Dimmable Electronic Ballast for Multiple Cold Cathode Fluorescent Lamps

Chen, Sheng-Hui

25 July 2011

A high-frequency half-bridge series resonant inverter with multiple output transformers is developed for driving multiple cold-cathode fluorescent lamps (CCFLs) with dimming feature. The primary sides of the transformers are connected in series with the resonant inverter to have an identical current, while the secondary sides are loaded by CCFLs with galvanic isolation to each other. To ensure a high circuit efficiency, the active power switches of the inverter are designed to be switched on at zero voltage. The resonant current of the inverter can be regulated by controlling the switching frequency of the inverter, so that all CCFLs can be dimmed simultaneously. On the other hand, the primary sides of the output transformers are associated with parallel switches to dim the CCFLs individually. These dimming switches are operated at a low frequency by integral cycle control with zero current switching (ZCS) to reduce the switching losses. The resonant circuit is tactfully designed to alleviate the variation of the resonant current caused by the switching of dimming switches. A laboratory circuit is built for driving 5 CCFLs. The intended circuit performances are confirmed by test results. The variation of the resonant current is less than 10% when the dimming switches are switching, and the measured efficiency for the circuit is 96.15% under the rated powers.

zero-current switching (ZCS)

zero-voltage switching (ZVS)

resonant inverter

Cold-cathode fluorescent lamp (CCFL)

integral cycle control

Consecutive Orthogonal Arrays on Design of Power Electronic Circuits

Yen, Hau-Chen

16 January 2003

An approach with ¡§consecutive orthogonal arrays (COA)¡¨ is proposed for solving the problems in designing power electronic circuits. This approach is conceptually based on the orthogonal array method, which has been successfully implemented in quality engineering. The circuit parameters to be determined are assigned as the controlled variables of the orthogonal arrays. Incorporating with the inferential rules, the average effects of each control variable levels are used as the indices to determine the control variable levels of the subsequent orthogonal array. By manipulating on COA, circuit parameters with the desired circuit performances can be found from an effectively reduced number of numerical calculations or experimental tests. In this dissertation, the method with COA is implemented on solving four problems often encountered in the design of power electronic circuits. The first problem one has to deal with is to find a combination with the best performance from a great number of analyzed results. The illustrative example is the design of LC passive filters. Using COA method, the desired component values of the filter can be effectively and efficiently found with far fewer calculations. The second design problem arises from the non-linearity of circuit. An experienced engineer may be able to figure out circuit parameters with satisfactory performance based on their pre-knowledge on the circuit. Nevertheless, they are always questioned whether a better choice can be made. The typical case is the self-excited resonant electronic ballast with the non-linear characteristics of the saturated transformer and the power transistor storage-time. In this case, the average effects of COA obtained from experimental tests are used as the observational indexes to search a combination of circuit parameters for the desired lamp power. The third problem is that circuit functions are mutually exclusive. The designers are greatly perplexed to decide the circuit parameters, with which all functions should be met at the same time. The method with COA is applied to design a filter circuit to achieve the goals of low EMI noise and high power factor simultaneously. Finally, one has to cope with the effects of the uncontrolled variables, such as: ambient temperature, divergence among different manufacturers, and used hours. By applying COA with inferential rules, electronic ballasts can be robustly designed to operate fluorescent lamps at satisfied performance under the influence of these uncontrolled variables.

Power Electronics

Average Effect

Fluorescent Lamp

Self-Excited Resonant Inverter

Orthogonal Array

Passive LC Filter

Electronic Ballast

EMI Filter

Conversor CC/CA de alta freq??ncia baseado em inversores ressonantes com comuta??o seq?encial para excita??o de uma tocha indutiva a plasma t?rmico

