Electric Power Systems: A Conceptual Introduction
Alexandra von Meier
- 出版商: IEEE
- 出版日期: 2006-07-01
- 售價: $4,680
- 貴賓價: 9.5 折 $4,446
- 語言: 英文
- 頁數: 328
- 裝訂: Hardcover
- ISBN: 0471178594
- ISBN-13: 9780471178590
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商品描述
Description
A clear explanation of the technology for producing and delivering electricity
Electric Power Systems explains and illustrates how the electric grid works in a clear, straightforward style that makes highly technical material accessible. It begins with a thorough discussion of the underlying physical concepts of electricity, circuits, and complex power that serves as a foundation for more advanced material. Readers are then introduced to the main components of electric power systems, including generators, motors and other appliances, and transmission and distribution equipment such as power lines, transformers, and circuit breakers. The author explains how a whole power system is managed and coordinated, analyzed mathematically, and kept stable and reliable.
Recognizing the economic and environmental implications of electric energy production and public concern over disruptions of service, this book exposes the challenges of producing and delivering electricity to help inform public policy decisions. Its discussions of complex concepts such as reactive power balance, load flow, and stability analysis, for example, offer deep insight into the complexity of electric grid operation and demonstrate how and why physics constrains economics and politics.
Although this survival guide includes mathematical equations and formulas, it discusses their meaning in plain English and does not assume any prior familiarity with particular notations or technical jargon. Additional features include:
* A glossary of symbols, units, abbreviations, and acronyms
* Illustrations that help readers visualize processes and better understand complex concepts
* Detailed analysis of a case study, including a Web reference to the case, enabling readers to test the consequences of manipulating various parameters
With its clear discussion of how electric grids work, Electric Power Systems is appropriate for a broad readership of professionals, undergraduate and graduate students, government agency managers, environmental advocates, and consumers.
Table of Contents
Preface.1. The Physics of Electricity.
