Design of Mazzilli’s Zero Voltage Switching (ZVS) Circuit as Plasma Glow Discharge Generator

Purification water has several methods; one of them is the plasma generation. The circuit used to generate plasma is Zero Voltage Switching (ZVS), where its use uses the resonance circuit concept. The main category to generate plasma glow discharge is the circuit should generate high voltage output with a current range from 10-6 A to 1 A. In this study, when ZVS connected to the flyback converter with an input voltage of 12 V, the output values of 11 kV and 11 μA were obtained. In comparison, if ZVS was not connected to the flyback converter, the circuit is less stable, and the output value is weak because the output values only reach 8.97 kV and 8.97 μA. For maximum output, the ZVS circuit should be connected to the converter circuit due to the flyback converter can repair and strengthen the voltage. The flyback converter circuit is affected by the diode and capacitance effects. The effect of using capacitors in a flyback converter circuit is when the capacitance is too low, the ripple will form. Then when capacitance reaches a specific value, the ripple will decrease, and the voltage graph will approach a straight line. Hence the use of components in the ZVS and the flyback converter need to be considered because it affects how the release of plasma glow discharge will form

Synchronous Flyback Converter Coupled with Fuzzy Logic Control Efficiently Controls a Serially Connected VRLA Battery String

AbstractThis paper presents a high efficiency charge equalization system for balancing the energy in a serially connected, valveregulated, lead acid battery string using a synchronous flyback converter. Each flyback converter was coupled through a DC-link bus in order to increase the overall energy transfer efficiency of the system and to eliminate the problem of unbalanced charging of the batteries. To ensure that the charge equalization system operated smoothly and safely charged the batteries, a fuzzy logic controller was used in the control section of the system. The validity of this approach was confirmed by computer simulation and by experimentation. The efficiency of this synchronous flyback converter was 78.9 percent, better by approximately 1.07 percentthan the conventional flyback converter

AC-DC PFC Converter Using Combination of Flyback Converter and Full-bridge DC-DC Converter

This paper presents a combination of power factor correction converter using Flyback converter and Full-bridge dc-dc converter in series connection. Flyback converter is operated in discontinuous conduction mode so that it can serve as a power factor correction converter and meanwhile Full-bridge dc-dc converter is used for dc regulator. This converter system is designed to produce a 86 Volt of output voltage and 2 A of output current. Both simulation and experiment results show that the power factor of this converter achieves up to 0.99 and meets harmonic standard of IEC61000-3-2.Keywords: Flyback Converter, Full-bridge DC-DC Converter, Power Factor Correction

An optimized tuned mass damper/harvester device

Much work has been conducted on vibration absorbers, such as tuned mass dampers (TMD), where significant energy is extracted from a structure. Traditionally, this energy is dissipated through the devices as heat. In this paper, the concept of recovering some of this energy electrically and reuse it for structural control or health monitoring is investigated. The energy-dissipating damper of a TMD is replaced with an electromagnetic device in order to transform mechanical vibration into electrical energy. That gives the possibility of controlled damping force whilst generating useful electrical energy. Both analytical and experimental results from an adaptive and a semi-active tuned mass damper/harvester are presented. The obtained results suggest that sufficient energy might be harvested for the device to tune itself to optimise vibration suppression

One-Quadrant Switched-Mode Power Converters

This article presents the main topics related to one-quadrant power converters. The basic topologies are analysed and a simple methodology to obtain the steady-state output-input voltage ratio is set out. A short discussion of different methods to control one-quadrant power converters is presented. Some of the reported derived topologies of one-quadrant power converters are also considered. Some topics related to one-quadrant power converters such as synchronous rectification, hard and soft commutation, and interleaved converters are discussed. Finally, a brief introduction to resonant converters is given.Comment: 25 pages, contribution to the 2014 CAS - CERN Accelerator School: Power Converters, Baden, Switzerland, 7-14 May 201

High voltage supply for charging output capacitor by using flyback controlled with IC LT3751

Napravljena je analiza rada zapornog pretvarača. Izrađen je zaporni pretvarač i testiran je. Upravljački dio realiziran je integriranim krugom LT3751. Izrađeni zaporni pretvarač se koristi za brzo visokonaponsko punjenje kondenzatora.An analysis of flyback converter was done. A flyback converter was made and it was tested. The essence of his controling system is integrated circuit LT3751. That flyback converter is designed for fast high voltage capacitor charging