Global ETD Search

21	Viability of Power-Split Hybrid-Electric Aircraft under Robust Control Co-Design Bandukwala, Mustafa January 2021 (has links) No description available. Aerospace Materials Viability Robust Co-design Hybrid Power-split Air vehicle Hybrid Unmanned Air vehicle Hybrid Electric Propulsion System stochastic dynamic optimization
22	ALTERNATIVE PROPULSION FOR AIRCRAFT OF GENERAL AVIATION CATEGORY / ALTERNATIVE PROPULSION FOR AIRCRAFT OF GENERAL AVIATION CATEGORY Kaddour, Mirvat January 2016 (has links) Letecká doprava jako všechny ostatní dopravy podílí na produkci emisí skleníkových plynů, což je hlavní důvod změn klimatu. Disertační práce je zaměřena na možnost využití alternativního zdroje energie (paliva, motor) v letectví, aby se snížily emise produkované letadel. Oblast,na která již pracuje je všeobecné letectví, zejména letadel kategorie LSA a VLA. Tři možnosti, alternativní zdroj energie, budou diskutovány. První používá LPG palivo, další je elektrické motory, a poslední přidání katalyzátoru a výfukového systému. U každého z nich bude uvedeno výhody a nevýhody, hlavní změnu pohon letadla nebo výfukového systému a různé výkonnosti letadla v důsledku těchto změn.
23	Hydroacoustic Modelling of Podded Propulsion System : Underwater Radiated Noise Prediction Using ANSYS Persson, Martin January 2022 (has links) Ocean noise pollution is an invisible but growing threat. There are many sources of sound in the ocean but human underwater radiated noise, in particular from shipping is one of the most prominent one. Ocean noise pollution can interfere or sometimes even directly harm marine life. This thesis is in collaboration with Kongsberg Maritime which aims to develop an underwater radiated noise prediction method for the ELegance pod system. In particular, the focus is on the noise generated as a direct effect of the permanent magnet motor vibrations. Kongsberg wants to be able to calculate the underwater radiated noise for different pod geometries and engine configurations in order to find an optimal operating speed of the electric motor. The underwater radiated noise prediction is carried out using two methods. The first one is a 2-way coupled fluid-structure interaction harmonic response model, dealing with the vibrations. In addition, the flow induced noise is evaluated using CFD combined with Ffowcs-Williams Hawkings acoustic analogy. The harmonic response model is used to calculate the sound in terms of a frequency response, which can be translated to revolutions per minute of the rotor. This allows Kongsberg to identify rotor speeds where the operation may or may not be optimal. The flow induced noise is investigated for a typical transit speed. The results show this noise is multiple orders of magnitude smaller than the sound caused by the vibrations. This together with the fact that the computational cost of CFD is large suggests that the flow induced noise is not something Kongsberg needs to consider at an early design stage. Neither the propeller nor cavitation is considered in this thesis, due to the limited computational resources but also that Kongsberg designs propellers that are vessel specific. These sources of sound become important when considering the full acoustic profile of a propulsion unit of this type. Fluid Mechanics Computational Aeroacoustics Frequency Response Noise and Vibration Pod Propulsion System ANSYS Kongsberg Maritime Sweden AB Engineering and Technology Teknik och teknologier
24	Measurement of Static and Dynamic Performance Characteristics of Electric Propulsion Systems Brezina, Aron Jon 21 June 2012 (has links) No description available. Aerospace Engineering Engineering Mechanical Engineering Propeller Small Unmanned Aerial Vehicle UAV Electric Propulsion System Advance Ratio Low Reynolds Number Wind Tunnel Testing
25	Manobras evasivas sub?timas em leo sujeitas ? for?a de arrasto atmosf?rico e a colis?es com detritos espaciais Oliveira, Eduardo Mendes 25 August 2016 (has links) Submitted by Verena Pereira (verenagoncalves@uefs.br) on 2017-02-17T22:06:12Z No. of bitstreams: 1 Disserta??o Final (Corre??es) - Eduardo Mendes.pdf: 20884254 bytes, checksum: 2f9c97501da8a0259ee7afa7dee7506d (MD5) / Made available in DSpace on 2017-02-17T22:06:12Z (GMT). No. of bitstreams: 1 Disserta??o Final (Corre??es) - Eduardo Mendes.pdf: 20884254 bytes, checksum: 2f9c97501da8a0259ee7afa7dee7506d (MD5) Previous issue date: 2016-08-25 / In this research we studied evasive maneuvers to avoid collisions in an environment with debris, enabling missions to the space. When a collision occurs, usually the space vehicle is completely damaged and destroyed, thus ensuring that the satellite avoids this collision will preserve the objective of the mission. In this study, we will see how a space vehicle can perform an evasive maneuver through thedriveline under the effect of the atmospheric drag force, whose efficiency will be established through the settings of technological parameters, which are the amount of fuel in the space vehicle and the ability to eject the propellant