Global ETD Search

31	Energy Harvesting Opportunities Throughout the Nuclear Power Cycle for Self-Powered Wireless Sensor Nodes Klein, Jackson Alexander 12 June 2017 (has links) Dedicated sensors are widely used throughout many industries to monitor everyday operations, maintain safety, and report performance characteristics. In order to adopt a more sustainable solution, much research is being applied to self-powered sensing, implementing solutions which harvest wasted ambient energy sources to power these dedicated sensors. The adoption of not only wireless sensor nodes, but also self-powered capabilities in the nuclear energy process is critical as it can address issues in the overall safety and longevity of nuclear power. The removal of wires for data and power transmission can greatly reduce the cost of both installation and upkeep of power plants, while self-powered capabilities can further reduce effort and money spent in replacing batteries, and importantly may enable sensors to work even in losses to power across the plant, increasing plant safety. This thesis outlines three harvesting opportunities in the nuclear energy process from: thermal, vibration, and radiation sources in the main structure of the power plant, and from thermal and radiation energy from spent fuel in dry cask storage. Thermal energy harvesters for the primary and secondary coolant loops are outlined, and experimental analysis done on their longevity in high-radiation environments is discussed. A vibrational energy harvester for large rotating plant machine vibration is designed, prototyped, and tested, and a model is produced to describe its motion and energy output. Finally, an introduction to the design of a gamma radiation and thermal energy harvester for spent nuclear fuel canisters is discussed, and further research steps are suggested. / Master of Science Energy harvesting Nuclear Power Plant Wireless Sensor Node Electromagnetic Generator Compliant Mechanism Thermoelectric Generator Gamma Radiation MCNP Simulation Gamma Heating Dry Cask Storage
32	Système thermoélectrique pour la récupération d'énergie : modélisation électrique et continuité de service de la circuiterie électronique / Thermoelectric system for energy harvesting : electrical modeling and continuity of service of electronic circuit Siouane, Saïma 06 December 2017 (has links) La récupération d'énergie thermique basée sur les générateurs thermoélectriques (TEG) est utilisée dans de nombreuses applications telles que les dispositifs médicaux auto-alimentés. La sûreté de fonctionnement et la continuité de service de ces systèmes sont aujourd'hui des préoccupations majeures. Ainsi, toute défaillance au niveau d'un des interrupteurs commandables de la circuiterie électronique d'interface peut provoquer de graves dysfonctionnements du système. Tout défaut non détecté et non compensé peut mettre en danger l'ensemble du système et interrompt l'alimentation en énergie de la charge. Par conséquent, la mise en œuvre d'une compensation de défaut efficace et rapide est impérative afin d'assurer la continuité de service. Dans ces travaux de recherche, nous étudions la continuité de service d'une interface électronique pour TEG basée sur une conversion à deux étages Buck/Buck-Boost cascadés. Une modélisation électrique générique (modèle de Thévenin) du TEG sous différentes conditions de fonctionnement et prenant en compte l'ensemble des résistances thermiques de contact est tout d'abord présentée. Ensuite, une méthode de compensation de défaut de type circuit-ouvert au niveau de l'interrupteur commandable de l'un des deux convertisseurs DC-DC est également proposée. Nous présentons une topologie originale de convertisseur DC-DC à tolérance de pannes, sans redondance matérielle classique. Cette topologie permet d'assurer la continuité de service du système de récupération d'énergie en mode nominal. Les études théoriques ont été validées par simulation et par des tests expérimentaux / Thermal energy harevsting based on thermoelectric generators is used in many applications such as self-powered medical devices. The reliability and continuity of service of these systems are now major concerns. Furthermore, any failure in the controllable switch of the electronic interface circuitry can cause serious system malfunctions. Any undetected and uncompensated fault can endanger the entire system and interrupt the power supply to the load. Therefore, the implementation of an efficient and rapid fault compensation is imperative in order to ensure the continuity of service. In this research, we study the continuity of service of an electronic interface for TEG, based on a two-stage conversion cascaded Buck/Buck-Boost. A generic electrical modeling of the TEG model under different operating conditions and with taking into account all the thermal contact resistances is first presented. Next, an open-circuit fault compensation method of the controllable switch of one of the two DC-DC converters is also proposed. We present an original fault-tolerant DC-DC converter topology with no conventional hardware redundancy. This topology ensures the continuity of service of the energy recovery system in nominal mode. Theoretical studies were validated by simulation and experimental tests Système de récupération d'énergie Continuité de service Tolérance de pannes Circuiterie électronique Conversion DC-DC Générateur thermoélectrique Energy harvesting system Continuity of service Fault tolerant Electronic circuitry DC-DC conversion Thermoelectric generator 620.004 52
