• Title/Summary/Keyword: Passive lossless

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A Passive Lossless Soft-Switching Single Inductor Dual Buck Full-Bridge Inverter

  • Hong, Feng;Wu, Yu;Ye, Zunjing;Ji, Baojian;Zhou, Yufei
    • Journal of Power Electronics
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    • v.18 no.2
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    • pp.364-374
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    • 2018
  • A novel passive lossless soft-switching single inductor dual buck full-bridge inverter (PLSSIDBFBI) is presented in this paper. To accomplish this, a passive lossless snubber circuit is added to a dual buck full-bridge inverter. Therefore, the advantages of the dual buck full-bridge inverter are included in the proposed inverter, and the inverter has just one filter inductor, which can decrease the system volume and improve the integration. In addition, the passive lossless snubber circuit achieves soft-switching by its own resonance, and all of the energy stored in the passive lossless snubber circuit can be transferred to load. A comparison between eight topologies is performed in this paper, and the analysis shows that the proposed soft-switching inverter topology has high reliability and efficiency. Finally, experimental results obtained with a 1 kW prototype verify the theoretical analysis and demonstrate the prominent characteristics of a reduced switching loss and improved efficiency.

A new lossless snubber for DC-DC converters with energy transfer capability

  • Esfahani, Shabnam Nasr;Delshad, Majid;Tavakoli, Mohhamad Bagher
    • Smart Structures and Systems
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    • v.25 no.3
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    • pp.385-391
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    • 2020
  • In this paper, a new passive lossless snubber circuit with energy transfer capability is proposed. The proposed lossless snubber circuit provides Zero-Current Switching (ZCS) condition for turn-on instants and Zero-Voltage Switching (ZVS) condition for turn-off instants. In addition, its diodes operate under soft switching condition. Therefore, no significant switching losses occur in the converter. Since the energy of the snubber circuit is transferred to the output, there are no significant conduction losses. The proposed snubber circuit can be applied on isolated and non-isolated converters. To verify the operation of the snubber circuit, a boost converter using the proposed snubber is implemented at 70W. Also, the measured conducted Efficiency Electromagnetic Interference (EMI) of the proposed boost converter and conventional ones are presented which show the effects of proposed snubber on EMI reduction. The experimental results confirm the presented theoretical analysis.

A Study on the High-Efficiency, High-Power-Factor AC/DC Boost Converter Using a Passive Energy Recovery Snubber (에너지 재생 수동 스너버를 적용한 고효율, 고역률 AC/DC Boost 컨버터에 관한 연구)

  • Ryu, Jong-Gyu;Kim, Yong;Baek, Soo-Hyun;Lee, Kyu-Hoon;Jung, Myung-Sub
    • Proceedings of the KIEE Conference
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    • 2005.04a
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    • pp.168-171
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    • 2005
  • The conception of the passive lossless snubber with the simpler is presented. Thus a necessity condition of the passive lossless soft switching converter with the simplest topology is directed. A novel passive regenerative snubber called soft snubber applied to a hard switching converter is proposed. The passive snubber consists of a snubber inductor, two snubber rectifiers, and a snubber capacitor. The losses are reduced by inserting a snubber inductor in the series path of the rectifier during it's turn off. It is so simple that can make energy reset or capacitor discharged directly without producing any current circulation. To show the superiority of this converter is verified through the experiment with a 640W, 100kHz prototype converter.

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Passive Lossless Snubbers Using the Coupled Inductor Method for the Soft Switching Capability of Boost PFC Rectifiers

  • Kim, Ho-Sung;Baek, Ju-Won;Ryu, Myung-Hyo;Kim, Jong-Hyun;Jung, Jee-Hoon
    • Journal of Power Electronics
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    • v.15 no.2
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    • pp.366-377
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    • 2015
  • In order to minimize switching losses for high power applications, a boost PFC rectifier with a novel passive lossless snubber circuit is proposed. The proposed lossless snubber is composed of coupled inductors merged into a boost inductor. This method compared with conventional methods does not need additional inductor cores and it reduces extra costs to implement a soft switching circuit. Especially, the proposed circuit can reduce the reverse recovery current of output diode rectifiers due to the coupling effect of the inductor. During turn-on and turn-off operating modes, the proposed PFC converter operates under soft switching conditions with high power conversion efficiency. In addition, the performance improvement and analysis of the operating effects of the coupled inductors were also presented and verified with a 3.3 kW prototype rectifier.

Soft-Switching PWM Boost Chopper-Fed DC-DC Power Converter with Load Side Auxiliary Passive Resonant Snubber

  • Nakamura, Mantaro;Ogura, Koki;Nakaoka, Mutsuo
    • Journal of Power Electronics
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    • v.4 no.3
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    • pp.161-168
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    • 2004
  • This paper presents a new circuit topology of high-frequency soft switching commutation boost type PWM chopper-fed DC-DC power converter with a loadside auxiliary passive resonant snubber. In the proposed boost type chopper-fed DC-DC power converter circuit operating under a principle of ZCS turn-on and ZVS turn-off commutation, the capacitor and inductor in the auxiliary passive resonant circuit works as the lossless resonant snubber. In addition to this, the voltage and current peak stresses of the power semiconductor devices as well as their di/dt or dv/dt dynamic stress can be effectively reduced by the single passive resonant snubber treated here. Moreover, it is proved that chopper-fed DC-DC power converter circuit topology with an auxiliary passive resonant snubber could solve some problems on the conventional boost type hard switching PWM chopper-fed DC-DC power converter. The simulation results of this converter are illustrated and discussed as compared with the experimental ones. The feasible effectiveness of this soft witching DC-DC power converter with a single passive resonant snubber is verified by the 5kW, 20kHz experimental breadboard set up to be built and tested for new energy utilization such as solar photovoltaic generators and fuel sell generators.

