Dissertations / Theses on the topic 'Automatic voltage regulator'

Synchronous generators used for hydro power and nuclear power is a well known topology but there is a vast amount of intricate technologies and methods to making them function properly. This masters thesis covers the development, implementation and verification of a magnetisation system for a synchronous generator. The software implementation is made in the LabVIEW programming environment and uses a high performance CompactRIO with an FPGA for measurements, calculation and output control signals. Together with several peripheral devices, the CompactRIO forms an excitation system and most importantly, an automatic voltage regulator. This system keeps the output voltage of the generator stable and has a variety of safety features such as over excitation limits, under excitation limits and a V/Hz limiter. The resulting system successfully monitors and controls the generator characteristics and the controllers, based on PI controllers, have short rise times, low overshoot and no significant static error. This magnetisation system was verified on a 185 kW synchronous machine and all functions showed satisfying results with the exception of the implemented power system stabiliser which need to be re-tuned.

Automatic voltage regulation is necessary for all power producing synchronous generators to ensure that the produced power have a constant and stable voltage level and to sustain grid stability. The aim of this thesis is to design and build an automatic voltage regulator for a synchronous generator. A six-phase permanent magnet alternator will be used to excite the rotor with solid-state relay controlled rotating bridge rectifier. The field current is regulated by a closed loop control system that is based on a programmable logic controller, PLC. Programing of the PLC is executed in the developing environment CoDeSys, IEC 61131-3, which is the international standard for programing PLC applications. Simulations for predicting the system behavior is done with a web based in-browser tool, circuitlab.com. The results show a good performance of the regulator and the closed loop system although there is room for improvement of the solid-state controlled rectifier system.

This thesis focuses on the design of an electrical drive system for the purpose of high precision motion control. A modern electrical drive is usually equipped with a current regulated voltage source along with powerful motion controller system utilizing one or more micro-controllers and/or digital signal processors (DSPs). That is, the motor drive control is mostly performed by a dedicated digital-motion controller system. Such a motor drive mostly interfaces with its host processor via various serial communication protocols such as Profibus, CAN+, RS-485 etc. for the purpose of receiving commands and sending out important status/control signals. Considering that the motor drives lie at the heart of every (multi-axis) motion control system, the aim of this thesis is to explore the design and implementation of a conventional DC motor drive system suitable for most industrial applications that require precision and accuracy. To achieve this goal, various underlying control concepts and important implementation details are rigorously investigated in this study. A low power DC motor drive system with a power module, a current regulator and a motion controller is built and tested. Several design revisions on these subsystems are made so as to improve the overall performance of the drive system itself. Consequently, important &ldquo
know-how&rdquo
required for building high performance (and high power) DC motor drives is gained in this research.

It is well known that a crucial factor determining the transmission capacity with regards to the voltage stability limit of a stressed power system, is the limitation of field and stator current of overexcited generators. These limiters are commonly referred to as overexcitation limiters (OEL) and stator current limiters (SCL). This thesis investigates the representation of overexcitation limiters and stator current limiters in the Swedish power system and how they could be implemented in the power system simulator PSS/E. Dynamic simulations in PSS/E are performed to investigate and validate differences between model types and parameters. The thesis compares different types of limiters and presents a representative set of parameters based on the documentation and implements them into PSS/E. The result from the study is a recommendation to migrate to limiter model MAXEX2 for generators without stator current limiters. The MAXEX2 model uses an inverse time characteristic which is becoming more common in installed voltage regulators. This feature makes it possible for extended use of generators before limiter action is applied. The MAXEX2 model is also possible to tune into a fixed time delay to represent older types of limiters.

