Research on Control Strategy of High-power Three-phase Combined Inverter-고전력 삼상 복합 인버터 제어 전략 연구-BY ZHANG HUAYING August, 2020 Department of Electrical Engineering Graduate School of Konkuk University

Thesis for Degree of Master Supervisor: Prof. Younghoon Cho 

Research on Control Strategy of High-power Three-phase Combined Inverter 

Submitted by ZHANG HUAYING 

Department of Electrical Engineering Graduate School of Konkuk University

ABSTRACT 

Research on Control Strategy of High-power Three-phase Combined Inverter Zhang Hua Ying Department of Electrical engineering Graduate School of Konkuk University 

Three-phase voltage-type inverters are used in various occasions, such as static reactive power compensator, uninterruptible power supply distribution network development system, motor control, etc. In today's world where energy is scarce, research on inverters and their control technology is of great significance and is gaining more and more attention. People have higher and higher requirements for inverter power supplies. High-performance, high-reliability high-power inverters are one of the development trends of inverter power supplies. In the high-power inverter power supply, the current on the main circuit power device is relatively large, which can reach hundreds of amps, or even thousands of amps. There are two main ways to increase the capacity of the inverter power supply. And parallel technology using inverters to achieve power modularity. This article takes 30kVA combined three-phase inverter as the research object, adopts PID control method, mainly studies the waveform control of high-power three-phase inverter, and focuses on the main circuit structure and system of high-power three-phase inverter. The mathematical model and waveform control were analyzed and studied in detail. The structure of the three-phase combined inverter suitable for high power is analyzed, the main circuit design of the combined threephase inverter with 30KVA is given, and the combined three-phase inverter established and analyzed under different coordinate systems The mathematical model of the model is simulated and studied according to the parameter settings.

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Задачник по теории линейных электрических цепей-Problemas sobre a teoria de circuitos elétricos lineares-Shebes M.R., Kablukova M.V.

 

Livro de problemas sobre a teoria de circuitos elétricos lineares 

Shebes M.R., Kablukova M.V. 1990

 O livro fornece um breve material de referência na forma de disposições e relacionamentos básicos, fórmulas de cálculo, tarefas típicas com soluções e explicações detalhadas, exemplos de aplicação de métodos básicos para cálculo de circuitos elétricos em modos estacionários e transitórios, A 4ª edição (3ª 1982) é complementada com problemas para cálculo de filtros polinomiais em relação a parâmetros operacionais, circuitos RC ativos, filtros ARC, etc.

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Bidirectional interleaved current-fed resonant converter with reduced size of output filter for Fuel cell electric vehicles -출력필터의 크기를 줄인 연료전지 자동차용 양방향 인터리브드 전류원 공진형 컨버터 author Moon Dong-ok=

 

Bidirectional interleaved current-fed resonant converter with reduced size of output filter for FCEV 출력필터의 크기를 줄인 연료전지 자동차용 양방향 인터리브드 전류원 공진형 컨버터 

 Author Moon Dong-ok 

Issue Seoul: Seoul National University of Science and Technology, 2015 

 Dissertation Thesis (Master's) -- Department of Electrical and Computer Engineering, Graduate School of Seoul National University of Science and Technology 2015 Year of issue 2015

ABSTRACT 

 Recently, eco-friendly cars such as an Electric Vehicles (EV), Hybrid Electric Vehicles (HEV) and Plug In Hybrid Electric Vehicles (PHEV) are attracting increasing attention as a solution of environ-mental pollution, global warming and exhaustion of fossil fuels. The low voltage dc/dc converter (LDC) provides power to 12V loads such as the head lamps, wiper blade motor, electronic power steering (EPS), radio system etc. and charges a 12V auxiliary battery from a high voltage battery(200~400V). This application requires an efficient (usually, higher than 90%), compact and light weight dc/dc converter. Also, due to safety and high step down conversion ratio galvanic isolation is generally required. This study proposes a bi-directional interleaved current-fed resonant converter (CRC) with reduced size of the output filter for a fuel cell electric vehicle. The proposed CRC achieves zero-current switching turn on and off of switches and diodes and makes ripple current of the output capacitor theoretically zero. As a result, the cost and volume of the output capacitor are significantly reduced. The two-stage power conversion technique is also applied for wide input and output voltage range operations. A 2kW prototype of the proposed converter is built and tested to verify the validity of the proposed operation

