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Summary
Summary
Filling a gap in the literature, Electrotechnical Systems: Simulation with Simulink® and SimPowerSystems(tm) explains how to simulate complicated electrical systems more easily using SimPowerSystems(tm) blocks. It gives a comprehensive overview of the powerful SimPowerSystems toolbox and demonstrates how it can be used to create and investigate models of both classic and modern electrotechnical systems.
Build from Circuit Elements and Blocks to System Models
Building from simple to more complex topics, the book helps readers better understand the principles, features, and detailed functions of various electrical systems, such as electrical drives, power electronics, and systems for production and distribution of electrical energy. The text begins by describing the models of the main circuit elements, which are used to create the full system model, and the measuring and control blocks. It then examines models of semiconductor devices used in power electronics as well as models of DC and AC motors. The final chapter discusses the simulation of power production and transmission systems, including hydraulic turbine, steam turbine, wind, and diesel generators. The author also develops models of systems that improve the quality of electrical energy, such as active filters and various types of static compensators.
Get a Deeper Understanding of Electrical Systems and How to Simulate Them
A companion CD supplies nearly 100 models of electrotechnical systems created using SimPowerSystems. These encompass adaptations of SimPowerSystems demonstrational models, as well as models developed by the author, including many important applications related to power electronics and electrical drives, which are not covered by the demonstrational models. In addition to showing how the models can be used, he supplies the theoretical background for each. Offering a solid understanding of how electrical systems function, this book guides readers to use SimPowerSystems to create and investigate electrical systems, including those under development, more effectively.
Author Notes
Viktor M. Perelmuter has been working as a scientific advisor at the National Technical University's Kharkov Polytechnic Institute and at the Research Electrotechnical Institute, Kharkov, Ukraine, since 2001. He is also a member of the IEEE. Along with his engineering activities, Perelmuter headed scientific work in the fields of electrical drives, power electronics, and control systems. He is the author or coauthor of nine books and more than 70 articles. He also holds 19 patents in the former USSR and Ukraine.
Table of Contents
Preface | p. xi |
Author | p. xv |
Chapter 1 Special Features of SimPowerSystems™ Models | |
1.1 General Characteristics | p. 1 |
1.2 Graphical User Interface Powergui | p. 7 |
References | p. 16 |
Chapter 2 Models of Power Circuit Devices | p. 17 |
2.1 Electrical Sources | p. 17 |
2.2 Impedances and Loads | p. 22 |
2.3 Transformers | p. 36 |
2.4 Transmission Line Models | p. 51 |
2.5 Miscellaneous | p. 59 |
References | p. 63 |
Chapter 3 Measuring and Control Blocks | p. 65 |
3.1 Measurement of Main Circuit Quantities | p. 65 |
3.2 Meters with Employment of Simulink® Blocks | p. 68 |
3.3 Control Blocks | p. 77 |
References | p. 83 |
Chapter 4 Simulation of Power Electronics Devices | p. 85 |
4.1 Models of Power Semiconductor Devices | p. 85 |
4.2 Control Blocks for Power Electronics | p. 92 |
4.3 Simulation of Converter with Thyristors | p. 101 |
4.4 Simulation of a High-Voltage Direct Current Electric Power Transmission System | p. 108 |