There are many ways to produce energy, using e.g. gas or hydro turbines. To guarantee a stable power output, it is important to consider components that could control and adjust the output power automatically. The intention of this thesis work is to carry out a pre-study and system design of a mobileplatform simulator system that could be used by companies like Siemens and help them to reduce their OPEX (Operational expenditure) and easily evaluate their AVR (AutomaticVoltage Regulator) solutions and test improvements. In this document, Siemens has decided to call the simulator system, MPSS (Mobile Platform Simulator System). The pre-study includes the theory behind energy production, synchronous generator, simulator system, AVR, control systems and electrical grid. Furthermore, the pre-study includes selection of the proposed components for the simulator system and design of the complete simulator system that will be built by the Siemens R&D engineers at a later stage. The Mobile Platform Simulator System (MPSS) is intended to test the AVR performance, which is a component with its prime purpose being to maintain the output voltage values from the generator at a fixed value, regardless of the current being drawn by the load. It is important that these output values are constantly regulated during the process of producing electricity, so that problems such as overvoltage, overcurrent etc. can be prevented. The MPSS will also be able to simulate real working scenarios e.g. from the different components of an energy production system, such as gas and hydro turbine, synchronous generator, AVR, electrical grid and serve for personnel training. The MPSS will consist of three main components; Simulator, AVR and control system. Therefore, the report will initially provide the background and general theory behind the synchronous generator, AVR and control system used in power generation systems. General information about the electrical grid is also provided. Furthermore, the report suggests the best possible choice for the necessary components to build a MPSS as well instructions on how to perform event simulation. The necessary documentation, including a circuit diagram to support the building of the MPSS by the R&D engineers at late stage, is also provided. Finally, the general analysis of the technical and non-technical aspects related to the choice of components, work process, method and result are discussed in the end of this report.
Det finns många sätt att producera energi, genom användning av exempelvis gas- eller hydroturbiner. För att garantera en stabil produktion är det viktigt att noga överväga komponenter, som kan styra och justera uteffekten automatiskt. Avsikten med detta arbete är att göra en förstudie och systemdesign av ett simulatorsystem som kan användas av företag som Siemens, med avsikt att hjälpa dem att minska sin driftskostnad(OPEX), och lättare kunna utvärdera sina AVR-lösningar (Automatic Voltage Regulator)och möjliga testförbättringar. För detta arbete har Siemens bestämt att kalla systemet för ett mobilt simulatorsystem eller MPSS (Mobile Platform Simulator System). Förstudien innehåller teorin bakom energiproduktion, synkrongenerator generator, simulatorsystem, AVR, styrsystem och elnät. Ett urval av de olika komponenterna för simulatorsystemet och en slutgiltig design tas fram. Det kompletta simulatorsystemet kommer i ett senare skede att byggas av forsknings- och utvecklingsingenjörerna på Siemens. Simulatorsystemet är avsett att testa AVR-prestanda, vilket är en komponent vars huvudsakliga syfte är att upprätthålla utspänningsvärdena från en generator inom ett fast intervallvärde, oberoende av vilken effekt som en last drar. Det är viktigt att utgångsvärden ständigt regleras under elproduktionsprocesser så att utgångsvärden hålls inom systemets tillåtna gränser så att problem som över-/underspänning, över-/underström, över-/underfrekvens etc. kan förhindras. Simulatorsystemet kommer också att kunna simulera verkliga arbetsscenarier för olika komponenter i ett energiproduktionssystem, såsom gas- och hydroturbin, synkrongenerator, AVR och laster, exempelvis elnät, samt kunna användas vid personalutbildning. Simulatorsystemet kommer att bestå av tre huvudkomponenter; Simulator, AVR och styrsystem. Inledande beskrivning av arbetets bakgrund och allmän teoretisk kring komponenterna synkrongenerator, AVR och styrsystem, som används vid i kraftgenereringssystem, ges. Även en allmän bakgrund om elnätet och dess funktion presenteras. Därefter presenteras förslag på bästa möjliga val av nödvändiga komponenter för att bygga ett simulatorsystem. Ett förslag om hur händelse simulering görs samt vilken nödvändig dokumentation och kretsdiagram som behövs för att bygga ett simulatorsystem presenteras. I slutet av detta arbete presenteras en allmän analys av de tekniska och icke-tekniska aspekterna kring val av komponenter, arbetsprocess samt metod och resultat.

