Electrical Machines with MATLAB Second Edition by Turan Gonen ISBN 978-1439877999 1439877998

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ISBN 10:  1439877998

ISBN 13: 978-1439877999

Author: Turan Gonen

invaluable insight and experience that eminent instructor Turan Gönen has acquired in almost 40 years of teaching. With simple, versatile content that separates it from other texts on electrical machines, this book is an ideal self-study tool for advanced students in electrical and other areas of engineering. In response to the often inadequate, rushed coverage of fundamentals in most basic circuit analysis books and courses, this resource is intelligently designed, easy to read, and packed with in-depth information on crucial concepts.

Topics include three-phase circuits, power measurement in AC circuits, magnetic circuits, transformers, and induction, synchronous, and direct-current machines. The book starts by reviewing more basic concepts, with numerous examples to clarify their application. It then explores new “buzzword” topics and developments in the area of electrical machine applications and electric power systems, including:

Renewable energy
Wind energy and related conversion
Solar energy
Energy storage
The smart grid
Using International Systems (IS) units throughout, this cross-disciplinary design guide delves into commonly used vocabulary and symbols associated with electrical machinery. Several new appendices contain tools such as an extensive glossary to explain important terms. Outlining a wide range of information―and the many different ways to apply it―this book is an invaluable, multifunctional resource for students and professors, as well as practicing professionals looking to refresh and update their knowledge.

Table of contents: 

Chapter 1

Basic Concepts

1.1 Introduction

1.2 Distribution System…

1.3 Impact of Dispersed Storage and Generation.

1.4 Brief Overview of Basic Electrical Machines.

1.5 Real and Reactive Powers in Single-Phase AC Circuits

Problems

Chapter 2 Three-Phase Circuits.

2.1 Introduction

2.2 Three-Phase Systems..

2.2.1 Ideal Three-Phase Power Sources.

2.2.1.1 Wye-Connected Ideal Three-Phase Source.

2.2.1.2 Delta-Connected Ideal Three-Phase Source

2.2.2 Balanced Three-Phase Loads.

2.3 Unbalanced Three-Phase Loads.

2.4 Measurement of Average Power in Three-Phase Circuits.

2.5 Power Factor Correction.

Problems

Chapter 3 Magnetic Circuits

3.1 Introduction

3.2 Magnetic Field of Current-Carrying Conductors.

3.3 Ampère’s Magnetic Circuital Law

3.4 Magnetic Circuits

3.5 Magnetic Circuit with Air Gap.

3.6 Brief Review of Ferromagnetism

3.7 Magnetic Core Losses

3.7.1 Hysteresis Loss.

3.7.2 Eddy-Current Loss

3.8 How to Determine Flux for a Given MMF

3.8.1 Trial-and-Error Method.

3.8.2 Graphical Method

3.8.3 Magnetization Curve Method

3.9 Permanent Magnets.

Problems

Chapter 4

Transformers

4.1 Introduction

4.2 Transformer Construction

4.3 Brief Review of Faraday’s and Lenz’s Laws of Induction.

4.4 Ideal Transformer

4.4.1 Dot Convention in Transformers

4.4.2 Impedance Transfer through a Transformer

4.4.3 Relationship between Input and Output Powers of an Ideal Transformer.

4.5 Real Transformer.

4.6 Approximate Equivalent Circuit of a Real Transformer

4.7 Determination of Equivalent-Circuit Parameters.

4.7.1 Open-Circuit Test

4.7.2 Short-Circuit Test

4.8 Transformer Nameplate Rating

4.9 Performance Characteristics of a Transformer.

4.9.1 Voltage Regulation of a Transformer.

4.9.2 Transformer Efficiency.

4.10 Three-Phase Transformers

4.11 Three-Phase Transformer Connections.

4.12 Autotransformers.

4.13 Three-Winding Transformers.

4.14 Instrument Transformers

4.15 Inrush Current

Problems

Chapter 5 Electromechanical Energy Conversion Principles.

5.1 Introduction

5.2 Fundamental Concepts…

5.3 Electromechanical Energy Conversion

5.3.1 Field Energy

5.3.2 Magnetic Force.

5.3.3 Energy and Coenergy.

5.3.4 Magnetic Force in a Saturable System.

5.4 Study of Rotating Machines

5.5 Singly Excited Rotating Systems..

5.6 Multiply Excited Rotating Systems.

5.7 Cylindrical Machines.

5.7.1 Single-Phase Synchronous Machine

5.7.2 Single-Phase Induction Machine.

5.8 Force Produced on a Conductor

5.9 Induced Voltage on a Conductor Moving in a Magnetic Field.

Problems

Chapter 6 Induction Machines.