through the propulsion system. The purpose of the evasive maneuver is to avoid the collision but to keep the vehicle in its nominal orbit. At first we found several initial conditions of collision with the space vehicle under the influence of Earth's gravitational force, to ensure that there would be a collision between objects, from that on, the propulsion force was applied, after that, considering only the effect of atmospheric drag on the objects and right after the two collisional objects were brought under the effect of both forces, the force of the atmospheric drag and the propulsion together. In search of the most economical maneuver, from the point of view of fuel consumption, maneuvers were performed with lower propulsion drive time, and at different times of the trajectory of the vehicle and also at random times with the use of the propulsion force . The maneuvers were found through numerical simulations for each mathematical model of disturbances added to the orbital dynamics under the influence of the gravitational force. / Neste trabalho, fizemos o estudo de manobras evasivas para evitar colis?es em ambiente de detritos, viabilizando as miss?es espaciais. Quando ocorre uma colis?o, normalmente o ve?culo espacial fica totalmente danificado e destru?do, portanto, garantir ao sat?lite o desvio da colis?o, preservar? o objetivo da miss?o. Neste estudo, veremos como um ve?culo espacial pode executar uma manobra evasiva, atrav?s do sistema propulsor, sob o efeito da for?a de arrasto atmosf?rico, cuja efici?ncia ser? estabelecida atrav?s das configura??es dos par?metros tecnol?gicos, sendo estes, a quantidade de combust?vel do ve?culo espacial e a capacidade de ejetar propelente pelo sistema propulsor. O objetivo da manobra evasiva ? evitar a colis?o, mas, mantendo o ve?culo em sua ?rbita nominal. A princ?pio foi encontrado um conjunto de condi??es iniciais de colis?o com o ve?culo espacial sob o efeito da for?a gravitacional da Terra, para garantir que haveria a colis?o entre os objetos e, a partir disto, foi aplicada a for?a de propuls?o, depois considerando somente o efeito do arrasto atmosf?rico sobre os objetos e logo ap?s, o ve?culo espacial e o detrito foram postos sob o efeito de ambas da for?a de propuls?o e do arrasto atmosf?rico, juntas. Em busca da manobra mais econ?mica, do ponto de vista do consumo de combust?vel, foram executadas manobras com tempo de acionamento de propuls?o menor, e em diferentes momentos da trajet?ria do ve?culo e tamb?m por tempos aleat?rios de acionamento de for?a de propuls?o. As manobras foram determinadas atrav?s de simula??es num?ricas para cada modelo matem?tico das perturba??es adicionadas ? din?mica orbital sob o efeito da for?a gravitacional. Detritos espaciais Manobras evasivas Sistema de propuls?o Arrasto atmosf?rico Computa??o aplicada Modelagem matem?tica Space debris Evasive maneuvers Propulsion system Atmospheric drag Computer applied Mathematical modeling
26	Solu??es de EDO e simula??es num?ricas para din?mica relativa colisional entre ve?culos operacionais e detritos espaciais Santana, Jadiane de Jesus 07 July 2018 (has links) Submitted by Verena Pereira (verenagoncalves@uefs.br) on 2018-11-14T22:49:02Z No. of bitstreams: 1 Disserta??o de Jadiane(C).pdf: 1600835 bytes, checksum: 6b3162236247731029b8ced5d94cc873 (MD5) / Made available in DSpace on 2018-11-14T22:49:02Z (GMT). No. of bitstreams: 1 Disserta??o de Jadiane(C).pdf: 1600835 bytes, checksum: 6b3162236247731029b8ced5d94cc873 (MD5) Previous issue date: 2018-07-07 / Earth's operational orbiting satellites are very useful for space science because it has great features as these services enable research and space explorations for scientific, commercial, and military interests as well. However, the increasing flow of space activities has increased the amount of debris orbiting in the operating regions, thereby increasing the chances of collisions in those areas, and allowing immeasurable damages if the satellite remains in this collision orbit. In view of the large number of operational objects, the study of evasive maneuvers for space vehicles has been growing, and this one is important in face of the possibility of collisions, not only with a single debris but with clouds of space debris. The objective of the evasive maneuver is to avoid collision, but by keeping the vehicle in its orbit nominally. The history of the phenomenon, that is, how it evolves over time, is found when the differential equation that represents the phenomenon is solved. From the point of view of Physics and Mathematics, the more realistic the model, the more difficult is the solution of the differential equations representing the phenomenon. Thus, this work seeks to present the analytical and semi-analytical solutions for the equations describing the relative dynamics between two bodies subjected to gravitational force, Chohessy-Wiltshire equations, under the influence of forces: gravitational, atmospheric drag, chemical propulsion ( exponential model and linear model), atmospheric drag plus chemical propulsion and