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Automatic Permanent Magnet Generator Controller Automatic Permanent Magnet Generator Controller for Small Applications A thesis submitted in partial fulfillment of the requirements for the degree of Master of Science in Engineering By William Scott Adkins B.S.E.E., Wright State University, 2013 2015 Wright State University WRIGHT STATE UNIVERSITY GRADUATE SCHOOL January 6, 2016 I HEREBY RECOMMEND THAT THE THESIS PREPARED UNDER MY SUPERVISION BY William Scott Adkins ENTITLED Automatic PMG Controller for Small Applications BE ACCEPTED IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF Master of Science in Engineering. ______________________________ Marian K. Kazimierczuk, Ph.D. Thesis Director Committee on Final Examination ______________________________ Brian Rigling, Ph.D. ______________________________ Chair Marian K. Kazimierczuk, Ph.D. Department of Electrical Engineering College of Engineering and Computer Science ______________________________ Lavern Alan Starman, Ph. D ______________________________ Saiyu Ren, Ph.D. ______________________________ Robert E. W. Fyffe, Ph.D. Vice President for Research and Dean of the Graduate School PROPRIETARY & INTECTUAL PROPERTY INFORMATION The information contained within this document is entitled as William Scott Adkins proprietary information and intellectual property and is disclosed in confidence. It is the property of William Scott Adkins and shall not be used, disclosed to others or reproduced without the express written consent of William Scott Adkins, including, but without limitation, it is not to be used in the creation, manufacture, development, or derivation of any repairs, modifications, spare parts, designs, or configuration changes or to obtain FAA or any other government or regulatory approval to do so. If consent is given for reproduction in whole or in part, this notice shall be applicable to all contents of this document or any document provide as such. iii ABSTRACT Adkins, William “Scott” M.S.Egr., Department of Electrical Engineering, Wright State University, 2015. Automatic PMG Controller for Small Applications. This thesis is used to describe the proof of concept and design for a much needed answer to a major flight time limitation in smaller application drones. All small electric drones and small electric vehicles have the same major problem, short run-times. The average time a multi-rotor helicopter runs is for approximately 20 minutes. The concept idea of the combination of a permanent magnet generator (PMG) and a controller can extend this flight time. The basic idea is to add the similar function an automobile has, which is the alternator. This thesis will include, but not limited to the following for an Automatic PMG controller for a PMG primary source that would be theoretically added to the vehicles power systems: Design needs for longer application usage Design steps taken with conceptual reasoning H-Bridge Buck-Boost description & operation Simulation and testing of the proof of concept Integration methods, and Implementation. It also serves as design template of a voltage and current source controller for multiple small application platforms and will be compared to the state-of-the-art design concepts in trying to reach a similar goal. iv TABLE OF CONTENTS PAGE LIST OF FIGURES ....................................................................................................................... vii LIST OF TABLES .......................................................................................................................... ix ACKNOWLEDGEMENTS ............................................................................................................. x DEDICATION ................................................................................................................................ xi CHAPTER 1: INTRODUCTION ................................................................................................. 1 CHAPTER 2: TYPES OF SMALL APPLICATIONS AND THEIR NEEDS ......................... 2 2.1 Aerial Applications .......................................................................................................... 2 2.1.1 Flight Limitations ..................................................................................................... 2 2.2 Land Applications ............................................................................................................ 3 2.2.1 Run Time Limitations .............................................................................................. 3 2.3 Improvements Needed for Small Land & Air Applications ............................................ 3 2.4 State-of-the-Art/Comparisons .......................................................................................... 4 Chapter 3: PERMANENT MAGNET GENERATOR (PMG) .................................................. 6 3.1 Overview of PMG ............................................................................................................ 6 3.1.1 3-Phase vs. Single Phase Machine ........................................................................... 6 3.2 Purpose of PMG in Application Design .......................................................................... 7 3.3 Primary Source of Mechanical Rotation .......................................................................... 8 Chapter 4: AUTOMATIC CONTROLLER ............................................................................... 9 4.1 Overview of Automatic Controller ........................................................................................ 9 4.2 Design Process ................................................................................................................. 9 4.2.1 Design Specifications ............................................................................................... 9 4.2.2 Block Diagram & Schematic ................................................................................... 9 4.2.3 Input Power Source ................................................................................................ 10 4.2.4 Buck-Boost Micro-Controller ................................................................................ 11 4.2.5 Battery Charging IC ............................................................................................... 17 4.2.6 Protection/Detection Features ................................................................................ 22 4.2.7 Filter Design ........................................................................................................... 24 v 4.2.8 PCB Layout Design ............................................................................................... 25 4.3 Simulation & Testing ..................................................................................................... 25 4.3.1 Simulation .............................................................................................................. 26 4.3.1.3 Battery Charging Circuit ........................................................................................ 29 4.3.2 Prototype Testing ................................................................................................... 32 Summary/Contributions.............................................................................................................. 42 References ..................................................................................................................................... 43 Figure References......................................................................................................................... 44 Table References .......................................................................................................................... 45 About the Author ........................................................................................................................... 46 APPENDIX A ............................................................................................................................... 47 APPENDIX B ............................................................................................................................... 48 APPENDIX C ............................................................................................................................... 49 APPENDIX D ............................................................................................................................... 50 vi LIST OF FIGURES Figure Page Fig. 1 Single Phase AC Sine Wave @ 1kHz ...................................................................... 7 Fig. 2 3-Phase AC Source @ 1kHz..................................................................................... 7 Fig. 3 Automatic PMG Controller Block Diagram ............................................................. 9 Fig. 4 Automatic PMG Controller Schematic................................................................... 10 Fig. 5 Buck-Boost Micro-Controller Schematic ............................................................... 12 Fig. 6 Buck-Boost Mode ................................................................................................... 13 Fig. 7 Buck Mode ............................................................................................................. 13 Fig. 8 Boost Mode............................................................................................................. 13 Fig. 9 Simplified H-Bridge Topology ..............................................................................
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