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Highly-Efficient Energy Harvesting Interfaces for Implantable BiosensorsKatic, 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
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Μελέτη και κατασκευή συστήματος ελέγχου ηλεκτροκίνητου μικρού πλωτού μέσου μεταφοράςΜπαϊραχτάρης, Νικόλαος 04 September 2009 (has links)
Στόχος της παρούσας διπλωματικής εργασίας είναι ο σχεδιασμός και η κατασκευή του ηλεκτρικού κινητηρίου συστήματος ενός ηλεκτροκίνητου σκάφους. Πραγματοποιήθηκαν μία σειρά από τεχνικές επεμβάσεις ώστε να μετατραπεί ένα απλό σκάφος σε ηλεκτροκίνητο. Στην εποχή μας τα ηλεκτροκίνητα σκάφη και η ηλεκτρική πρόωση αποτελούν τμήμα των ηλεκτροκίνητων μέσων μεταφοράς. Τα ηλεκτροκίνητα μέσα μεταφοράς αποτελούν πιθανή λύση στην συνεχώς αυξανόμενη ζήτηση στον τομέα των μεταφορών καθώς και στα ενεργειακά και περιβαλλοντικά προβλήματα που αυτή προκαλεί. Ο υψηλός βαθμός απόδοσης των ηλεκτρικών κινητήρων και των ηλεκτρονικών μετατροπέων ισχύος, το υψηλό επίπεδο ελέγχου μέσω των ηλεκτρονικών μετατροπέων ισχύος που προσφέρει ευκινησία σε ένα σκάφος, η έλλειψη θορύβου-διαταραχών και η απουσία ρύπανσης μας οδηγούν στη χρήση των ηλεκτροκίνητων σκαφών και της ηλεκτρικής πρόωσης όλο και περισσότερο στις μέρες μας.
Στη συγκεκριμένη εφαρμογή για πρακτικούς λόγους αλλά και για λόγους ασφάλειας οδηγηθήκαμε στην επιλογή κινητήρα συνεχούς ρεύματος (Σ.Ρ.) μονίμου μαγνήτη χαμηλής τάσης 24V. Αυτό έχει ως αποτέλεσμα υψηλή τιμή ρεύματος για την επίτευξη της απαιτούμενης ισχύος 1,5 kW . Για αυτό το λόγο σχεδιάστηκε και κατασκευάστηκε ο ηλεκτρονικός μετατροπέας υποβιβασμού συνεχούς τάσης σε συνεχή με διαδοχική αγωγή τεσσάρων κλάδων, ο οποίος έχει τη δυνατότητα διαχείρισης υψηλών τιμών ρεύματος και είναι ιδανικός για τέτοιου είδους εφαρμογές.
Ο συγκεκριμένος μετατροπέας αποτελείται από 4 παράλληλους κλάδους, λειτουργεί στην συνεχή αγωγή και υποβιβάζει την τάση των 36V σε 0-24V για τον έλεγχο των στροφών του κινητήρα, ο οποίος έχει ονομαστικό ρεύμα 78A. Ο μετατροπέας εξετάστηκε αρχικά μέσω της εξομοίωσης χρησιμοποιώντας το λογισμικό PSpice και στη συνέχεια πειραματικά πραγματοποιώντας μία σειρά από δοκιμές και μετρήσεις. Από τις δοκιμές, παρατηρούμε ότι ο βαθμός απόδοσης του μετατροπέα διαδοχικής αγωγής που κατασκευάστηκε, κυμαίνεται γύρω στο 95%, άρα είναι μια καλή λύση στην οδήγηση κινητήρων συνεχούς ρεύματος (Σ.Ρ.) χαμηλής τάσης (υψηλού ρεύματος). Τέτοιοι κινητήρες χρησιμοποιούνται σε πληθώρα εφαρμογών ηλεκτροκίνητων μέσων μεταφοράς.
