Global ETD Search

21	AC-DC Cuk converter based on three state switching cell with power factor correction applied in battery charger / Conversor CA-CC Ćuk baseado na cÃlula de comutaÃÃo de trÃs estados com correÃÃo de fator de potÃncia aplicado em carregador de banco de baterias Juliano de Oliveira Pacheco 30 January 2014 (has links) CoordenaÃÃo de AperfeiÃoamento de Pessoal de NÃvel Superior / This work presents the study and implementation of an ac-dc Ćuk converter based on the three state switching cells applied in charger stations for electric vehicles. This converter has, as main characteristics, reduction of conducting power losses in the semiconductors, a single stage topology and current source behavior for both input and output terminals. As drawbacks, the topology presents: the voltage across the semiconductors is equal to the sum of the input and the output voltages, and a difference between the current values through the semiconductors caused by an inappropriate layout of the power prototypes or by a lack of symmetry between the control signals. The analysis of the converter is made through the qualitative and quantitative studies, beyond the analysis of the semiconductor losses which are presented as well. The current and voltage of the battery are controlled by the average current mode technique, which consist in a fast current control loop if compared with the terminals battery voltage control loop. The topology is design for 1 kW output power, 220 V in input voltage and 162 V in the output terminals (12 batteries in series connection). Experimental results for resistive load, as well batteries, are shown in order to verify the functionalities of the topology and its characteristics. / Este trabalho apresenta o estudo e desenvolvimento de um conversor ca-cc Ćuk baseado na cÃlula de comutaÃÃo trÃs estados para aplicaÃÃo em carregadores de baterias para veÃculos elÃtricos. As principais caracterÃsticas deste conversor sÃo: a reduÃÃo das perdas por conduÃÃo nos interruptores controlados, um Ãnico estÃgio de processamento de potÃncia e caracterÃstica de fonte de corrente na entrada e na saÃda. Como inconvenientes a topologia apresenta: a tensÃo sobre os semicondutores igual Ã soma das tensÃes de entrada e saÃda e o desequilÃbrio de corrente atravÃs dos componentes quando hÃ assimetria no layout da placa de potÃncia ou nos sinais de comando dos interruptores. Um estudo teÃrico Ã realizado atravÃs das anÃlises qualitativa e quantitativa, alÃm das anÃlises do processo de comutaÃÃo e das perdas nos componentes do conversor. Para controlar o fluxo de potÃncia da rede elÃtrica para as baterias Ã utilizada a estratÃgia de controle modo corrente mÃdia, sendo que, a mesma apresenta uma malha de corrente rÃpida que monitora a corrente de entrada e uma malha de tensÃo lenta que supervisiona a tensÃo sobre os terminais da bateria. Neste trabalho Ã realizado o projeto do carregador de baterias para aplicaÃÃo em veÃculos elÃtricos com 1 kW de potÃncia, tensÃo de entrada eficaz de 220 V e tensÃo de saÃda de 162 V, correspondente a 12 baterias conectadas em sÃrie. Um protÃtipo com as especificaÃÃes indicadas foi construÃdo e testado experimentalmente em laboratÃrio e os resultados de simulaÃÃo e experimentais obtidos sÃo utilizados para validar a anÃlise teÃrica e o projeto realizado. Foram realizados testes com carga puramente resistiva e em seguida com um banco de baterias, que comprovaram o funcionamento da topologia. Conversores Carregador de baterias ENGENHARIA ELETRICA
22	Mikroprocesorem řízený nabíječ baterií / Microcontroller driven battery charger Michalčík, Bohumil January 2012 (has links) The first part of the work was dealing in general with switched power supply and types of battery chargers. The second part is made by my own design of microprocessor driven battery charger. The design is based on datasheets and recommended circuit connection. The electrical scheme and also the printed circuit board was designed in Eagle 5.11.0 design system. The battery charger is capable of charging these types of batteries: lead acid, NiMH, NiCd, LiPol a alkaline accumulators, and the maximal output current from charger is 3A. The software implementation and design are also part of this master‘s thesis.
23	Nabíječka 14,6 V 100 A pro LiFePO4 akumulátor / LiFePO4 battery charger 14,6 V 100 A Hanžl, Ondřej January 2020 (has links) This thesis deals with a design, construciton and testing of a switch-mode power supply (SMPS) which is working as a LiFEPO4 battery charger with output current up to 100~A and output voltage up to 14,6~V. The output voltage and current can be regulated by the operator from zero to maximum value. For this SMPS Half-bridge asymmetrical forward converter with two transformers and common output inductor topology is chosen. The control circuits are run by the IC SG3525. Cascaded regulation of output voltage and current is implemented by two discrete operational amplifiers. Undervoltage protection of the control circuits and independent overcurrent protection on the primary side is also implemented.