plasma propulsion, and finally present their respective computational simulations. These simulations made it possible to show what happens to the operational satellites against a collision, for each specified model. With the contribution of the development of the atmospheric drag equation, with the drag coefficient varying / Os sat?lites operacionais em ?rbita da Terra s?o muito ?teis para a Ci?ncia Espacial, pois possuem grandes aplica??es e fun??es. Seus servi?os possibilitam pesquisas e explora??es espaciais para interesses cient?ficos, comerciais e tamb?m militares. Por?m, o crescente fluxo das atividades espaciais tem elevado a quantidade de detritos orbitando nas regi?es operacionais e, desse modo, aumentando as chances de colis?es nessas ?reas, e possibilitando imensur?veis preju?zos, caso o sat?lite permane?a nessa ?rbita de colis?o. Diante da grande quantidade de objetos operacionais e n?o operacionais, o estudo de manobras evasivas para os ve?culos espaciais torna-se urgente e necess?rio, visto a possibilidade de colis?es, n?o s? com um ?nico detrito, mas com nuvens de detritos espaciais. O objetivo da manobra evasiva ? evitar a colis?o, mas, mantendo o ve?culo em sua ?rbita nominal. A hist?ria do fen?meno, ou seja, como ele evolui no tempo, ? encontrada quando a equa??o diferencial que o representa ? resolvida. Assim obtemos a posi??o relativa entre os objetos colisionais no tempo. Do ponto de vista da F?sica e da Matem?tica, quanto mais realista for o modelo, mais dif?cil ser? a solu??o das equa??es diferenciais representantes do fen?meno. Assim, este trabalho busca apresentar as solu??es anal?ticas e semi-anal?tica para as equa??es que descrevem a din?mica relativa entre dois corpos sob a atua??o das for?as: gravitacional, de arrasto atmosf?rico, propuls?o qu?mica (modelo exponencial e modelo linear) e propuls?o plasma. Por fim, busca apresentar suas respectivas simula??es computacionais. Estas simula??es possibilitaram mostrar o que acontece com os sat?lites operacionais frente ? uma colis?o, para cada um modelo especificado. Outra contribui??o deste trabalho ? solu??o semi-anal?tica da din?mica relativa com arrasto atmosf?rico para densidade atmosf?rica n?o constante Detritos espaciais Manobras evasivas Sistema de propuls?o Arrasto atmosf?rico Computa??o aplicada Modelo matem?tico Space debris Evasive maneuvers Propulsion system Atmospheric drag Applied computing Mathematical model
27	Robust design methodology for common core gas turbine engines Sands, Jonathan Stephen 08 June 2015 (has links) A gas turbine engine design process was developed for the design of a common core engine family. The process considers initial and projected variant engine applications, likely technology maturation, and various sources of uncertainty when making initial core design considerations. A physics based modeling and simulation environment was developed to enforce geometric core commonality between the core defining design engine and a common core variant engine. The environment also allows for upgrade options and technology to be infused into the variant engine design. The relationships established in the model enable commonality to be implicitly enforced when performing simultaneous design space explorations of the common core design and all corresponding variant engine designs. A robust design simulation process was also developed, enabling probabilistic surrogate model representations of the common core engine family design space to be produced. The probabilistic models provide confidence interval performance estimates with a single function call for an inputted set of core and variant design settings and the uncertainty distribution shape parameter settings representative of an uncertainty scenario of interest. The unique form of the probabilistic surrogate models enables large numbers of common core engine family applications to be considered simultaneously, each being simulated under a unique uncertainty scenario. Implications of core design options can be instantaneously predicted for all engine applications considered, allowing for favorable common core design regions to be identified in a highly efficient manner. Robust design Robust design simulation Propulsion system Gas turbine engine core Product family Common core Design Systems design and optimization Design variant Probabilistic design Design under uncertainty Multiple design point
