Description

Book Synopsis
Introduction to Modern Analysis of Electric Machines and Drives Comprehensive resource introducing magnetic circuits and rotating electric machinery, including models and discussions of control techniques Introduction to Modern Analysis of Electric Machines and Drives is written for the junior or senior student in Electrical Engineering and covers the essential topic of machine analysis for those interested in power systems or drives engineering. The analysis contained in the text is based on Tesla's rotating magnetic field and reference frame theory, which comes from Tesla's work and is presented for the first time in an easy to understand format for the typical student. Since the stators of synchronous and induction machines are the same for analysis purposes, they are analyzed just once. Only the rotors are different and therefore analyzed separately. This approach makes it possible to cover the analysis efficiently and concisely without repeating derivations. In fact, the synchron

Table of Contents

Preface

CHAPTER 1 COMMON ANALYSIS TOOLS

1.1 INTRODUCTION

1.2 STEADY-STATE PHASOR CALCULATIONS

Power and Reactive Power

1.3 STATIONARY MAGNETICALLY-LINEAR SYSTEMS

Two-Winding Transformer

1.4 WINDING CONFIGURATIONS

1.5 TWO- AND THREE-PHASE STATORS

Two-Phase Stator

Three-Phase Stator

Line-to-Line Voltage

1.6 PROBLEMS

1.7 REFERENCE

CHAPTER 2 ANALYSIS OF THE SYMMETRICAL STATOR

2.1 INTRODUCTION

2.2 TESLA’S ROTATING MAGNETIC FIELD

Two-Pole Two-Phase Stator

Two-Pole Three-Phase Stator

2.3 REFERENCE FRAME THEORY

Two-Phase Transformation

Three-Phase Transformation

2.4 STATOR VOLTAGE AND FLUX LINKAGE EQUATIONS IN THE ARBITRARY REFERENCE FRAME AND THE INSTANTANEOUS PHASOR

Two-Phase Stator

Three-Phase Stator

Instantaneous and Steady-State Phasors

2.5 PROBLEMS

2.6 REFERENCES

CHAPTER 3 SYMMETRICAL INDUCTION MACHINE

3.1 INTRODUCTION

3.2 SYMMETRICAL MACHINES

3.3 SYMMETRICAL TWO-POLE ROTOR WINDINGS

Two-Phase Rotor Windings

Three-Phase Rotor Windings

3.4 SUBSTITUTE VARIABLES FOR SYMMETRICAL ROTATING CIRCUITS AND EQUIVALENT CIRCUIT

Two-Phase Machine

Three-Phase Machine

3.5 ELECTROMAGNETIC FORCE AND TORQUE

3.6 P-POLE MACHINES

3.7 FREE ACCELERATING VARIABLES VIEWED FROM DIFFERENT REFERENCE FRAMES

3.8 STEADY-STATE EQUIVALENT CIRCUIT

3.9 PROBLEMS

3.10 REFERENCES

CHAPTER 4 SYNCHRONOUS MACHINES

4.1 INTRODUCTION

4.2 ANALYSIS OF THE PERMANENT-MAGNET ac MOTOR

Torque

Unequal Direct– and Quadrature-Axis Inductances

Three-Phase Machine

4.3 WINDINGS OF THE SYNCHRONOUS MACHINE

4.4 EQUIVALENT CIRCUIT – VOLTAGE AND TORQUE EQUATIONS

Torque

Rotor Angle

4.5 DYNAMIC AND STEADY-STATE PERFORMANCES

4.6 ANALYSI OF STEADY-STATE OPERATION

4.7 TRANSIENT STABILITY

Three-Phase Fault

4.8 PROBLEMS

4.9 REFERENCE

CHAPTER 5 DIRECT CURRENT MACHINE AND DRIVE

5.1 INTRODUCTION

5.2 COMMUTATION

5.3 VOLTAGE AND TORQUE EQUATIONS

5.4 PERMANENT-MAGNET dc MACHINE

5.5 DC DRIVE