Η καθέλκυση του ηλεκτροκίνητου σκάφους και οι δοκιμές που πραγματοποιήθηκαν στη θάλασσα, δίνουν σαφή εικόνα των πλεονεκτημάτων της ηλεκτρικής πρόωσης. / The object of this diploma thesis is the designing and the construction of an electric drive system for an electric boat. A number of technical interventions were made to transform a simple boat to an electrically driven boat. In our days the electric boats and the electric propulsion in general constitute a part of the electric transportation. The electric transportation may be a possible solution in the continuously increasing demand in the sector of transports as well as in energy and environmental problems that this causes. The high efficient electric machines and power electronic converters, the high control level of power electronics that offers manoeuvrability in a ship, the lack of noise - disturbance and the absence of pollution lead us to use electric boats and electric propulsion more and more in our days.
In our application for practical and safety reasons we were led to the choice of a low voltage permanent magnet direct current (DC) motor. This is resulting to a high value of current to get the nominal power of 1.5 kW. For this reason an interleaved four – channel dc/dc converter was designed and constructed which has the ability to control high currents and is ideal for such type applications.
The particular converter is constituted by 4 parallel channels, it is working in the continuous conduction mode (CCM) and it degrades the voltage of 36V to 0-24V for the control of the rpm of the dc propulsion motor which its full load current is 78A. Firstly a number of simulations made via PSpice program and also a number of experiments to see how the converter is working. The experiments shows that the efficiency of the interleaved converter of the application is about 95%, so it is a good solution for driving low voltage – high current dc motors. Such types of electric motors are used in many electric transportation applications.
The launching of the boat and a number of sea tests shows us the advantages electric propulsion has.
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Akumulátorový svařovací zdroj / Battery-powered welding inverterStarec, Stanislav January 2019 (has links)
This master thesis is focused on proposition and following implementation of DC arc welder. This paper is based on semester’s paper, where the first version was realized. The welder is powered by a battery pack with LiFePO4 type cells. Battery cells are protected by BMS circuits. The driving electronics controls the duty cycle step-down (buck) converter in a closed current or power regulation loop. The power regulator has been designed and validated by simulations. Switching power transistors, low side and high side, are implemented by optically isolated gate drivers. Charging the battery is solved by a switching flyback converter. For the charger and the welder is sheet metal construction made of aluminum sheet.
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Palubní multifunkční jednotka pro motocykly / Multifunction board computer for motorcyclesNetáhlo, Tomáš January 2012 (has links)
Master’s thesis deals with a design and a realization of multifunction board computer for motorcycles. The goal of the device is measuring speed, rotation speed of engine, temperature of ambient, temperature of engine, temperature in intake including signalization of overvoltage and hightemperature. The device is completed by above standard function such as measuring titl of motorcycle, climbing of route, route recording and data transmission to the computer. The thesis includes a complete solution of hardware and software part of the device.
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Racionalizace konceptu připojení fotovoltaické elektrárny / Rationalization of the concept of photovoltaic power station connectionSvozil, Marek January 2015 (has links)
This masters thesis addresses the racionalization of the concept of photovoltaic power station connection. A way of compensation valuable components involvement standar- tizovaným inverter controlled by a microcontroller. Also includes the measurement of voltage and current using a microcontroller. The output voltage of the DC/DC con- verter is controlled by the variable duty cycle of the PWM signal generated by the microcontroller ATmega32.
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Peltierovy články pro výrobu elektrické energie / Thermoelectric Power Generation SystemBrázdil, Marian January 2011 (has links)
In the last decade there is a rising interest in thermoelectric applications. Thermoelectric generators enabling the direct conversion of the heat into the electricity become attractive. This fact is caused by the demands of environmental operation and saving primary resources. Scientists intensively investigate and develop new materials and structures suitable for these applications. The efficiency of the thermoelectric conversion progressively increases. Unfortunately we have no available materials with sufficient thermoelectric properties which could provide cost-competitive price. Thermoelectric generators seem to be useable devices. For example, in case of the unused waste heat using of the thermoelectric generator can increase the overall effectiveness of the unit despite the low efficiency of the generator. This master thesis deals with the issue of the Peltier modules representing the main part of the thermoelectric generators. The physical principles and structures of the thermoelectric modules and the possibility of thermoelectric power production are described here. In the practical part of this thesis the design of the low power generator utilizing waste heat from biomass boiler Verner A 251.1 is proposed.
