A highly accessible resource covering the basics of the design and operation of electrical power systems with minimal technical background required Electrical Power System Essentials delivers a thorough introduction to the electrical power system and its functioning, and the changes that come with the worldwide energy transition process. This revised and updated Third Edition includes new material on HVDC developments, electricity markets, capacity calculation (NTC and flow-based), power system protection, and energy storage. Discussions on how renewable sources play a more dominant role in…mehr
A highly accessible resource covering the basics of the design and operation of electrical power systems with minimal technical background required Electrical Power System Essentials delivers a thorough introduction to the electrical power system and its functioning, and the changes that come with the worldwide energy transition process. This revised and updated Third Edition includes new material on HVDC developments, electricity markets, capacity calculation (NTC and flow-based), power system protection, and energy storage. Discussions on how renewable sources play a more dominant role in the generation of electrical energy and the effects they have on the control and operation of the grid and electricity markets are also included. Written in the accessible style that has made previous editions so popular with readers, this book restricts math content to the Appendix in order to maintain an easy reading experience of the main text while still providing complete coverage. A companion website includes downloadable teaching materials and accessory videos are viewable on the Wiley website and YouTube. Topics discussed in the book include: Generation of electric energy, covering nuclear fission, wind energy and wind turbine concepts, hydropower and pumped storage, and solar powerElectricity markets, covering gas scarcity, its influence on the marginal price of electricity, and negative energy pricesFuture power systems, covering higher harmonics, increased use of cables instead of overhead transmission lines, distributed generation and power-electronic interfacesTransmission of electric energy, covering DC circuit breakers, wide area measurement systems, and distribution networks Electrical Power System Essentials is a perfect textbook for second- and third-year undergraduate electrical engineering students who need an accessible course text introducing concepts in power system engineering. The text is also valuable for other students and professionals who require an up-to-date reference on power systems technology.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Dr. Pieter Schavemaker, Managing Director of E-Bridge Consulting B.V., has worked in the energy sector for more than 25 years. Pieter has a varied experience as assistant professor at the Delft University of Technology, with a large manufacturer of power system equipment (ABB), with a Transmission System Operator (Tennet TSO), and as a consultant. Lou van der Sluis worked as researcher and test engineer at KEMA's High-Power and High-Voltage Laboratories. From 1992 until his retirement in 2015 he held the chair of full-time Professor in Electrical Power Systems in the Electrical Sustainable Energy department of the Delft University of Technology. Prof. van der Sluis is a life-senior member of IEEE.
Inhaltsangabe
Preface List of Abbreviations List of Symbols
1 Introduction to Power System Analysis 1.1 Introduction 1.2 Scope of the Material 1.3 General Characteristics of Power Systems 1.4 Phasors 1.5 Equivalent Line-to-neutral Diagrams 1.6 Power in Single-phase Circuits 1.7 Power in Three-phase Circuits 1.8 Per-unit Normalization 1.9 Power System Structure Problems References
2 The Generation of Electric Energy 2.1 Introduction 2.2 Thermal Power Plants 2.3 Nuclear Power Plants 2.4 Renewable Energy 2.5 The Synchronous Machine Problems References
3 The Transmission of Electric Energy 3.1 Introduction 3.2 Transmission and Distribution Network 3.3 Network Structures 3.4 Substations 3.5 Substation Concepts 3.6 Protection of Transmission and Distribution Networks 3.7 Surge Arresters¿ 3.8 Transformers 3.9 Power Carriers 3.10 SF6 Alternatives 3.11 High-Voltage Direct Current Transmission From AC to DC Problems References
4 The Utilization of Electric Energy 4.1 Introduction 4.2 Types of Load 4.3 Classification of Grid Users
