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# Fundamentals of Electric Power Engineering From Electromagnetics to Power Systems

PDF Free Download | Fundamentals of Electric Power Engineering From Electromagnetics to Power Systems by Massimo Ceraolo and Davide Poli

## Contents of Fundamentals of Electric Power Engineering

• PART I PRELIMINARY MATERIAL
• Introduction
• The Scope of Electrical Engineering
• This Book’s Scope and Organization
• International Standards and Their Usage in This Book
• International Standardization Bodies
• The International System of Units (SI)
• Graphic Symbols for Circuit Drawings
• Names, Symbols, and Units
• Other Conventions
• Specific Conventions and Symbols in This Book
• Boxes Around Text
• Grayed Boxes
• Terminology
• Acronyms
• Reference Designations
• The Fundamental Laws of Electromagnetism
• Vector Fields
• Definition of E and B; Lorentz’s Force Law
• Gauss’s Law
• Ampère’s Law and Charge Conservation
• Magnetic Field and Matter
• Gauss’s Law for Magnetism
• Constitutive Equations of Matter
• General Considerations
• Continuous Charge Flow Across Conductors
• Maxwell’s Equations and Electromagnetic Waves
• Historical Notes
• Short Biography of Gauss
• Short Biography of Maxwell
• Short Biography of Ampère
• Short Biography of Lorentz
• PART II ELECTRIC CIRCUIT CONCEPT AND ANALYSIS
• Circuits as Modelling Tools
• Introduction
• Definitions
• Charge Conservation and Kirchhoff’s Current Law
• The Charge Conservation Law
• Charge Conservation and Circuits
• The Electric Current
• Formulations of Kirchhoff’s Current Law
• Circuit Potentials and Kirchhoff’s Voltage Law
• The Electric Field Inside Conductors
• Formulations of Kirchhoff’s Voltage Law
• Solution of a Circuit
• Determining Linearly Independent Kirchhoff Equations
• (Loop-Cuts Method)
• Constitutive Equations
• Number of Variables and Equations
• The Substitution Principle
• Kirchhoff’s Laws in Comparison with Electromagnetism Laws
• Power in Circuits
• Tellegen’s Theorem and Energy Conservation Law in Circuits
• Historical Notes
• Short Biography of Kirchhoff
• Short Biography of Tellegen
• Techniques for Solving DC Circuits
• Introduction
• Modelling Circuital Systems with Constant Quantities as Circuits
• The Basic Rule
• Resistors: Ohm’s Law
• Ideal and “Real” Voltage and Current Sources,
• Solving Techniques
• Basic Usage of Combined Kirchhoff-Constitutive Equations
• Nodal Analysis
• Mesh Analysis
• Series and Parallel Resistors; Star/Delta Conversion
• Voltage and Current Division
• Linearity and Superposition
• Thévenin’s Theorem
• Power and Energy and Joule’s Law
• More Examples
• Resistive Circuits Operating with Variable Quantities
• Historical Notes
• Short Biography of Ohm
• Short Biography of Thévenin
• Short Biography of Joule
• Proposed Exercises
• Techniques for Solving AC Circuits
• Introduction
• Energy Storage Element
• Power in Time-Varying Circuits
• The Capacitor
• Inductors and Magnetic Circuits
• Modelling Time-Varying Circuital Systems as Circuits
• The Basic Rule
• Modelling Circuital Systems When Induced EMFs Between Wires Cannot
• Be Neglected
• Mutual Inductors and the Ideal Transformer
• Systems Containing Ideal Transformers: Magnetically Coupled
• Circuits
• Simple R–L and R–C Transients
• AC Circuit Analysis
• Sinusoidal Functions
• Steady-State Behaviour of Linear Circuits Using Phasors
• AC Circuit Passive Parameters
• The Phasor Circuit
• Circuits Containing Sources with Different Frequencies
• Power in AC Circuits
• Instantaneous, Active, Reactive, and Complex Powers
• Circuits Containing Sources Having Different Frequencies
• Conservation of Complex, Active, and Reactive Powers
• Power Factor Correction
• Historical Notes
• Short Biography of Boucherot
• Proposed Exercises
• Three-Phase Circuits
• Introduction
• From Single-Phase to Three-Phase Systems
• Modelling Three-Phase Lines When Induced EMFs Between Wires Are
• Not Negligible
• The Single-Phase Equivalent of the Three-Phase Circuit
• Power in Three-Phase Systems
• Single-Phase Feeding from Three-Phase Systems
• Historical Notes
• Short Biography of Tesla
• Proposed Exercises
• PART III ELECTRIC MACHINES AND STATIC CONVERTERS
• Magnetic Circuits and Transformers
• Introduction
• Magnetic Circuits and Single-Phase Transformers