Average-Value Time-Domain Block Diagram

Torque Control

5.6 PROBLEMS

5.7 REFERENCE

CHAPTER 6 BRUSHLESS dc AND FIELD ORIENTED DRIVES

6.1 INTRODUCTION

6.2 THE BRUSHLESS dc DRIVE CONFIGURATION

6.3 COMMON MODE OF BRUSHLESS dc DRIVE OPERATION

6.4 OTHER MODES OF BRUSHLESS dc DRIVE OPERATION

Maximum-Torque Per Volt Operation of a Brushless dc Drive

Maximum-Torque Per Ampere Operation of a Brushless dc Drive

Torque Control

6.5 FIELD ORIENTED INDUCTION MOTOR DRIVE

6.6 PROBLEMS

6.7 REFERENCES

CHAPTER 7 SINGLE-PHASE INDUCTION MOTORS

7.1 INTRODUCTION

7.2 SYMMETRICAL COMPONENTS

7.3 ANALYSIS OF UNBALANCED MODES OF OPERATION

Unbalanced Stator Voltages

Unbalanced Stator Impedances

Open-Circuited Stator Phase

7.4 SINGLE-PHASE AND CAPACITOR-STATOR INDUCTION MOTORS

Single-Phase Induction Motor

Capacitor-Start Induction Motor

7.5 DYNAMIC AND STEADY-STATE PERFORMANCE OF A CAPACITOR-START SINGLE-PHASE INDUCTION MOTOR

7.6 SPLIT-PHASE INDUCTION MOTOR

7.7 PROBLEMS

7.8 REFERENCES

CHAPTER 8 STEPPER MOTORS

8.1 INTRODUCTION

8.2 BASIC CONFIGURATIONS OF MULTISTACK VARIABLE-RELUCTANCE STEPPER MOTORS

8.3 EQUATIONS FOR MULTSTACKVARIABLE-RELUCTANCE STEPPER MOTORS

8.4 OPERATING CHARACTERISTICS OF MULTISTACK VARIABLE-RELUCTANCE STEPPER MOTORS

8.5 SINGLE-STACK VARIABLE-RELUCTANCE STEPPER MOTORS

8.6 BASIC-CONFIGURATION OF PERMANENT-MAGNET STEPPER MOTORS

8.7 EQUATIONS FOR PERMANENT-MAGNET STEPPER MOTORS

8.8 PROBLEMS

8.9 REFERENCES

Introduction to Modern Analysis of Electric

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A Hardback by Paul C. Krause, Thomas C. Krause

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    View other formats and editions of Introduction to Modern Analysis of Electric by Paul C. Krause

    Publisher: John Wiley & Sons Inc
    Publication Date: 19/12/2022
    ISBN13: 9781119908159, 978-1119908159
    ISBN10: 1119908159
    Also in:
    Energy

    Description

    Book Synopsis
    Introduction to Modern Analysis of Electric Machines and Drives Comprehensive resource introducing magnetic circuits and rotating electric machinery, including models and discussions of control techniques Introduction to Modern Analysis of Electric Machines and Drives is written for the junior or senior student in Electrical Engineering and covers the essential topic of machine analysis for those interested in power systems or drives engineering. The analysis contained in the text is based on Tesla's rotating magnetic field and reference frame theory, which comes from Tesla's work and is presented for the first time in an easy to understand format for the typical student. Since the stators of synchronous and induction machines are the same for analysis purposes, they are analyzed just once. Only the rotors are different and therefore analyzed separately. This approach makes it possible to cover the analysis efficiently and concisely without repeating derivations. In fact, the synchron

