Electronic Ballast for Starting Fluorescent Lamps with Zero Glow Current

Lee, Mu-en

21 January 2003

This thesis proposes a single-stage high-power-factor electronic ballast with series-resonant inverter for rapid-start fluorescent lamps with zero glow current during preheating period. A buck-boost converter is integrated into the ballast as the power-factor-corrector. Two auxiliary windings are wound on the same core of the buck-boost inductor for filament heating. During the preheating period, the buck-boost converter is initiated while the series-resonant inverter is disabled by controlling the corresponding active power switches. Due to zero voltage across the lamp, the glow current can be effectively eliminated. As the filaments reach appropriate emission temperature, the series-resonant inverter is activated. The lamp is then ignited and consequently operated at the rated lamp power. Circuit analyses and experimental tests of the proposed preheating control scheme are carried out on an electronic ballast for a T8-40W rapid-start fluorescent lamp.

glow current

electronic ballast

series-resonant inverter

buck-boost converter

power-factor-corrector

Fluorescent lamp

Low voltage autonomous buck-boost regulator for wide input energy harvesting

Ahmed, Khondker Zakir

08 June 2015

While high power buck-boost regulators have been extensively researched and developed in the academia and industry, low power counterparts have only recently gained momentum due to the advent of different battery powered and remote electronics. The application life-time of such applications, e.g., remote surveillance electronics can be extended tremendously by enabling energy autonomy. While battery powered electronics last long but they must be replenished once the battery is depleted either by replacing the battery or by retrieving the electronics and then recharging. Instead, energy harvesting from available ambient sources on the spot will enable these electronics continuous operation unboundedly, probably even beyond the lifetime of the electronics. Interestingly enough, recent advancements in micro-scale energy transducers compliment these demand [1-13]. Micro-transducers producing energy from different ambient sources have been reported. These transducers produce enough energy to support a wide range of operations of the remote electronics concurrently. These transducers along with an additional storage elements greatly increase the energy autonomy as well as guaranteed operation since harvested energy can then be stored for future use when harvestable energy is temporarily unavailable. Recently several buck-boost regulators with low power and low input operating voltage have been reported both from academia and industry [14-24]. Some of this work focuses on increasing efficiency in the mid-load range (10mA-100mA), while some other focuses on lowering input range. However, so far no one has reported a buck-boost regulator operating with sub-200nW bias power while harvesting energy from sub-500mV input range. This work focuses on the development of a low voltage low bias current buckboost regulator to attain these goals. In this work, complete design of a PFM mode buck-boost regulator has been discussed in details. Basic topology of the regulator and working principle of the implemented architecture along with the advantages of the specific topology over that of the others have been discussed in short to provide an uninterrupted flow of idea. Later, Transistor level design of the basic building blocks of the buck-boost regulator is discussed in details with different design features and how those are attained through transistor level implementation are discussed. Subsequently, the physical layout design technique and considerations are discussed to inform the reader about the importance of the layout process and to avoid pitfalls of design failure due to layout quality issues. Measurement results are presented with the fabricated IC. Different characterization profile of the IC have been discussed with measured data and capture oscilloscope waveforms. Load regulation, line regulation, efficiency, start-up from low voltage, regulation with line and load transient events are measured, presented and discussed. Different characteristics of the prototype are compared with prior arts and are presented in a comparison table. Die micrograph is also presented along with the different issue of the IC testing

Buck-boost regulator

|Low voltage energy harvesting

Low current regulator

nA bias current regulator

A SINGLE-PHASE DUAL-OUTPUT AC-DC CONVERTER WITH HIGH QUALITY INPUT WAVEFORMS

LI, QIANG

01 January 2003

A single-phase, buck-boost based, dual-output AC-DC converter is studied in this thesis. The converter has two DC outputs with opposite polarities, which share the same ground with the input power line. The power stage performance, including the input filter, is studied and procedure to select power components is given. The circuit model is analyzed to develop appropriate control. Zerocrossing distortion of the source input current is addressed and a solution is proposed. Experimental results are satisfactory in that a high power factor line current results for steady-state operation.

