Soft-Switching DC-DC Converter Is to shape the voltage or the current waveform by creating a resonant condition to: Force the voltage across the switching.

Slides:



Advertisements
Similar presentations
Bi-directional DC-DC converter with Soft Switching Cell
Advertisements

1 Series Resonant Converter with Series-Parallel Transformers for High Input Voltage Applications C-H Chien 1,B-R Lin 2,and Y-H Wang 1 1 Institute of Microelectronics,
Ch6 DC-DC Converters 6-1 Linear voltage regulators Fig. 6.1 Adjustingbasecurrent, => linear DC-DC converter orlinear regulator Thetransistor operates in.
Electronic Engineering Final Year Project 2008 By Claire Mc Kenna Title: Point of Load (POL) Power Supply Design Supervisor: Dr Maeve Duffy.
Introduction to DC-DC Conversion – Cont.
CIRCUITS, DEVICES, AND APPLICATIONS Eng.Mohammed Alsumady
1 Research and Development of Machine Drives and Power Conditioning and its Development for Electric Vehicles From 1999 to 2009 Prof. Eric Cheng Department.
Quasi-square-wave ZVS converters
Chapter 20 Quasi-Resonant Converters
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 37 Zero-voltage transition converters The phase-shifted full bridge converter.
Fundamentals of Power Electronics 1 Chapter 20: Quasi-Resonant Converters 20.2 Resonant switch topologies Basic ZCS switch cell: SPST switch SW : Voltage-bidirectional.
1 Parameters for various resonant switch networks.
1 Power Electronics Edited by Prof. Tsai-Fu Wu September 1, 2004.
Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion Reduction of power converter size through increase of switching frequency Increasing.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 37 Soft-switching converters with constant switching frequency With two.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lectures Zero-voltage transition converters The phase-shifted full bridge.
1 Quasi-square-wave ZVS converters A quasi-square-wave ZVS buck Resonant transitions but transistor and diode conduction intervals are similar to PWM Tank.
Chapter 20 Quasi-Resonant Converters
Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion 19.4 Load-dependent properties of resonant converters Resonant inverter design objectives:
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 23 General Solution for the Steady-State Characteristics of the Series.
Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion I plan on indicating for each lecture(s) of this year the equivalent lecture(s) from.
Soft-switching converters with constant switching frequency
Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion 19.4 Load-dependent properties of resonant converters Resonant inverter design objectives:
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 36 Midterm Exam Averages: all students 78.1 on-campus students 78.3 off-campus.
Fundamentals of Power Electronics 1 Chapter 20: Quasi-Resonant Converters Chapter 20 Quasi-Resonant Converters Introduction 20.1The zero-current-switching.
Parallel resonant dc-dc converter
Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion Operation of the full bridge below resonance: Zero-current switching Series.
Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion Chapter 19 Resonant Conversion Introduction 19.1Sinusoidal analysis of resonant converters.
1 Manipulation to standard state-space form Eliminate X s1 and X s2 from previous equations. Result is: Collect terms, and use the identity µ + µ’ = 1:
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 23 Operating Modes of the Series Resonant Converter Lecture 23 Resonant.
Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion Upcoming Assignments Preparation for Lecture 2: Read Section 19.1, Sinusoidal analysis.
Fundamentals of Power Electronics 1 Chapter 20: Quasi-Resonant Converters Chapter 20 Quasi-Resonant Converters Introduction 20.1The zero-current-switching.
Power Electronics Chapter 8 Soft-Switching Techniques.
Copyright by UNIT III DC Choppers 4/17/2017 Copyright by
Chapter 8 Switching Power Supplies
Chapter 20 Quasi-Resonant Converters
Fundamentals of Power Electronics 1 Chapter 20: Quasi-Resonant Converters Chapter 20 Quasi-Resonant Converters Introduction 20.1The zero-current-switching.
Resonant and Soft-Switching Techniques in Power Electronics ECEN 5817
Waveforms of the half-wave ZCS quasi-resonant switch cell
Buck-derived full-bridge converter
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 19 Time-Domain Analysis of Resonant and Soft-Switching Converters Principles.
Instrumentation & Power Electronics
POWER SUPPILES LECTURE 20.
By: Professor Wilmer Arellano
Power Electronics Notes 07B Some Real-World Issues in DC/DC Converters
1 Institute of Mechatronics and Information Systems Control and Driving Systems.
DC-DC Fundamentals 1.3 Switching Regulator
1 © Alexis Kwasinski, 2012 Power electronic interfaces Power electronic converters provide the necessary adaptation functions to integrate all different.
PFC ( Single Stage ) 36.
Power Electronics Notes 07A Introduction to DC/DC Converters
WEEK 7 DC SWITCHING POWER SUPPLIES, PART II 1. EXPECTATIONS Describe the supply isolation characteristics afforded by transformers. Draw basic forward,
Switching DC Power Supplies
Power Electronics and Drives (Version ) Dr. Zainal Salam, UTM-JB 1 Chapter 3 DC to DC CONVERTER (CHOPPER) General Buck converter Boost converter.
Switching Power Supplies Week 6
Pål AndreassenTore M. Undeland NORPIE 2004 Power device selection and a comparative study of transistor technologies for a Zero Voltage Switching.
Zero Voltage Switching Quasi-resonant Converters
Chapter 6 Soft-Switching dc-dc Converters Outlines
A New Full-Protected Control Mode to Drive Piezoelectric Transformers in DC-DC Converters J.A.M. Ramos, M.A.J. Prieto, F.N. Garica, J.D. Gonzalez, F.M.F.
A Unified Model for the ZVS DC-DC Converters With Active Clamp
1 SEA_uniovi_CC1_00 Lección 4 Teoría básica de los convertidores CC/CC (I) (convertidores con un único transistor) Diseño de Sistemas Electrónicos de Potencia.
LARGE VALUE X2Y® IN DC-DC CONVERTERS All commonly deployed DC-DC converter topologies:  Buck, boost, flyback, SEPIC (Cuk topology is rare) have at least.
Power PSoC 101: Intro to Power Converters. Section 1: Power Converter Overview Course Outline Section 2: Power Converter Circuit Elements Section 3: Operating.
ParameterBuckBoostBuck/Boost Pulse Current InputOutput Both Topology Impacts on Component Stress.
PARISUTHAM INSTITUTE OF TECHNOLOGY AND SCIENCE
Introduction to DC-DC Conversion – Cont.
IEEE TRANSACTIONS ON POWER ELECTRONICS, VOL. 28, NO. 11, NOVEMBER 2013 Yuanmao Ye and K. W. E. Cheng A Family of Single-Stage Switched-Capacitor–Inductor.
Switch Mode Power Supply(SMPS) BY: Arijit Acharya NETAJI SUBHASH ENGINEERING COLLEGE M.tech(P.S.) Roll No - 1.
Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion 19.3 Soft switching Soft switching can mitigate some of the mechanisms of switching.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 19 Time-Domain Analysis of Resonant and Soft-Switching Converters Principles.
DC-DC Converter.
Presentation transcript:

