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.

Slides:

Advertisements

Similar presentations

DC-DC Fundamentals 1.4 Charge Pump Regulator

Advertisements

Kazi Md. Shahiduzzaman Lecturer, EEE,NUB

DC Choppers 1 Prof. T.K. Anantha Kumar, E&E Dept., MSRIT

Ch6 DC-DC Converters 6-1 Linear voltage regulators Fig. 6.1 Adjustingbasecurrent, => linear DC-DC converter orlinear regulator Thetransistor operates in.

7. Introduction to DC/DC Converters

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

Modeling conduction loss SEPIC example MOSFET R on, diode V D Averaged terminal voltages of switch network, including conduction losses:

DC-DC Switch-Mode Converters

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

AC Power Supplies Applications –Standby source for “critical” loads (computer) –Primary source when normal ac not available Uninterrupted Power Supply.

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.

Power Electronics Lecture-10 D.C to D.C Converters (Choppers)

Power Electronics Chapter 5 DC to DC Converters (Choppers)

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.

Waveforms of the half-wave ZCS quasi-resonant switch cell

DC-DC Switch-Mode Converters

Instrumentation & Power Electronics

By: Professor Wilmer Arellano

1 Institute of Mechatronics and Information Systems Control and Driving Systems.

DC-DC Fundamentals 1.3 Switching Regulator

Power Supply Design -an introduction Adapted from a Presentation By Doug Miller, SPU EE Alumnus.

Power Electronics Notes 07A Introduction to DC/DC Converters

A review of power converter topologies for wind generators

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

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.

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.

MULTILEVEL INVERTERS By Vaishnavi.

Lecture # 12&13 SWITCHING-MODE POWER SUPPLIES

PWM Dc-to-Dc Power Conversion

1 An FPGA-Based Novel Digital PWM Control Scheme for BLDC Motor Drives 學生 : 林哲偉學號 :M 指導教授 : 龔應時 IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS, VOL.

UCI Power Electronics Lab Control of A Dual-Boost Power Factor Corrector for High Power Applications Yaoping Liu and Keyue Smedley University of California,

Fundamentals of Power Electronics 1 Chapter 19: Resonant Conversion Solution of converter voltage conversion ratio M = V/V g Eliminate R e :

A NOVEL CONTROL METHOD OF DC-DC CONVERTERS Dr.M.Nandakumar Professor Department of Electrical engineering Govt. Engineering College Thrissur 1 Dept. of.

PARISUTHAM INSTITUTE OF TECHNOLOGY AND SCIENCE

Introduction to DC-DC Conversion – Cont.

Department of Electrical Engineering Southern Taiwan University of Science and Technology Robot and Servo Drive Lab. 2016/2/10 Novel PWM Technique Without.

 General description of Power Supply  Advantages/Disadvantages of SMPS  Block diagram of SMPS  Basic topologies and practical  Requirements  Various.

EE 481 Design Project 10 KVA Inverter Intro Stage DC-DC Boost Converter Greg Hopper Todd Reilly.

By: P. Liang, M. Shi, Y. Wang University of Ottawa November 24, 2006 ELG 4135 Course Project.

Switch Mode Power Supply(SMPS) BY: Arijit Acharya NETAJI SUBHASH ENGINEERING COLLEGE M.tech(P.S.) Roll No - 1.

Professor Mukhtar ahmad Senior Member IEEE Aligarh Muslim University

6/22/2016 “IN THE NAME OF ALLAH THE MOST MERCIFUL AND THE MOST BENEFICIAL”

1 ANNEXURE PROJECT TITLE : A Novel Power Management Control Strategy for Renewable Energy Power System SUBMITTED BY : N.SAHUL HAMEED V.DINESH BABO P.PURSOTHAMAN.

1 Step Input Change Response Closed-Loop Control.

A Gain/Efficiency-Improved Serial- Parallel Switched-Capacitor Step-Up DC– DC Converter IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS—I: REGULAR PAPERS, VOL.

بحث مشترك منشور فى مؤتمر دولى متخصص (منشور ، التحكيم علي البحث الكامل) B. M. Hasaneen and Adel A. Elbaset البحث التاسع 12 th International Middle East.

