A Dq Rotating Frame Controller for Single Phase Full-Bridge Inverters Used in Small Distributed Generation Systems

Roshan, Arman

24 August 2007

Today, small distributed power generation (DG) systems are becoming more common as the need for electric power increases. Small DG systems are usually built close to the end-user and they take advantage of using different energy sources such as wind and solar. A few examples are hybrid cars, solar houses, data centers, or hospitals in remote areas where providing clean, efficient and reliable electric power is critical to the loads. In such systems, the power is distributed from the source side to the load side via power electronic converters in the system. At low and medium power applications, the task is often left to single phase inverters where they are the only interface between sources connected to DC bus and loads connected to an AC bus. Much has been done for the control of single phase inverters in the past years; however, due to the requirements of stand alone systems and the time-varying nature of the converter, its controller design is still quite difficult, and especially so if its critical functionality within the system is taken into consideration. Part of the challenge is also due to the fact that the load is not known at all time, further complicating the controller design. This thesis proposes a different method of control for single phase inverters used in low and medium power DG systems. The new control method takes advantage of the well-known DQ transformation and analysis mostly employed for three phase converters' analysis and control design. Providing a time-invariant model of single phase inverters is the main feature of DQ transformation. In addition to that, control design of the inverter in DQ frame becomes similar to those of DC-DC and three phase converters making it easier to achieve superior performance under different operation conditions while achieving a robust controller. The transformation requires at least two independent phases for each state variable in the system; thus a second phase must be created. This thesis proposes the creation of an imaginary circuit based on the real circuit of the inverter to provide the second required phase for transformation. The state variables of the imaginary circuit are obtained by differentiating the state variables of the main inviter's circuit. The differentiation can be implemented in DSP so there is no need for additional hardware in the system, making it more attractive and cost effective method. The DQ controller not only provides superior transient response, it also provides zero steady-state error as well as low output voltage THD under nonlinear load operation. The entire controller can be implemented in a digital control board which is becoming more common in power electronics converters within the past decade. Analysis and design of a DQ controller for a 2.5kW single phase full-bridge inverter is presented in this study with the final results implemented in a FPGA/DSP based digital controller board. / Master of Science

Single phase full-bridge inverter

DQ control method

DQ transformation

Electronic Ballast for Fluorescent Lamps with DC Current

Lai, Chien-cheng

09 June 2005

Fluorescent lamps are in general driven by ac ballasting currents. The cyclic variation in arc discharging power results in light fluctuation at twice the frequency of the ac current. Light fluctuation may be intolerable when a steady light output is required in some particular applications. To eliminate light fluctuation, an electronic ballast with dc current is proposed to operate the fluorescent lamp at a constant power. The main power conversion of the electronic ballast employs the single-stage high-power-factor inverter, which is originated from a combination of the half-bridge resonant inverter and the buck-boost converter. With such a circuit configuration, the output power can be regulated by asymmetrical pulse-width-modulation. The ac output of the inverter is then rectified and filtered to provide the dc ballasting current. Driven by dc current, however, the fluorescent lamp emits electrons unilaterally from one end leading to wearing out of emission material on the cathode filament. To solve this problem, an inverter is integrated for commutation of the lamp electrodes. Furthermore, a preheating control is included to start the fluorescent lamps with zero glow-current. A prototype is designed and built for the OSRAM T5-80W fluorescent lamp. The dc operating characteristics of starting transient, light fluctuation, lighting spectra, color temperature as well as the light fluctuation are investigated from experiments. Experimental results also show that the electronic ballast is capable of high-power-factor, dimming capability and zero glow-current preheating.

light fluctuation

fluorescent lamp

electronic ballast

full-bridge inverter

resonant inverter

Controle e simulação de um sistema fotovoltaico de baixa potência conectado à rede elétrica