Dubut, Jean Paul

15 July 2010

Made available in DSpace on 2014-12-17T14:54:55Z (GMT). No. of bitstreams: 1 JeanPD_TESE.pdf: 2551926 bytes, checksum: 0cea6096dad85829234a17d89574bd1e (MD5) Previous issue date: 2010-07-15 / This work describes the study, the analysis, the project methodology and the constructive details of a high frequency DC/AC resonant series converter using sequential commutation techniques for the excitation of an inductive coupled thermal plasma torch. The aim of this thesis is to show the new modulation technique potentialities and to present a technological option for the high-frequency electronic power converters development. The resonant converter operates at 50 kW output power under a 400 kHz frequency and it is constituted by inverter cells using ultra-fast IGBT devices. In order to minimize the turn-off losses, the inverter cells operates in a ZVS mode referred by a modified PLL loop that maintains this condition stable, despite the load variations. The sequential pulse gating command strategy used it allows to operate the IGBT devices on its maximum power limits using the derating and destressing current scheme, as well as it propitiates a frequency multiplication of the inverters set. The output converter is connected to a series resonant circuit constituted by the applicator ICTP torch, a compensation capacitor and an impedance matching RF transformer. At the final, are presented the experimental results and the many tests achieved in laboratory as form to validate the proposed new technique / Este trabalho descreve o estudo, a an?lise, a metodologia de projeto e os detalhes de constru??o de um conversor ressonante CC/CA de alta freq??ncia usando t?cnicas de comuta??o seq?encial (sequential pulse gating), para a excita??o de uma tocha indutiva a plasma t?rmico. Esta tese objetiva mostrar a potencialidade desta nova t?cnica de modula??o e apresentar uma alternativa tecnol?gica para o projeto de conversores eletr?nicos de pot?ncia em altas freq??ncias. O conversor ressonante opera na freq??ncia nominal de 400 kHz, com pot?ncia de 50 kW, e ? constitu?do por c?lulas inversoras empregando chaves IGBTs de comuta??o r?pida. Para minimizar as perdas de comuta??o no corte, as c?lulas ressonantes operam no modo de chaveamento suave ZVS, referenciado por uma malha PLL modificada que mant?m esta condi??o est?vel apesar das varia??es de carga. A estrat?gia de comando por comuta??o seq?encial permite operar os dispositivos IGBTs no seu limite superior de pot?ncia usando as propriedades de redu??o (derating) e de al?vio (destressing) de corrente, assim como propicia um efeito de multiplica??o na freq??ncia final do conjunto de inversores. A sa?da do conversor ? conectada a um circuito ressonante s?rie formado pelo aplicador da tocha ICTP e um capacitor de compensa??o, por interm?dio de um transformador RF de adapta??o de imped?ncias. No final, s?o apresentados resultados experimentais e ensaios conduzidos em laborat?rio como forma de validar a nova t?cnica proposta

Conversor CC/CA

Inversor ressonante

Comuta??o sequencial

R?diofreq??ncia

Series resonant inverter

IGBT

Sequential pulse gating

Soft switching ZVS

Thermal plasma

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA

Active Source Management to Maintain High Efficiency in Resonant Conversion over Wide  Load Range