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Este trabalho apresenta a aplicaÃÃo do algoritmo de OtimizaÃÃo por Enxame de PartÃculas (PSO â Particle Swarm Optimization) para sintonia Ãtima de controladores associados à regulaÃÃo de tensÃo e ao aumento do amortecimento de geradores sÃncronos utilizados em plantas termelÃtricas de ciclo combinado. Para representaÃÃo matemÃtica do gerador sÃncrono, utiliza-se o modelo linearizado de terceira ordem do sistema mÃquina conectada a uma barra infinita, vÃlido para estudos de estabilidade a pequenos sinais. Os parÃmetros do regulador automÃtico de tensÃo (AVR â Automatic Voltage Regulator) e do estabilizador de sistema de potÃncia (PSS â Power System Stabilizer) sÃo determinados de maneira Ãtima pela ferramenta computacional proposta. Os parÃmetros obtidos para o AVR e PSS sÃo comparados com valores calculados por tÃcnicas de sintonia convencionais, baseadas em aproximaÃÃes das equaÃÃes que descrevem o sistema. Os resultados de simulaÃÃes a variaÃÃes na tensÃo de referÃncia, considerando a anÃlise da resposta temporal do sistema controlado, demonstram que o PSO à uma tÃcnica eficiente na sintonia dos parÃmetros do AVR e PSS, destacando-se sua simplicidade, baixo esforÃo computacional e boa caracterÃsticas de convergÃncia.
This work presents the application of the Particle Swarm Optimization (PSO) algorithm for optimal tuning of controllers associated with voltage regulation and damping enhancement of synchronous generators used in combined cycle power station. For mathematic representation of the synchronous generator, the third order linearized model of a single machine connected to an infinite bus, valid for small signal stability studies, is used. The Automatic Voltage Regulator (AVR) and Power System Stabilizer (PSS) parameters are optimally determined by the proposed computational tool. The parameters obtained for AVR and PSS are compared with values calculated by conventional tuning techniques based on approximations of the equations that describe the system. The simulations results to reference voltage disturbances, considering the time response analysis of the controlled system, show that PSO is an efficient technique in the tuning of AVR and PSS parameters, with emphasis on its simplicity, low computational effort and good convergence characteristics.

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior
Os sistemas de controle de excitação em máquinas síncronas devem detectar com bastante rapidez as mudanças causadas pela entrada de carga no gerador isolado e atuar no sistema de excitação de forma rápida e eficiente, para manter a tensão terminal em níveis desejados. Ao contrário de outros trabalhos realizados nesta área com circuitos eletrônicos analógicos, em muitos casos, este controlador pode ser construído utilizando tecnologia microcontrolada por possuir alto nível de eficiência no controle, circuito com flexibilidade para implementação de diferentes estratégias de controle e baixo custo para produção. A abordagem deste trabalho consiste em uma proposta para aplicação de um controle de excitação automático utilizando uma malha PID, com opções de controle manual, monitoramento de tensão terminal e temperatura de estator da máquina, utilizando um microcontrolador PIC16F877A da empresa Microchip Technology. Os resultados obtidos a partir de ensaios práticos em laboratório com partidas diretas de motores de indução (1 e 2 cv) com um gerador de 2 kVA mostra que a atuação do controlador recuperou a tensão terminal em pouco tempo, para o setpoint adotado. E por fim, os resultados obtidos foram comparados com os tempos de resposta de outro conhecido regulador automático de tensão encontrado no mercado, para comprovar o bom desempenho de controle deste projeto.
The excitation control systems in synchronous machines must very quickly detect changes caused by load increase on the isolated generator and act on the excitation system in a rapid and efficient way in order to maintain terminal voltage at optimal desired levels. Unlike other works related with this area which used analog-based electronic circuits, this controller can in many case be built utilizing microcontrolled technology which is more efficient and flexible to implement different control strategies, as well as having a low cost of production. The approach of this research consists in a proposal to apply an automatic excitation controller, utilizing a PID control loop, including manual adjustments and monitorings of terminal voltage and stator temperature of the machine. It employs a PIC16F877A microcontroller from the Microchip Technology Company. The results obtained through practical tests in laboratory with a direct online start of induction motors (1 and 2 HP) on a 2 kVA generator show that the controller acts to recover the terminal voltage to the adopted setpoint in a reduced time. Finally, the results were also compared to the time of response provided from another well-known automatic voltage regulator found in the market, in order to prove the good control performance of this project.
Dissertação (Mestrado)

