ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 37 Zero-voltage transition converters The phase-shifted full bridge converter.

Slides:



Advertisements
Similar presentations
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,
Advertisements

DC Choppers 1 Prof. T.K. Anantha Kumar, E&E Dept., MSRIT
Three Phase Controlled Rectifiers
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 19 Averaging: Charge Arguments Averaging a terminal current of a (resonant)
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 19 State plane trajectory of a parallel-loaded tank circuit.
Quasi-square-wave ZVS converters
Switched-Mode DC Power Supplies Five configurations –Flyback –Forward –Push-pull –Half Bridge –Full-Bridge Operate at high frequencies –Easy to filter.
Chapter 20 Quasi-Resonant Converters
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 37 Active clamp circuits Can be viewed as a lossless voltage-clamp snubber.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lectures The conventional forward converter Max v ds = 2V g + ringing Limited.
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.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 19.
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.
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 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
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.
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 19: Resonant Conversion Chapter 19 Resonant Conversion Introduction 19.1Sinusoidal analysis of resonant converters.
ECE 442 Power Electronics1 Step Up Converter Close the switch to store energy in the inductor L Open the switch to transfer the energy stored in L to the.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 23 Series resonant converter.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 23 Operating Modes of the Series Resonant Converter Lecture 23 Resonant.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 23 Steady state solution of state plane Two possible trajectories for given.
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.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 23 Announcements Correction to HW #2, Problem 19.3 solution Clarification.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 23 Next Homework Assignment Problem 1 Conventional hard-switched flyback.
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.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lectures Active clamp forward converter.
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 26 Discontinuous conduction mode (DCVM) Occurs at heavy load and low output.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 19 Time-Domain Analysis of Resonant and Soft-Switching Converters Principles.
Controlled Rectifiers
Power Electronics and Drives (Version ) Dr. Zainal Salam, UTM-JB 1 Chapter 3 DC to DC CONVERTER (CHOPPER) General Buck converter Boost converter.
Zero Voltage Switching Quasi-resonant Converters
Recall Lecture 6 Rectification – transforming AC signal into a signal with one polarity Half wave rectifier Full Wave Rectifier Center tapped Bridge Rectifier.
Chapter 3 DC to DC Converters
19.4 Load-dependent properties of resonant converters
Diode Rectifier Circuits Section 4.5. In this Lecture, we will:  Determine the operation and characteristics of diode rectifier circuits, which is the.
Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion 19.3 Soft switching Soft switching can mitigate some of the mechanisms of switching.
Final Year Project: Wireless Power Transfer For Mobile Phone Kong Chin Hung D Supervisor: Dr. Wei-Nong FU.
ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 19 Time-Domain Analysis of Resonant and Soft-Switching Converters Principles.
Half-wave Rectifier.
Zero-current Switching Quasi-resonant Converters
Chapter 3 Power Electronic Circuits
Power Electronics Professor Mohamed A. El-Sharkawi
General Solution for the Steady-State Characteristics of the Series Resonant Converter Type k CCM Mode index k and subharmonic number 
Buck-derived full-bridge converter
Resonant and Soft-Switching Techniques in Power Electronics ECEN 5817
Recall Lecture 6 Rectification – transforming AC signal into a signal with one polarity Half wave rectifier Full Wave Rectifier Center tapped Bridge Rectifier.
ECEN 5817 Housekeeping I plan on indicating for each lecture(s) of this year the equivalent lecture(s) from Spr. 06. This will make it easy if you choose.
Diode rectifiers (uncontrolled rectifiers)
Power Electronics Lecture -11 Single Phase Controlled Rectifier.
AC modeling of converters containing resonant switches
Chapter 5 Isolated Switch-Mode dc-to-dc Converters
Presentation transcript:

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 1 Lecture 37 Zero-voltage transition converters The phase-shifted full bridge converter Buck-derived full-bridge converter Zero-voltage switching of each half- bridge section Each half-bridge produces a square wave voltage. Phase-shifted control of converter output A popular converter for server front- end power systems Efficiencies of 90% to 95% regularly attained Controller chips available

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 2 Lecture 37 Phase-shifted control Approximate waveforms and results (as predicted by analysis of the parent hard- switched converter)

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 3 Lecture 37 Actual waveforms, including resonant transitions

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 4 Lecture 37 Result of analysis Basic configuration: full bridge ZVT Phase shift  assumes the role of duty cycle d in converter equations Effective duty cycle is reduced by the resonant transition intervals Reduction in effective duty cycle can be expressed as a function of the form FP ZVT (J), where P ZVT (J) is a negative number similar in magnitude to 1. F is generally pretty small, so that the resonant transitions do not require a substantial fraction of the switching period Circuit looks symmetrical, but the control, and hence the operation, isn’t. One side of bridge loses ZVS before the other.

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 5 Lecture 37 ZVT Analysis

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 6 Lecture 37 Interval 1

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 7 Lecture 37 Normalized state plane

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 8 Lecture 37 Solution of state plane

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 9 Lecture 37 Subintervals 2 and 3

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 10 Lecture 37 Subinterval 4

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 11 Lecture 37 Subinterval 5 ZVS: output current charges C leg without requiring J > 1

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 12 Lecture 37 Subinterval 6 Current i c circulates around primary-side elements, causing conduction loss This current arises from stored energy in L c The current is needed to induce ZVS during next subinterval To maxzimize efficiency, minimize the length of this subinterval by choosing the turns ratio n such that M = V/nV g is only slightly less than 1

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 13 Lecture 37 Subintervals 7 to 11 Subintervals 7 to 11 and 0 are symmetrical to subintervals 1 to 6 Complete state plane trajectory:

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 14 Lecture 37 Averaging

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 15 Lecture 37 Phase-shift control

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 16 Lecture 37 Phase shift control

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 17 Lecture 37 Phase shift control: result

ECEN 5817 Resonant and Soft-Switching Techniques in Power Electronics 18 Lecture 37 Effect of ZVT: reduction of effective duty cycle

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

© 2024 SlidePlayer.com Inc. All rights reserved.