Design of power amplifier and antenna for wireless power transmission in 125kHz (125kHz대에서 무선전력전송을 위한 전력증폭기와 송수신 Antenna 설계)

  • Im, Sang-Uk;Kim, Yong-Sang;Kim, Do-Hun;Kim, Yang-Mo
    • Proceedings of the KIEE Conference
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    • 2003.11b
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    • pp.27-30
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    • 2003
  • Wireless power transmission system is one of the very interesting field not only in a technical and economical point of view but also that people are still trying to realize lossless power transmission. This paper has a purpose on the efficient power transmission at the passive type ICcard by using wireless power transmission system. The most difficult but important part of the passive type RF-ID system is building the system that supplies power from Reader-antenna to IDcard-antenna. To check what is the most efficient way to deliver power depending on what kind of specifications of the power-amp in reader, antenna and antenna in IDcard is for operating IDcard circuit efficiently receiving the power from reader-antenna. For this, we used 125kHz sinewave for RF signal as a basic specification, power-amp : OP-Amp for amplifying signal and AB Class push-pull power-amp for amplifying power, loop type antenna.

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The new Soft-Switching AC-DC Boost Type Converter using Lossless Snubber (무손실 스너버회로를 이용한 새로운 소프트 스위칭 AC-DC승압형 컨버터)

  • Mun Sang-Pil;Suh Ki-Young;Kim Young-Mun
    • Proceedings of the KIEE Conference
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    • summer
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    • pp.1226-1228
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    • 2004
  • A novel lossless passive snubber is proposed for soft switching the boost type converters. The proposed snubber does not use any auxiliary switches. but uses two identical snubber capacitors which are charged in parallel at turn off of the main switch and discharged in series at turn on automatically, and the discharged energy is recovered effectively (more than $95[\%]$ recovery) into the output capacitor. Thus, the snubber provides zero voltage switching for the converter main switch, reducing both the turn off losses and the electromagnetic interference(EMI) noise, whitch improves the converter performance. The experimental results of a 20[kHz] 600[W] DC-DC boost converter and a single-phase AC-DC boost rectifier with the new snubber are presented.

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High Efficiency Lossless Snubber for Photovoltaic Maximum Power Point Tracker (태양광 최대 전력 추종기를 위한 고효율 무손실 스너버)

  • Jang, Du-Hee;Kang, Jeong-Il;Han, Sang-Kyoo
    • The Transactions of the Korean Institute of Power Electronics
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    • v.18 no.5
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    • pp.485-491
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    • 2013
  • A new passive lossless snubber for boost converter based on magnetic coupling is proposed. It is composed of a winding coupled with boost inductor, one snubber inductor, two snubber capacitor and three additional diodes. Especially, the snubber inductor can not only limit the reverse recovery current of output diode but also minimize switch turn-on losses greatly. Moreover, all of the energy stored in the snubber is transferred to the load in the manner of resonance. To confirm the validity of proposed system, theoretical analysis, design consideration, and verification of experimental results are presented.

High-Power-Factor Boost Rectifier with a Passive Lossless Snubber (무손실 수동스너버를 갖는 고역율 부스트 정류기)

  • 김만고
    • Journal of Advanced Marine Engineering and Technology
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    • v.22 no.5
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    • pp.617-625
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    • 1998
  • A passive energy recovery snubber for high-power-factor boost rectifier, in which the main switch is implemented with a MOSFET, is described in terms of the equivalent circuits that are operational during turn-on and turn-off sequences. These equivalent circuits are analyzed so that the overshoot voltage across the main switch, the snubber current, and the turn-off transition time can be predicted analytically. From these results, the normalized overshoot voltage is reduced to 1 as $_W2T_on$ varies from zero to $\pi$/2, and then it is fIxed at 1 for $_W2T_on$> $\pi$/2. The peak snubber inductor current is directly proportional to the input current. The turn-offtransition time wltoffvaries from 0 to 2.57, depending on $_W2T_on$. The main switch combined with proposed snubber can be turned on with zero current and turned off at limited voltage stress. The high-power-factor boost rectifier with proposed snubber is implemented, and the experimental results are presented to confirm the validity of proposed snubber.

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Design of Power Amplifier and Antenna for Power Transmission at RF-ID (RF-ID에서 전력전송을 위한 전력증폭기와 송수신 Antenna 설계)

  • Yim Sang-Wook;Kim Yong-Sang;Kim Yang-Mo
    • Proceedings of the KIEE Conference
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    • summer
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    • pp.1263-1265
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    • 2004
  • RF-ID system is one of the very interesting field not only in a technical and economical point of view but also that people are still trying to realize lossless power transmission. This paper has a purpose on the efficient power transmission at the passive type IDcard by using wireless power transmission system. The most difficult but important part of the passive type RF-ID system is building the system that supplies power from Reader-antenna to IDcard-antenna. To check what is the most efficient way to deliver power depending on what kind of specifications of the power-amp in reader, antenna and antenna in IDcard is for operating IDcard circuit efficiently receiving the power from reader-antenna. For this, we used 125kHz sinewave for RF signal as a basic specification, OP-amp for amplifying signal and power-amp for amplifying power, loop type antenna.

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