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This text provides an invaluable source of practical guidance on how anyone can find out the type of electrical equipment they have, and how to convert it to run on a single-phase supply. It offers calculations, step-by-step instructions with photographs and diagrams and also advises on which equipment cannot be converted at all.
Three phase motors are a type of electric motor, and they power a multitude of things. You may encounter these motors in about any field you are involved in. From farmers to machine shop operators to business owners, sooner or later a three phase machine shows up. How do you handle that? If you don't have three phase the cost to get it is probably prohibitive. What's next? I have spent years running and testing various ways to run three phase motors on single phase power. There are a number of ways to make the phase conversion and you need to know the best way for your situation. I started with the phase conversion process in the early 90's. I had an industrial vacuum cleaner that I needed to run. The local electric shop brought out a rotary phase converter and it was unable to start the vacuum. I sought out and found a better way. It's called the transformer converter and it was cheap for me to build and worked great! I started selling information about how to build one. Accumulating a few thousand customers gave me more insight into what people needed. Which turned out to be more information. Over the years my teaching has morphed into a full answer to the question "How should I run my machines?" I should point out that many times my advice to people after hearing about their situation is to buy a commercial converter. I like to be right up front with people and for some, building your own is not the answer. In those cases I feel that I am guiding those people through a maze of information and steering them to the most logical conclusion. But what about the person that wants to build their own? That's where I spend quite a bit of time and pages in the book. There are only two types of converters you can build yourself: the transformer converter and the rotary converter. Which is best for your machines? I help you decide. But of course, I take it much further than that. I show you all the parameters of what you are going to run into and what you can get away with. How to balance a rotary converterDoes you power company meter really record what the rotary is using?What is the best way to raise the voltage to run motors at twice you power company volts? i detail five different ways to do that, one you have never heard of before. It's my own invention.How to make your own transformer out of commonly available cores.How to modify commercial transformers.I put special emphasis on my overseas customers and their unique needs. How to hook up the start relay.How to use capacitors and hook them up.How to build the transformer converter using either a transformer you made or a commercial transformer.Basic electrical principals and why the power company and motor manufacturers use three phase.Construction helps on how to save money putting a converter together.How to build a big welder or battery charger power supply.Using oil cooling to run larger motors with your homemade transformer.What is motor protection and how does a motor starter work?What is meant by service factor and ambient temperature and how that helps usTo help illustrate some of these points I have a link in the book to videos, only for book purchasers..A chapter detailing how you can make money in three phase conversion, not by making and selling converters on eBay but much bigger and potentially more profitable than that. This is pretty much a complete guide to running three phase motors on single phase power. It contains over 20 years of knowledge put into one master book. I hope you enjoy it and have fun with an exciting field of interest. Starting and running a 25 or 30 hp air compressor at home will get your blood flowing more than stamp collecting. This is an action hobby with thrilling results.
Model Predictive Control for Doubly-Fed Induction Generators and Three-Phase Power Converters describes the application of model predictive control techniques with modulator and finite control sets to squirrel cage induction motor and in doubly-fed induction generators using field orientation control techniques as both current control and direct power control. Sections discuss induction machines, their key modulation techniques, introduce the utility of model predictive control, review core concepts of vector control, direct torque control, and direct power control alongside novel approaches of MPC. Mathematical modeling of cited systems, MPC theory, their applications, MPC design and simulation in MATLAB are also considered in-depth. The work concludes by addressing implementation considerations, including generator operation under voltage sags or distorted voltage and inverters connected to the grid operating under distorted voltage. Experimental results are presented in full. - Adopts model predictive control design for optimized induction machines geared for complex grid dynamics - Demonstrates how to simulate model predictive control using MATLAB and Simulink - Presents information about hardware implementation to obtain experimental results - Covers generator operation under voltage sags or distorted voltage
Presents the latest developments in switchgear and DC/DC converters for DC grids, and includes substantially expanded material on MMC HVDC This newly updated edition covers all HVDC transmission technologies including Line Commutated Converter (LCC) HVDC; Voltage Source Converter (VSC) HVDC, and the latest VSC HVDC based on Modular Multilevel Converters (MMC), as well as the principles of building DC transmission grids. Featuring new material throughout, High Voltage Direct Current Transmission: Converters, Systems and DC Grids, 2nd Edition offers several new chapters/sections including one on the newest MMC converters. It also provides extended coverage of switchgear, DC grid protection and DC/DC converters following the latest developments on the market and in research projects. All three HVDC technologies are studied in a wide range of topics, including: the basic converter operating principles; calculation of losses; system modelling, including dynamic modelling; system control; HVDC protection, including AC and DC fault studies; and integration with AC systems and fundamental frequency analysis. The text includes: A chapter dedicated to hybrid and mechanical DC circuit breakers Half bridge and full bridge MMC: modelling, control, start-up and fault management A chapter dedicated to unbalanced operation and control of MMC HVDC The advancement of protection methods for DC grids Wideband and high-order modeling of DC cables Novel treatment of topics not found in similar books, including SimPowerSystems models and examples for all HVDC topologies hosted by the 1st edition companion site. High Voltage Direct Current Transmission: Converters, Systems and DC Grids, 2nd Edition serves as an ideal textbook for a graduate-level course or a professional development course.