4.5 Simulation of Converters with Forced-Commutated Devices | p. 115 |
4.6 Cascaded H-Bridge Multilevel Inverter Simulation | p. 122 |
4.7 Four-Level Inverter with "Flying" Capacitor Simulation | p. 126 |
4.8 Simulation of Z-Source Converters | p. 134 |
4.9 Simulation of Resonant Inverters | p. 143 |
4.10 Simulation of Modular Multilevel Converters | p. 152 |
4.11 Simulation of Matrix Converters | p. 157 |
References | p. 166 |
Chapter 5 Electric Machine and Electric Drive Simulation | p. 167 |
5.1 Direct Current (DC) Motors and Drives | p. 167 |
5.1.1 DC Drives with Chopper Control | p. 167 |
5.1.2 Saturation Consideration | p. 179 |
5.1.3 Continuous Models of DC Electrical Drives in SimPowerSystems™ | p. 187 |
5.2 Induction Motors and Electric Drives | p. 190 |
5.2.1 Model Description | p. 190 |
5.2.2 Simulation of IM with Two-Level Voltage-Source Inverter (VSI) and DTC | p. 196 |
5.2.3 Models of the Standard IM Drives in SimPowerSystems™ | p. 204 |
5.2.4 IM with Two-Level VSI and an Active Front-End Rectifier | p. 209 |
5.2.5 IM with Three-Level VSI | p. 211 |
5.2.5.1 IM with Three-Level VSI and DTC | p. 211 |
5.2.5.2 IM with Three-Level Inverter and L-C Filter | p. 214 |
5.2.6 Simulation of IM Supplied from CHB Inverter | p. 216 |
5.2.7 IM Supplied from the Four-Level Inverter with "Flying" Capacitors | p. 221 |
5.2.8 Simulation of the Five-Level H-Bridge Neutral-Point Clamped Inverter (5L-HNPC) Supplying IM | p. 223 |
5.2.9 Simulation of the IM with Phase-Wound Rotor | p. 236 |
5.2.10 IM with Current Source Inverter | p. 240 |
5.2.11 Simulation of IM Soft-Start | p. 242 |
5.2.12 IM Model with Six Terminals | p. 244 |
5.2.13 Model of Six-Phase IM | p. 247 |
5.2.14 Simulation of the Special Operation Modes of the Line-Fed IM | p. 254 |
5.3 Synchronous Motors (SM) and Electric Drives | p. 256 |
5.3.1 SM Model | p. 256 |
5.3.2 Simulation of the Electrical Drive with SM and Load-Commutated Converters | p. 264 |
5.3.3 Model of Six-Phase SM | p. 271 |
5.3.4 Cycloconverter Simulation | p. 277 |
5.3.5 SM with VSI Simulation | p. 284 |
5.3.5.1 Standard Model | p. 284 |
5.3.5.2 Power Electrical Drive with Three-Level VSI | p. 287 |
5.3.5.3 Power Electrical Drive with CHB Inverter | p. 291 |
5.3.6 Simplified SM Model | p. 297 |
5.4 Synchronous Motor with Permanent Magnets | p. 299 |
5.5 Switched Reluctance Motor Simulation | p. 305 |
5.6 Mechanical Coupling Simulation | p. 311 |
References | p. 315 |
Chapter 6 Electric Power Production and Transmission Simulation | p. 317 |
6.1 Computation of Transmission Line Parameters | p. 317 |
6.2 Use of the Simplified SM Model | p. 324 |
6.3 Simulation of Systems with Hydraulic-Turbine Generators | p. 326 |
6.4 Simulation of Systems with Steam Turbine-Synchronous Generator | p. 338 |
6.5 Simulation of Wind Generation Systems (WG) | p. 349 |
6.5.1 WG with an Induction Generator (IG) | p. 349 |
6.5.2 WG with a Synchronous Generator with Permanent Magnets (SGPM) | p. 356 |
6.5.3 WG with SGPM and Diesel-Generator | p. 359 |
6.5.4 Simulation of a Stand-Alone WG | p. 363 |
6.6 Simulation of the Unit: Diesel-Squirrel-Cage IG | p. 369 |
6.7 FACTS Simulation | p. 372 |
6.7.1 Static Synchronous Compensator Simulation | p. 372 |
6.7.2 STATCOM Simulation | p. 384 |
6.7.2.1 Models of Standard STATCOM Systems | p. 384 |
6.7.2.2 DSTATCOM Simulation | p. 390 |
6.7.2.3 STATCOM with Cascaded H-Bridge Multilevel Inverter Simulation | p. 392 |
6.7.3 Active Filter Simulation | p. 397 |
6.7.4 Static Synchronous Series Compensator Simulation | p. 403 |
6.7.5 Unified Power Flow Controller Simulation | p. 407 |
6.7.6 Phase-Shifting Transformer Simulation | p. 415 |
References | p. 418 |
List of the Models on CD | p. 419 |
Index | p. 423 |