    Table of Contents

    Preface

    CHAPTER 1 COMMON ANALYSIS TOOLS

    1.1 INTRODUCTION

    1.2 STEADY-STATE PHASOR CALCULATIONS

    Power and Reactive Power

    1.3 STATIONARY MAGNETICALLY-LINEAR SYSTEMS

    Two-Winding Transformer

    1.4 WINDING CONFIGURATIONS

    1.5 TWO- AND THREE-PHASE STATORS

    Two-Phase Stator

    Three-Phase Stator

    Line-to-Line Voltage

    1.6 PROBLEMS

    1.7 REFERENCE

    CHAPTER 2 ANALYSIS OF THE SYMMETRICAL STATOR

    2.1 INTRODUCTION

    2.2 TESLA’S ROTATING MAGNETIC FIELD

    Two-Pole Two-Phase Stator

    Two-Pole Three-Phase Stator

    2.3 REFERENCE FRAME THEORY

    Two-Phase Transformation

    Three-Phase Transformation

    2.4 STATOR VOLTAGE AND FLUX LINKAGE EQUATIONS IN THE ARBITRARY REFERENCE FRAME AND THE INSTANTANEOUS PHASOR

    Two-Phase Stator

    Three-Phase Stator

    Instantaneous and Steady-State Phasors

    2.5 PROBLEMS

    2.6 REFERENCES

    CHAPTER 3 SYMMETRICAL INDUCTION MACHINE

    3.1 INTRODUCTION

    3.2 SYMMETRICAL MACHINES

    3.3 SYMMETRICAL TWO-POLE ROTOR WINDINGS

    Two-Phase Rotor Windings

    Three-Phase Rotor Windings

    3.4 SUBSTITUTE VARIABLES FOR SYMMETRICAL ROTATING CIRCUITS AND EQUIVALENT CIRCUIT

    Two-Phase Machine

    Three-Phase Machine

    3.5 ELECTROMAGNETIC FORCE AND TORQUE

    3.6 P-POLE MACHINES

    3.7 FREE ACCELERATING VARIABLES VIEWED FROM DIFFERENT REFERENCE FRAMES

    3.8 STEADY-STATE EQUIVALENT CIRCUIT

    3.9 PROBLEMS

    3.10 REFERENCES

    CHAPTER 4 SYNCHRONOUS MACHINES

    4.1 INTRODUCTION

    4.2 ANALYSIS OF THE PERMANENT-MAGNET ac MOTOR

    Torque

    Unequal Direct– and Quadrature-Axis Inductances

    Three-Phase Machine

    4.3 WINDINGS OF THE SYNCHRONOUS MACHINE

    4.4 EQUIVALENT CIRCUIT – VOLTAGE AND TORQUE EQUATIONS

    Torque

    Rotor Angle

    4.5 DYNAMIC AND STEADY-STATE PERFORMANCES

    4.6 ANALYSI OF STEADY-STATE OPERATION

    4.7 TRANSIENT STABILITY

    Three-Phase Fault

    4.8 PROBLEMS

    4.9 REFERENCE

    CHAPTER 5 DIRECT CURRENT MACHINE AND DRIVE

    5.1 INTRODUCTION

    5.2 COMMUTATION

    5.3 VOLTAGE AND TORQUE EQUATIONS

    5.4 PERMANENT-MAGNET dc MACHINE

    5.5 DC DRIVE

    Average-Value Time-Domain Block Diagram

    Torque Control

    5.6 PROBLEMS

    5.7 REFERENCE

    CHAPTER 6 BRUSHLESS dc AND FIELD ORIENTED DRIVES

    6.1 INTRODUCTION

    6.2 THE BRUSHLESS dc DRIVE CONFIGURATION

    6.3 COMMON MODE OF BRUSHLESS dc DRIVE OPERATION

    6.4 OTHER MODES OF BRUSHLESS dc DRIVE OPERATION

    Maximum-Torque Per Volt Operation of a Brushless dc Drive

    Maximum-Torque Per Ampere Operation of a Brushless dc Drive

    Torque Control

    6.5 FIELD ORIENTED INDUCTION MOTOR DRIVE

    6.6 PROBLEMS

    6.7 REFERENCES

    CHAPTER 7 SINGLE-PHASE INDUCTION MOTORS

    7.1 INTRODUCTION

    7.2 SYMMETRICAL COMPONENTS

    7.3 ANALYSIS OF UNBALANCED MODES OF OPERATION

    Unbalanced Stator Voltages

    Unbalanced Stator Impedances

    Open-Circuited Stator Phase

    7.4 SINGLE-PHASE AND CAPACITOR-STATOR INDUCTION MOTORS

    Single-Phase Induction Motor

    Capacitor-Start Induction Motor

    7.5 DYNAMIC AND STEADY-STATE PERFORMANCE OF A CAPACITOR-START SINGLE-PHASE INDUCTION MOTOR

    7.6 SPLIT-PHASE INDUCTION MOTOR

    7.7 PROBLEMS

    7.8 REFERENCES

    CHAPTER 8 STEPPER MOTORS

    8.1 INTRODUCTION

    8.2 BASIC CONFIGURATIONS OF MULTISTACK VARIABLE-RELUCTANCE STEPPER MOTORS

    8.3 EQUATIONS FOR MULTSTACKVARIABLE-RELUCTANCE STEPPER MOTORS

    8.4 OPERATING CHARACTERISTICS OF MULTISTACK VARIABLE-RELUCTANCE STEPPER MOTORS

    8.5 SINGLE-STACK VARIABLE-RELUCTANCE STEPPER MOTORS

    8.6 BASIC-CONFIGURATION OF PERMANENT-MAGNET STEPPER MOTORS

    8.7 EQUATIONS FOR PERMANENT-MAGNET STEPPER MOTORS

    8.8 PROBLEMS

    8.9 REFERENCES

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