Sistema de extração de potência (power harvesting) usando transdutores piezelétricos

Souza, Flavilene da Silva [UNESP]

05 August 2011

Made available in DSpace on 2014-06-11T19:22:31Z (GMT). No. of bitstreams: 0 Previous issue date: 2011-08-05Bitstream added on 2014-06-13T20:09:42Z : No. of bitstreams: 1 souza_fs_me_ilha.pdf: 685362 bytes, checksum: 69b1ef9da6ea6cde4e9978452b127ff7 (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Este trabalho descreve um sistema de extração de potência de power harvesting utilizando transdutores piezelétricos. Com o objetivo de extrair a máxima potência e assim ter um maior rendimento do sistema, foram projetados e testados alguns circuitos eletrônicos. Um circuito de controle com componentes discretos e de baixo consumo foi projetado para controle da chave do retificador chaveado e bias-flip. A energia extraída será utilizada para alimentar um sistema de aquisição de dados e um sensor de temperatura associado a este sistema. O sistema de power harvesting é constituído por uma estrutura mecânica, transdutor piezelétrico, circuito retificador e um conversor CC-CC. Na estrutura mecânica está localizado o transdutor piezelétrico e este transdutor proporciona a conversão de energia mecânica em energia elétrica. Para efeito deste estudo considera-se que o transdutor piezelétrico comporta-se como uma fonte de tensão alternada, que será retificada e armazenada em um supercapacitor, para depois ser utilizada na alimentação do sistema de aquisição de dados. Os conversores CC-CC são utilizados para maximizar a quantidade de energia obtida do transdutor piezelétrico e fornecer tensão ao supercapacitor. No entanto, uma das limitações desses sistemas é a baixa quantidade de energia gerada por esses dispositivos. Assim, para que haja uma minimização das perdas dos circuitos eletrônicos e possa se extrair a máxima potência possível do piezelétrico obtendo um melhor rendimento do sistema, este trabalho investigará a utilização dos circuitos retificadores em ponte, retificador em ponte chaveado, retificador bias-flip e o conversor buck-boost, além de utilizar a energia armazenada para alimentar um sistema de aquisição de dados associados a um sensor de temperatura... / This work describes several circuits for power extracting of power harvesting systems using piezoelectric transducers. In order to extract the maximum power and to achieve the maximum performance of these systems some electronic circuits were projected and tested. A control circuit with discrete components and low power consumption is designed to control switch of the switch-only and bias-flip rectifier. The goal is that the energy extracted is used to supply power electronic devices. That will be, in this work, a temperature sensor that is placed in a difficult access area. The power harvesting system is composed by a mechanical structure, a piezoelectric transducers, a rectifier and a DC-DC converter. The piezoelectric transducers were placed in the mechanical structure, these transducers are responsible to convert mechanical energy into electrical energy. In this work the piezoelectric transducer was considered an AC voltage source. This voltage will be rectified and then stored in supercapacitor, to be used in electronic circuits. The DC-DC converters were used to achieve maximum power from piezoelectric transducer and to supply voltage to the supercapacitor. However, one of the limitations of these systems is the low amount of power generated by the transducer. This way, it is mandatory to reduce the losses at the electronic components and extract the maximum power possible from the piezoelectric to improve the performance. This work investigates the full-bridge rectifier, switch-only rectifier, bias-flip rectifier and buck- boost converter, besides it aims to use the stored energy to supply a temperature sensor. Using the flip-bias rectifier improves the power up to 200%, and the switch-only rectifier by 150% in relation to full-bridge rectifier. And the efficiency changed from 35% (full-bridge)... (Complete abstract click electronic access below)

Transdutores piezoeletricos

Retificadores (Eletronica)

Power harvesting

Conversor buck-boost

Piezoelectric transducer

Design and Analysis of a Single-Stage Inverter Using Parallel DC-DC Converters for Solar Cell Application

Leonides, Gabriel

01 August 2021

This thesis introduces the design and analysis of a single-stage inverter. A circuit was designed and simulated as a proof of concept to investigate the possibility of using boost and buck-boost converters to provide an AC output. The proposed circuit utilizes non-synchronous boost and buck-boost converters due to their simplicity in control signals as opposed to synchronous converters. The application of the proposed inverter is for use with individual solar cells. The aim of the inverter for a single cell is to improve the efficiency of a solar panel, whose performance is limited to the performance of the least efficient cell. With each cell independent of any other cell in the solar panel, the overall efficiency of the panel can be improved. This circuit uses a 3.6VDC input from the solar cell to produce a 10VPP 60Hz square wave output. The inverter consists of a solar cell, two DC-DC converters, two linear dropout (LDO) regulators, a square wave generator, and a switching circuit . The design and analysis of all parts were investigated individually in detail. The different parts of the circuit were then simulated using LTspice before testing the overall circuit. Simulation results demonstrate the feasibility of the proposed inverter with all design requirements but efficiency meeting or exceeding the goals.

