AUTOR DO BLOG ENG.ARMANDO CAVERO MIRANDA SÃO PAULO BRASIL

"OBRIGADO DEUS PELA VIDA,PELA MINHA FAMILIA,PELO TRABALHO,PELO PÃO DE CADA DIA,PROTEGENOS DO MAL"

"OBRIGADO DEUS PELA VIDA,PELA MINHA FAMILIA,PELO TRABALHO,PELO PÃO DE CADA DIA,PROTEGENOS  DO MAL"

“SE SEUS PROJETOS FOREM PARA UM ANO,SEMEIE O GRÂO.SE FOREM PARA DEZ ANOS,PLANTE UMA ÁRVORE.SE FOREM PARA CEM ANOS,EDUQUE O POVO.”

“Sixty years ago I knew everything; now I know nothing; education is a progressive discovery of our own ignorance. Will Durant”

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quinta-feira, 14 de julho de 2022

Research on the Optimal Design of Weinberg Converter Qian Chen*a, Peng Qiu*,Yi Lu*, Jinpei Du**, Jiayi Wu***, Haihong Yu*, IEEJ TRANSACTIONS ON ELECTRICAL AND ELECTRONIC ENGINEERING IEEJ Trans 2018


 


Research on the Optimal Design of Weinberg Converter 

AUTHORS:Qian Chen*a, Peng Qiu*, Yi Lu*, Jinpei Du**, Jiayi Wu***, Haihong Yu*,

Because of its advantages of continuous input and output currents, stable transfer function, and high efficiency, the Weinberg converter is used as battery discharge regulator. Its working principle under overlap and nonoverlap modes with stray parameters is analyzed. Then a design method is proposed to optimize the parameters. In order to estimate the heat distribution, the power loss is calculated according to the performance parameters, and then the efficiency trend is achieved toward the output current. In addition, the experimental results verify the optimal design using a 600W prototype. © 2018 Institute of Electrical Engineers of Japan. Published by John Wiley & Sons, Inc. 1. 

Introduction
 A power conditioning unit (PCU) is comprised of the main error amplifier (MEA), the shunt regulator (SR), the battery charge regulator (BCR), the battery discharge regulator (BDR), and telemetering/telecontrol (TM/TC) [1–5]. PCU balances the energy between each unit to keep the bus voltage constant so that the electrical equipment of satellites can obtain stable power from the main bus. When the satellites cannot get enough energy from the solar battery array in the shadow region or sunshine region, the batteries provide energy for the bus to keep bus voltage constant. BDR plays an important role during this process. Our aim is to study a highpower and high-efficiency boost converter that is easy to expand and realize current-sharing to achieve excellent bus performance. Efficiency, complexity, and linearity play an important role in choosing the topology of the BDR. The normal boost converter is not suitable for BDR because of its low efficiency, instability, and discontinuous output current. So far, the topologies that have been used in BDR are [6–8] phase-shift full bridge (PSFB), Superboost, Smart Add on, HE-Boost, and Weinberg.


sexta-feira, 8 de julho de 2022

Analysis and Design of Multioutput Flyback Converter A study For A Lab Upgrade on the Flyback converter assignment at CHALMERS UNIVERSITY TECHNOLOGY Master's thesis in Electric Power Engineering Abdi Ahmed Abdullahi Kosar


 



Master's thesis 2016:ENM Analysis and Design of Multioutput Flyback Converter A study For A Lab Upgrade on the Flyback converter assignment at Chalmers Elteknik ABDI AHMED ABDULLAHI KOSAR Department of Energy & Environment Division of Electric Power Engineering Chalmers University of Technology Gothenburg, Sweden 2016

Abstract 

This thesis work is done in order to improve the existing lab in Chalmers for the study of Power Electronics. Assignments for the practical lab and computer simulation sessions of a yback converter have been reviewed and analysed. The analyses of the existing assignments shows that the circuit board used in the lab today is a multi purpose circuit and it is dicult to relate a equivalent circuit diagram of a yback converter. Furthermore, there is no relationship between the circuit and the simulation model. A simulation was done using PSpice and a prototype PCB board built with the aim of showing some of these interesting concepts in the course. The main suggestions are related to the simpli cation of the circuits so that immediate correlation can be made between the circuits being shown in the class and the PCB used in the lab. The simulation model can be used in the simulation session of the course. The new simulation model and the circuit board can demonstrate the role of the inductor in the yback transformer by varying its value. Another area of improvement would be on demonstrating of magnetics theory. There is no simulation or practical assignments about magnetics in the course today. Understanding the relation between the current ripple and magnetic ux is in the scope of the courses. It is also important to understand how high frequency a ects the losses and the size of the core. Two transformers are designed in order to investigate these relationships. The result of the transformer design shows that a new assignment that can demonstrate how magnetic core behaves can be introduced.

