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Boost and Buck-Boost Power-Factor-Corrected AC-to-DC Resonant Converters with ZVS OperationLi, Yan-Cun 31 July 2008 (has links)
The research presents two novel high power factor ac-to-dc resonant converters with symmetrical topologies and zero-voltage-switching (ZVS) operation. The derived circuits are obtained from the integration of a dual-switch boost-type or buck-boost-type power factor corrector (PFC) into a half-bridge resonant converter. With symmetrical topology, the circuit is simple and the voltage and current stresses on the two active power switches are identical to each other.
The PFC is operated at discontinuous conduction mode (DCM) to achieve unity power factor. The resonant energy tank of half-bridge resonant converter is designed to be inductive to retain ZVS operation. The design equations are derived based on fundamental approximation. Prototypes of the two proposed converters designed for 100 W and 50 W, respectively, were built and tested to verify the computer simulations and analytical predictions. Satisfactory results are obtained experimentally.
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Soft-Switching High-Frequency AC-Link Universal Power Converters with Galvanic IsolationAmirabadi, Mahshid 16 December 2013 (has links)
In this dissertation the ac-link universal power converters, which are a new class of power converters, are introduced and studied in detail. The inputs and outputs of these converters may be dc, ac, single phase, or multi-phase. Therefore, they can be used in a variety of applications, including photovoltaic power generation, wind power generation, and electric vehicles. In these converters the link current and voltage are both alternating and their frequency can be high, which leads to the elimination of the dc electrolytic capacitors and the bulky low-frequency transformers. Therefore, the ac-link universal power converters are expected to have higher reliability and smaller size. Moreover, these converters are soft switching, which results in negligible switching losses and minimized current and voltage stress over devices.
In the first part of the dissertation, the parallel ac-link universal power converter is studied in detail. This converter is an extension of the buck-boost converter. The series ac-link universal power converter, which is dual of the parallel ac-link universal power converter, is proposed in the second part of this dissertation. This converter is an extension of the Cuk converter. A modified configuration with fewer switches, named sparse ac-link universal power converter is proposed in the third part of this dissertation. The sparse ac-link universal power converters can appear as parallel or series.
The performance of all these configurations is evaluated through simulations and experiments.
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Switching Power Converter Techniques for Server and Mobile ApplicationsSingh, Manmeet 13 November 2020 (has links)
No description available.
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Design and Construction of 1800W Modular Multiple Input Single Output Non-isolated DC-DC ConvertersGallardo, Angelo Miguel Asuncion 01 June 2017 (has links) (PDF)
This thesis report details the design and construction of non-isolated DC-DC converters to create a Multiple Input Single Output (MISO) converter for combining multiple renewable energy sources into one single output. This MISO uses the four-switch buck-boost topology to output a single 48V from multiple nominal 24V inputs. The MISO converter implements a modular approach to deliver 1800W output power. Each module in the MISO is rated at 600W and they share the output power equally. Hardware results show that the converter produces 1800W of output power from three sources with 96.4% efficiency. Each module also demonstrates equal sharing feature of the MISO converter.
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A Wide Input Power Line Energy Harvesting Circuit For Wireless Sensor NodesWang, Jinhua January 2021 (has links)
Massive deployment of wireless IoT (Internet of Things) devices makes replacement or recharge of batteries expensive and impractical for some applications. Energy harvesting is a promising solution, and various designs are proposed to harvest power from ambient resources including thermal, vibrational, solar, wind, and RF sources. Among these ambient resources, AC powerlines are a stable energy source in an urban environment. Many researchers investigated methods to exploit this stable source of energy to power wireless IoT devices.
The proposed circuit aims to harvest energy from AC powerlines with a wide input range of from 10 to 50 A. The proposed system includes a wake-up circuit and is capable of cold-start. A buck-boost converter operating in DCM is adopted for impedance matching, where the impedance is rather independent of the operation conditions. So, the proposed system can be applied to various types of wireless sensor nodes with different internal impedances. Experimental results show that the proposed system achieves an efficiency of 80.99% under the powerline current of 50 A. / M.S. / Nowadays, with the magnificent growth of IoT devices, a reliable, and efficient energy supply system becomes more and more important, because, for some applications, battery replacement is very expensive and sometimes even impossible. At this time, a well-designed self-contained energy harvesting system is a good solution. The energy harvesting system can extend the service life of the IoT devices and reduce the frequency of charging or checking the device.
In this work, the proposed circuit aims to harvest energy from the AC power lines, and the harvested power intends to power wireless sensor nodes (WSNs). By utilizing the efficient and self-contained EH system, WSNs can be used to monitor the temperature, pressure, noise level and humidity etc.