Danilovic, Milisav

18 September 2015

High-frequency and large amplitude current is a driving requirement for applications such as induction heating, wireless power transfer, power amplifier for magnetic resonant imaging, electronic ballasts, and ozone generators. Voltage-fed resonant inverters are normally employed, however, current-fed (CF) resonant inverters are a competitive alternative when the quality factor of the load is significantly high. The input current of a CF resonant inverter is considerably smaller than the output current, which benefits efficiency. A simple, parallel resonant tank is sufficient to create a high-power sinusoidal signal at the output. Additionally, input current is limited at the no-load condition, providing safe operation of the system. Drawbacks of the CF resonant inverter are associated with the implementation of the equivalent current source. A large input inductor is required to create an equivalent dc current source, to reduce power density and the bandwidth of the system. For safety, a switching stage is implemented using bidirectional voltage-blocking switches, which consist of a series connection of a diode and a transistor. The series diode experiences significant conduction loss because of large on-state voltage. The control of the output current amplitude for constant-frequency inverters requires a pre-regulation stage, typically implemented as a cascaded hard-switched dc/dc buck converter. The pre-regulation also reduces the efficiency. In this dissertation, a variety of CF resonant inverters with two input inductors and two grounded switches are investigated for an inductive-load driver with loaded quality factor larger than ten, constant and high-frequency (~500 kHz) operation, high reactive output power (~14 kVA), high bandwidth (~100 kHz), and high efficiency (over 95 %). The implementation of such system required to question the fundamental operation of the CF resonant inverter. The input inductance is reduced by around an order of magnitude, ensuring sufficient bandwidth, and allowing rich harmonic content in the input current. Of particular importance are fundamental and second harmonic components since they influence synchronization of the zero-crossing of the output voltage and the turn-on of the switches. The synchronization occurs at a particular frequency, termed synchronous frequency, and it allows for zero switching loss in the switches, which greatly boosts efficiency. The synchronous conditions were not know prior this work, and the dependence among circuit parameters, input current harmonics, and synchronous frequency are derived for the first time. The series diode of the bidirectional switch can reduce the efficiency of the system to below 90 %, and has to be removed from the system. The detrimental current-spikes can occur if the inverter is not operated in synchronous condition, such as in transients, or during parametric variations of the load coil. The resistance of the load coil has a wide variance, five times or more, while the inductance changes as well by a few percent. To accommodate for non-synchronous conditions, a low-loss current snubber is proposed as a safety measure to replace lossy diodes. The center-piece of the dissertation is the proposal of a two-phase zero-voltage switching buck pre-regulator, as it enables fixed frequency and synchronous operation of the inverter under wide parametric variations of the load. The synchronous operation is controlled by phase-shifting the switching functions of the pre-regulator and inverter. The pre-regulator reduces the dc current in the input inductors, which is a main contributor to current stress and conduction losses in the inverter switches. Total loss of the inverter switches is minimized since no switching loss is present and minimal conduction losses are allowed. The dc current in the input inductors, once seen as a means to transfer power to load, is now contradictory perceived as parasitic, and the power is transferred to the load using a fundamental frequency harmonic! The input current to the resonant tank, previously designed to be a square-wave, now resembles a sine-wave with very rich harmonic content. Additionally, the efficiency of the pre-regulator at heavy-load condition is improved by ensuring ZVS for with an additional inductive tank. The dissertation includes five chapters. The first chapter is an introduction to current-fed resonant inverters, applications, and state-of-the-art means to ensure constant frequency operation under load's parametric variations. The second chapter is dedicated to the optimization of the CF resonant inverter topology with a dc input voltage, two input inductors, and two MOSFETs. The topology is termed as a boost amplifier. If the amplifier operates away from the synchronous frequency, detrimental current spikes will flow though the switches since the series diodes are eliminated. Current spikes reduce the efficiency up to few percent and can create false functioning of the system. Operation at the synchronous frequency is achieved with large, bulky, input inductors, typically around 1-2 mH or higher, when the synchronous frequency follows the resonant frequency of the tank at 500 kHz. The input inductance cannot be reduced arbitrarily to meet the system bandwidth requirement, since the synchronous frequency is increased based on the inductance value. The relationship between the two (input inductance and the synchronous frequency) was unknown prior this work. The synchronous frequency is determined to be a complicated mathematical function of harmonic currents through the input inductors, and it is found using the harmonic decomposition method. As a safety feature, a current snubber is implemented in series with the resonant tank. Snubber utilizes a series inductance of cable connection between the tank and the switching stage, and it is more efficient than the previously employed series diodes. Topology optimization and detailed design procedure are provided with respect to efficiency and system dynamics. The mathematics is verified by a prototype rated at 14 kVA and 1.25 kW. The input inductance is reduced by around an order of magnitude, with the synchronous frequency increase of 2 %. The efficiency of the power amplifier reached 98.5 % and might be improved further with additional optimization. Silicon carbide MOSFETs are employed for their capability to operate efficiently at high frequency, and high temperature. The third chapter is dedicated to the development of the boost amplifier's large signal model using the Generalized State-space Averaging (GSSA) method. The model accurately predicts amplifier's transient and steady-state operation for any type of input voltage source (dc, dc with sinusoidal ripple, pulse-width modulated), and for either synchronous or non-synchronous operating frequency. It overcomes the limitation of the low-frequency model, which works well only for dc voltage-source input and at synchronous frequency. As the measure of accuracy, the zero-crossing of the resonant voltage is predicted with an error less than 2° over a period of synchronous operation, and for a range of interest for input inductance (25 μH – 1000 μH) and loaded-quality factor (10 – 50). The model is validated both in simulation and hardware for start-up transient and steady-state operation. It is then used in the synthesis of modulated output waveforms, including Hann-function and trapezoidal-function envelopes of the output voltage/current. In the fourth chapter, the GSSA model is employed in development of the PWM compensation method that ensures synchronous operation at constant frequency for the wide variation of the load. The boost amplifier is extended with a cascaded pre-regulator whose main purpose is to control the output resonant voltage. The pre-regulator is implemented as two switching half-bridges with same duty-cycle and phase-shift of 180°. The behavior of the cascaded structure is the same as of the buck converter, so the half-bridges are named buck pre-regulators. ZVS operation is ensured by putting an inductive tank between the half-bridges. Each output of half-bridges is connected to each of input inductors of the boost to provide the PWM excitation. Using the GSSA model, the synchronous condition and control laws are derived for the amplifier. Properties of the current harmonics in the input inductors are well examined. It is discovered that the dc harmonic, once used to transfer power, is unwanted (parasitic) since it increases conduction loss in switches of the boost. A better idea is to use the fundamental harmonic for power transfer, since it does not create loss in the switches. Complete elimination of the dc current is not feasible for constant frequency operation of the amplifier since the dc current depends on the load coil's resistance. However, significant mitigation of around 55 % is easily achievable. The proposed method improves significantly the efficiency of both the buck pre-regulator and the boost. Synchronous operation is demonstrated in hardware for fixed switching frequency of 480 kHz, power level up to 750 W, input voltage change from 300 V to 600 V, load coil's resistance change of three times, and load coil's inductance change of 3.5 %. Measured efficiency is around 95 %, with a great room for improvements. Chapter five summarizes key contributions and concludes the dissertation. / Ph. D.