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Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico
The power system stabilizers are used to suppress low-frequency electromechanical oscillations and improve the synchronous generator stability limits. This master thesis proposes a wavelet-based power system stabilizer, composed of a new methodology for extraction and compensation of electromechanical oscillations in electrical power systems based on the scaling coefficient energy of the maximal overlap discrete wavelet transform in order to reduce the effects of delay and attenuation of conventional power system stabilizers. Moreover, the wavelet coefficient energy is used for electric oscillation detection and triggering the power system stabilizer only in fault situations. The performance of the proposed power system stabilizer was assessed with experimental results and comparison with the conventional power system stabilizer. Furthermore, the effects of the mother wavelet were also evaluated in this work
Os estabilizadores de sistemas de pot?ncia s?o empregados para suprimir oscila??es eletromec?nicas, de baixa frequ?ncia, e estender os limites de estabilidade de geradores s?ncronos. Prop?e-se nesta disserta??o de mestrado um estabilizador de sistema de pot?ncia baseado nas wavelets, composta por uma novametodologia para extra??o e compensa??o de oscila??es eletromec?nicas em sistemas el?tricos de pot?ncia baseada nas energias dos coeficientes de aproxima??o da transformada wavelet discreta redundante, com o objetivo de reduzir os efeitos de atraso e atenua??es dos estabilizadores de sistemas de pot?ncia convencionais. Por outro lado, as energias dos coeficientes wavelet s?o utilizadas para detec??o das oscila??es el?tricas e habilita??o do estabilizador de sistema de pot?ncia proposto apenas nas situa??es de falta. A efic?cia do desempenho do estabilizador de sistema de pot?ncia proposto foi comprovada por meio de resultados experimentais, cujo desempenho foi comparado com o desempenho do estabilizador de sistema de pot?ncia convencional. Al?m disso, os efeitos das wavelets m?es tamb?m foram avaliados

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Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico
The stability of synchronous generators connected to power grid has been the object of study and research for years. The interest in this matter is justified by the fact that much of the electricity produced worldwide is obtained with the use of synchronous generators. In this respect, studies have been proposed using conventional and unconventional control techniques such as fuzzy logic, neural networks, and adaptive controllers to increase the stabilitymargin of the systemduring sudden failures and transient disturbances. Thismaster thesis presents a robust unconventional control strategy for maintaining the stability of power systems and regulation of output voltage of synchronous generators connected to the grid. The proposed control strategy comprises the integration of a sliding surface with a linear controller. This control structure is designed to prevent the power system losing synchronism after a sudden failure and regulation of the terminal voltage of the generator after the fault. The feasibility of the proposed control strategy was experimentally tested in a salient pole synchronous generator of 5 kVA in a laboratory structure
A estabilidade de geradores s?ncronos conectados a rede el?trica tem sido objeto de estudo e investiga??es durante anos. O interesse por este assunto ? justificado pelo fato de grande parte da energia el?trica produzida no mundo ser obtida com a utiliza??o de geradores s?ncronos. Nesse aspecto, muitos trabalhos t?m sido propostos utilizando t?cnicas de controle convencional e n?o convencional como l?gica fuzzy, redes neurais e controladores adaptativos visando aumentar a margem de estabilidade do sistema quando ele est? sujeito a falhas s?bitas e dist?rbios transit?rios. Este trabalho apresenta uma estrat?gia de controle robusta n?o-convencional para a manuten??o da estabilidade dos sistemas de pot?ncia e regula??o da tens?o de sa?da de geradores s?ncronos conectados ? rede el?trica. A estrat?gia de controle utilizada ? composta pela integra??o de uma superf?cie deslizante com um controlador linear. Esta estrutura de controle contribui para a preven??o dos sistemas de pot?ncia de perder o sincronismo ap?s uma falha s?bita e regula??o da tens?o terminal do gerador ap?s a falta. A viabilidade da estrat?gia de controle proposta foi testada experimentalmente em um gerador s?ncrono de p?los salientes de 5 kVA em uma estrutura de laborat?rio