Department of Electrical Engineering

DOUBLE INPUT Z-SOURCE DC-DC CONVERTER

DOUBLE INPUT Z-SOURCE DC-DC CONVERTER

DOUBLE INPUT Z-SOURCE DC-DC CONVERTER

PROBLEM DEFINITION: In general, various single-input single-output dc–dc converters with different voltage gains are combined to satisfy the requirement.

IMPEDENCE - SOURCE INVERTER FOR MOTOR DRIVES

Switching DC Power Supplies

DOUBLE INPUT Z-SOURCE DC-DC CONVERTER

TE – FTIK – UHT Djogi Lubis Ir, M.A.P

Modeling of Dc-dc Boost Converter in Discontinuous Conduction Mode

DC-DC Switch-Mode Converters

Hafez Sarkawi (D1) Control System Theory Lab

Presentation transcript:

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 PWM Converters 1 Reporter: Yu-Kai Lin

Outline 2 1. Introduction 2. Configuration(New Family of SCI Converters) 3. Detailed Analysis and Design Considerations 4. Simulation and Experimental Results 5. Conclusion 6. Personal Remark

1.Introduction(1/4) 3 A family of single-stage-switched-capacitor–inductor converters with different voltage conversion features and similar structures is presented in this paper. Unlike conventional switched-capacitor/switched- inductor converters that are produced by cascade operation, all of the proposed converters are operated in single-stage mode.

1.Introduction(2/4 ) 4 The basic switched-mode dc–dc converters including (buck, boost, buck–boost, cuk, zeta, and sepic) have been used in various electronic applications due to their numerous advantages such as simple structure, good performance, high efficiency, easy design, and simple control circuit.

1.Introduction(3/4 ) 5 A small resonant inductor has been added in SC converters to eliminate the current peak, therefore, the SC converters have good performance and high efficiency as well. Even though these converters have different structures and can provide different voltage conversion ratios, they have a characteristic in common which is that all of them are multistage combination of switched- inductor cells and SC cells

1.Introduction(4/4 ) 6

2.Configuration(1/8) 7 Fig. 2. New family of SCI converters. (a) Dual-input step-up converter. (b) Single-input step-up converter. (c) Dual-input step-down converter. (d) Single-input step-down converter. (e) Inverting step-up converter.

2.Configuration(2/8) 8

2.Configuration(3/8) 9

2.Configuration(4/8) 10

2.Configuration(5/8) 11

2.Configuration(6/8) 12

2.Configuration(7/8) 13 Fig. 3. Two new members of the proposed SCI converters family. (a) High step- down SCI converter. (b) Inverting step-down SCI converter. However, there is no member in Fig. 2 that can provide high step-down and inverting step-down output levels. To compensate for the two deficiencies, two new members are developed to expand the proposed family as shown in Fig. 3.

2.Configuration(8/8) 14

3.Analysis and Design(1/4) 15

3.Analysis and Design(2/4) 16

3.Analysis and Design(3/4) 17

3.Analysis and Design(4/4) 18

4.Simulation(1/5) 19

4.Simulation(2/5) 20

4.Simulation(3/5) 21 duty ratio is 0.5. (a) Simulated results. (b) Experimental results.

4.Simulation(4/5) 22 V1 = 30 V, V2 = 20 V, d = 0.5, IO = 2.4 A

4.Simulation(5/5) 23 (a) Efficiency versus output power. (b) Output voltage versus output power.

5.Conclusion(1/2) 24 The proposed converters employ two energy transfer components (one SC and one inductor) and do not use the cascade method like conventional SC/switched-inductor converters. This design can meet the high efficiency requirement with a simple structure. The other members of the proposed family have also been simulated and their operations have been confirmed.

5.Conclusion(2/2) 25 Fig. 2(b) is always higher than twice the input voltage and is only suitable for high voltage gain applications. Similar problem is also found in the high step-down member [see Fig. 3(a)]. proposed step-up converters can provide both higher and lower voltage levels than input voltage under different duty ratios.

6.Personal Remark 26 In this paper the experimental circuit switch use IRFI540N,but simulated didn’t use this so the result will different. In this paper author propose seven’s different circuit, but only experiment one circuit.

6.Personal Remark 27

28 Thank your for listening