Soft-Switching DC-DC Converter Is to shape the voltage or the current waveform by creating a resonant condition to: Force the voltage across the switching device to drop to zero before turning it ON  Zero-Voltage Switching (ZVS) Force the current through the switching device to drop to zero before turning it OFF  Zero-Current Switching (ZCS)

Overview Many soft-switching dc-dc converter families were introduced in the open literature The objectives of these topologies are to develop high switching frequency converters with high power density and high efficiency This was accomplished by adding additional components to the power stage. Steady-state analysis tend to be time consuming. Provided little insight into the converter switching-cell operation.

Hard-Switching and Soft-Switching Hard-Switching Zero-Current Switching Zero-Voltage Switching

Why Soft-Switching? Reduce switching losses especially at high switching frequencies Increase the power density, since the size and weight of the magnetic components is decreased by increasing the operating frequency Reduce the Electromagnetic Interference (EMI)

Conventional DC-DC Converters (Hard-Switching) Buck Boost Buck-Boost Cuk ZetaSepic

Switching-Cell Sharing All the Conventional DC-DC Converters shares the same switching-cell With different orientation of the cell in a specific converter The Conventional DC-DC Switching-Cell

Analyzed Soft-Switching Cells

Zero-Voltage-Switching Quasi-Resonant ZVS-QRC Switching-CellZVS-QRC Cell Basic Switching-Waveforms

ZVS-QRC Family ZVS-QRC Buck ZVS-QRC Boost ZVS-QRC Buck-Boost ZVS-QRC Cuk ZVS-QRC ZetaZVS-QRC Sepic

Zero-Current-Switching Quasi-Resonant ZCS-QRC Switching-CellZCS-QRC Cell Basic Switching-Waveforms

ZCS-QRC Family ZCS-QRC BuckZCS-QRC Boost ZCS-QRC Buck-BoostZCS-QRC Cuk ZCS-QRC ZetaZCS-QRC Sepic

ero-Current-Transition PWM Cell ZCT-PWM Switching-Cell ZCT-PWM Cell Basic Switching-Waveforms

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2024 SlidePlayer.com Inc. All rights reserved.