24	Mikroprocesorem řízený nabíječ baterií / Microcontroller driven battery charger Michalčík, Bohumil January 2012 (has links) The first part of the work was dealing in general with switched power supply and types of battery chargers. The second part is made by my own design of microprocessor driven battery charger. The design is based on datasheets and recommended circuit connection. The electrical scheme and also the printed circuit board was designed in Eagle 5.11.0 design system. The battery charger is capable of charging these types of batteries: lead acid, NiMH, NiCd, LiPol a alkaline accumulators, and the maximal output current from charger is 3A. The software implementation and design are also part of this master‘s thesis.
25	PCB-Based High-Power DC/DC Converters with Integrated Magnetics for Battery Charger Applications Jin, Feng 07 June 2024 (has links) Rising fuel costs and concerns about air pollution have significantly increased interest in electric vehicles (EVs). EVs are equipped with rechargeable batteries that can be fully recharged by connecting to an external electrical source. However, the wider adoption of EVs is hindered by the need for an on-board charger system that is both lightweight and efficient. EVs utilize two main charging methods: on-board chargers (OBC) for regular charging and off-board (fast) chargers for quick refills of battery pack. Most EVs currently use 400V battery packs paired with 6.6kW or 11kW OBCs, while larger vehicles with over 100 kWh battery packs employ 16.5kW or 19.2kW OBCs, constrained by household voltage and current limits. Some manufacturers are transitioning to 800V battery packs to lower costs and enhance fast charging capabilities, necessitating the development of 800V OBCs with high efficiency and power density. For household use, EVs can charge via OBC in a grid-to-vehicle transfer and can supply energy back to the home or grid (vehicle-to-grid) for emergency use or to support smart grid functionalities, requiring bidirectional OBCs. Advanced power semiconductor devices have been instrumental in advancing power conversion technology. The introduction of power semiconductor devices based on wide bandgap (WBG) materials marks a revolutionary shift, offering potential improvements over silicon-based devices. These WBG devices are capable of achieving higher efficiency, and higher power density in power conversion at higher operation frequency. Elevating the switching frequency diminishes the voltage-second across the transformer, facilitating the utilization of printed-circuit-board (PCB) technology for the windings as opposed to Litz wire implementations. Compared to traditional Litz wire-based transformers, the manufacturing process is significantly streamlined, and the management of parasitic is considerably more straightforward. Furthermore, the integration of resonant inductors with PCB-based transformer results in a reduction in the overall number of magnetic components and improved power density. This dissertation focuses on the DC/DC conversion stage of a bi-directional battery charger. It aims to achieve high power density and high efficiency using a PCB-based integrated transformer, enhancing manufacturing processes. The dissertation details the specific accomplishments in this area: Firstly, a two-stage on-board charger structure for 800 V battery EVs is proposed. The first stage is a four-phase bridgeless totem pole AC/DC converter working at critical conduction mode (CRM) so that soft switching can be achieved for all the fast switches. The second stage is single phase CLLC (1PCLLC) converter which is attractive due to its less component counts of devices and driver circuits. A novel matrix integrated transformer with controllable built-in leakage inductance for bi-directional 1PCLLC converter was proposed. Integrating three UI-core-based (1UI-based) elemental transformers with non-perfectly interleaved winding structures into one 3UI-based integrated transformer can reduce the core loss significantly with a smaller footprint compared with three EI-core-based integrated transformers. The proposed integrated magnetics can be scalable for higher voltage and higher power converters by assembling more 1UI-based elemental transformers. A SiC-based 1PCLLC converter prototype operating at 250-kHz switching frequency for 11-kW OBC applications was built with the proposed integrated transformer, and it can achieve a power density of 250 W/in3 with maximum efficiency of 98.4%. Secondly, the challenge of increased common mode (CM) noise after adopting PCB-based windings in the design was discussed. The inter-winding capacitors between the primary and secondary windings act as a conduction path for high dv/dt CM noise, which can lead to electromagnetic interference (EMI) issues. To address this, a winding cancellation method for an integrated matrix transformer in a 1PCLLC converter was proposed and validated. This approach was tested in an 11-kW 1PCLLC converter. The EMI measurement results align with the analysis, confirming the effectiveness of the proposed