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Hocheffizienter DC/DC-Wandler auf Basis von GaN-Leistungsschaltern für Hochleistungs-Leuchtdioden im KraftfahrzeugWerkstetter, Mario 12 April 2018 (has links)
In der vorliegenden Arbeit werden Möglichkeiten zur Maximierung der Effizienz von stromregelnden DC/DC-Wandlern für den Betrieb von Hochleistungs-LEDs in PKW-und Motorrad-Beleuchtungseinrichtungen untersucht, mit dem Ziel, das Gewicht und den Energieverbrauch der Steuergeräte zu reduzieren und so zu dem stetigen Bestreben der Minimierung der Gesamtfahrzeugemissionen beizutragen.
Dafür werden verschiedene, teils sequenziell aufbauende Maßnahmen in Topologie, Bauelementen, Dimensionierung und Betriebsart betrachtet. Eine grundlegende Herausforderung für die Auslegung der Schaltung stellt dabei deren universelle Verwendbarkeit als Gleichteil in einem großen Bereich an Ausgangsstrom und -spannung in den individuellen Scheinwerfersystemen der verschiedenen Fahrzeugderivate dar.
Die Grundlage für die Verringerung der Verlustleistung bildet die Vereinfachung der Schaltreglertopologie hinsichtlich des Bauteilaufwands. Dies wird durch die Versorgung der Schaltung aus dem 48 V-Energiebordnetz und die Verwendung der Topologie des Tiefsetzstellers erreicht.
Elementarer Anteil dieser Arbeit ist die Untersuchung der Wirksamkeit des Einsatzes neuartiger Galliumnitrid-Leistungsschalter (GaN-HEMTs) anstelle der konventionellen Silizium-MOSFETs, was zunächst an Hand von Berechnungen und schaltungstechnischen, parasitärbehafteten und zeitvarianten Simulationen durchgeführt wird. Bereits bei herkömmlichen Schaltfrequenzen und hartgeschaltetem Betrieb können signifikante Verbesserungen des Wirkungsgrades erreicht werden.
Weitergehend wird der Nutzen der durch die GaN-Transistoren ermöglichten höheren Schaltfrequenzen eruiert. Die um bis zu Faktor 20 erhöhte Schaltfrequenz macht den Einsatz einer resonanten Betriebsart (Zero-Voltage-Switching) und einer Luftspule als Hauptinduktivität notwendig.
Auf Steuergeräteebene kann somit die Verlustleistung auf unter ein Drittel reduziert werden, was zudem ein deutlich einfacheres und kompakteres Gehäuse ermöglicht, wodurch das Gesamtgewicht etwa halbiert werden kann.
Abschließend wird die Schaltung in einem Prototypen praktisch umgesetzt und die Funktionsfähigkeit im ZVS-Betrieb bei Schaltfrequenzen von bis zu 10 MHz verifiziert. / This thesis deals with the research of possibilities for maximising efficiency of current-regulating DC/DC-Converters for driving high-power-LEDs in passenger-car- and motorcycle-lighting-devices. The ambition is to reduce weight and energy-consumption of the electronic-control-units, to contribute to reach the continuously decreasing target-values for vehicle-emissions.
Therefor different approaches in topology, components, design and operating mode are considered. A key-challenge for the circuit-design is the common-part-strategy for usage in many individual vehicle-headlamp-systems with a wide range of output-current and LED-string-voltages.
Basis for the reduction of power-losses is the simplification of the converters topology in terms of quantity of components. This is achieved by using the 48 V -vehicle-electrical-system as voltage-supply and a step-down-topology.
Mainpart of this research is about the potential benefits of applying novel Galliumnitride High-electron-mobility-transistors (GaN-HEMTs) instead of silicon MOS-FETs. Initially this is done by calculations and parasitic-afflicted, timevariant circuit-simulations.
Already in hardswitching operation under conventional switching-frequencies significant improvements in converter-efficiency can be achieved.
Furthermore the advantages of higher switching-frequencies, offered by the GaN-transistors, are investigated. Up to 20 times higher switching-frequencies necessitate a resonant operating mode of the circuit (Zero-voltage-switching) and the use of an aircoil as main-inductor.
On ECU-level power-losses can be reduced down to less than one third, which enables a more simplified and compact housing-concept, so that the overall weight can drop to about the half.