6.1 Introduction

6.2 Construction of Induction Motors

6.3 Rotating Magnetic Field Concept.

6.3.1 Graphical Method

6.3.2 Analytical Method..

6.4 Induced Voltages

6.5 Concept of Rotor Slip

6.6 Effects of Slip on the Frequency and Magnitude of Induced Voltage of the Rotor

6.7 Equivalent Circuit of an Induction Motor.

6.7.1 Stator Circuit Model.

6.7.2 Rotor-Circuit Model

6.7.3 Complete Equivalent Circuit

6.7.4 Approximate Equivalent Circuit

6.8 Performance Calculations

6.9 Equivalent Circuit at Start-Up.

6.10 Determination of Power and Torque by Use of Thévenin’s Equivalent Circuit….

6.11 Performance Characteristics

6.12 Control of Motor Characteristics by Squirrel-Cage Rotor Design…..

6.13 Starting of Induction Motors

6.13.1 Direct-on-Line Starting.

6.13.2 Reduced-Voltage Starting.

6.13.3 Current Limiting by Series Resistance or Impedance.

6.14 Speed Control.

6.15 Tests to Determine Equivalent-Circuit Parameters.

6.15.1 No-Load Test

6.15.2 DC Test…….

6.15.3 Blocked-Rotor Test.

Problems

Chapter 7 Synchronous Machines.

7.1 Introduction

7.2 Construction of Synchronous Machines

7.3 Field Excitation of Synchronous Machines.

7.4 Synchronous Speed

7.5 Synchronous Generator Operation.

7.6 Equivalent Circuits

7.7 Synchronous Motor Operation

7.8 Power and Torque Characteristics

7.9 Stiffness of Synchronous Machines

7.10 Effect of Changes in Excitation.

7.10.1 Synchronous Machine Connected to an Infinite Bus..

7.10.2 Synchronous Generator Operating Alone.

7.11 Use of Damper Windings to Overcome Mechanical Oscillations

7.12 Starting of Synchronous Motors

7.13 Operating a Synchronous Motor as a Synchronous Condenser.

7.14 Operating a Synchronous Motor as a Synchronous Reactor.

7.15 Tests to Determine Equivalent-Circuit Parameters.

7.15.1 Open-Circuit Test…

7.15.2 Short-Circuit Test

7.15.3 DC Test.

7.15.4 Unsaturated Synchronous Reactance.

7.15.5 Saturated Synchronous Reactance.

7.15.6 Short-Circuit Ratio

7.16 Capability Curve of Synchronous Machine

7.17 Parallel Operation of Synchronous Generators.

Problems

Chapter 8

Direct-Current Machines

8.1 Introduction

8.2 Constructional Features.

8.3 Brief Review of Armature Windings

8.4 Elementary DC Machine.

8.5 Armature Voltage

8.6 Methods of Field Excitation

8.7 Armature Reaction

8.8 Commutation

8.9 Compensating Windings

8.10 Magnetization Curve.

8.11 DC Generators

8.12 Separately Excited Generator.

8.13 Self-Excited Shunt Generator.

8.14 Series Generator.

8.15 Compound Generator

8.16 Voltage Regulation

8.17 Developed Power..

8.18 Developed Torque.

8.19 Power Flow and Efficiency

8.20 DC Motor Characteristics.

8.20.1 Speed Regulation.

8.20.2 Speed-Current Characteristic

8.20.3 Speed-Torque Characteristic.

8.20.4 Torque-Current Characteristic

8.20.5 Internal Generated Voltage-Current Characteristic.

8.21 Control of DC Motors.

8.22 DC Motor Starting..

8.23 DC Motor Braking.

Problems

Chapter 9

Single-Phase and Special-Purpose Motors.

9.1 Introduction

9.2 Single-Phase Induction Motors

9.2.1 Equivalent Circuit..

9.2.2 Performance Analysis

9.3 Starting of Single-Phase Induction Motors..

9.4 Classification of Single-Phase Induction Motors

9.4.1 Split-Phase Motors

9.4.2 Capacitor-Start Motors.

9.4.3 Capacitor-Run Motors

untented

9.4.4 Capacitor-Start Capacitor-Run Motors..

9.4.5 Shaded-Pole Motors

9.5 Universal Motors

9.6 Single-Phase Synchronous Motors.

9.6.1 Reluctance Motors.

9.6.2 Hysteresis Motors.

9.6.3 Stepper Motors

9.7 Subsynchronous Motors

9.8 Permanent-Magnet DC Motors

Problems

Chapter 10 Transients and Dynamics of Electric Machines.

10.1 Introduction

10.2 DC Machines

10.3 Separately Excited DC Generator

10.3.1 Field-Circuit Transient

10.3.2 Armature-Circuit Transient..

10.4 Separately Excited DC Motor..

10.5 Synchronous Generator Transients..

10.6 Short-Circuit Transients

10.7 Transient Stability.

10.8 Swing Equation

Problems

Chapter 11 Renewable Energy

11.1 Introduction

11.2 Renewable Energy

11.3 Impact of Dispersed Storage and Generation.

11.4 Integrating Renewables into Power Systems.

11.5 Distributed Generation.

11.6 Renewable Energy Penetration.

11.7 Active Distribution Network

11.8 Concept of Microgrid.

References

Chapter 12 Wind Energy and Wind Energy Conversion System (WECS).

