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Low voltage autonomous buck-boost regulator for wide input energy harvestingAhmed, Khondker Zakir 08 June 2015 (has links)
While high power buck-boost regulators have been extensively researched and
developed in the academia and industry, low power counterparts have only recently gained
momentum due to the advent of different battery powered and remote electronics. The
application life-time of such applications, e.g., remote surveillance electronics can be
extended tremendously by enabling energy autonomy. While battery powered electronics
last long but they must be replenished once the battery is depleted either by replacing the
battery or by retrieving the electronics and then recharging. Instead, energy harvesting from
available ambient sources on the spot will enable these electronics continuous operation
unboundedly, probably even beyond the lifetime of the electronics. Interestingly enough,
recent advancements in micro-scale energy transducers compliment these demand [1-13].
Micro-transducers producing energy from different ambient sources have been reported.
These transducers produce enough energy to support a wide range of operations of the
remote electronics concurrently. These transducers along with an additional storage
elements greatly increase the energy autonomy as well as guaranteed operation since
harvested energy can then be stored for future use when harvestable energy is temporarily
unavailable.
Recently several buck-boost regulators with low power and low input operating
voltage have been reported both from academia and industry [14-24]. Some of this work
focuses on increasing efficiency in the mid-load range (10mA-100mA), while some other
focuses on lowering input range. However, so far no one has reported a buck-boost
regulator operating with sub-200nW bias power while harvesting energy from sub-500mV input range. This work focuses on the development of a low voltage low bias current buckboost regulator to attain these goals.
In this work, complete design of a PFM mode buck-boost regulator has been
discussed in details. Basic topology of the regulator and working principle of the
implemented architecture along with the advantages of the specific topology over that of
the others have been discussed in short to provide an uninterrupted flow of idea. Later,
Transistor level design of the basic building blocks of the buck-boost regulator is discussed
in details with different design features and how those are attained through transistor level
implementation are discussed. Subsequently, the physical layout design technique and
considerations are discussed to inform the reader about the importance of the layout process
and to avoid pitfalls of design failure due to layout quality issues.
Measurement results are presented with the fabricated IC. Different
characterization profile of the IC have been discussed with measured data and capture
oscilloscope waveforms. Load regulation, line regulation, efficiency, start-up from low
voltage, regulation with line and load transient events are measured, presented and
discussed. Different characteristics of the prototype are compared with prior arts and are
presented in a comparison table. Die micrograph is also presented along with the different
issue of the IC testing
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Energy transfer between low current discharge and insulation surfacesXiao, An January 2015 (has links)
With the development of electricity transmission systems, more and more insulators have been used in the system to isolate the high potential conductors from the earth. In order to secure the reliability of power system, it is necessary to understand the ageing mechanism of the insulators. A model for energy (heat) transfer between low current discharges and insulation surfaces has been built in this project which contributes to the understanding and prediction of insulator ageing. Within the experimental work, the temperature of low current discharges under different conditions has been measured with the “Best-fit” method. The temperature was found to vary between 1200 K and 2300 K with current level, sub cycle duration, gap length, electrode conductivity and polarity of DC discharges. The discharge temperature increases with the growth of current and sub cycle duration by means of the elevation of energy, while the discharge temperature is hotter between salt water droplets than between tap water droplets even though the former has a lower energy (I^2 Rt). The temperature is insensitive to a change of gap length and a positive discharge has a higher temperature than an equivalent negative one. The specific measurement shows the middle part is hotter than the electrode areas. Within the simulation work, the presence of water droplet(s) on the insulation surface concentrates and enhances the electric field over the surface which increases the risk of partial discharge. For practical insulators, this means the core, rather than the sheds, suffers more from discharges between water droplets as they are aligned to the electric field. This highlights the importance of keeping the core dry. The simulation of heat transfer between low current discharges insulation surface was achieved using COMSOL software. The simulated results show that the surface temperature increases rapidly in the first few seconds and arrives at a thermal equilibrium state after 20 seconds of discharge, which meets the experimental observation. The insulation surface temperature distribution under AC discharge is symmetric and the surface centre has the highest temperature which decreases towards the water droplets. In DC, the surface around the cathode is the hottest and the anode area is the coldest.