Finally the designed circuit is build up in a prototype and the functional capability is verified in ZVS-mode with up to 10 MHz switching-frequency.
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DC-DC Converter for Fast Charging with Mobile BESS in a Weak Grid : Enabling remote charging and increased efficiency with less resource intensity / DC-DC-omvandlare för snabbladdning med mobilt batterienergilagringssystem i svaga elnät : Möjliggör laddning och ökad effektivitet med mindre resursintensitet på avlägsna platserMedén, Alexander January 2023 (has links)
With the increase of electric vehicles (EVs) on the roads the availability of charging infrastructure becomes more important. Today it is relatively straightforward to install fast chargers in areas with strong power grid connections, such as in urban areas. However, in areas with less available electrical power, the grid is considered to be a weak grid, typically in remote areas, which limits charging speeds. Local peak shaving can be implemented with battery energy storage systems (BESS) to support faster charging at these locations by increasing available power when needed. As the majority of the power is supplied by the BESS there are noticeable conversion losses when converting from the BESS DC voltage to AC in the grid and then back to DC through the fast charger. This thesis investigates DC/DC converters to charge EVs directly from a BESS DC bus by regulating the voltage to the level of the EV, while also supporting safe simultaneous charging capability. It was done through understanding relevant standards’ requirements, converter review, as well as design and simulation of the interesting topologies. The converters selected to simulate were the Buck-Boost and the Dual-Active Bridge (DAB). After analysing the efficiency result in combination with industry requirements, it was concluded that one DAB per output is the preferred option in most use cases. This would potentially also reduce the material usage and carbon footprint of this type of infrastructure compared to the current solution. Furthermore, some suggestions were made for improving the design of DAB converter before making a prototype for real testing. / Denna avhandling har undersökt hur en snabbladdares effektelektronik för en mobil batterienergilagringssystem kan designas för att ladda två elbilar samtidigt. För att göra detta har systemkrav från relevanta standarder sammanställts och olika snabbladdares kapacitet undersökts. Därefter har olika DC/DC-omvandlare identifierats i ändamål att välja ut de mest lämpade för att uppfylla funktionen. De utvalda omvandlarna designades iterativt och simulerades med i verktyget PLECS för att kunna jämföra hur vardera omvandlare presterade under olika scenarior och med olika transistorer. Resultat och slutsatser från detta arbete är att galvanisk isolering krävs mellan de två elbilarna samt att två Dual-Active Bridge (DAB) omvandlare är den mest lämpade utifrån effektivitet, kapacitet och materialanvänding. Det finns även flera områden att fortsätta arbetet på för att förbättra designen och testa med en prototyp.
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Univerzální mikropočítačová jednotka / Universal Microcontroller UnitKulenda, Vít January 2011 (has links)
Master’s thesis contains description parameters of microcontroller ATMEGA644P, also contains differences between older and newer version of microcontrollers ATMEGA644 and ATMEGA644PA. Inside structure of microcontroller, memories and peripherals are described here. The construction of the universal microcontroller unit is main target of this thesis. The unit contains supply, A/D converter, current loop, communication interfaces, temperature sensor, accelerometer and other. The unit collects and saves data, communicates by interfaces and manages other functions. Using devices and circuits are described in this thesis. Development of software for microcontroller(firmware) are positioned to last part of this thesis. This software control functions of all parts positioned on the unit.