Vodní energie se nyní stala nejlepším zdrojem elektrické energie na zemi. Vyrábí se pomocí energie poskytované pohybem nebo pádem vody. Historie dokazuje, že náklady na tuto elektrickou energii zůstávají konstantní v průběhu celého roku. Vzhledem k mnoha výhodám, většina zemí nyní využívá vodní energie jako hlavní zdroj pro výrobu elektrické energie.Nejdůležitější výhodou je, že vodní energie je zelená energie, což znamená, že žádné vzdušné nebo vodní znečišťující látky nejsou vyráběny, také žádné skleníkové plyny jako oxid uhličitý nejsou vyráběny, což činí tento zdroj energie šetrný k životnímu prostředí. A tak brání nebezpečí globálního oteplování. Použití internetové techniky k ovladání několika vodních elektráren má velmi významné výhody, jako snížení provozních nákladů a flexibilitu uspokojení změny poptávky po energii na straně spotřeby. Také velmi efektivně čelí velkým narušením elektrické sítě, jako je například přidání nebo odebrání velké zátěže, a poruch. Na druhou stranu, systém získávání dat poskytuje velmi užitečné informace pro typické i vědecké analýzy, jako jsou ekonomické náklady, predikce poruchy systémů, predikce poptávky, plány údržby, systémů pro podporu rozhodování a mnoho dalších výhod. Tato práce popisuje všeobecný model, který může být použit k simulaci pro sběr dat a kontrolní systémy pro vodní elektrárny v prostředí Matlab / Simulink a TrueTime Simulink knihovnu. Uvažovaná elektrárna sestává z vodní turbíny připojené k synchronnímu generátoru s budicí soustavou, generátor je připojen k veřejné elektrické síti. Simulací vodní turbíny a synchronního generátoru lze provést pomocí různých simulačních nástrojů. V této práci je upřednostňován SIMULINK / MATLAB před jinými nástroji k modelování dynamik vodní turbíny a synchronního stroje. Program s prostředím MATLAB SIMULINK využívá k řešení schematický model vodní elektrárny sestavený ze základních funkčních bloků. Tento přístup je pedagogicky lepší než komplikované kódy jiných softwarových programů. Knihovna programu Simulink obsahuje funkční bloky, které mohou být spojovány, upravovány a modelovány. K vytvoření a simulování internetových a Real Time systémů je možné použít bud‘ knihovnu simulinku Real-Time nebo TRUETIME, v práci byla použita knihovna TRUETIME.

After decades of routine operation, the hydropower industry faces new challenges. Large-scale integration of other renewable sources of generation in the power system accentuates the role of hydropower as a regulating resource. At the same time, an extensive reinvestment programme has commenced where many old components and apparatus are being refurbished or replaced. Introduction of new technical solutions in existing power plants requires good systems knowledge and careful consideration. Important tools for research, development and analysis are suitable mathematical models, numerical simulation methods and laboratory equipment. This doctoral thesis is devoted to studies of the electromechanical interaction between hydropower units and the power system. The work encompasses development of mathematical models, empirical methods for system identification, as well as numerical and experimental studies of hydropower generator and power system interaction. Two generator modelling approaches are explored: one based on electromagnetic field theory and the finite element method, and one based on equivalent electric circuits. The finite element model is adapted for single-machine infinite-bus simulations by the addition of a network equivalent, a mechanical equation and a voltage regulator. Transient simulations using both finite element and equivalent circuit models indicate that the finite element model typically overestimates the synchronising and damping properties of the machine. Identification of model parameters is performed both numerically and experimentally. A complete set of equivalent circuit parameters is identified through finite element simulation of standard empirical test methods. Another machine model is identified experimentally through frequency response analysis. An extension to the well-known standstill frequency response (SSFR) test is explored, which involves measurement and analysis of damper winding quantities. The test is found to produce models that are suitable for transient power system analysis. Both experimental and numerical studies show that low resistance of the damper winding interpole connections are vital to achieve high attenuation of rotor angle oscillations. Hydropower generator and power system interaction is also studied experimentally during a full-scale startup test of the Nordic power system, where multiple synchronised data acquisition devices are used for measurement of both electrical and mechanical quantities. Observation of a subsynchronous power oscillation leads to an investigation of the torsional stability of hydropower units. In accordance with previous studies, hydropower units are found to be mechanically resilient to subsynchronous power oscillations. However, like any other generating unit, they are dependent on sufficient electrical and mechanical damping. Two experimentally obtained hydraulic damping coefficients for a large Francis turbine runner are presented in the thesis.

碩士
國立中央大學
電機工程研究所
93
Three-phase ac voltage regulator is capable of providing regulated power source, and one of the important issues of it is to stabilize the power quality. In this paper, a novel switching strategy called phase-shift pulse width modulation is applied to the three-phase four-wire ac voltage regulator（AVR）which utilizes a YY connection for the purpose of enhancing output power rating. The system is made up of three ac choppers with reversible voltage, AVR motherboards and transformers for series voltage compensation. The switching strategy is to match up the components of the system as mentioned above such that the compensation voltage with the same or opposite polarity for the input utility voltage can be simply obtained by controlling the duty cycle of power devices. Consequently, variations of the output voltage would be compensated or restrained. The fast sensing technique is adopted toward output voltage and the control law is implemented through the fixed-point digital signal microcontroller（DSM）（dsPIC30F2010）. The system is able to improve reliability, response, efficiency, power factor and reduce cost. It is shown via the experimental results that the system achieves the expected goal of fast voltage regulation.