1.1 Basic Quantities.
1.1.1 Introduction.
1.1.2 Charge.
1.1.3 Potential or Voltage.
1.1.4 Ground.
1.1.5 Conductivity.
1.1.6 Current.
1.2 Ohm’s law.
1.2.1 Resistance.
1.2.2 Conductance.
1.2.3 Insulation.
1.3 Circuit Fundamentals.
1.3.1 Static Charge.
1.3.2 Electric Circuits.
1.3.3 Voltage Drop.
1.3.4 Electric Shock.
1.4 Resistive Heating.
1.4.1 Calculating Resistive Heating.
1.4.2 Transmission Voltage and Resistive Losses.
1.5 Electric and Magnetic Fields.
1.5.1 The Field as a Concept.
1.5.2 Electric Fields.
1.5.3 Magnetic Fields.
1.5.4 Electromagnetic Induction.
1.5.5 Electromagnetic Fields and Health Effects.
1.5.6 Electromagnetic Radiation.
2. Basic Circuit Analysis.
2.1 Modeling Circuits.
2.2 Series and Parallel Circuits.
2.2.1 Resistance in Series.
2.2.2 Resistance in Parallel.
2.2.3 Network Reduction.
2.2.4 Practical Aspects.
2.3 Kirchhoff’s Laws.
2.3.1 Kirchhoff’s Voltage Law.
2.3.2 Kirchhoff’s Current Law.
2.3.3 Application to Simple Circuits.
2.3.4 The Superposition Principle.
2.4 Magnetic Circuits.
3. AC Power.
3.1 Alternating Current and Voltage.
3.1.1 Historical Notes.
3.1.2 Mathematical Description.
3.1.3 The rms Value.
3.2 Reactance.
3.2.1 Inductance.
3.2.2 Capacitance.
3.2.3 Impedance.
3.2.4 Admittance.
3.3 Power.
3.3.1 Definition of Electric Power.
3.3.2 Complex Power.
3.3.3 The Significance of Reactive Power.
3.4 Phasor Notation.
3.4.1 Phasors as Graphics.
3.4.2 Phasors as Exponentials.
3.4.3 Operations with Phasors.
4. Generators.
4.1 The Simple Generator.
4.2 The Synchronous Generator.
4.2.1 Basic Components and Functioning.
4.2.2 Other Design Aspects.
4.3 Operational Control of Synchronous Generators.
4.3.1 Single Generator: Real Power.
4.3.2 Single Generator: Reactive Power.
4.3.3 Multiple Generators: Real Power.
4.3.4 Multiple Generators: Reactive Power.
4.4 Operating Limits.
4.5 The Induction Generator.
4.5.1 General Characteristics.
4.5.2 Electromagnetic Characteristics.
4.6 Inverters.
5. Loads.
5.1 Resistive Loads.
5.2 Motors.
5.3 Electronic Devices.
5.4 Load from the System Perspective.
5.4.1 Coincident and Noncoincident Demand.
5.4.2 Load Profiles and Load Duration Curve.
5.5 Single- and Multiphase Connections.
6. Transmission and Distribution.
6.1 System Structure.
6.1.1 Historical Notes.
6.1.2 Structural Features.
6.1.3 Sample Diagram.
6.1.4 Topology.
6.1.5 Loop Flow.
6.1.6 Stations and Substations.
6.1.7 Reconfiguring the System.
6.2 Three-Phase Transmission.
6.2.1 Rationale for Three Phases.
6.2.2 Balancing Loads.
6.2.3 Delta and Wye Connections.
6.2.4 Per-Phase Analysis.
6.2.5 Three-Phase Power.
6.2.6 D.C. Transmission.
6.3 Transformers.
6.3.1 General Properties.
6.3.2 Transformer Heating.
6.3.3 Delta and Wye Transformers.
6.4 Characteristics of Power Lines.
6.4.1 Conductors.
6.4.2 Towers, Insulators, and Other Components.
6.5 Loading.
6.5.1 Thermal Limits.
6.5.2 Stability Limit.
6.6 Voltage Control.
6.7 Protection.
6.7.1 Basics of Protection and Protective Devices.
6.7.2 Protection Coordination.
7. Power Flow Analysis.
7.1 Introduction.
7.2 The Power Flow Problem.
7.2.1 Network Representation.
7.2.2 Choice of Variables.
7.2.3 Types of Buses.
7.2.4 Variables for Balancing Real Power.
7.2.5 Variables for Balancing Reactive Power.
7.2.6 The Slack Bus.
7.2.7 Summary of Variables.
7.3 Example with Interpretation of Results.
7.3.1 Six-Bus Example.
7.3.2 Tweaking the Case.
7.3.3 Conceptualizing Power Flow.
7.4 Power Flow Equations and Solution Methods.
7.4.1 Derivation of Power Flow Equations.
7.4.2 Solution Methods.
7.4.3 Decoupled Power Flow.
7.5 Applications and Optimal Power Flow.
8. System Performance.
8.1 Reliability.
8.1.1 Measures of Reliability.
8.1.2 Valuation of Reliability.
8.2 Security.
8.3 Stability.
8.3.1 The Concept of Stability.
8.3.2 Steady-State Stability.
8.3.3 Dynamic Stability.
8.3.4 Voltage Stability.
8.4 Power Quality.
8.4.1 Voltage.
8.4.2 Frequency.
8.4.3 Waveform.
9. System Operation, Management, and New Technology.
9.1 Operation and Control on Different Time Scales.
9.1.1 The Scale of a Cycle.
9.1.2 The Scale of Real-Time Operation.
9.1.3 The Scale of Scheduling.
9.1.4 The Planning Scale.
9.2 New Technology.
9.2.1 Storage.
9.2.2 Distributed Generation.
9.2.3 Automation.
9.2.4 FACTS.
9.3 Human Factors.
9.3.1 Operators and Engineers.
9.3.2 Cognitive Representations of Power Systems.
9.3.3 Operational Criteria.
9.3.4 Implications for Technological Innovation.
9.4 Implications for Restructuring.
Appendix: Symbols, Units, Abbreviations, and Acronyms.
Index.
商品描述(中文翻譯)
描述
本書清楚解釋了電力生產和傳輸技術。
《Electric Power Systems》以清晰、直接的風格說明和展示電網的運作,使高度技術性的內容變得易於理解。書中首先徹底討論了電力、電路和複雜功率的基本物理概念,這些概念為更高級的內容奠定了基礎。接著,讀者將了解電力系統的主要組成部分,包括發電機、馬達及其他設備,以及傳輸和配電設備,如電力線、變壓器和斷路器。作者解釋了整個電力系統是如何管理和協調的,並進行數學分析,以保持系統的穩定性和可靠性。
考慮到電能生產的經濟和環境影響,以及公眾對服務中斷的關注,本書揭示了生產和傳輸電力所面臨的挑戰,以幫助制定公共政策決策。書中對於複雜概念的討論,例如無功功率平衡、負載流和穩定性分析,提供了對電網運作複雜性的深入見解,並展示了物理學如何限制經濟和政治。
儘管本生存指南包含數學方程式和公式,但它用簡單的英語討論其意義,並不假設讀者對特定符號或技術術語有任何先前的熟悉度。其他特色包括:
* 符號、單位、縮寫和首字母縮略詞的詞彙表
* 幫助讀者可視化過程並更好理解複雜概念的插圖
* 詳細分析案例研究,包括該案例的網路參考,讓讀者能測試操控各種參數的後果
《Electric Power Systems》以其清晰的電網運作討論,適合廣泛的讀者群,包括專業人士、本科生和研究生、政府機構管理者、環保倡導者及消費者。
目錄
前言
1. 電力的物理學
1.1 基本量
1.1.1 介紹
1.1.2 電荷
1.1.3 潛力或電壓
1.1.4 接地
1.1.5 導電性
1.1.6 電流
1.2 歐姆定律
1.2.1 電阻
1.2.2 導納
1.2.3 絕緣
1.3 電路基礎
1.3.1 靜電荷
1.3.2 電路
1.3.3 電壓降
1.3.4 電擊
1.4 電阻加熱
1.4.1 計算電阻加熱
1.4.2 傳輸電壓和電阻損耗
1.5 電場和磁場