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Contribution to the DC-AC conversion in photovoltaic systems : Module oriented converters / Contribution à l’étude de la conversion DC-AC dans des systèmes photovoltaïques : Convertisseurs orientés au module PVLopez Santos, Oswaldo 06 February 2015 (has links)
Ces dernières années, un intérêt croissant pour les systèmes électroniques de puissance a été motivé par l'émergence de sources d'énergie distribuées et renouvelables raccordées aux réseaux électriques. Dans ce contexte, la nécessité de topologies de faibles puissances alimentées par quelques modules photovoltaïques, en évitant l'utilisation de transformateurs, a ouvert l'étude de convertisseurs spéciaux et l’étude des stratégies de commande associées afin d’assurer la stabilité, la fiabilité et un rendement élevé du dispositif. Une possible solution est d’utiliser un dispositif générique connu dans la littérature scientifique et commerciale comme « micro-onduleur » ou «convertisseur intégré au module » qui avec le module photovoltaïque définit un produit « plug and play » appelé "module AC".Ce travail est consacré à l'étude d'un micro-onduleur monophasé avec deux étapes sans transformateur raccordée au réseau. La topologie proposée est composé d’un convertisseur DC-DC non isolé élévateur avec un gain quadratique et un onduleur réducteur lié au réseau connectés en cascade. Le convertisseur DC-DC extrait en permanence la puissance maximale du module photovoltaïque malgré les changements dans les conditions environnementales. L'étape DC-AC injecte la puissance extraite par l'étape DC-DC dans le réseau et assure un niveau élevé de qualité de l’énergie. Les efforts de recherche de ce travail sont concentrés sur la mise au point de commandes utilisant comment base, la théorie de contrôle par mode de glissement, qui conduit à une mise en œuvre simple avec une description théorique complète validée á partir de simulations et expérimentations.Après avoir décrit l'état de l’art dans le premier chapitre, le manuscrit est divisé en quatre chapitres, qui sont dédiés respectivement à l’algorithme de recherche du point de puissance maximale (MPPT), á l’étape de conversion DC-DC, á l'étape de conversion DC-AC et finalement au micro-onduleur complet. Un nouvel algorithme de recherche extrémal du point de puissance maximale est développé (SM-ESC). Pour la étape DC-DC, le convertisseur élévateur quadratique avec seulement un interrupteur contrôlé est étudié utilisant le concept de résistance sans perte par mode de glissement (de l’acronyme anglais : Sliding-Mode Loss-Free-Resistor – SM-LFR) afin d’obtenir un gain de tension élevé avec un fonctionnement sûr et compatible avec l’algorithme MPPT. Pour la étape DC-AC, le convertisseur de pont complet est contrôlé comme un onduleur de source de puissance (de l’acronyme anglais : Power Source Inverter - PSI) en utilisant une commande par mode de glissement qui poursuit une référence sinusoïdale de courant de sortie. Cette commande est complétée par une boucle de régulation de la tension du bus DC qui assure une haute qualité d’énergie injectée dans le réseau. Enfin, les trois étapes constitutives sont fusionnées pour obtenir un micro-onduleur complètement contrôlé par la technique de mode de glissement, ce qui constitue le principal résultat et contribution de cette thèse. / These last years, a growing interest in power electronic systems has been motivated by the emergence of distributed renewable energy resources and their interconnection with the grid. In this context, the need of low power topologies fed by a few photovoltaic modules avoiding the use of transformers opens the study of special converters and the associated control strategies ensuring stability, reliability and high efficiency. A resulted generic device known in the commercial and scientific literature as “microinverter” or “module integrated converter” performs a plug and play product together with the PV module called an “AC module”.This work is devoted to the study of a transformer-less single-phase double-stage grid-connected microinverter. The proposed topology has a non-isolated high-gain boost type DC-DC converter and a non-isolated buck type DC-AC converter connected in cascade through a DC bus. The DC-DC converter permanently extracts the maximum power of the PV module ensuring at the same time a good performance coping with power changes introduced by the change in the environmental conditions. The DC-AC stage injects the power extracted by the DC-DC stage into the grid ensuring a high level of power quality. The research efforts focus on the involved control functions based on the sliding mode control theory, which leads to a simple implementation with a comprehensive theoretical description validated through simulation and experimental results.After giving the state-of-the-art in the first chapter, the manuscript is divided into four chapters, which are dedicated to the Maximum Power Point Tracking (MPPT), the DC-DC stage and its control, the DC-AC stage and its control and the complete microinverter. A new Extremum Seeking Control (ESC) MPPT algorithm is proposed. The single-switch quadratic boost converter is studied operating as a Loss-Free-Resistor (LFR) obtaining a high DC output voltage level with a safe operation. The full-bridge converter is controlled as a Power Source Inverter (PSI) using a simple sliding-mode based tracking law, regulating the voltage of the DC bus and then ensuring a high power quality level in the grid connection. Finally, the three building blocks are merged to obtain a sliding mode controlled microinverter constituting the main result and contribution of the work
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