33	Herstellung, Simulation und Charakterisierung thermoelektrischer Generatoren auf Basis anisotroper Oxidmaterialien Dreßler, Christian 18 September 2017 (has links) (PDF) Die thermoelektrische Energiekonversion auf der Basis des Seebeck-Effekts ist eine Methode zur direkten Erzeugung elektrischer Energie aus thermischer Energie. Für die wesentlichen anwendungsrelevanten Parameter Temperaturbereich, elektrische Leistung und Herstellungskosten sind Materialauswahl und Aufbau der TEG entscheidend. In der vorliegenden Arbeit wurden erstmalig thermoelektrische Oxidkeramiken in monolithischen TEG verwendet, die auf der Grundlage des transversalen thermoelektrischen Effekts arbeiten. Die TEG wurden mit industriell skalierbaren Keramiktechnologien hergestellt, untersucht und hinsichtlich ihrer Parameter detailliert theoretisch und experimentell bewertet. Als Modellsystem für die Materialien wurde La1-xSrxCuO4 in Kombination mit Ag bzw. Ag6Pd1 verwendet. Es konnte belegt werden, dass diese monolithischen TEG im Bereich kleiner elektrischer Leistungen eine vorteilhafte Alternative zu herkömmlichen longitudinalen thermoelektrischen Generatoren sein können. Thermoelektrisches Oxid thermoelektrischer Generator transversaler thermoelektrischer Effekt anisotrope Thermoelektrik Multilagen-Prozess thermoelctric oxide thermoelectric generator transversal thermoelectric effect anisotropic thermoelectric multilayer process ddc:660 Oxidkeramik Thermoelektrischer Generator Seebeck-Effekt
34	Systèmes multisources de récupération d'énergie dans l'environnement humain : modélisation et optimisation du dimensionnement / Multisource systems for harvesting energy in the human environment : modeling and sizing optimization Lossec, Marianne 07 July 2011 (has links) Ces travaux s'inscrivent dans la problématique de l'alimentation autonome de systèmes électroniques communicants fondée sur la récupération de l'énergie disponible dans l'environnement humain. Cette thèse traite du dimensionnement d'un générateur multisource (thermique, photovoltaïque et cinétique) avec stockage d'énergie. Afin d'optimiser le dimensionnement d'un tel système dans un contexte de ressources paramétrables, des modèles génériques, adaptés à une large plage de dimensions, ont été établis, à partir de technologies déjà existantes, et validés expérimentalement. L'approche système a permis d'étudier les nombreux couplages multiphysiques existants et de mieux dimensionner le système. Ainsi, il a été montré qu'optimiser le rendement global de toute la chaîne de conversion d'énergie conduit à des solutions différentes de celles résultant d'une optimisation du dimensionnement de chaque organe pris séparément. Enfin, dans la dernière partie de cette thèse, une étude a été menée sur l'impact du profil de consommation sur le dimensionnement du système. Cette étude a permis, sur le cas particulier d'une application réelle, de mettre en évidence le potentiel d'une gestion d'énergie en cas de ressources faibles notamment par l'adaptation des profils de consommation. / This work deals with the problematic of self-powered communicating electronic systems based onenergy harvesting in the human environment. This thesis addresses the sizing of a multisource generator(thermal, photovoltaic and kinetic) with energy storage. To optimize the sizing of such a systemin the context of configurable resources, generic models, adapted to a wide range of dimensions, wereestablished from existing technology, and validated experimentally. The system-level approach wasused to study the many existing multiphysics couplings to better size the system. Thus, it was shownthat optimizing the global efficiency of the whole energy conversion chain leads to solutions differentfrom those resulting from sizing optimization of each component separately. Finally, in the latter partof this thesis, a study was conducted on the impact of load profil on the sizing of the system. Thisstudy, on the particular case of a real application, highlight the potential for energy management inthe case of poor ressources, notably by adapting the load profils. Récupération d'énergie ambiante Générateur micro-cinétique Générateur thermoélectrique Optimisation du dimensionnement Gestion de la consommation Energy harvesting Multisource generator modelling Micro-kinetic generator Thermoelectric generator Sizing optimization Demand-side management