VIEW FULL TEXT:https://odr.chalmers.se/handle/20.500.12380/252784

sexta-feira, 24 de junho de 2022

Multi Level Inverter System using Dual Output DC-DC Converter with High Gain-Doctoral Dissertation-Department of Electrical Engineering Graduate School, Chonnam National University by Ibadullaev Anvar-February 2021

 





Multi Level Inverter System using Dual Output DC-DC Converter with High Gain Ibadullaev Anvar Department of Electrical Engineering Graduate School Chonnam National University (Supervised by Professor Park SungJun)

 (Abstract) Electricity has a weighty and an important impact on the social, industrial and economic developments of countries around the world because it is an essential ingredient of modern civilization. XXI century civilization depends on constant accessibility of this wealth in order to continue the present form of life and developing. Recently, with the development of green energy producing technology, the use of renewable sources such that photovoltaic arrays(PV), fuel cell sources, etc. have been increasing rapidly. Depending on the new research report published by “Markets and Market“, the inverter market is projected to grow from USD 12.8 billion in 2020 to USD 26.5 billion by 2025. The inverter market is likely to exhibit lucrative growth potential during the forecast period. The growth of the inverter market is expected to be driven by continuosly rising number of industrial and household solar rooftop installations. This exponentially growth of the inverter selling segment can be understood the entering of photovoltaic energy generation plants, HEV(hybrid electric vehicles) and electric vehicles charging stations that has brought new opportunities and challenges in the power electronics industry, especially in terms of the research and development of the main traction three phase AC motor drives. The multilevel inverter structure based topologies gives the OK to these vehicles to hold out to high voltages and power levels without using bulky and hard transformers. And also, the limited installation spaces of the HEVs have also led to the requirement for small size and power efficient inversion devices. Among end users, the residential segment held the largest share of the inverter market in 2019. Continuously rising electricity bills, coupled with supportive government policies worldwide, have led to the increasing adoption of energy conservation measures such as solar rooftop installations for controlling the increased energy expenditure in residential applications. Countries such as Japan, the United States, the Netherlands and Australia which are among the prominent markets for residential rooftop solar installations, have widely adopted solar inverters over conventional non-solar inverters. In addition, countries such as Brazil, the United Kingdom, India and Mexico are currently witnessing significant growth in the residential solar energy market. In modern smart grid solutions, control technologies for the consumption can response based on information about the electricity generation and transmission system and prices in an automatic way to improve the performance and reliability of the system. Demand for better designed hardware topology and controllers is constantly rising as the renewable energy market continues to sharply grow. In a typical residential, or small factory utility photovoltaic arrays are connected in series, in parallel or mixed type to form high DC voltage bus to can connect to DC-AC inverter, which then is connected directly to single or three phase AC Grid. Using renewable power generation systems established with step up dc-dc converters is being popularized because of the rising demand of zero pollution and eco friendly renewable energy sources. In this study, a new constructed multi level inverter system using dual outptut DC–DC converter was proposed to match a low DC voltage output sources, such as photovoltaic source or fuel cell systems with single phase AC grid bus lines. When comparing to other conventional multi level inverters, the proposed multi level inverter has a decreased number of the semiconductors, can create higher quality power with lower THD values, has decreased and balanced voltage stress for dual output dc-dc converter DC capacitors. The proposed topology requires a single DC source.

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segunda-feira, 4 de abril de 2022

A Study on Modulated Carrier Control Method for Power Factor Correction Boost Converter BY Jintae Kim- Interdisciplinary Program in Photovoltaic System Engineering The Graduate School Sungkyunkwan University




















 Ph.D. Dissertation A Study on Modulated Carrier Control Method for Power Factor Correction Boost Converter BY Jintae Kim 
Interdisciplinary Program in Photovoltaic System Engineering
The Graduate School Sungkyunkwan University

 Abstract 
A Study on Modulated Carrier Control Method For Power Factor Correction Boost Converter As demand of electrical devices steeply increases, harmonic pollution on the power grid has attracted concern. This circumstance leads standards such as IEC61000-3-2 and 80-Plus regulating harmonic currents or PF (Power Factor) to have been more stringent. Thus, a PFC (Power Factor Correction) circuit able to improve power quality while reducing current harmonics has been indispensible at the electrical devices. For the reason, the PFC has been constantly researched so that various topologies and control types have been proposed and realized as silicon. So far, many of proposed PFC converters have each optimal operation mode offering good PFC performance such as CCM (Continuous Conduction Mode), DCM (Discontinuous Conduction Mode) or BCM (Boundary Conduction Mode). The same is true of conventional MCC (Modulated Carrier Control) PFC converters. The conventional MCC PFC method does not require sensing the line input voltage and offers very fast dynamic current control by directly comparing an inductor current. These are advantages of the conventional ones. However, these conventional MCC converters enter into DCM by load reduction, the line input current is distorted and harmonic current is increased. In this dissertation, a research on new MCC method is revealed from a study and analysis on the conventional MCC PFC converter. Two types of MCC method are proposed to overcome the problem of the conventional MCC aforementioned. The proposed MCC methods newly employ a circuit to detect DCM region and generate DCM compensation signal in common. Using the compensation, the MCC methods can control the line input current as a desirable sinusoidal waveform, which results in better PFC performance regardless of a line input voltage range or load variation unlike the conventional MCC method. With all them, the proposed method can maintain the advantages of the conventional MCC method and even it can be easily implemented with analog or digital circuits. This dissertation describes the proposed MCC methods and the operating principle. In addition, to verify the proposed methods, they are implemented in 400 W PFC boost converter.