method, which achieved a reduction in CM noise by 17dB. Furthermore, the 1PCLLC converter, incorporating the proposed planar matrix integrated transformer and winding cancellation technique, attained a power density of 420 W/in³ and a peak efficiency of 98.5%. Thirdly, to enhance efficiency further, the 1PCLLC converter is substituted with the proposed three-phase CLLC (3PCLLC) resonant converter equipped with three-phase rectifiers. The 3PCLLC converter becomes more promising for high power applications as its lower RMS current stress and automatic current sharing capabilities. It can achieve soft switching under all conditions. In addition, due to the symmetrical resonant tank, it is more suitable for bi-directional operation. Variable DC-link voltage is adopted so that the DC/DC stage can always work at its optimized point, providing best efficiency for the entire battery voltage. An improved core structure for the three-phase integrated transformer was proposed to reduce the core loss and simplify the magnetic components by integrating three primary resonant inductors, three secondary resonant inductors and three transformers into one magnetic component. A systematic method of converter design which includes the design of integrated transformer, converter loss optimization was adopted to design an 11kW 3PCLLC resonant converter. A SiC-based 3PCLLC converter prototype operating at 250-kHz switching frequency for 11-kW OBC applications was built with the proposed integrated transformer, and it can achieve a power density of 330 W/in3 with peak efficiency of 98.7%. Fourthly, the power level of OBC continues to increase to make up the large capacitance battery pack inside the EVs to relief the concern of mileage range. To address this challenge of higher power, a scalable matrix integrated transformer for multi-phase CLLC converter was proposed. A universal method of integrating magnetizing inductance with built-in leakage inductance based on multiple perfectly coupled transformers (PCTs). The integration of built-in leakage inductance can be achieved by connecting several PCTs using a standardized core type for cost considerations or can be further integrated into a customized core with interleaved magnetomotive force polarities across transformer legs to achieve better flux distribution and smaller core loss. The proposed concept can be applied to single-input single-output, and multiple-inputs multiple-outputs integrated transformer applications. A 3x3 PCTs-based integrated transformer built with PCB windings was designed for a 3PCLLC resonant converter, which integrates three primary resonant inductors, three secondary resonant inductors, and three transformers into one magnetic core to simplify the complexity of the converter. The effectiveness of the proposed concept was demonstrated through a high-efficiency, high-power density 3PCLLC DC/DC converter for an 800V 16.5kW OBC. The designed converter can achieve a power density of 500 W/in3 and a peak efficiency of 98.8%. / Doctor of Philosophy / Rising fuel costs and concerns about air pollution have significantly increased interest in electric vehicles (EVs). EVs are equipped with rechargeable batteries that can be fully recharged by connecting to an external electrical source. However, the wider adoption of EVs is hindered by the need for an on-board charger system that is both lightweight and efficient. The dissertation presents advances in OBC technology to address these challenges, focusing on the development of efficient, high-power density OBCs suitable for various EV applications. EVs utilize two main charging methods: on-board chargers (OBC) for regular charging and off-board (fast) chargers for quick refills of battery pack. Most EVs currently use 400V battery packs paired with 6.6kW or 11kW OBCs, while larger vehicles with over 100 kWh battery packs employ 16.5kW or 19.2kW OBCs, constrained by household voltage and current limits. Some manufacturers are transitioning to 800V battery packs to lower costs and enhance fast charging capabilities, necessitating the development of 800V OBCs with high efficiency and power density. For household use, EVs can charge via OBC in a grid-to-vehicle transfer and can supply energy back to the home or grid (vehicle-to-grid) for emergency use or to support smart grid functionalities, requiring bidirectional OBCs. Advanced power semiconductor devices have been instrumental in advancing power conversion technology. The introduction of power semiconductor devices based on wide bandgap (WBG) materials marks a revolutionary shift, offering potential improvements over silicon-based devices. These WBG devices are capable of achieving higher efficiency, and higher power density in power conversion at higher operation frequency. Elevating the switching frequency diminishes the voltage-second across the transformer, facilitating the utilization of printed circuit board (PCB) technology for the windings as opposed to Litz wire implementations. Compared to traditional Litz wire-based transformers, the manufacturing process is significantly streamlined, and the management of parasitic is considerably more straightforward. Furthermore, the integration of resonant inductors with PCB-based transformer results in a reduction in the overall number of magnetic components and improved power density. Addressing cost concerns, a novel, cost-effective single-phase converter design was proposed, achieving high efficiency with integrated magnetics. Additionally, the research tackled the challenge of electromagnetic interference (EMI) through a winding cancellation technique, significantly reducing common-mode noise and further improving the converter's performance. The research introduces an improved core structure for a three-phase integrated transformer, significantly reducing core loss and simplifying the design by combining multiple components into a single unit. This approach facilitated the creation of a high-efficiency, SiC-based converter prototype, demonstrating remarkable power density and peak efficiency compared with state-of-the-art solutions. To accommodate the increasing power requirements of OBCs, a scalable, matrix integrated transformer design was developed for multi-phase converters, optimizing cost and performance. This design simplifies the converter architecture, enhancing efficiency and power density, and is adaptable to both single and multiple output applications. These advancements offer promising solutions to the challenges hindering the wider adoption of EVs. The dissertation underscores the potential of advanced power conversion technologies, including the application of WBG devices, integrated magnetics to streamline converter design and enhance both the efficiency and power density of battery chargers. single phase three phase DC/DC CLLC Resonant converter integrated magnetics printed circuit board (PCB) transformer battery charger
26	High-Frequency Quasi-Single-Stage (QSS) Isolated AC-DC and DC-AC Power Conversion Wang, Kunrong 11 November 1998 (has links) The generic concept of quasi-single-stage (QSS) power conversion topology for ac-dc rectification and dc-ac inversion is proposed. The topology is reached by direct cascading and synchronized switching of two variety of buck or two variety of boost switching networks. The family of QSS power converters feature single-stage power processing without a dc-link low-pass filter, a unidirectional pulsating dc-link voltage, soft-switching capability with minimal extra commutation circuitry, simple PWM control, and high efficiency and reliability. A new soft-switched single-phase QSS bi-directional inverter/rectifier (charger) topology is derived based on the QSS power conversion concept. A simple active voltage clamp branch is used to clamp the otherwise high transient voltage on the current-fed ac side, and at the same time, to achieve zero-voltage-switching (ZVS) for the switches in the output side bridge. Seamless four-quadrant operation in the inverter mode, and rectifier operation with unity power factor in the charger (rectifier) mode are realized with the proposed uni-polar center-aligned PWM scheme. Single-stage power conversion, standard half-bridge connection of devices, soft-switching for all the power devices, low conduction loss, simple center-aligned PWM control, and high reliability and efficiency are among its salient features. Experimental results on a 3 kVA bi-directional inverter/rectifier prototype validate the reliable operation of the circuit. Other single-phase and three-phase QSS bi-directional inverters/rectifiers can be easily derived as topological extensions of the basic QSS bi-directional inverter/rectifier. A new QSS isolated three-phase zero-voltage/zero-current-switching (ZVZCS) buck PWM rectifier for high-power off-line applications is also proposed. It consists of a three-phase buck bridge switching under zero current and a phase-shift-controlled full-bridge with ZVZCS, while no intermediate dc-link is involved. Input power and displacement factor control, input current shaping, tight output voltage regulation, high-frequency transformer isolation, and soft-switching for all the power devices are realized in a unified single stage. Because of ZVZCS and single-stage power conversion, it can operate at high switching frequency while maintaining reliable operation and achieving higher efficiency than standard two-stage approaches. A family of isolated ZVZCS buck rectifiers are obtained by incorporating various ZVZCS schemes for full-bridge dc-dc converters into the basic QSS isolated buck rectifier topology. Experimental and simulation results substantiate the reliable operation and high efficiency of selected topologies. The concept of charge control (or instantaneous average current control) of three-phase buck PWM rectifiers is introduced. It controls precisely the average input phase currents to track the input phase voltages by sensing and integrating only the dc rail current, realizes six-step PWM, and features simple implementation, fast dynamic response, excellent noise immunity, and is easy to realize with analog circuitry or to integrate. One particular merit of the scheme is its capability to correct any duty-cycle distortion incurred on only one of the two active duty-cycles which often happens in the soft-switched buck rectifiers, another merit is the smooth transition of the input currents between the 60o sectors. Simulation and preliminary experimental results show that smooth operations and high quality sinusoidal input currents in the full line cycle are achieved with the control scheme. / Ph. D. Battery Charger PFC Charge Control UPS Matrix Converter Soft-Switched Rectifier Single-Stage Rectifier/Inverter Three-Phase Rectifier