28	Multiphase fluid hammer: modeling, experiments and simulations Lema Rodríguez, Marcos 10 October 2013 (has links) This thesis deals with the experimental and numerical analysis of the water hammer phenomenon generated by the discharge of a pressurized liquid into a pipeline kept under vacuum conditions. This flow configuration induces several multiphase phenomena such as cavitation and gas desorption that cannot be ignored in the water hammer behavior.<p><p>The motivation of this research work comes from the liquid propulsion systems used in spacecrafts, which can undergo fluid hammer effects threatening the system integrity. Fluid hammer can be particularly adverse during the priming phase, which involves the fast opening of an isolation valve to fill the system with liquid propellant. Due to the initial vacuum conditions in the pipeline system, the water hammer taking place during priming may involve multiphase phenomena, such as cavitation and desorption of a non-<p>condensable gas, which may affect the pressure surges produced in the lines. Even though this flow behavior is known, only few studies model the spacecraft hardware configuration, and a proper characterization of the two-phase flow is still missing. The creation of a reliable database and the physical understanding of the water hammer behavior in propulsion systems are mandatory to improve the physical models implemented in the numerical codes used to simulate this flow configuration.<p><p>For that purpose, an experimental facility modeling a spacecraft propulsion system has been designed, in which the physical phenomena taking place during priming are generated under controlled conditions in the laboratory using inert fluids. An extended experimental campaign was performed on the installation, aiming at analyzing the effect of various working parameters on the fluid hammer behavior, such as the initial pressure in the line, liquid saturation with the pressurant gas, liquid properties and pipe configuration. The influence of the desorbed gas during water hammer occurrence is found to have a great importance on the whole process, due to the added compressibility and lower speed of sound by an increasing amount of non-condensable gas in the liquid + gas mixture. This results in lower pressure levels and faster pressure peaks attenuation, compared to fluids without desorption. The two-phase flow was characterized by means of flow visualization of the liquid front at the location where the fluid hammer is generated. The front arrival was found to be preceded by a foamy mixture of liquid, vapor and non-condensable gas, and the pressure wave reflected at the tank may induce the liquid column separation at the bottom end. While column separation takes place, the successive pressure peaks are generated by the impact of the column back against the bottom end.<p><p>The resulting experimental database is then confronted to the predictions of the 1D numerical code EcosimPro/ESPSS used to assess the propulsion system designs. Simulations are performed with the flow configuration described before, modeling the experimental facility. The comparison of the numerical results against the experimental data shows that aspects such as speed of sound computation with a dissolved gas and friction modeling need to be improved. / Doctorat en Sciences de l'ingénieur / info:eu-repo/semantics/nonPublished Mécanique Sciences de l'ingénieur Multiphase flow Liquid propellants Propulsion systems Ecoulement polyphasique Propergols liquides Systèmes de propulsion Water hammer fluid hammer cavitation gas absorption gas des- orption multiphase flow two-phase flow liquid propellant propulsion system priming flow visualization CFD simulation
29	Néandertal en armes ? : des armes, et de l'arc, au tournant du 50ème millénaire en France méditerranéenne / Neandertal in arms ? : about weapons, and bow, at the turn of the 50th millennium in Mediterranean France Metz, Laure 14 December 2015 (has links) Ce travail consiste en l’étude fonctionnelle de la séquence supérieure de la Grotte Mandrin (du 55 au 43ème millénaire) en France méditerranéenne. Dans cette séquence, le niveau Néronien de la Grotte Mandrin apparaît comme une anomalie, tant d’un point de vue technique, que fonctionnel. Sa profusion de pointes, leur caractère non seulement microlithique mais plus encore standardisé m’a amené à réfléchir sur la finalité de ces productions. Quelle est la signification de cette signature associant standardisation et microlithisation réelle au sein d’une unique unité de cette vaste séquence archéologique ? Au travers d’une étude fonctionnelle spécifiquement orientée vers la recherche, la détermination et la compréhension des associations de stigmates d’impact, une méthode d’approche, l’étude impactologique, est ici exposée à partir de la constitution d’un référentiel expérimental original. L’étude impactologique des pointes de Mandrin E révèle qu’au moins 15,5 % d’entre-elles ont été utilisées comme partie vulnérante ou perforante d’arme. Le module extrêmement réduit de ces micro- et nanopointes induit une inertie pondérale particulièrement faible que seul un système de propulsion à très forte énergie cinétique peut compenser. La réflexion a donc porté sur le mode de propulsion employé permettant de rendre effectif et efficace ces pointes de très faible dimension. Les résultats amènent à la conclusion que seul un système de propulsion tel que l’arc a pu compenser la faible énergie cinétique des tous petits éléments impactés découverts à Mandrin E. / This work is an use-wear analysis of the upper sequence of Grotte Mandrin in Mediterranean France (from the 55th to 43rd millennium). In this sequence, the Neronian level of Grotte Mandrin