Dynamic Simulation of Electric Machinery: Using MATLAB/SIMULINKElectrical engineers can significantly improve the way they design power components and systems using the PC-based modeling and simulation tools discussed in this book.KEY TOPICS: This book covers the fundamentals of electrical system modeling and simulation, using two of the industry's most popular software packages, MATLAB and SIMULINK. It also shows how to interpret the results and use them in the design process. The book reviews the basics of magnetics and line modeling. It covers a wide range of electrical components and systems, including: transformers, electric machines, three-phase induction machines, synchronous machines, and DC machines. The accompanying website (at www.informit.com/title/0137237855) offer a complete treatment from background theory and models to implementation and verification techniques for simulations and linear analysis of frequently studies machine systems.MARKET: For working engineers and graduate students interested in simulating power systems. |
Contents
INTRODUCTION | 1 |
BASICS OF MAGNETICS AND LINE MODELING | 30 |
TRANSFORMERS | 85 |
Copyright | |
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Common terms and phrases
a-phase airgap angle armature armature winding axis block braking capacitor coil sides components computed conductor constant curve d-axis damper winding determined electrical equivalent circuit excitation expressed field winding Figure flux linkage frequency given in Eq induction machine induction motor infinite bus initial input integration linear linear model load torque MATLAB M-file matrix obtain open-circuit output parameters permanent magnet motor Pgen phase phasor plot pole power factor Project q-axis resistance resistor RLC circuit root-locus rotating reference frame rotor speed rotor windings saturation shown in Fig SIMULINK file SIMULINK simulation single-phase sinusoidal space vector stationary stator current stator voltage stator windings steady-state step sub-transient synchronous machine synchronously rotating synchronously rotating reference terminal voltage three-phase Tmech torque transfer function transformer transient variables voltage equations wr/wb Yn+1 zero