27	High Efficiency DC-DC Converter for EV Battery Charger Using Hybrid Resonant and PWM Technique Wan, Hongmei 11 September 2012 (has links) The battery charger plays an important role in the development of electric vehicles (EVs) and plug-in hybrid electric vehicles (PHEVs).This thesis focuses on the DC-DC converter for high voltage battery charger and is divided into four chapters. The background related to EV battery charger is introduced, and the topologies of isolated DC-DC converter possibly applied in battery charge are sketched in Chapter 1. Since the EV battery charger is high voltage high power, the phase-shifted full bridge and LLC converters, which are popularly used in high power applications, are discussed in detail in Chapter 2. They are generally considered as high efficiency, high power density and high reliability, but their prominent features are also limited in certain range of operation. To make full use of the advantages and to avoid the limitation of the phase-shifted full bridge and LLC converters, a novel hybrid resonant and PWM converter combining resonant LLC half-bridge and phase shifted full-bridge topology is proposed and is described in Chapter 3. The converter achieves high efficiency and true soft switching for the entire operation range, which is very important for high voltage EV battery charger application. A 3.4 kW hardware prototype has been designed, implemented and tested to verify that the proposed hybrid converter truly avoids the disadvantages of LLC and phase-shifted full bridge converters while maintaining their advantages. In this proposed hybrid converter, the utilization efficiency of the auxiliary transformer is not that ideal. When the duty cycle is large, LLC converter charges one of the capacitors but the energy stored in the capacitor has no chance to be transferred to the output, resulting in the low utilization efficiency of the auxiliary transformer. To utilize the auxiliary transformer fully while keeping all the prominent features of the previous hybrid converter in Chapter 3, an improved hybrid resonant and PWM converter is proposed in Chapter 4. The idea has been verified with simulations. The last chapter is the conclusion which summaries the key features and findings of the two proposed hybrid converters. / Master of Science LLC Resonant Converter Hybrid Resonant and PWM Converter Phase-shifted Full Bridge Converter DC-DC Converter Electric Vehicle Battery Charger
28	Wide Input Common-mode Range Fully Integrated Low-dropout Voltage Regulators January 2016 (has links) abstract: The modern era of consumer electronics is dominated by compact, portable, affordable smartphones and wearable computing devices. Power management integrated circuits (PMICs) play a crucial role in on-chip power management, extending battery life and efficiency of integrated analog, radio-frequency (RF), and mixed-signal cores. Low-dropout (LDO) regulators are commonly used to provide clean supply for low voltage integrated circuits, where point-of-load regulation is important. In System-On-Chip (SoC) applications, digital circuits can change their mode of operation regularly at a very high speed, imposing various load transient conditions for the regulator. These quick changes of load create a glitch in LDO output voltage, which hamper performance of the digital circuits unfavorably. For an LDO designer, minimizing output voltage variation and speeding up voltage glitch settling is an important task. The presented research introduces two fully integrated LDO voltage regulators for SoC applications. N-type Metal-Oxide-Semiconductor (NMOS) power transistor based operation achieves high bandwidth owing to the source follower configuration of the regulation loop. A low input impedance and high output impedance error amplifier ensures wide regulation loop bandwidth and high gain. Current-reused dynamic biasing technique has been employed to increase slew-rate at the gate of power transistor during full-load variations, by a factor of two. Three design variations for a 1-1.8 V, 50 mA NMOS LDO voltage regulator have been implemented in a 180 nm Mixed-mode/RF process. The whole LDO core consumes 0.130 mA of nominal quiescent ground current at 50 mA load and occupies 0.21 mm x mm. LDO has a dropout voltage of 200 mV and is able to recover in 30 ns from a 65 mV of undershoot for 0-50 pF of on-chip load capacitance. / Dissertation/Thesis / Masters Thesis Electrical Engineering 2016 Electrical engineering Design Engineering Analog Design Battery Charger Fast Transient Response LDO LDO Voltage Regulators Power Management Integrated Circuits Power Supply