appears as an anomaly, both from a technical and a functional perspective. Its profusion of points and their not only microlithic but also standardized character prompts reflection on the purpose of these productions. What is the meaning of this signature, combining standardization and real microlithization within a single unit of this vast archaeological sequence? Through a functional study specifically oriented toward research, determination and understanding of the associations of impact scars, a method of approach, an impact study, is presented here, and constructed from a systematic, original experiment. An impactological study of the Mandrin E points reveals that at least 15.5% of them were used as weapons. In the absence of any other criteria revealing other functions, and in view of the exceptionally high rate of impacted pieces, we must consider whether all of these small objects belong directly and exclusively to the sphere of armaments. The extreme reduction of these micro- and nanopoints results in a particularly weak inert weight that can only be compensated for by a propulsion system with very high kinetic energy. Attention has therefore been focused on the mode of propulsion used to make these very small, sometimes less than a centimeter, points effective and efficient. The results lead to the conclusion that only a propulsion system such as the bow would be able to offset the low kinetic energy of all of these small impacted elements discovered at Mandrin E. Paléolithique moyen Moustérien Néronien Grotte Mandrin Pointes Stigmates diagnostiques d’impact Etude impactologique Système de propulsion mécanique Arc Middle Paleolithic Mousterian Neronian Grotte Mandrin Points Diagnostic impact scars Impactology study Mechanical propulsion system Bow
30	Co-Optimisation du Dimensionnement et du Contrôle des Groupe Motopropulseurs Innovants / Design and Control Co-Optimization for Advanced Vehicle Propulsion Systems Zhao, Jianning 26 October 2017 (has links) Des technologies avancées sont très demandées dans l'industrie automobile pour respecter les réglementations de consommation de carburant de plus en plus rigoureuses. La co-optimisation du dimensionnement et du contrôle des groupes motopropulseurs avec une efficacité de calcul améliorée est étudiée dans cette thèse.Les composants des groupes motopropulseurs, tels que le moteur, la batterie et le moteur électrique, sont modélisés analytiquement au niveau descriptif et prédictif afin de permettre une optimisation du contrôle rapide et une optimisation du dimensionnement scalable. La consommation d'énergie minimale des véhicules hybrides-électriques est évaluée par des nouvelles méthodes optimales. Ces méthodes – y compris Selective Hamiltonian Minimization et GRaphical-Analysis-Based energy Consumption Optimization – permettent d'évaluer une consommation minimale d'énergie avec une efficacité de calcul améliorée. De plus, la méthode de Fully-Analytic energy Consumption Evaluation (FACE) approxime la consommation d'énergie minimale sous forme analytique en fonction des caractéristiques de la mission et des paramètres de conception des composants du groupe motopropulseur. Plusieurs cas d’études sont présentées en détail par rapport aux approches de co-optimisation à bi-niveaux et à uni-niveau, ce qui montre une réduction efficace du temps de calcul requis par le processus global de co-optimisation. / Advanced technologies are highly demanded in automotive industry to meet the more and more stringent regulations of fuel consumption. Cooptimization of design and control for vehicle propulsion systems with an enhanced computational efficiency is investigated in this thesis.Powertrain components, such as internal combustion engines, batteries, and electric motor/generators, are analytically modeled at descriptive and predictive level correspondingly for the development of fastrunning control optimization and for the scalability of design optimization. The minimal fuel consumption of a hybrid-electric vehicle is evaluated through novel optimization methods. These methods – including the Selective Hamiltonian Minimization, and the GRaphical-Analysis-Based energy Consumption Optimization – are able to evaluate the minimal energy consumption with the enhanced computational efficiency. In addition, the Fully-Analytic energy Consumption Evaluation method approximates the minimal energy consumption in closed form as a function of the mission characteristics and the design parameters of powertrain components.A few case studies are presented in details via the bi-level and uni-level co-optimization approaches, showing an effective improvement in the computational efficiency for the overall co-optimization process. Optimisation du dimensionnement, Optimisation du contrôle Groupes moto-Propulseurs Véhicule électrique hybride Véhicule électrique Véhicule conventionnel Design optimization Control optimization Vehicle propulsion system Hybrid electric vehicle Battery-electric vehicle Conventional vehicle

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