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LIVRO – INVERSORES MONOFÁSICOS-VERSÃO BETA-DR. IVO BARBI-Programa de Pós-Graduação em Engenharia Elétrica da UFSC, pesquisador do Centro Integrado de Pesquisa em Energia Solar da UFSC,

 

IVO BARBI 

O Prof. Ivo Barbi Possui graduação (1973) e mestrado(1976) em Engenharia Elétrica pela Universidade Federal de Santa Catarina e doutorado em Engenharia Elétrica pelo Institut National Polytechnique de Toulouse (1979). Fundador da SOBRAEP – Sociedade Brasileira de Eletrônica de Potência(1990), da qual é Presidente de Honra e Presidente do primeiro COBEP -Congresso Brasileiro de Eletrônica de Potência(1991). Em fevereiro de 2016 liderou a criação do IBEPE-Instituto Brasileiro de Eletrônica de Potência e atualmente é seu Diretor Presidente.

O Prof. Ivo Barbi, membro fundador da SOBRAEP, recebeu em cerimônia híbrida da SOBRAEP às 17h do dia 08/11/2021 em João pessoa na Paraíba, uma homenagem ao seu recente marco em número de orientações entre mestrados e doutorados. A singela homenagem desta sociedade visa reconhecer em forma de gratidão todas as ações que o professor Ivo vêm fazendo em prol da eletrônica de potência no Brasil e no mundo. O momento foi oportuno, pois o professor acaba de atingir o marco de mais de 200 orientações entre mestres e doutores, algo que acreditamos que expressa diretamente tamanha a sua contribuição na área de Eletrônica de Potência e, consequentemente em nossa sociedade. Em sua trajetória, o Prof. Ivo atuou efetivamente para criação e consolidação do Instituto de Eletrônica de Potência (INEP), do Congresso Brasileiro de Eletrônica de Potência (COBEP), bem como desta sociedade e mais recentemente do Instituto Brasileiro de Eletrônica de Potência (IBEPE). Atualmente é Professor Permanente do PPGEEL-Programa de Pós-Graduação em Engenharia Elétrica da UFSC, pesquisador do Centro Integrado de Pesquisa em Energia Solar da UFSC, coordenador do GPEN – Grupo de Pesquisa em Processamento de Energia, cadastrado no CNPq e Diretor Presidente do IBEPE. Foi um dos pioneiros da moderna eletrônica de potência no Brasil, juntamente com os professores Edson Roberto Cabral da Silva e Edson Watanabe. Além de ser membro do IEEE com o grau de LIFE FELLOW e ter recebido IEEE William E. Newell Power Electronics Award em 2020. Junto à Sobraep o Prof. Ivo também possui atuação destacada, colaborando nos Congressos Brasileiros de Eletrônica de Potência, bem como na revista eletrônica de potência.

DEVO AGRADECER PUBLICAMENTE EM MEU BLOG A ATITUDE NOBRE DO DR. IVO BARBI DE COMPARTILHAR SEU CONHECIMENTOS EM ESTE LIVRO MUITO DIDACTICO E COM EXERCICIOS PARA O ENSINO DOS ESTUDANTES DE ENGENHARIA, POSTGRADO ALEM DE PROFISSIONAIS QUE DESEJAM ATUALIZARSE CONTINUAMENTE,QUE DEUS

PROTEJA E ABENÇÕE COM MUITA SAÚDE  O DR. IVO BARBI E FAMILIA.