Presents Fundamentals of Modeling, Analysis, and Control of Electric Power Converters for Power System Applications Electronic (static) power conversion has gained widespread acceptance in power systems applications; electronic power converters are increasingly employed for power conversion and conditioning, compensation, and active filtering. This book presents the fundamentals for analysis and control of a specific class of high-power electronic converters—the three-phase voltage-sourced converter (VSC). Voltage-Sourced Converters in Power Systems provides a necessary and unprecedented link between the principles of operation and the applications of voltage-sourced converters. The book: Describes various functions that the VSC can perform in electric power systems Covers a wide range of applications of the VSC in electric power systems—including wind power conversion systems Adopts a systematic approach to the modeling and control design problems Illustrates the control design procedures and expected performance based on a comprehensive set of examples and digital computer time-domain simulation studies This comprehensive text presents effective techniques for mathematical modeling and control design, and helps readers understand the procedures and analysis steps. Detailed simulation case studies are included to highlight the salient points and verify the designs. Voltage-Sourced Converters in Power Systems is an ideal reference for senior undergraduate and graduate students in power engineering programs, practicing engineers who deal with grid integration and operation of distributed energy resource units, design engineers, and researchers in the area of electric power generation, transmission, distribution, and utilization.
Grid converters are the key player in renewable energy integration. The high penetration of renewable energy systems is calling for new more stringent grid requirements. As a consequence, the grid converters should be able to exhibit advanced functions like: dynamic control of active and reactive power, operation within a wide range of voltage and frequency, voltage ride-through capability, reactive current injection during faults, grid services support. This book explains the topologies, modulation and control of grid converters for both photovoltaic and wind power applications. In addition to power electronics, this book focuses on the specific applications in photovoltaic wind power systems where grid condition is an essential factor. With a review of the most recent grid requirements for photovoltaic and wind power systems, the book discusses these other relevant issues: modern grid inverter topologies for photovoltaic and wind turbines islanding detection methods for photovoltaic systems synchronization techniques based on second order generalized integrators (SOGI) advanced synchronization techniques with robust operation under grid unbalance condition grid filter design and active damping techniques power control under grid fault conditions, considering both positive and negative sequences Grid Converters for Photovoltaic and Wind Power Systems is intended as a coursebook for graduated students with a background in electrical engineering and also for professionals in the evolving renewable energy industry. For people from academia interested in adopting the course, a set of slides is available for download from the website. www.wiley.com/go/grid_converters
Filling the need for a reference that explains the behavior of power electronic converters, this book provides information currently unavailable in similar texts on power electronics. Clearly organized into four parts, the first treats the dynamics and control of conventional converters, while the second part covers the dynamics and control of DC-DC converters in renewable energy applications, including an introduction to the sources as well as the design of current-fed converters applying duality-transformation methods. The third part treats the dynamics and control of three-phase rectifiers in voltage-sourced applications, and the final part looks at the dynamics and control of three-phase inverters in renewable-energy applications. With its future-oriented perspective and advanced, first-hand knowledge, this is a prime resource for researchers and practicing engineers needing a ready reference on the design and control of power electronic converters.
Power electronic converters can be broadly classified as AC to DC, DC to AC, DC to DC and AC to AC converters. AC to AC converters can be further classified as AC Controllers or AC regulators, Cycloconverters and Matrix converters. AC controllers and cycloconverters are fabricated using Silicon Controlled Rectifiers (SCR) whereas matrix converters are built using semiconductor bidirectional switches. This text book provides a summary of AC to AC Converter modelling excluding AC controllers. The software Simulink® by Mathworks Inc., USA is used to develop the models of AC to AC Converters presented in this text book. The term model in this text book refers to SIMULINK model. This text book is mostly suitable for researchers and practising professional engineers in the industry working in the area of AC to AC converters. Features Provides a summary of AC to AC Converter modelling excluding AC controllers Includes models for three phase AC to three phase AC matrix converters using direct and indirect space vector modulation algorithm Presents new applications such as single and dual programmable AC to DC rectifier with derivations for output voltage Displays Hardware-in-the Loop simulation of a three phase AC to single phase AC matrix converter Provides models for three phase multilevel matrix converters, Z-source Direct and Quasi Z-source Indirect matrix converters; a model for speed control and brake by plugging of three phase induction motor and separately excited DC motors using matrix converter; a model for a new single phase and three phase sine wave direct AC to AC Converter without a DC link using three winding transformers and that for a square wave AC to square wave AC converter using a DC link; models for variable frequency, variable voltage AC to AC power supply; models for Solid State Transformers using Dual Active Bridge topology and a new direct AC to AC Converter topology; and models for cycloconverters and indirect matrix converters
This book is a collection of scientific papers concerning multilevel inverters examined from different points of view. Many applications are considered, such as renewable energy interface, power conditioning systems, electric drives, and chargers for electric vehicles. Different topologies have been examined in both new configurations and well-established structures, introducing novel and particular modulation strategies, and examining the effect of modulation techniques on voltage and current harmonics and the total harmonic distortion.
This book provides a concise introduction to switching strategies for power electronics. It provides an in-depth examination of this one concept giving a newcomer a complete immersive experience which has both the depth that is needed to gain confidence yet is simple to understand. The authors examine the basic operation of power electronic systems from scratch and with the help of simulations, how these systems can be constructed. The approach used treats power electronics similar to puzzles and rather than merely presenting them and describing how they work, explore why they came to have the construction they have, and how they could potentially be modified. The authors make extensive use of simulations, with every theory and every result accompanied by a simulation. All simulations are performed by the free and open source Python programming language and the free and open source circuit simulator Python Power Electronics.