Gil, Gloria Milena Vargas

January 2016

Orientador: Dr. José L. Azcue Puma / Dissertação (mestrado) - Universidade Federal do ABC, Programa de Pós-Graduação em Engenharia Elétrica, 2016. / Este trabalho apresenta o estudo, modelagem e projeto de um sistema de conversão de energia para a conexão de um módulo fotovoltaico com a rede elétrica. Nesta pesquisa são abordados três conversores para adequar a energia gerada por um painel fotovoltaico e conectá-la à rede elétrica. O primeiro conversor é um Boost intercalado de dois níveis encarregado de implementar o MPPT (Maximum Power Point Tracking), o segundo conversor é um Ressonante LLC que realiza o isolamento galvânico e o terceiro conversor é um inversor em ponte completa que mantém a tensão de barramento em um valor determinado e realiza a conversão de corrente contínua para corrente alternada. Os três conversores são projetados, calculando os elementos passivos que os compõem e simulando os circuitos obtidos. Também, é realizada a modelagem dos conversores e o projeto dos controladores utilizando a análise de pequenos sinais. Os resultados de simulação são apresentados utilizando os softwares PSIM e MATLAB. Na parte experimental são verificados os dois primeiros conversores usando o kit High Voltage Isolated Solar MPPT fabricado pela Texas Instruments. / This work presents the study, modeling and design of a photovoltaic conversion system for the connection of a photovoltaic module with the grid. In this research three converters are approached to adequate the generated energy for a photovoltaic panel and to transfer the energy to the grid. The first converter is an interleaved two-level boost responsible for implementing the MPPT (Maximum Power Point Tracking) the second converter is a Resonant LLC that performs galvanic isolation and the third converter is a complete bridge inverter that keeps the bus voltage at a certain value and performs the conversion of continuos current to alternating current. The three converters are designed, calculating the passive elements that compose them and simulating the obtained circuits. Also, the modeling of the inverters and the design of the controllers are performed using small signal analysis. Simulation results are presented using the PSIM and MATLAB software. In the experimental part the first two inverters are verified using the High Voltage Isolated Solar MPPT kit manufactured by Texas Instruments.

CONVERSOR BOOST INTERCALADO

CONVERSOR RESSONANTE LLC

INVERSOR PONTE COMPLETA

INTERLEAVED BOOST CONVERTER

RESONANT CONVERTER LLC

FULL BRIDGE INVERTER

Conversor ressonante para geração de ozônio aplicado à água de processos de higienização industrial, com controle digital /

Alburqueque Valdivia, Marlon Jesus

January 2019

Orientador: Carlos Alberto Canesin / Resumo: No presente trabalho de dissertação, é analisado e desenvolvido um conversor ressonante com o objetivo de produzir ozônio, aplicado à água de processos de higienização industrial. Na atualidade, no ano de 2018, dois dos fatores de grande importância no desenvolvimento de conversores para geração de ozônio são: a eficiência energética, isto é, quanta energia é aproveitada em relação à energia total fornecida ao conversor, e a outra é a produção de ozônio fazendo uso dessa energia aproveitada. Os dois fatores não necessariamente estão relacionados, por exemplo, para dois conversores distintos com a mesma energia disponível, pode acontecer que em um deles possa ser produzido maiores concentrações de ozônio com um menor aproveitamento de energia. Portanto, este trabalho enfatiza a melhoria da eficiência energética na produção de ozônio, empregando comutação suave nas estruturas envolvidas do conversor ressonante proposto, o que resulta em uma eficiência energética de 91,57%. A estrutura do conversor proposto apresenta dois estágios em cascata, o primeiro deles, um conversor que é responsável por gerar um barramento CC estável de 400,5 V e que atende aos requisitos de fator de potência e distorção harmônica total com valores de 0,994 e 5,79%(para a corrente de entrada), respectivamente, e o segundo, um inversor ressonante capaz de fornecer uma tensão de 4,4 kV com uma frequência de 10 kHz que atua como fonte de alimentação de um reator conformado por câmaras de descarga usadas em ... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: In the present dissertation, it is studied and developed a resonant converter in order to produce ozone, applied in water treatment for cleaning processes. Currently, in the year 2018, two of the factors of great importance in the development of converters for ozone generation are: energy efficiency, that is, how much energy is used in relation to the total energy supplied to the converter, and the other is the production of ozone making use of this energy harnessed. The two factors are not necessarily related, for example, for two different converters with the same energy available, it can happen that in one of them can be produced higher concentrations of ozone with a lower use of energy. Therefore, this work emphasizes the improvement of energy efficiency in the production of ozone using soft switching in the involved structures of the proposed resonant converter, which results in an energy efficiency of 91.57%. The structure of the proposed converter has two stages in cascade, the first one, a converter that is responsible for generating a stable DC bus of 400.5 V and that meets the requirements of power factor and total harmonic distortion with values of 0.994 and 5.79% (for the input current), respectively, and the second, a resonant inverter capable of providing a voltage of 4.4 kV with a frequency of 10 kHz which acts as a power supply for a reactor formed by discharge chambers used in ozone generation applications by electric discharge. Naturally, relevant ozone info... (Complete abstract click electronic access below) / Mestre

Geração de ozônio

Conversor Boost “Flying Capacitor”

Comutação suave ou não dissipativa

Ozone generation

Boost Flying Capacitor converter

Phase-shift Full-bridge inverter

Soft or non dissipative switching