VIEW FULL LIBRO NA WEB: https://ivobarbi.com.br/livro-inversores-monofasicos/

Hydrogen Fuel Cell Hybrid Railway Vehicle-BY Kang, DongHun -Department of Electrical Engineering Graduate School, Myongji University-수소연료전지 하이브리드 철도차량을 위한 DC/DC 컨버터 최적 토폴로지 선정 및 설계

 

Optimal Topology Selection and Design of DC/DC Converter for Hydrogen Fuel Cell Hybrid Railway Vehicle BY Kang, DongHun 

Department of Electrical Engineering Graduate School, Myongji University Directed by Professor Lee, Il Oun

 Dissertation Thesis (Master's) -- Department of Electrical Engineering, Graduate School, Myongji University 2020

ABSTRACT

As Korea entered into the 2015 Paris Climate Convention, studies are being actively conducted to reduce the emission of pollutants such as carbon dioxide and fine dust in various fields. In particular, Korea is actively supporting the research and development of eco-friendly transportation means using electricity and hydrogen in the transportation industry, and research related to this is being actively conducted. In 2019, a new pollutant emission standard for railroad vehicles, which was a blind spot for pollutant emissions in Korea, was established, and research is underway to replace aging diesel railway vehicles. In particular, research on hybrid railway vehicles using hydrogen fuel cells with no combustion process and high generation efficiency is being actively conducted. However, since there are no railway vehicles using hydrogen fuel cells developed and operated in Korea, it is necessary to refer to constructing the railway vehicle system based on the successful cases operating in overseas. In this paper, the optimal topology selection and design of DC/DC converter, which charges high-voltage battery by receiving the voltage of fuel cell in hydrogen fuel cell railway vehicle system and supplies power to inverter for propulsion of railway vehicle Deal with. Hydrogen fuel cell railway vehicles have three driving patterns of acceleration, deceleration, and grid connection. The DC/DC converter performs one-way step-up operation in all three driving patterns. Therefore, in this paper, we compare unidirectional step-up converter topology. The optimal topology is selected in a three-level boost converter, in which the semiconductor device has half the voltage stress of the output voltage, and in a two-level interleaving boost converter, in which the semiconductor device has half the current stress of the input current. The specification of DC/DC converter was selected by referring to the railroad cars that are developed and operated overseas because there is no commercially available hydrogen fuel cell railroad car. The final specifications were selected as input voltage 600V, output voltage 1500V, output power 250kW. In this paper, we verify the validity of hardware and controller design and analysis by developing a 20kW miniature converter with the same dynamic characteristics as a 250kW DC/DC converter. Therefore, the 20kW miniature DC/DC converter of this paper is reduced to 600V input voltage, 1200V output voltage, and 20kW output power, but has the same switching frequency as the 250kW DC/DC converter reflecting similar dynamic characteristics. To achieve over 95% efficiency, the 3-level boost converter is designed with a switching frequency of 30kHz and the 2-level interleaving boost converter with a switching frequency of 8kHz. The two-level interleaving boost converter is designed at 8kHz because a high output voltage is applied to the switch, resulting in high switching losses. Designed with switching frequency. In this paper, the three-level boost converter with 20kW capacity and the two-level interleaving boost converter were designed under the worst condition, and the expected efficiency was derived through the loss analysis of the converter according to the output voltage. Various simulation models verify the validity of the hardware and controller design. In particular, the controller design was designed considering the digital delay components of the digital controller, and the validity of the theoretical analysis on the delay components was verified through simulation. As a result of the experiment of the actual hardware, the error between the estimated loss and the actual loss through the simulation was less than 1%, confirming the validity of the loss analysis. When comparing the efficiency, power density, dynamic and static performance among the two topologies, we expect a three-level boost converter to be advantageous. Was verified. In particular, considering the current doubling effect of the three-level boost converter, the sampling frequency was 60kHz, resulting in better dynamic performance. Comparing the experimental results of the three-level boost converter and the two-level interleaving boost converter, the final topology was selected as a three-level boost converter with high efficiency, high power density, and excellent dynamic and static characteristics. Based on the experimental results, the hardware design method, the controller design method considering the digital delay component, the loss analysis and various simulation models are expected to be used to design the actual 250kW DC/DC converter.

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