5 Power System Control 5.1 Introduction 5.2 Basics of Power System Control 5.3 Active Power and Frequency Control 5.4 Voltage Control and Reactive Power 5.5 Control of Transported Power 5.6 Flexible AC Transmission Systems (FACTS) Problems References
6 Energy Management Systems 6.1 Introduction 6.2 Load Flow or Power Flow Computation 6.3 Optimal Power Flow 6.4 State Estimator
8 Future Power Systems 8.1 Introduction 8.2 Renewable Energy 8.3 Decentralized or Distributed Generation 8.4 Power-Electronics in the Power System 8.5 Energy Storage 8.6 Blackouts and Chaotic Phenomena 8.7 Wide Area Monitoring of Power Systems
A Maxwell's Laws A.1 Introduction A.2 Power Series Approach to Time-Varying Fields A.3 Quasi-static Field of a Parallel-plate Capacitor A.4 Quasi-static Field of a Single-turn Inductor A.5 Quasi-static Field of a Resistor A.6 Circuit Modeling Reference
B Power Transformer Model B.1 Introduction B.2 The Ideal Transformer B.3 Magnetically Coupled Coils B.4 The Nonideal Transformer B.5 Three-Phase Transformer
C Synchronous Machine Model C.1 Introduction C.2 The Primitive Synchronous Machine C.3 The Single-Phase Synchronous Machine C.4 The Three-Phase Synchronous Machine C.5 Synchronous Generator in the Power System
D Induction Machine Model D.1 Introduction D.2 The Basic Principle of the Induction Machine D.3 The Magnetic Field in the Air Gap D.4 A Simple Circuit Model for the Induction Machine D.5 Induction Motor in the Power System
E The Representation of Lines and Cables E.1 Introduction E.2 The Long Transmission Line E.3 The Medium-Length Transmission Line E.4 The Short Transmission Line E.5 Comparison of the Three Line Models E.6 The Underground Cable
F The Physics behind the Maxwell Equations F.1 Introduction F.2 Ampère's Law F.3 Faraday's Law F.4 Maxwell's Equations
1 Introduction to Power System Analysis 1.1 Introduction 1.2 Scope of the Material 1.3 General Characteristics of Power Systems 1.4 Phasors 1.5 Equivalent Line-to-neutral Diagrams 1.6 Power in Single-phase Circuits 1.7 Power in Three-phase Circuits 1.8 Per-unit Normalization 1.9 Power System Structure Problems References
2 The Generation of Electric Energy 2.1 Introduction 2.2 Thermal Power Plants 2.3 Nuclear Power Plants 2.4 Renewable Energy 2.5 The Synchronous Machine Problems References
3 The Transmission of Electric Energy 3.1 Introduction 3.2 Transmission and Distribution Network 3.3 Network Structures 3.4 Substations 3.5 Substation Concepts 3.6 Protection of Transmission and Distribution Networks 3.7 Surge Arresters¿ 3.8 Transformers 3.9 Power Carriers 3.10 SF6 Alternatives 3.11 High-Voltage Direct Current Transmission From AC to DC Problems References
4 The Utilization of Electric Energy 4.1 Introduction 4.2 Types of Load 4.3 Classification of Grid Users
5 Power System Control 5.1 Introduction 5.2 Basics of Power System Control 5.3 Active Power and Frequency Control 5.4 Voltage Control and Reactive Power 5.5 Control of Transported Power 5.6 Flexible AC Transmission Systems (FACTS) Problems References
6 Energy Management Systems 6.1 Introduction 6.2 Load Flow or Power Flow Computation 6.3 Optimal Power Flow 6.4 State Estimator
8 Future Power Systems 8.1 Introduction 8.2 Renewable Energy 8.3 Decentralized or Distributed Generation 8.4 Power-Electronics in the Power System 8.5 Energy Storage 8.6 Blackouts and Chaotic Phenomena 8.7 Wide Area Monitoring of Power Systems
A Maxwell's Laws A.1 Introduction A.2 Power Series Approach to Time-Varying Fields A.3 Quasi-static Field of a Parallel-plate Capacitor A.4 Quasi-static Field of a Single-turn Inductor A.5 Quasi-static Field of a Resistor A.6 Circuit Modeling Reference
B Power Transformer Model B.1 Introduction B.2 The Ideal Transformer B.3 Magnetically Coupled Coils B.4 The Nonideal Transformer B.5 Three-Phase Transformer
C Synchronous Machine Model C.1 Introduction C.2 The Primitive Synchronous Machine C.3 The Single-Phase Synchronous Machine C.4 The Three-Phase Synchronous Machine C.5 Synchronous Generator in the Power System
D Induction Machine Model D.1 Introduction D.2 The Basic Principle of the Induction Machine D.3 The Magnetic Field in the Air Gap D.4 A Simple Circuit Model for the Induction Machine D.5 Induction Motor in the Power System
E The Representation of Lines and Cables E.1 Introduction E.2 The Long Transmission Line E.3 The Medium-Length Transmission Line E.4 The Short Transmission Line E.5 Comparison of the Three Line Models E.6 The Underground Cable
F The Physics behind the Maxwell Equations F.1 Introduction F.2 Ampère's Law F.3 Faraday's Law F.4 Maxwell's Equations
Solutions Further Reading Index
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