The proposed energy harvesting circuit was implemented with discrete components on a printed circuit board (PCB). Under a power line current of 50 A @ 50 Hz, the proposed energy harvesting circuit can harvest 156.6 mW, with a peak efficiency of 80.99 %.
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Design And Analysis Of A New Buck-Boost Converter With A Low-Side SwitchAwidah, Abdullah 01 June 2024 (has links) (PDF)
This work explores the design, simulation, construction, and analysis of a novel Non-isolated DC-DC Buck-Boost converter which has the advantage of incorporating a low-side switch compared to the traditional buck-boost which requires a high-side switch. This allows the use of a low-side driver which further simplifies the design and operation of the converter. The proposed Buck-Boost converter was constructed to provide -24 V output from an input range of 12V-18V with 15V nominal input at 10W maximum output power utilizing 500kHz switching frequency. Findings from simulations and hardware tests verify that the converter effectively provides the desired -24 V output at varying loads with less than 3% ripple. At the nominal input voltage, the efficiency of the converter reaches 82.37% at full load and peak efficiency of 88.5% at 20% load. Moreover, the input voltage ripple of the proposed non-isolated converter reached 8.4% at full load, due to the pulsating nature of the input current. Overall, results verify the feasibility of the proposed non-isolated Buck-Boost converter as an alternative solution for the conventional buck-boost with the advantage of a low side switch while maintaining a low component count.
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Commande et optimisation d'une installation multi-sources. / Control and Optimization of a Photovoltaic Installation.Alotaibi, Lafi 30 March 2012 (has links)
Cette thèse traite la commande et l'optimisation d'une installation photovoltaïquepour un site isolé. Ainsi, nous avons proposé un algorithme par logique flouepermettant la poursuite du point de puissance maximal afin de remédier auxinconvénients des méthodes classiques. Ensuite, nous nous sommes intéressés àl'optimisation de la structure de l'installation. En effet, dans les installationsclassiques, dans le cas de défaillance d'un panneaux, tout le bloc série devientinutilisable, ce qui réduit considérablement les capacités de production del'installation. Pour résoudre ce problème, nous avons proposé un superviseur permettant la reconfiguration automatique de l'installation de telle sorte que seul lepanneaux défaillant est mis hors connexion. Par ailleurs, pour gérer le flux depuissance et pour répondre à la demande de l'utilisateur, nous avons développé un superviseur par logique floue. Ainsi, le surplus de production est stocké systématiquement dans la batterie pour l'utiliser ensuite en cas où la demandedépasse la production. De plus, la structure proposée permet de ne solliciter la batterie en cas de besoin de ce qui permet de prolonger considérablement sa duréede vie. / This thesis addresses the control and optimization of a stand-alone photovoltaicsystem. Thus, we proposed a fuzzy logic algorithm for tracking the maximum powerpoint to overcome the disadvantages of classical methods. Then we focused onoptimizing the structure of the installation. Indeed, in conventional systems, in thecase of failure of a panel, the whole serie block becomes unusable, greatly reducingthe production capacity. To resolve this problem, we proposed a supervisor for theautomatic reconfiguration of the installation so that only the failed panels is takenoffline. Furthermore, to manage the power flow and to meet user demand, wedeveloped a fuzzy supervisor. Thus, the surplus production is systematically storedin the battery for later use in cases where demand exceeds production. In addition,the proposed structure can not draining the battery in case of need thereby greatlyextend its lifetime.
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Integrated, Dynamically Adaptive Supplies for Linear RF Power Amplifiers in Portable ApplicationsSahu, Biranchinath 19 November 2004 (has links)
Energy-efficient radio frequency (RF) power amplifiers (PAs) are critical and paramount to achieve longer battery life in state-of-the-art portable systems because they typically determine and dominate the power consumption of such devices. In this dissertation, a high-efficiency, linear RF PA with a dynamically adaptive supply and bias current control for code division multiple access (CDMA) and wideband CDMA (WCDMA) is conceived, simulated, and experimentally demonstrated with a discrete PCB-level design and in integrated circuit (IC) form. The PA efficiency is improved by dynamically adjusting both its supply voltage and bias current, there by minimizing its quiescent power dissipation. The PA supply voltage is derived from the battery by a noninverting, synchronous buck-boost switching regulator because of its flexible functionality and high efficiency. Adjusting the PA supply voltage and bias current by tracking the output power, instead of following the complete envelope in large baseband bandwidth wireless applications, is achieved by a converter with a lower switching frequency and consequently higher light-load efficiency, which translates to prolonged battery life.