Solar Cell

Inverter

Single-Stage

DC-AC Converter

Boost

Buck-Boost

Power and Energy

Energy Harvesting from Exercise Machines: Buck-Boost Converter Design

Forster, Andrew E

01 March 2017

This report details the design and implementation of a switching DC-DC converter for use in the Energy Harvesting From Exercise Machines (EHFEM) project. It uses a four-switch, buck-boost topology to regulate the wide, 5-60 V output of an elliptical machine to 36 V, suitable as input for a microinverter to reclaim the energy for the electrical grid. Successful implementation reduces heat emissions from electrical energy originally wasted as heat, and facilitates a financial and environmental benefit from reduced net energy consumption.

DC-DC converter

switching converter

four switch buck boost

nonisolated

EHFEM

Power and Energy

Analysis of a Small-Signal Model of a PWM DC-DC Buck-Boost Converter in CCM

Lee, Julie JoAnn

12 September 2007

No description available.

BUCK-BOOST

vo

¿¿¿¿¿¿¿

Bode plot

step change

open-loop

transfer functions

Automatic PMG Controller for Small Applications

Adkins, William Scott

January 2015

No description available.

Electrical Engineering

Buck-Boost Micro-Controller

UAV

Current Contolled Source

Voltage Controlled Source

Battery Charger

Alternator

Development of an Efficient Hybrid Energy Storage System (HESS) for Electric and Hybrid Electric Vehicles

Zhuge, Kun

January 2013

The popularity of the internal combustion engine (ICE) vehicles has contributed to global warming problem and degradation of air quality around the world. Furthermore, the vehicles??? massive demand on gas has played a role in the depletion of fossil fuel reserves and the considerable rise in the gas price over the past twenty years. Those existing challenges force the auto-industry to move towards the technology development of vehicle electrification. An electrified vehicle is driven by one or more electric motors. And the electricity comes from the onboard energy storage system (ESS). Currently, no single type of green energy source could meet all the requirements to drive a vehicle. A hybrid energy storage system (HESS), as a combination of battery and ultra-capacitor units, is expected to improve the overall performance of vehicles??? ESS. This thesis focuses on the design of HESS and the development of a HESS prototype for electric vehicles (EVs) and hybrid electric vehicles (HEVs). Battery unit (BU), ultra-capacitor unit (UC) and a DC/DC converter interfacing BU and UC are the three main components of HESS. The research work first reviews literatures regarding characteristics of BU, UC and power electronic converters. HESS design is then conducted based on the considerations of power capability, energy efficiency, size and cost optimization. Besides theoretical analysis, a HESS prototype is developed to prove the principles of operation as well. The results from experiment are compared with those from simulation.

Sistema para gerenciamento do carregamento de baterias alimentado por uma turbina eólica

Farias, Guilherme de Carvalho

29 February 2016

Made available in DSpace on 2016-08-17T14:52:41Z (GMT). No. of bitstreams: 1 Dissertacao-GuilhermeCarvalhoFarias.pdf: 1837201 bytes, checksum: 75a44efdfd7752087fd597668e388184 (MD5) Previous issue date: 2016-02-29 / This study consists in a comparative analysis of MPPT strategies for low power wind turbines and the development of a control methodology for a battery charging system. The main MPPT strategies in the literature are described and implemented, along with all of their auxiliary control loops. To perform the comparison, a simulation platform is developed. Mathematical modeling of all components in the platform is described, as well as how they relate with each other. This platform allows keeping the system parameters the same for all methods, and modifying only the necessary to implement each of them. The control method for battery charging is presented and analyzed. One of the MPPT strategies described is applied together with this methodology. The methodology of the simulations are performed with switched models to validate the project realized with the developed average models. / Este trabalho consiste na análise comparativa entre métodos MPPT para turbinas eólicas de pequeno porte e desenvolvimento de uma metodologia de controle para um sistema de carregamento de baterias. Os principais métodos de MPPT presentes na literatura são descritos e implementados, juntamente com suas malhas de controle auxiliares. Para realizar a comparação, uma plataforma de simulação é desenvolvida. O modelamento matemático de todos os componentes presentes na plataforma é descrito, bem como a forma como eles se relacionam. Essa plataforma permite manter os parâmetros do sistema iguais para todos os métodos, somente modificando o necessário para implementar cada um deles. A metodologia de controle para carregamento de baterias é apresentada e analisada. Um dos métodos de MPPT descritos é aplicado juntamente à essa metodologia. As simulações da metodologia são realizadas com modelos chaveados, para validar o projeto realizado com os modelos médios levantados.

Métodos MPPT

Turbinas eólicas

Energia eólica

Conversor buck-boost não inversor

Carregamento de baterias

MPPT strategies

Wind turbines

Wind power

Non-inverter buck-boost converter

Battery charging

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA