free society the IHI group is committed to provide products, technologies and services in line with ecological and economical sustainability. Storage and transportation of green energy are major challenges related to the global transition from fossil fuels towards 100% renewables. IHI is active in various areas ranging from SOFC technology via ammonia combustion to smart community demonstrator projects. With respect to mobility hydrogen fuel cell technology is identified as one major pillar for CO2-neutral vehicular propulsion – especially for higher payloads and extended driving distances. Since more than 20 years IHI is providing charging systems for stationary fuel cell applications and since 2004 also for mobile fuel cell applications. IHI´s oil free turbocharger for fuel cell applications is providing state-of-the-art boosting technology to enable emission free propulsion systems. It comprises a turbine, a compressor and, on the same shaft, an electric motor as well as air foil bearings to support the rotor. The turbine utilizes the enthalpy from the stack exhaust to lower the required electric power for driving the compressor. It can provide up to 40% of the needed compressor power and hence substantially increases the system efficiency. Compressor and turbine are optimized for operating conditions in fuel cell systems regarding specified airflow and pressure ratio, which is typically in the range of 3.0. info:eu-repo/classification/ddc/620 ddc:620 Brennstoffzelle; Mobilität; Turbine

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