Presentation is loading. Please wait.

Presentation is loading. Please wait.

Self-Oscillating Converters By: Andrew Gonzales EE136.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Self-Oscillating Converters By: Andrew Gonzales EE136."— Presentation transcript:

1 Self-Oscillating Converters By: Andrew Gonzales EE136

2 INTRODUCTION  General Operating Principle  How the circuits work  Transformer Design for Converter

3 General Operating Principle  Switching action –Maintained by positive feedback from a winding on the main transformer.  Frequency –Controlled either by saturation of the main or subsidiary transformer –Controlled by a drive clamping action

4 Single transformer two transistor converter

5 Single Transformer Converter

6 Transformer Design (Step 1) Core Size  No fundamental equation linking transformer size to power rating.  Use nomograms provided by manufacturers to pick core size

7 Transformer Design (Step 2) Primary Turns  Assuming the following parameters:  Frequency = 30 kHz (½ period t = 16.5  s)  Core area A e 20.1 mm­ 2  Supply Voltage V cc 100 V  Flux density swing DB 250 mT  N p = = 330 turns

8 Transformer Design (Step 3) Feedback and Secondary turns  We want the feedback voltage to be at least 3 V to make sure we have an adequate feed back factor for the fast switching of Q1.  N fb = = 9.9 turns The secondary voltage should be 12.6 V because we want the output voltage to be 12 V and there is a 0.6 V diode loss.  N s = = 42 turns

9 Transformer Design (Step 4) Primary current  Assuming 70% efficiency and output power of 3 W, our input power should be 4.3 W. Which gives the mean input current at V cc = 100 V to be I m = = 43 mA  The peak current can be calculated as  I peak = 4 x I mean = 172 mA  The actual collector current must exceed this calculated mean current by at least 50% to make sure that the diode D2 remains in conduction during the complete flyback period. I p = 1.5 x I peak = 258 mA.

10 Transformer Design (Step 5) Core Gap  2 ways to calculate core gap –Empirical method –By Calculation and Published data  Empirical method Use a temporary gap and and operate with a dummy load at the required power. Adjust the gap for the required period.

11 Transformer Design (Step 5) Core Gap (cont.)  By Calculation and Published Data We first calculate the required inductance of the transformer using the following formula: L p = = 6.4mH We can then use this value to calculate the A L factor (nH/turn 2 ) A L = = 59 nH/turn

12 Transformer Design (Step 5) Core gap (cont.)  From the graph we can determine the core gap at A L = 59 nH

13 Conclusion  Applications –Auxiliary power for larger power converters –Stand-by power source in off line power supplies  Advantages –Low cost, simplicity, and small size  Disadvantages –Frequency instability due to changes in the magnetic properties of the core, load or applied voltage

Download ppt "Self-Oscillating Converters By: Andrew Gonzales EE136."

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,

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,
High Frequency Saturable Reactor

High Frequency Saturable Reactor
Inductors and Chokes In Switch mode Supplies

Inductors and Chokes In Switch mode Supplies
Dr. Ali M. Eltamaly King Saud University

Dr. Ali M. Eltamaly King Saud University
DC Choppers 1 Prof. T.K. Anantha Kumar, E&E Dept., MSRIT

DC Choppers 1 Prof. T.K. Anantha Kumar, E&E Dept., MSRIT
Switched-Mode DC Power Supplies Five configurations –Flyback –Forward –Push-pull –Half Bridge –Full-Bridge Operate at high frequencies –Easy to filter.

Switched-Mode DC Power Supplies Five configurations –Flyback –Forward –Push-pull –Half Bridge –Full-Bridge Operate at high frequencies –Easy to filter.
EE 136 Project Presentation

EE 136 Project Presentation
Lecture 8 Power Amplifier (Class A)

Lecture 8 Power Amplifier (Class A)
Switchmode Transformer Design By: Rizwan Khalid. Outline Introduction Theory Pexpert simulations Applications Conclusion.

Switchmode Transformer Design By: Rizwan Khalid. Outline Introduction Theory Pexpert simulations Applications Conclusion.
Magnetic Design Considerations Transformers –Used to step-up or step-down voltages Inductors –Storage during energy transfer –Carries a DC current while.

Magnetic Design Considerations Transformers –Used to step-up or step-down voltages Inductors –Storage during energy transfer –Carries a DC current while.
Bridge Converters and Faraday Screens By Paul Wilson.

Bridge Converters and Faraday Screens By Paul Wilson.
EE 136 Final Presentation Professor Dr. Zhou Presented by: Cynthia David.

EE 136 Final Presentation Professor Dr. Zhou Presented by: Cynthia David.
Duty Ratio Controlled Push Pull Converter

Duty Ratio Controlled Push Pull Converter
EE 136 Project CURRENT TRANSFORMERS By Pramod Haridass.

EE 136 Project CURRENT TRANSFORMERS By Pramod Haridass.
Transformers.

Transformers.
Noadswood Science, 2013.  To understand how step-up and step-down transformers work Monday, August 10, 2015.

Noadswood Science,  To understand how step-up and step-down transformers work Monday, August 10, 2015.
POWER AMPLIFIER CHAPTER 4.

POWER AMPLIFIER CHAPTER 4.
Transformers  A transformer is used to change alternating p.d.s. from a lower to a higher voltage or vice versa. A simple transformer consists of two.

Transformers  A transformer is used to change alternating p.d.s. from a lower to a higher voltage or vice versa. A simple transformer consists of two.
Chapter 2 Transformers.

Chapter 2 Transformers.
1 Fly-back Converter fall 2012. 2 Basic Topology of a Fly-back Converter.

1 Fly-back Converter fall Basic Topology of a Fly-back Converter.

Similar presentations

Ads by Google