29	Conception d'un équilibreur de charge de batterie à base du réseau de micro-convertisseurs / Battery charge balancer based on network of micro-converters. Design and development for improvement of energy efficiency and reliability Phung, Thanh Hai 20 December 2013 (has links) Depuis ces années, le développement de systèmes de stockage d'énergie pour la mobilité électrique avec davantage d'autonomie de durabilité est au cœur des contraintes de développement des véhicules électriques ou hybrides entraînant une émergence de l'utilisation des systèmes de management ainsi que des circuits d'équilibrage. Les travaux de thèse portent sur la conception et la réalisation d'une nouvelle structure d'équilibrage à base du réseau de micro-convertisseurs (RµC) utilisant les matrices de connections ainsi que les stratégies de commande appropriées. L'objectif principal est de concevoir un équilibreur actif forcé de haute performance, intégrable à base de technologies d'aujourd'hui et avec une stratégie de contrôle simple à mettre en œuvre. Le mémoire de thèse se structure en quatre chapitres : approche du RµC versus l'équilibrage des batteries, conception de la structure et des stratégies d'équilibrage à base du RµC, conception et dimensionnement du système de contrôle intégrée, version intégrée de l'équilibreur-perspectives. Les premiers prototypes de l'équilibreur utilisant des composants discrets ont été mis en place afin de valider notre structure ainsi que les solutions de contrôle proposées. La réalisation des versions intégrées en se basant sur l'utilisation les technologies disponible au sein du laboratoire ouvre un avenir promettant pour les systèmes de management de batterie. / In recent years, the development of energy storage systems for electric mobility with greater autonomy of sustainability is at the heart of development constraints of electric or hybrid vehicles resulting in the emergence of the use of management systems as well as balancing circuits. The thesis focuses on the design and implementation of a new balancing based network structure of micro-inverters (RμC) using matrices connections and appropriate control strategies. The main objective is to design an active balancer forced high performance integrated based technologies of today and a simple control strategy to implement. The thesis is structured in four chapters: RμC approach versus balancing batteries, structural design and balancing based strategies RμC, design and simulation of control system built, integrated version of the balancer - perspectives. The first prototypes of the balancer using discrete components were developed to validate our structure and control solutions proposed. The realization of integrated based on using the technologies available in the laboratory versions opens a promising future for battery management systems. Li-ion Conversion DC/DC Chargeur de batterie Équilibreur de charge Intégration de convertisseur Micro-convertisseurs Li-ion DC/DC converters Battery charger Charge balancer Integrated converters Micro-converters
30	Μέθοδοι εξοικονόμησης ενέργειας σε ηλεκτροκίνητα οχήματα / Methods of energy saving in electric vehicles Ρίκος, Ευάγγελος 25 June 2007 (has links) Σκοπός της παρούσας εργασίας είναι η μελέτη των βασικών τμημάτων που απαρτίζουν ένα ηλεκτρικό όχημα, με άμεσο στόχο τη μέγιστη δυνατή εξοικονόμηση ενέργειας. Προς την κατεύθυνση αυτή μελετάται αρχικά η βαθμίδα φόρτισης των συσσωρευτών. Παρουσιάζονται οι προδιαγραφές και προτείνεται ως βέλτιστη τοπολογία αυτή του Flyback η οποία αντιμετωπίζει λειτουργικές δυσκολίες. Έτσι προτείνεται μια ειδική μεθοδολογία σχεδιασμού βασιζόμενη στην επιλογή του λόγου του Μ/Τ. Επίσης προτείνεται ένα νέο κύκλωμα καταστολής των υπερτάσεων λόγω σκέδασης. Η αποτελεσματική λειτουργία επιβεβαιώνεται μέσω εξομοιώσεων και πειραματικών δοκιμών. Στο δεύτερο μέρος παρουσιάζεται ένα νέο κύκλωμα τροφοδοσίας. Πρόκειται για μετατροπέα μονής βαθμίδας με ένα τρανζίστορ κα αποτελεσματική καταστολή υπερτάσεων. Παράλληλα πραγματοποιεί βελτίωση του συντελεστή ισχύος του κυκλώματος. Στο τρίτο μέρος μελετάται το κινητήριο σύστημα και προτείνεται μια μέθοδος ελέγχου της μαγνητικής ροής και του λόγου μετάδοσης του κιβωτίου ταχυτήτων ώστε να επιτυγχάνεται η ελάχιστη δυνατή ενεργειακή κατανάλωση του οχήματος. Τα αποτελέσματα εξομοίωσης επιβεβαιώνουν την αποτελεσματικότητα της προτεινόμενης μεθόδου. / Basic aim of the present work is the analytical study of the basic part of an EV, in order to be obtained a good energy saving. For this purpose the charging unit of an EV is studied. The specifications which must fulfill this device are exhibited and the Flyback topology is suggested as the optimal. However it appears some important problems. For this purpose, a new strategy of design based on the transformer. Μετατροπέας Flyback 629.229 3 Electric vehicles Energy saving Electromotion system Battery charger Switch mode power supplies DC motor Flyback converter

Search results