Demystifies FACTS controllers, offering solutions to power control and power flow problems
Flexible alternating current transmission systems (FACTS) controllers represent one of the most important technological advances in recent years, both enhancing controllability and increasing power transfer capacity of electric power transmission networks. This timely publication serves as an applications manual, offering readers clear instructions on how to model, design, build, evaluate, and install FACTS controllers. Authors Kalyan Sen and Mey Ling Sen share their two decades of experience in FACTS controller research and implementation, including their own pioneering FACTS design breakthroughs.
Readers gain a solid foundation in all aspects of FACTS controllers, including:
Basic underlying theories
Step–by–step evolution of FACTS controller development
Guidelines for selecting the right FACTS controller
Sample computer simulations in EMTP programming language
Key differences in modeling such FACTS controllers as the voltage regulating transformer, phase angle regulator, and unified power flow controller
Modeling techniques and control implementations for the three basic VSC–based FACTS controllers STATCOM, SSSC, and UPFC
In addition, the book describes a new type of FACTS controller, the Sen Transformer, which is based on technology developed by the authors. An appendix presents all the sample models that are discussed in the book, and the accompanying FTP site offers many more downloadable sample models as well as the full–color photographs that appear throughout the book.
This book is essential reading for practitioners and students of power engineering around the world, offering viable solutions to the increasing problems of grid congestion and power flow limitations in electric power transmission systems.
1. Applications of FACTS Controllers.
2. Power Flow Control Concepts.
2.2 Implementation of Power Flow Control Concepts.
2.3 Interline Power Flow Concept.
3. Modeling Principles.
3.1 The Modeling in EMTP.
3.2 Vector Phase–Locked Loop (VPLL).
3.3 Transmission Line Steady–State Resistance Calculator.
3.4 Simulation of an Independent PFC in a Single Line Application.
4. Transformer–Based FACTS Controllers.
4.1 Voltage Regulating Transformer (VRT).
4.2 Phase Angle Regulator (PAR).
5. Mechanically Switched FACTS controllers.
5.1 Shunt Compensation.
5.2 Series Compensation.
Chapter 6: Voltage–Sourced Converter (VSC).
6.1 Modeling an Ideal VSC.
6.2 DC–to–AC VSC.
7. Two–Level Pole Design.
7.1 A Three–Phase, Six–Pulse VSC with Two–Level Poles.
7.2 Analysis of a Pole.
8. VSC–Based FACTS Controllers.
8.1 Shunt Compensation.
8.2 Series Compensation.
8.3 Shunt–Series Compensation Using a Unified Power Flow Controller (UPFC).
9. Sen Transformer.
9.1 Existing Solutions.
9.2 Desired Solution.
9.3 Comparison Among the VRT, PAR, UPFC, and ST.
9.4 Multiline Sen Transformer.
9.5 Flexible Operation of the ST.
9.6 ST with Shunt–Connected Compensating Voltages.
9.7 Limited Angle Operation of the ST with Shunt–Connected Compensating Voltages.
9.8 MST with Shunt–Connected Compensating Voltages.
9.9 Generalized Sen Transformer.
Appendix A. Miscellaneous.
Appendix B. Power Flow Control Equation in a Lossy Transmission Line.
Appendix C. EMTP Files.
About he Authors.