A discrete PCB-level prototype of the proposed system with 915 MHz center frequency, CDMA IS-95 signal having 27-dBm peak-output power resulted in more than four times improvement in the average efficiency compared to a fixed-supply class-AB PA while meeting the required performance specifications. In the IC solution fabricated in AMIs 0.5-micron CMOS process through MOSIS, a dual-mode, buck-boost converter with pulse-width modulation (PWM) control for high power and pulse-frequency modulation (PFM) for low power is designed and implemented to improve the PA efficiency during active and standby operation, respectively. The performance of the dynamically adaptive supply and bias control IC was validated by realizing a 25-dBm, 1.96 GHz center frequency, WCDMA PA over an input supply range of 1.4 4.2 V. The PA with dual-mode power supply and bias control IC showed an average-efficiency improvement of seven times compared to a fixed-supply class-AB PA, which translates to five times improvement in battery life assuming the PA is active for 2 % of the total time and in standby mode otherwise.
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Design Of An Educational Purpose Multifunctional Dc/dc Converter BoardBaglan, Fuat Onur 01 August 2008 (has links) (PDF)
In this thesis a multifunctional DC/DC converter board will be developed for utilization as an educational experiment set in the switched-mode power conversion laboratory of power electronic courses. The board has a generic power-pole structure allowing for easy configuration of various power converter topologies and includes buck, boost, buck-boost, flyback, and forward converter topologies. All the converters can be operated in the open-loop control mode with a switching frequency range of 30-100 kHz and a maximum output power of 20 W. Also the buck converter can be operated in voltage mode control and the buck-boost converter can be operated in peak-current-mode control for the purpose of demonstrating the closed loop control performance of DC/DC converters. The designed board allows for experimentation on the DC/DC converters to observe the macroscopic (steadystate/ dynamic, PWM cycle and low frequency) and microscopic (switching dynamic) behavior of the converters. In the experiments both such characteristics can be clearly observed such that students at basic learning level (involving only the macroscopic behavior), and students at advanced learning level (additionally involving the parasitic effects) can benefit from the experiments. The thesis reviews the switch mode conversion principles, gives the board design and proceeds with the experiments illustrating the capabilities of the experimental system.
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Οικιακό φωτοβολταϊκό σύστημα συνδεδεμένο στο δίκτυοΦραγκιουδάκη, Άννα 09 January 2012 (has links)
Στην παρούσα διπλωματική εργασία διερευνώνται οι προδιαγραφές για την εγκατάσταση και τη διασύνδεση με το δίκτυο διανομής ενός οικιακού φωτοβολταϊκού συστήματος. Ο όρος «οικιακό» αναφέρεται σε φωτοβολταϊκά συστήματα μικρής ισχύος, έως 10 kWp, τα οποία τοποθετούνται πάνω σε κτίρια ή ενσωματώνονται σε αυτά ενώ παρέχουν ηλεκτρική ενέργεια στο δίκτυο μέσω της ίδιας παροχής του κτιρίου. Τα οικιακά φωτοβολταϊκά παρουσιάζουν πολλά πλεονεκτήματα ώστε να αποτελέσουν πόλο έλξης για τους μελλοντικούς παραγωγούς όπως θερμική μόνωση, ηχομόνωση, ηλιο-προστασία, δεν απαιτούν επιπλέον χώρο για την εγκατάσταση τους, συνεισφέρουν στην κάλυψη του φορτίου αιχμής, δε περιλαμβάνουν κινητά μέρη, προσφέρουν έναν ελκυστικό σχεδιασμό κτιρίου και αντικαθιστούν συμβατικά κατασκευαστικά υλικά.