35	Development of laser-based joining technology for the fabrication of ceramic thermoelectric modules Börner, Floriana-Dana, Schreier, Max, Feng, Bing, Lippmann, Wolfgang, Martin, Hans-Peter, Michaelis, Alexander, Hurtado, Antonio 17 April 2020 (has links) The process of laser-induced brazing constitutes a potential option for connecting several ceramic components (n- and p-type ceramic bars and ceramic substrate) of a thermoelectric generator (TEG) unit. For the construction of the TEGs, TiOₓ and BₓC were used as thermoelectric bars and AlN was used as substrate material. The required process time for joining is well below that of conventional furnace brazing processes and, furthermore, establishes the possibility of using a uniform filler system for all contacting points within the thermoelectric unit. In the work reported here, the application-specific optimization of the laser-joining process is presented as well as the adapted design of the thermoelectric modules. The properties of the produced bonding were characterized by using fatigue strength and microstructural investigations. Furthermore, the operational reliability of the modules was verified. info:eu-repo/classification/ddc/670 ddc:670
36	Termoelektrický solární generátor / Thermo-electric solar generator Kočvárek, Ondřej January 2008 (has links) The introduction of this work is devoted to the description of physical principals and condtruction of modern semiconductor thermoelectric transformers. This work describes thein basic characters and the most commonly used materials for thein production. Further, it mentions the basic principals and physical effects that describe the thermoelectric conversion of energy and the nondestructive method for establishing the basic material characteristics of thermoelectric transformers. The substantiv part of this work is the measuring of the material’s characteristics of the accessible thermoelectric elements through the medium of experimental measuring network. The optimal construction of thermoelectric solar generators used for individual thermoelectric elements are designed based on the taken measurements and the evaluation of material’s characteristics of the observed thermoelectric elements.
37	Využití termoelektrického generátoru pro zvýšení využití odpadního tepla / Use of a thermoelectric generator for increasing heat recovery Laga, Ondřej January 2015 (has links) This thesis deals with the problem of waste heat, namely, the exhaust gas which are not frequently used. Specifically, it is a design of thermoelectric generators set, power electronics for fan and heat exchanger proposal. The entire system uses the energy of the waste heat to increase the heating efficiency.
38	Implementation of DC-DC converter with maximum power point tracking control for thermoelectric generator applications Jahanbakhsh, David January 2012 (has links) A heavy duty vehicle looses approximately 30-40 % of the energy in the fuel as waste heat through the exhaust system. Recovering this waste heat would make the vehicle meet the legislative and market demands of emissions and fuel consumption easier. This recovery is possible by transforming the waste heat to electric power using a thermoelectric generator. However, the thermoelectric generator electric characteristics makes direct usage of it unprotable, thus an electric power conditioner is necessary. First a study of dierent DC-DC converters is presented, based on that the most suitable converter for thermoelectric application is determined. In order to maximize the harvested power, maximum power point tracking algorithms have been studied and analyzed. After the investigation, the single ended primary inductor converter was simulated and implemented with a perturb and observe algorithm, and the incremental conductance algorithm. The converter was tested with a 20 W thermoelectric generator, and evaluated.The results show that the incremental conductance is more robust and stable compared to the perturb and observe algorithm. Further on, the incremental conductance also has a higher average eciency during real implementation. Thermoelectric generator Waste heat recovery DC-DC converter single ended primary inductor converter Maximum power point tracking Perturb and observe Incremental conductance Elektroteknik och elektronik
39	Nízoenergetické měniče v pevné fázi pro Energy harvesting / Low Energy Solid-State Converters for Energy Harvesting Znbill, Laila January 2021 (has links) Disertační práce je zaměřena na nízkoenergetické konvertory pro zpracování energie. Pro fotovoltaické generátory pracující při nízké úrovní osvětlení byly navrženy konvertory založené na konfiguraci single cell. Pomocí levných výrobních procesů a dostupných materiálů byl navržen a vyroben jednoduchý a spolehlivý termogenerátor. Výrobní postupy využívaly plazmatické aktivace povrchu pomocí výboje s dielektrickou bariérou a modifikované metody depozice PEDOT. Byly navrženy jednoduché a spolehlivé DC/DC měniče pro nízkonapěťové aplikace jako termoelektrické generátory a fotovoltaické články v konfiguraci single cell. Měniče pracují od napětí několika desítek mV a výstupní napětí může být na úrovni několika voltů. Účinnost se blíží 50% a náklady na materiál a výrobu jsou ve srovnání s použitím běžně dostupných integrovaných obvodů pro Energy Harvesting výrazně nižší. Pro řídicí obvody byly použity bipolární tranzistory, které v režimu velmi malých proudů mohou mít napájecí napětí od 0,5 V. Byla ověřena možnost výroby integrovaných obvodů s extrémně nízkým provozním napětím. Tranzistory FET zde pracují v podprahovém režimu a v režimu Bulk-driven.