12.1 Introduction

12.2 Advantages and Disadvantages of Wind Energy Conversion Systems.

12.2.1 Advantages of a Wind Energy Conversion System..

12.2.2 Disadvantages of a Wind Energy Conversion System.

12.3 Categories of Wind Turbines.

12.4 Visual Impact of Wind Turbines

12.5 Types of Generators Used in Wind Turbines

12.6 Wind Turbine Operating Systems

12.6.1 Constant-Speed Wind Turbines..

12.6.2 Variable-Speed Wind Turbine System

12.7 Meteorology of Wind

12.8 Power in the Wind

12.9 Effects of a Wind Force..

12.10 Impact of Tower Height on Wind Power

12.11 Wind Measurements..

12.12 Characteristics of a Wind Generator

12.13 Efficiency and Performance

12.14 Efficiency of a Wind Turbine

12.14.1 Generator Efficiency.

12.14.2 Gearbox

12.14.3 Overall Efficiency

12.15 Other Factors to Define the Efficiency.

12.16 Grid Connection

12.17 Some Further Issues Related to Wind Energy

12.18 Development of Transmission System for Wind Energy in the United States.

12.19 Energy Storage

12.20 Wind Power Forecasting..

Problems

References

Chapter 13 Solar Energy Systems..

13.1 Introduction

13.2 Crystalline Silicon.

13.3 Effect of Sunlight on Solar Cell’s Performance

13.4 Effects of Changing Strength of the Sun on a Solar Cell.

13.5 Temperature’s Effect on Cell Characteristics.

13.6 Efficiency of Solar Cells.

13.7 Interconnection of Solar Cells

13.8 Overall System Configuration.

13.9 Thin-Film PV

13.10 Concentrating PV

13.11 PV Balance of Systems..

13.12 Types of Conversion Technologies

13.13 Linear CSP Systems

13.14 Power Tower CSP Systems

13.15 Dish/Engine CSP Systems

13.16 PV Applications.

13.16.1 Utility-Interactive PV Systems.

13.16.2 Stand-Alone PV Systems

Problems

References

Chapter 14 Energy Storage Systems.

14.1 Introduction

14.2 Storage Systems.

14.3 Storage Devices

14.3.1 Large Hydro

14.3.2 Compressed-Air Storage

14.3.3 Pumped Hydro

14.3.4 Hydrogen

14.3.5 High-Power Flow Batteries

14.3.6 High-Power Flywheels

14.3.7 High-Power Supercapacitors.

14.3.8 Superconducting Magnetic Energy Storage.

14.3.9 Heat or Cold Storage.

14.4 Battery Types.

14.4.1 Secondary Batteries

14.4.2 Sodium-Sulfur Batteries

14.4.3 Flow Battery Technology.

14.4.3.1 Zinc-Bromine Flow Battery.

14.4.3.2 Vanadium Redox Flow Battery

14.4.4 Lithium-Ion Batteries

14.4.4.1 Lithium Titanate Batteries

14.4.4.2 Lithium Iron Phosphate Batteries.

14.4.5 Lead-Acid Batteries.

14.4.5.1 Advanced Lead-Acid Batteries.

14.4.6 Nickel-Cadmium Batteries.

14.5 Operational Problems in Battery Usage.

14.6 Fuel Cells.

14.6.1 Types of Fuel Cells

14.6.1.1 Polymer Electrolyte Membrane

14.6.1.2 Phosphoric Acid Fuel Cell.

14.6.1.3 Molten Carbonate Fuel Cell.

14.6.1.4 Solid Oxide Fuel Cell

References

Chapter 15 The Smart Grid

15.1 Introduction

15.2 Need for Establishment of Smart Grid.

15.3 Roots of the Motivation for the Smart Grid

15.4 Distribution Automation

15.5 Active Distribution Networks.

15.6 Volt/Var Control in Distribution Networks

15.6.1 Traditional Approach to Volt/Var Control in the Distribution Networks

15.6.2 SCADA Approach to Control Volt/Var in the Distribution Networks

15.6.3 Integrated Volt/Var Control Optimization

15.7 Existing Electric Power Grid.

15.8 Supervisory Control and Data Acquisition

15.9 Advanced SCADA Concepts.

15.10 Substation Controllers

15.11 Advanced Developments for Integrated Substation Automation.

15.12 Evolution of Smart Grid

15.13 Smart Microgrids

15.14 Topology of a Microgrid.

15.15 Topology of a Smart Grid.

15.16 Standards of Smart Grids

15.17 Existing Challenges to the Application of the Concept of Smart Grids

References

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