碩士
國立中央大學
電機工程研究所
92
Abstract In this paper, a novel pulse width modulation (PWM) switching strategy for single-phase inverter is proposed. It is applied to the automatic voltage regulator (AVR) to improve its performance. In contrast with conventional PWM switching strategy of the inverter, the proposed strategy uses phase-shifted control to the PWM switching signals. Though those switches have the same switching frequency, the output switching frequency in the inverter is doubled due to the phase-shifted control. It reduces the total harmonic distortions and the filter size for system output. The novel AVR is made up of an AC chopper with reversible voltage control and a compensation transformer in series with AC line. To obtain an inphase or reverse voltage with respect to AC line to compensate the variations, one only needs to control the duty ratio of switches by using the proposed phase-shifted PWM. The AVR uses a fully digital controller, which is implemented by a fixed-point digital signal processor(DSP) (TMS320F240). Therefore, the proposed AVR gives high efficiency and reliability. It is also shown via some experimental results that the presented novel AVR gives fast response for high quality control of the output voltage.

碩士
國立高雄應用科技大學
電機工程系碩士班
91
The power capacitors are widely used for improving the power factor of distribution power system. However, it still has the problems of inrush current at the instant of turn-on and over-voltage at the instant of turn-off. The above problems may result in the violent failure of power capacitor and electromagnetic switch. Besides, the power resonance may occur between the power capacitor and the system impedance. It will result in over-voltage/over-current on the power capacitor due to the harmonic amplification. In this paper, the protection techniques for power capacitors are developed. Firstly, the hybrid switch for suppressing the inrush current and avoiding the transient over-voltage in the turn-on/turn-off processes is developed. Secondly, the over-voltage/over-current protection method, based on changing the system parameter, is developed for avoiding the over-voltage/over-current of power capacitor causing by harmonics. Finally, an automatic power factor regulator including the performance of inrush current suppression and over-voltage/over-current protection is developed and tested. The tested results shows it has the expected performance.

Η παρούσα διπλωματική εργασία έχει ως στόχο την αντιμετώπιση των ηλεκτρομηχανικών ταλαντώσεων οι οποίες εμφανίζονται σε μία σύγχρονη γεννήτρια παραγωγής Ηλεκτρικής Ενέργειας μετά από διαταραχές. Ο συμβατικός έλεγχος για τη διατήρηση της μηχανής σε συγχρονισμό μετά από ξαφνικές αλλαγές φορτίου, βραχυκυκλωμάτων, κλείσιμο διακοπτών ή οποιασδήποτε κατάστασης που μπορεί να προκαλέσει αστάθεια στο Σύστημα της Ηλεκτρικής Ενέργειας, γίνεται με χρήση ελεγκτικών διατάξεων Σταθεροποιητών Συστημάτων Ισχύος σε συνδυασμό με τον Αυτόματο Ρυθμιστή Τάσης (ΑΡΤ/ΣΣΙ). Σκοπός της εργασίας αυτής είναι να σχεδιαστούν και να ρυθμιστούν κατάλληλα οι διατάξεις αυτές, ώστε να εξασφαλίζεται η απόσβεση των ηλεκτρομηχανικών ταλαντώσεων που εμφανίζονται ανάμεσα στην γεννήτρια και το υπόλοιπο σύστημα. Στην εργασία αυτή, αρχικά γίνεται μια εισαγωγή στα είδη των ηλεκτρομηχανικών ταλαντώσεων και την ευστάθεια για δυναμικά Συστήματα Ηλεκτρικής Ενέργειας. Στη συνέχεια αναπτύσσεται το δυναμικό μοντέλο ενός απλού συστήματος μιας γεννήτριας άπειρου ζυγού βασισμένο στο απλοποιημένο μοντέλο 4ης τάξης της σύγχρονης μηχανής. Επειδή το μοντέλο αυτό είναι μη γραμμικό προχωράμε στην εξαγωγή του γραμμικοποιημένου μοντέλου που θα μας βοηθήσει για τον σχεδιασμό του κατάλληλου ελεγκτή. Αξιοποιώντας ιδιότητες του μοντέλου παρουσιάζεται μια συστηματική μέθοδος σχεδίασης του Σταθεροποιητή Συστήματος Ισχύος που είναι βασισμένη στη λογική των ολοκληρωτικών υπολοίπων. Τέλος με τη βοήθεια του λογισμικού SIMULINK του MATLAB προσομοιώνεται το σύστημα σύγχρονης γεννήτριας συνδεδεμένης σε άπειρο ζυγό, που ελέγχεται με την χρήση του Αυτόματου Ρυθμιστή Τάσης και του Σταθεροποιητή Συστήματος Ισχύος σε κατάσταση τυπικής φόρτισης. Εφαρμόζοντας διαταραχές στο σύστημα παρατηρείται η απόκριση του συστήματος και εκτιμάται η λειτουργία του ελεγκτή.
This thesis aims to address the electromechanical oscillations which appear in a synchronous generator after disturbances. The conventional control for maintaining the machine synchronized after sudden load changes, short circuits, switching or any condition which may cause instability phenomena, is achieved by the use of control circuits such as Power System Stabilizers combined with the Automatic Voltage Regulator ( PSS / AVR). The purpose of this work is to design and configure properly these control circuits to ensure the reduction of electromechanical oscillations that occur between the generator and the rest of the system. In the beginning this thesis, an introduction of the types of power system electromechanical oscillations and stability is being discussed. Afterwards, the dynamic model of a simple system of a generator infinite-bus based on simplified 4th order of synchronous machine is being developed. Due to the model nonlinearities, we export the linearized model which helps us to design a suitable controller. Taking into account the model properties, we provide a systematic method for designing a Power System Stabilizer based on the residues method. Finally, using the MATLAB-SIMULINK software, the synchronous generator infinite-bus system is simulated which is controlled by an Automatic Voltage Regulator and a Power System Stabilizer. After applying disturbances, the system response is driven and analyzed along with the controller functioning.

