LCL filter based high power density AC/DC converter for fast charging applications-Nguyen Dinh Tuyen, Nguyen Van Minh Tam, Truong Phuoc Hoa Department of Power Delivery, Faculty of Electrical and Electronics Engineering, Ho Chi Minh City University of Technology

 Journal homepage: http://ijpeds.iaescore.com LCL filter based high power density AC/DC converter for fast charging applications Nguyen Dinh Tuyen, Nguyen Van Minh Tam, Truong Phuoc Hoa

 Department of Power Delivery, Faculty of Electrical and Electronics Engineering, Ho Chi Minh City University of Technology (HCMUT), Vietnam National University (VNU), Ho Chi Minh City, Vietnam 

 ABSTRACT This paper introduces a LCL filter design tailored for a 40 kW three-phase grid-connected converter utilized in electric vehicle onboard fast chargers. In contrast to conventional filters, the LCL filter finds extensive application in AC/DC converters for power factor correction, thanks to its enhanced harmonic reduction and improved stability of the system. The parameters of LCL filter are devised based on considerations such as the system’s power, the frequency of the alternating current (AC) input, and the PWM frequency, determined through simulation and comprehensive theoretical analysis. By implementing a dual-current closed-loop control strategy, the system ensures a robust response for both the current on the AC side of the converter and the voltage on the direct current (DC) side. The analysis of the system’s performance includes rapid dynamic response, system efficiency, AC current harmonic, and DC ripple voltage. Both simulation and experimental results are presented to validate the proposed design for the LCL filter.

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A single-stage full bridgeless boost half-bridge AC/DC converter with bidirectional switch Mohamad Affan Bin Mohd Noh1, Mohd Rodhi Bin Sahid2, Vinesh Thiruchelvam3 1,3School of Engineering, Asia Pacific University of Technology & Innovation, Malaysia 1,2School of Electrical Engineering, Universiti Teknologi Malaysia, Malaysia

 International Journal of Power Electronics and Drive Systems (IJPEDS) Vol. 12, No. 4, December 2021, pp. 2336~2348 ISSN: 2088-8694, DOI: 10.11591/ijpeds.v12.i4.pp2336-2348 

A single-stage full bridgeless boost half-bridge AC/DC converter with bidirectional switch Mohamad Affan Bin Mohd Noh1, Mohd Rodhi Bin Sahid2, Vinesh Thiruchelvam3 1,3School of Engineering, Asia Pacific University of Technology & Innovation, Malaysia 1,2School of Electrical Engineering, Universiti Teknologi Malaysia, Malaysia 

 ABSTRACT

 Article history: Received Mar 22, 2021 Revised Oct 18, 2021 Accepted Oct 25, 2021 This paper proposed an isolated full bridgeless single stage alternating current-direct current (AC-DC) converter. The proposed converter integrates the operation of a pure bridgeless power factor correction with input boost inductor cascaded with center-tap transformer and half bridge circuit. In addition, the bidirectional switch can be driven with single control signal which further simplifies the controller circuit. It was proven that this converter reduced the total number of components compared to some conventional circuit and semi-bridgeless circuit topologies. The circuit operation of the proposed circuit was then confirmed with the small signal model, large signal model, circuit simulation and then verified experimentally. It was designed and tested at 115 Vac, 50 Hz of input supply, and 20 Vdc output voltage with maximum output power of 100 W. In addition, the crossover distortion at the input current was minimized at high input line frequency.

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Power Electronics Technology] Xi'an Jiaotong University丨Course ware Included [6.1.1]--AC voltage regulation circuit AC-AC CONVERTER-PART1-【电力电子技术】西安交通大学丨含课件 [6.1.1]--交流调压电路与其他交流电力控制电路-1

 

Paralelismo de inversores de tensão aplicado a Nobreaks: teoria, estratégias de controle e exemplo de projeto-Autor: Telles B. Lazzarin Ano: 2012 - INSTITUTO FEDERAL SANTA CATARINA-BRASIL

 EXCELENTE APORTE CIENTIFICO DO DR. TELLES B. LAZZARIN UM LIVRO ESPECIALMENTE UTIL PARA ESTUDANTES,ENGENHEIROS DE GRADUAÇÃO E POS-GRADUAÇÃO DE ENGENHARIA ELETRICA E ELETRÔNICA

President of the Brazilian Association of Power Electronics (SOBRAEP) Coordinator of the Postgraduate Program in Electrical Engineering at UFSC (PPGEEL) Professor at the Federal University of Santa Catarina (UFSC) Universidade Federal de Santa Catarina Universidade Federal de Santa Catarina Santa Catarina, Brazil.

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https://www.ifsc.edu.br/documents/30701/523474/Paralelismo+de+Inversores+de+Tens%C3%A3o.pdf/91102ec6-4064-b5c7-05f2-3bfa092f0cdc

An Active AC Grid to DC Microgrid Interface Using a Bidirectional Bridgeless Flyback Converter Pablo J. Quintana-Barcia*, Jorge Garcia, Manuel Rico-Secades and Emilio L. Corominas University of Oviedo, Department of Electrical, Electronic, Computers and Systems Engineering, Spain

 An Active AC Grid to DC Microgrid Interface Using a Bidirectional Bridgeless Flyback Converter Pablo J. Quintana-Barcia*, 

 Abstract The usage of power electronics in power systems is one of the key techniques for boosting the development of microgrids. Particularly, in the case of public lighting systems, power electronics converters are applied to both the LED driving stage and the grid interfacing stage. From the point of view of the grid, the latter stage usually behaves as a high power factor (PF) load. However, recent trends in these systems imply a manifold of different storage and renewable energy microgeneration units connected to the DC bus of each street lamp. All together are usually known as lighting smartgrids. The present work aims for keeping the DC bus stable, injecting or extracting energy whereas maintaining high PF with respect to the AC grid. This idea is performed by means of a power droop control that provides the current reference to the grid-tie power converter: a bidirectional bridgeless discontinuous conduction mode (DCM) Flyback converter. This paper defines, explains and implements a power droop control as well as a novel unified switching pattern for the bidirectional DCM Flyback converter, suitable for both inverter and rectifier operating modes. Another contribution is that the proposed switching pattern enables for a smooth transition between these modes. The proposed strategy provides the pulses for every switch at the interfacing stage in the adequate sequence, thus simplifying the design and implementation of the power and control stages. The proposed switching pattern is validated through experimental results.

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https://www.scitechnol.com/peer-review/an-active-ac-grid-to-dc-microgrid-interface-using-a-bidirectional-bridgeless-flyback-converter-aqU1.php?article_id=6749