Current-fed

current-source

push-pull

boost

buck-boost

amplifier

resonant tank

resonant frequency

resonant inverter

synchronization

synchronous frequency

load range

load variation

adaptive matching

silicon carbide MOSFET

Podpůrné měniče v elektrické trakci / Auxiliary inverters for electric traction

Polášek, Petr

January 2009

This thesis concerns with specified problems of an electric traction. It deals with the concept of module controlling EC motor of the voltage 24V and the current 100A. There are described possibilities and principles of controlling EC motor in detail. For controlling, the single-purpose IO MC33035, which is directly specified for it, is used. The thesis describes implementation of both testing and final versions of converter for a circulating pump drive of a cooling circuit in locomotives. The convertor is partly universal and can be used in other applications. According to the implemented convertor, a laboratory test and a model protocol were made. In the second part, the concept is described as well as the implementation of DC/DC conventor of output voltage of 24V and which is supplied by 12V battery. The specified output current is 4A. It is used for supplying of the controlling traction vehicle unit and is installed as a boost convertor which contains a resonance conventor. The presentation of measured parameters of the complete convertor is either a part of this thesis.

Gallium Nitride: Analysis of Physical Properties and Performance in High-Frequency Power Electronic Circuits

Saini, Dalvir K.

11 August 2015

No description available.

Electrical Engineering

Gallium nitride

GaN

silicon carbide

high frequency power converters

semiconductors

Efficient Power Conversion

power losses

high-efficiency

switching losses

field-effect transistors

synchronous buck dc-dc converter

class-D resonant inverter

Επαγωγική ζεύξη ισχύος για ενεργά εμφυτεύσιμα ιατροτεχνολογικά προϊόντα / Inductively coupled power systems for active implantable medical devices