• Three-Phase Transformers
• Magnetic Hysteresis and Core Losses
• Open-Circuit and Short-Circuit Tests
• Permanent Magnets
• Proposed Exercises
• Fundamentals of Electronic Power Conversion
• Introduction
• Power Electronic Devices
• Diodes, Thyristors, Controllable Switches
• The Branch Approximation of Thyristors and Controllable Switches
• Diodes
• Thyristors,
• Insulated-Gate Bipolar Transistors (IGBTs)
• Summary of Power Electronic Devices
• Power Electronic Converters
• Rectifiers
• DC–DC Converters
• Inverters
• Analysis of Periodic Quantities
• Introduction
• Periodic Quantities and Fourier’s Series
• Properties of Periodic Quantities and Examples
• Frequency Spectrum of Periodic Signals
• Filtering Basics
• The Basic Principle
• Summary
• Principles of Electromechanical Conversion
• Introduction
• Electromechanical Conversion in a Translating Bar
• Basic Electromechanics in Rotating Machines
• Rotating Electrical Machines and Faraday’s Law
• Generation of Torques in Rotating Machines
• Electromotive Force and Torque in Distributed Coils
• The Uniform Magnetic Field Equivalent
• Reluctance-Based Electromechanical Conversion
• DC Machines and Drives and Universal Motors
• Introduction
• The Basic Idea and Generation of Quasi-Constant Voltage
• Operation of a DC Generator Under Load
• Different Types of DC Machines
• Generators and Motors
• Starting a DC Motor with Constant Field Current
• Independent, Shunt, PM, and Series Excitation Motors
• Universal Motors
• DC Electric Drives
• Proposed Exercises
• Synchronous Machines and Drives
• The Basic Idea and Generation of EMF
• The Rotating Magnetic Field
• Stator–Rotor Interaction
• The Phasor Diagram and the Single-Phase Equivalent Circuit
• Practical Considerations
• Power Exchanges
• Generators and Motors
• Permanent-Magnet Synchronous Machines
• Synchronous Electric Drives
• Introduction
• PM, Inverter-Fed, Synchronous Motor Drives
• Control Implementation
• Historical Notes
• Short Biography of Ferraris and Behn-Eschemburg
• Proposed Exercises
• Induction Machines and Drives
• Induction Machine Basics
• Machine Model and Analysis
• Induction Machine Motor Drives
• Single-Phase Induction Motors
• Introduction
• Different Motor Types
• Proposed Exercises
• PART IV POWER SYSTEMS BASICS
• Low-Voltage Electrical Installations
• Another Look at the Concept of the Electric Power System
• Electrical Installations: A Basic Introduction
• Cables
• Maximum Permissible Current and Choice of the Cross-Sectional
• Area
• Determining Voltage Drop
• Overcurrents and Overcurrent Protection
• Short Circuits
• Breaker Characteristics and Protection Against Overcurrents
• Protection in Installations: A Long List
• Electric Shock and Protective Measures
• Introduction
• Electricity and the Human Body
• Effects of Current on Human Beings
• The Mechanism of Current Dispersion in the Earth
• A Circuital Model for the Human Body
• The Human Body in a Live Circuit
• System Earthing: TT, TN, and IT
• Protection Against Electric Shock
• Direct and Indirect Contacts
• Basic Protection (Protection Against Direct Contact)
• Fault Protection (Protection Against Indirect Contact)
• SELV Protection System
• The Residual Current Device (RCD) Principle of Operation
• What Else?
• References
• Large Power Systems: Structure and Operation
• Aggregation of Loads and Installations: The Power System
• Toward AC Three-Phase Systems
• Electricity Distribution Networks
• Transmission and Interconnection Grids
• Modern Structure of Power Systems and Distributed Generation
• Basics of Power System Operation
• Frequency Regulation
• Voltage Regulation
• Vertically Integrated Utilities and Deregulated Power Systems
• Recent Challenges and Smart Grids
• Renewable Energy Sources and Energy Storage
• Photovoltaic Plants
• Wind Power Plants
• Energy Storage
• Appendix: Transmission Line Modelling and Port-Based Circuits
• A Modelling Transmission Lines Through Circuits
• A Issues and Solutions When Displacement Currents are Neglected
• A Steady-State Analysis Considering Displacement Currents
• A Practical Considerations
• A Modelling Lines as Two-Port Components
• A Port-Based Circuits
• A Port-Based Circuit and Transmission Lines
• A A Sample Application

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