40	Highly-Efficient Energy Harvesting Interfaces for Implantable Biosensors Katic, Janko January 2017 (has links) Energy harvesting is identified as an alternative solution for powering implantable biosensors. It can potentially enable the development of self-powered implants if the harvested energy is properly handled. This development implies that batteries, which impose many limitations, are replaced by miniature harvesting devices. Customized interface circuits are necessary to correct for differences in the voltage and power levels provided by harvesting devices from one side, and required by biosensor circuits from another. This thesis investigates the available harvesting sources within the human body, proposes various methods and techniques for designing power-efficient interfaces, and presents two CMOS implementations of such interfaces. Based on the investigation of suitable sources, this thesis focuses on glucose biofuel cells and thermoelectric harvesters, which provide appropriate performance in terms of power density and lifetime. In order to maximize the efficiency of the power transfer, this thesis undertakes the following steps. First, it performs a detailed analysis of all potential losses within the converter. Second, in relation to the performed analysis, it proposes a design methodology that aims to minimize the sum of losses and the power consumption of the control circuit. Finally, it presents multiple design techniques to further improve the overall efficiency. The combination of the proposed methods and techniques are validated by two highly efficient energy harvesting interfaces. The first implementation, a thermoelectric energy harvesting interface, is based on a single-inductor dual-output boost converter. The measurement results show that it achieves a peak efficiency of 86.6% at 30 μW. The second implementation combines the energy from two sources, glucose biofuel cell and thermoelectric harvester, to accomplish reliable multi-source harvesting. The measurements show that it achieves a peak efficiency of 89.5% when the combined input power is 66 μW. / Energiskörd har identifierats som en alternativ lösning för att driva inplanterbara biosensorer. Det kan potentiellt möjliggöra utveckling av själv-drivna inplanterbara biosensorer. Denna utveckling innebär att batterier, som sätter många begränsningar, ersätts av miniatyriserade energiskördsenheter. Anpassade gränssnittskretsar är nödvändiga för att korrigera för de skillnader i spänning och effektnivå som produceras av de energialstrande enheterna, och de som krävs av biosensorkretsarna. Denna avhandling undersöker de tillgängliga källorna för energiskörd i den mänskliga kroppen, föreslår olika metoder och tekniker för att utforma effektsnåla gränssnitt och presenterar två CMOS-implementeringar av sådana gränssnitt. Baserat på undersökningen av lämpliga energiskördskällor, fokuserar denna avhandling på glukosbiobränsleceller och termoelektriska energiskördare, som har lämpliga prestanda i termer av effektdensitet och livstid. För att maximera effektiviteten hos effektöverföringen innehåller denna avhandling följande steg. Först görs en detaljerad analys av alla potentiella förluster inom boost-omvandlare. Sedan föreslår denna avhandling en designmetodik som syftar till att maximera den totala effektiviteten och effektförbrukningen. Slutligen presenterar den flera designtekniker för att ytterligare förbättra den totala effektiviteten. Kombinationen av de föreslagna metoderna och teknikerna är varierade genom två högeffektiva lågeffekts energigränssnittskretsar. Den första inplementeringen är ett termoelektriskt energiskördsgränssnitt baserat på en induktor, med dubbla utgångsomvandlare. Mätresultaten visar att omvandlaren uppnår en maximal effektivitet av 86.6% vid 30 μW. Det andra genomförandet kombinerar energin från två källor, en glukosbiobränslecell och en termoskördare, för att åstadkomma en tillförlitlig multi-källas energiskördslösning. Mätresultaten visar att omvandlaren uppnår en maximal effektivitet av 89.5% när den kombinerade ineffekten är 66 μW. / <p>QC 20170508</p> / Mi-SoC Energy harvesting interface thermoelectric generator glucose biofuel cell power management dc-dc converter boost converter zero-current switching zero-voltage switching implantable biosensor Energiskördsgränssnitt termoelektrisk generator glukosbiobränslecell energihantering DC-DC-omvandlare boost-omvandlare inplanterbar biosensor Annan elektroteknik och elektronik

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