Αθανασόπουλος, Παναγιώτης

19 April 2010

Στην παρούσα διπλωματική εργασία αναζητείται ένας αυτόματος τρόπος ελέγχου, του επιπέδου της εκπεμπόμενης ισχύος προς το εσωτερικό του ανθρωπίνου σώματος. Εκεί μέσα βρίσκεται κάποιο ενεργό ιατροτεχνολογικό εμφύτευμα. Αυτό το εμφύτευμα στην περίπτωση της εργασίας αυτής, ήταν μία κάψουλα που καταγράφει με φωτογραφίες το γαστρεντερικό σύστημα καθώς οι περισταλτικές κινήσεις του εντέρου προωθούν την κάψουλα προς την έξοδο. Οι φωτογραφίες μεταδίδονται προς καταγραφικό που βρίσκεται έξω από το σώμα με ασύρματο τρόπο. Όπως καταλαβαίνουμε η κάψουλα αυτή αλλά και οποιοδήποτε άλλο ενεργό ιατροτεχνολογικό εμφύτευμα έχει ενεργειακές ανάγκες για την απρόσκοπτη λειτουργία του. Αυτές οι ανάγκες καλύπτονται με ασύρματη μετάδοση ενέργειας. Οι καινοτομίες που υπάρχουν σ’ αυτήν την εργασία είναι οι εξής: 1. Όσον αφορά το εξωτερικό τροφοδοτικό χρησιμοποιήθηκε ένας αντιστροφέας συντονισμού κλάσης D 2. Το πιο καινοτόμο στοιχείο είναι η δημιουργία κλειστού βρόχου ελέγχου μεταξύ του εξωτερικού τροφοδοτικού και του εμφυτεύματος ώστε αυτό να λαμβάνει την ποσότητα της ενέργειας που χρειάζεται κάθε στιγμή. 3. Επίσης σημαντικό είναι ότι η μετάδοση πληροφορίας από το εμφύτευμα προς τα έξω δεν γίνεται με μία ξεχωριστή συχνότητα αλλά χρησιμοποιώντας αρχές παθητικής τηλεμετρίας. Η εργασία αυτή πέρα από την θεωρητική προσέγγιση υλοποιήθηκε και πρακτικά σε εργαστήρια του πανεπιστημίου KUL (ESAT MICAS) στο Βέλγιο. Ο Βρόγχος ελέγχου λειτούργησε και πολλά συμπεράσματα εξάχθηκαν για περεταίρω βελτιώσεις. Η δομή του παρόντος πονήματος είναι ως εξής: Μετά την αρχική εισαγωγή το δεύτερο κεφάλαιο μας δίνει ένα θεωρητικό υπόβαθρο για την ασύρματη μετάδοση ενέργειας. Στη συνέχεια τα διάφορα μέρη των ηλεκτρονικών κυκλωμάτων που αναπτύχθηκαν αναλύονται διεξοδικά στα επόμενα κεφάλαια. Τέλος καταγράφονται τα συμπεράσματα και προτείνονται πιθανές βελτιώσεις για το μέλλον. / In this diploma thesis a way to have an automated control of the transmitted power level into the human body is sought. Inside the body there is an active medical implant. This implant in the case of this project is a swallowable capsule-camera that captures images along the GI tract as the peristaltic propulusion of the bowel push the capsule towards the exit. The photos are transmitted wirelessly to a special recording device that is located out of the body. It is obvious that not only this capsule but any other active medical implant needs energy to operate uninterrupted. This necessary energy is given through inductive power transmission. Innovations in this project are these: 1. The power supply outside the body is realized with Class-D resonant inverter topology. 2. The most innovative is the effectuation of closed control loop between the outer power supply and the implant in order to be received from the implant the exact amount of power that is needed every instant. 3. Also significant is that the transmission of data from the implant to the controlled power supply is not be done with a different carrier but using passive telemetry principles. Beyond the theoretic approximation that was made for this project, it was also realized in KUL university laboratories (ESAT MICAS) in Belgium. The closed control loop functioned properly and conclusions for further development are inferred. The structure of this diploma thesis is as follows: After the starting introduction the theoretic background for wireless inductive power transmission is given in chapter 2. Following, the different parts of the electronic circuits that were developed are analyzed comprehensively in next chapters. Finally conclusions are registered and future improvements are proposed.

Επαγωγική ζεύξη

Ενεργά εμφυτεύματα

Κάμερα κάψουλα

Παθητική τηλεμετρία

Χάπι κάμερα

Αντιστροφέας κλάσης D

621.381

Inductive power transmission

Wireless capsule endoscopy

Passive telemetry

Active implants

Class D resonant inverter

WCE

Wireless control loop

PFM

Swallowable camera

ESAT MICAS

Wireless power transmision

Pill cam