Στο πρώτο κεφάλαιο παρουσιάζεται μια θεωρητική ανασκόπηση της φύσης της ηλιακής ακτινοβολίας. Στο δεύτερο κεφάλαιο γίνεται μια περιγραφή του ηλιακού κυττάρου, των φωτοβολταϊκών πλαισίων και των αρχών λειτουργίας τους, καθώς και παρουσιάζονται τα ηλεκτρικά χαρακτηριστικά τους και οι παράγοντες που τα επηρεάζουν. Εν συνεχεία, στο τρίτο κεφάλαιο μπορούμε να δούμε τα κριτήρια με τα οποία επιλέγεται ο τόπος και ο τρόπος εγκατάστασης ενός φωτοβολταϊκού συστήματος, και παρουσιάζονται οι αρχές σχεδιασμού του συστήματος ξεκινώντας από την επιλογή του αντιστροφέα μέχρι τα μέσα προστασίας και την καλωδίωση. Στο τέταρτο κεφάλαιο παρουσιάζονται οι απαιτήσεις που πρέπει να τηρούνται ώστε να καθίσταται εφικτή η διασύνδεση με το δίκτυο ΧΤ μιας εγκατάστασης παραγωγής ενέργειας. Επιπλέον, εξετάζονται τα κριτήρια τήρησης των ανωτέρω απαιτήσεων, όπως η επάρκεια του δικτύου, η διαμόρφωση των προστασιών της διασύνδεσης, οι μεταβολές της τάσης, το φαινόμενο flicker, η έγχυση αρμονικών, η νησιδοποίηση και οι επιπτώσεις στα συστήματα Τηλεχειρισμών Ακουστικής Συχνότητας. Εν τέλει, στο πέμπτο κεφάλαιο πραγματοποιούνται προσομοιώσεις για την μελέτη των παραπάνω προδιαγραφών σε δύο διατάξεις που εξομοιώθηκαν με το πρόγραμμα PSCAD. Η μια διάταξη περιλαμβάνει μια φωτοβολταϊκή συστοιχία ισχύος 9.6 kWp, έναν μετατροπέα υποβιβασμού τάσης ο οποίος κάνει την ανίχνευση του σημείου μεγίστης ισχύος, έναν τριφασικό αντιστροφέα με παλμοδότηση SPWM, το φίλτρο LC για τη μείωση του αρμονικού περιεχομένου, έναν μετασχηματιστή απομόνωσης και ανύψωσης τάσης 150V/400V, το δίκτυο ΧΤ και το οικιακό φορτίο. Η δεύτερη διάταξη διαφοροποιείται από την πρώτη στο ότι δεν περιλαμβάνει μετατροπέα υποβιβασμού τάσης, έτσι ο αντιστροφέας αναλαμβάνει την ανίχνευση του σημείου μεγίστης ισχύος. Αρχικά παρουσιάζεται η απόκριση των συστημάτων σε κανονικές συνθήκες λειτουργίας και μέση φόρτιση, ενώ εξετάζεται και η επίδραση των τιμών των ελεγκτών στην απόκριση τους. Στη συνέχεια, γίνεται η μελέτη αρμονικών και η διερεύνηση της επίδρασης της ακτινοβολίας στους συντελεστές ολικής αρμονικής παραμόρφωσης ρεύματος και τάσης, και στο συντελεστή ισχύος. Έπειτα εξετάζεται η απόκριση των συστημάτων σε απότομες μεταβολές της ακτινοβολίας και του φορτίου. Τέλος διερευνώνται οι διακυμάνσεις της τάσης που εμφανίζονται σε οριακές καταστάσεις λειτουργίας του φωτοβολταϊκού και φόρτισης του δικτύου ενώ εξετάζονται και οι επιπτώσεις στα συστήματα Τηλεχειρισμών Ακουστικής Συχνότητας. / The aim of the present thesis is the study of the installation and grid-interconnection requirements and specifications of a domestic photovoltaic system. The term “domestic” refers to low power photovoltaic systems (up to 10 kWp), installed or integrated into buildings while providing electric power to the grid through the buildings main power connection. Domestic photovoltaic systems have a number of advantages, such as thermal / sound insulation, solar protection, they do not require extra space in order to be installed, they can contribute in the case of high power demand, they do not require any moving parts, they can prove attractive in terms of building design and even eventually substitute conventional building materials. These advantages are bound to put them in the center of electric power producers’ attention in the immediate future.
In the first chapter a theoretic overview of the nature of solar radiation is presented. In the second chapter, photovoltaic cells and panels as well as their function and electrical properties are briefly analyzed. In the third chapter, the criteria of the photovoltaic system’s installation location and method – from the selection of a proper inverter to the system’s electrical protection equipment and wiring. In the fourth chapter the requirements that must be met in order to establish a connection with the power distribution grid are being presented. The relevant criteria such as: a) power grid adequacy, b) proper design and configuration of the grid connection protection equipment, c) voltage variations, d) flickering, e) voltage/current harmonics, f) islanding, and g) effects on 175Hz remote-operation systems are being studied. Finally, in the fifth chapter, PSCAD-realized simulations with two configurations are presented. The first configuration consists of a 9.6kWp photovoltaic array, a dc-to-dc buck converter which implements a maximum-power-point-tracking algorithm, a SPWM-pulsed three-phase inverter, a LC harmonic filter, an isolating 150V/400Vvoltage transformer, the low-voltage grid and a domestic electric load. The second configuration does not include a buck converter and thus, the maximum-power-point-tracking algorithm is implemented on the inverter. The systems’ response in normal operating conditions and with a medium load as well as the effect of different controller gains in the aforementioned response are initially presented. Afterwards, the system’s voltage/current harmonics and the effect of solar radiation in the Total Harmonic Distortion and Power factors are being studied. In continuation the system’s response in rapid change of solar irradiance / electrical load is presented. Finally, voltage variations which appear in boundary operating conditions of the grid and photovoltaic system, as well as the impact on 175Hz remote-operation systems are studied.
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