碩士
輔仁大學
電機工程學系碩士在職專班
104
This thesis proposes a bidirectional DC-DC power converter based on microcontroller for charging and discharging of lithium-ion battery set. The converter can automatically reads the input voltage and setup the output voltage command after turning on or reset, parallel connect to power source without setting. After reading the battery voltage, it then determines the required quantities of series connected cells, set up the charging profile, and control the pulse-width-modulation (PWM) duty cycle in order to achieve a stable constant current and constant voltage charging mode as well as discharging voltage output mode. From simulation and experimental results show the feasibility and correctness of the proposed converter and control system.

碩士
明志科技大學
電機工程系碩士班
103
This thesis presents the development of single-phase three-arm automatic voltage regulators. In this system, the three-arm full-bridge circuitry with boosting inductor in series at input side and low-pass filter in parallel at output side are proposed to regulate single-phase AC to electrical power with constant-voltage. It can not only maintain voltage stability at output side, but also decrease the size and cost of the system. The control strategy operated under phase-compensated amplitude-locked loop algorithm can provide a single-phase source with fast response, stable and low harmonic distortion power to loads. In this thesis, the mathematical model of single-phase three-arm automatic voltage regulators are built and simulated by Matlab/Simulink. Then, a high-performance and low-cost micro-controller (MCU, Renesas RL78G14) is used to control the system for reducing the circuit complexity. A prototype of 1kW voltage regulation system is developed. The system can feed proper power, while the rated effective output voltage is 110V and the frequency is 60 Hz. Besides, the simulation data show that the voltage harmonic distortion is 1.01%, which complies with IEEE Std. 519.

Digitally controlled switching DC-DC converters have recently emerged as an attractive alternative to conventional switching converters based on analog control techniques. This research focuses on eliminating the issues associated with the state of the art switching converters by proposing three novel control techniques: (1) a digitally controlled Buck-Boost converter uses a fully synthesized constant ON/OFF time-based fractional-N controller to regulate the output over a 3.3V-to-5.5V input voltage range and provides seamless transition from buck to buck-boost modes (2) a hysteretic buck converter that employs a highly digital hybrid voltage/current mode control to regulate output voltage and switching frequency independently (3) a 10MHz continuous time PID controller using time based signal processing which alleviates the speed limitations associated with conventional analog and digital. All the three techniques employ digitally assisted control techniques and require no external compensation thus making the controllers fully integrated and highly cost effective.
Graduation date: 2013
Access restricted to the OSU Community at author's request from June 25, 2012 - June 25, 2014