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Développement de comparateur cryogénique de courants très faible bruit pour la métrologie électrique quantique. / Development of very low noise cryogenic current comparator for quantum electrical metrology.Rengnez, Florentin 30 November 2015 (has links)
Dans un contexte de besoin grandissant en précision dans la mesure des faibles courants pour les instituts nationaux de métrologie, l’industrie, les fabricants d’instruments et la physique fondamentale, l’étude des dispositifs à un électron (SET) capables de générer un courant continu directement proportionnel à une fréquence et la charge élémentaire, couplés à un amplificateur de courant très performant, le comparateur cryogénique de courant (CCC), devient pertinente pour réaliser un étalon quantique de courant. Dans ce contexte, les travaux ont été poursuivis au LNE sur l’étude de nouveaux dispositifs SET et le développement de nouveaux CCC. Durant cette thèse, un montage expérimental a été mis en place afin d’évaluer les performances d’un nouveau CCC, constitué d’une conception originale et de 30 000 tours. Les résultats expérimentaux obtenus sont satisfaisant par rapport aux objectifs fixés, que ce soit en termes de résolution en courant, d’erreurs, de stabilité des mesures et de reproductibilité. Le CCC développé durant la thèse peut donc être utilisé pour quantifier de manière métrologique les dispositifs à un électron. De plus, une modélisation réalisée à partir d’un schéma électrique équivalent a été mis en place afin de simuler le comportement réel du CCC en prenant en compte les aspects magnétiques et électriques mis en jeu. Cette simulation a permis la quantification de l’erreur due aux fuites de courants au travers des capacités parasites entourant les enroulements. Les résultats de la simulation indiquent que cette erreur atteint 10 10 à la fréquence de travail, ce qui est inférieure de deux ordres de grandeurs à l’erreur maximale tolérable : 10-8. Les résultats expérimentaux et de modélisation fournissent de nouveaux éléments d’amélioration de la conception de CCCs de grand gain. Enfin, la modélisation développée, une fois insérée dans une routine d’optimisation, pourra aussi être un outil de conception des CCCs très utile. / In a context of growing need of precision in measuring low currents for national metrology institutes, industry, instrument manufacturers and fundamental physics, study of single-electron tunneling (SET) devices capable of generating a direct current directly proportional to the frequency and the elementary charge, coupled with a high performance current amplifier, the cryogenic current comparator (CCC), becomes relevant to realize a quantum current standard. In this framework, at LNE, study of new SET devices and the development of CCCs continues. In this thesis, an experimental setup was implemented to evaluate the performance of a new CCC, consisting of a new design and 30 000 turns. The experimental results fulfill our goals, whether in terms of current resolution, errors, measurement stability and reproducibility. The CCC developed during the thesis can thus be used to metrologically quantify SET devices. In addition, a model based on an equivalent circuit diagram has been developed to simulate the actual behavior of the CCC, taking into account the magnetic and electrical aspects involved. This simulation allows the quantification of the error due to currents leakage through parasitic capacitances surrounding the windings. Results of the simulation indicate that this error reaches 10 10, which is less, by two orders of magnitude, than the maximum tolerable error: 10 8. Results obtained experimentally and by simulation provide new improvement elements in the design of high ratio CCCs. The developed model, once inserted into an optimization routine, can also be a very useful design tool of CCCs.
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Analysis of high-voltage low-current DC/DC converters for electrohydrodynamic pumpsAxelsson, Sigge, Gartner, Jonas, Stafström, Axel January 2023 (has links)
Moving parts cause vibrations and tend to wear out. In applications where maintenance is complicated, solutions without moving parts are therefore advantageous. Electrohydrodynamic pumps are such a solution. Instead of mechanical propulsion, they use strong electric fields to induce movement in a dielectric cooling liquid. These pumps require very little power, but to generate sufficiently strong electric fields, they need to be fed with very high voltage. This project explored various methods for designing DC/DC-converters which fulfil the demands of an electrohydrodynamic pump. This was done by altering and combining existing topologies that were deemed to be relevant. The main method for testing and evaluation was by simulating in LTspice. The project also briefly investigated methods of overcurrent protection. This was relevant because gas bubbles in the cooling fluid can cause electric arcs which damage the pumps. Three converter topologies were chosen for further evaluation. First, a conventional resonant Royer-based converter that has previously been used by APR Technologies which was altered by the inclusion of a feedback loop. Second, a high-frequency resonant Royer-based converter with a planar air-core transformer. Third, a transformerless converter with a switched boost converter IC. All circuits included a Cockroft-Walton voltage multiplier bridge. The two resonant Royer-based converters fulfilled all requirements except the one on efficiency, while the transformerless converter fulfilled all requirements except the one on cost, set by APR. The more expensive transformerless converter had a significantly higher efficiency and a wider range of acceptable input voltages. Furthermore three general conclusions were drawn. The first was that planar air-core transformers are not beneficial compared to conventional transformers in these type of applications. The second was that a discrete voltage regulator controlled by feedback from the output is more effective than using a voltage regulator without feedback, as it also eliminates temperature and load variations. The third conclusion was that to protect the circuits from overcurrent, a large series resistor is needed, which causes significantly lowered efficiency.
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