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作 者:科萨里(Kothari.D P),纳格拉斯(Nagrath.I J) 著
出 版 社:清华大学出版社
出版时间:2009-12-01
I S B N:9787302215745
| 《现代电力系统分析(第3版)》介绍了现代电力系统的运行、控制和分析方法。 第3版的主要特色 新增章节 电力系统安全性 状态估计 电力系统中的补偿装置(包括SVS和FACTS) 负荷预测 电压稳定 新增附录 MATLAB和SIMULINK在电力系统中的应用演示 基于计算机的电力系统实时控制 专家评论 《现代电力系统分析(第3版)》内容全面、组织合理、材料新颖,叙述清晰流畅,易于自学。同时,书中每一个概念和方法都有相应的算例进行说明。 |
| D P Kothari,is Professor, Centre for Energy Studies,Indian Institute of Technology, Delhi. He hasbeen Head of the Centre for Energy Studies(1995-97) and Principal (1997-98) VisvesvarayaRegional Engineering College, Nagpur. He has been Director-incharge, liT Delhi (2005), Deputy Director (Admn.) (2003-2006). Earlier (1982-83 and 1989), he was a visiting fellow at RMIT,Melbourne, Australia. He obtained his BE, ME and Ph.D degrees from BITS, Pilani. A fellow of the Institution of Engineers (India), fellow of National Academy of Engineering,fellow of National Academy of Sciences, Senior Member IEEE, Member IEE,Life Member ISTE, Professor Kothari has published/presented around 500papers in national and international journals/conferences. He has authored/co-authored more than 18 books, including Power System Optimization, ModernPower System Analysis, Electric Machines, Power System Transients, Theoryand Problems of Electric Machines and Basic Electrical Engineering. Hisresearch interests include power system control, optimization, reliability andenergy conservation. He has received the National Khosla award for LifetimeAchievements in Engineering for 2005 from liT Roorkee. I J Nagrath is Adjunct Professor, BITS, Pilani, and retired as Professor of electrical engineering and Deputy Director of Birla Institute of Technology and Science, Pilani. He obtained his BE with Hons. in electrical engineering from the University of Rajasthan in 1951 and MS from the University of Wisconsin in 1956. He has co-authored several successful books which include Electric Machines, Modern Power System Analysis and Systems: Modelling and Analysis. He has also published several research papers in prestigious national and international journals. |
| Preface to Third Edition Preface to First Edition 1. Introduction 1.1 A Perspective 1.2 Structure of Power Systems 1.3 Conventional Sources of Electric Energy 1.4 Renewable Energy Sources 1.5 Energy Storage 1.6 Growth of Power Systems in India 1.7 Energy Conservation 1.8 Deregulation 1.9 Distributed and Dispersed Generation 1.10 Environmental Aspects of Electric Energy Generation 1.11 Power System Engineers and Power System Studies 3! 1.12 Use of Computers and Microprocessors 1.13 Problems Facing Indian Power Industry and its Choices References 2. Inductance and Resistance of Transmission Lines 2.1 Introduction 2.2 Definition of Inductance 2.3 Flux Linkages of an Isolated Current-Carrying Conductor 2.4 Inductance of a Single-Phase Two-Wire Line 2.5 Conductor Types 2.6 Flux Linkages of one Conductor in a Group 2.7 Inductance of Composite Conductor Lines 2.8 Inductance of Three-Phase Lines 2.9 Double-Circuit Three-Phase Lines 2.10 Bundled Conductors 2.11 Resistance 2.12 Skin Effect and Proximity Effect Problems References 3. Capacitance of Transmission Lines 3.1 Introduction 3.2 Electric Field of a Long Straight Conductor 3.3 Potential Difference between two Conductors of a Group of Parallel Conductors 3.4 Capacitance of a Two-Wire Line 3.5 Capacitance of a Three-Phase Line with Equilateral Spacing 3.6 Capacitance of a Three-Phase Line with Unsymmetrical Spacing 3.7 Effect of Earth on Transmission Line Capacitance 3.8 Method of GMD (Modified) 3.9 Bundled Conductors Problems References 4. Representation of Power System Components 4.1 Introduction 4.2 Single-phase Solution of Balanced Three-phase Networks 4.3 One-Line Diagram and Impedance or Reactance Diagram 4.4 Per Unit (PU) System 4.5 Complex Power 4.6 Synchronous Machine 4.7 Representation of Loads Problems References 5. Characteristics and Performance of Power Transmission Lines 5.1 Introduction 5.2 Short Transmission Line 5.3 Medium Transmission Line 5.4 The Long Transmission Line——Rigorous Solution 5.5 Interpretation of the Long Line Equations 5.6 Ferranti Effect 5.7 Tuned Power Lines 5.8 The Equivalent Circuit of a Long Line 5.9 Power Flow through a Transmission Line 5.10 Methods of Voltage Control Problems References 6. Load Flow Studies 6.1 Introduction 6.2 Network Model Formulation 6.3 Formation of YBus by Singular Transformation 6.4 Load Flow Problem 6.5 Gauss-Seidel Method 6.6 Newton-Raphson (NR) Method 6.7 Decoupled Load Flow Methods 6.8 Comparison of Load Flow Methods 6.9 Control of Voltage Profile Problems References 7. 0 ptimal System Operation 7.1 Introduction 7.2 Optimal Operation of Generators on a Bus Bar 7.3 Optimal Unit Commitment (UC) 7.4 Reliability Considerations 7.5 Optimum Generation Scheduling 7.6 Optimal Load Flow Solution 7.7 Optimal Scheduling of Hydrothermal System Problems References 8. Automatic Generation and Voltage Control 8.1 Introduction 8.2 Load Frequency Control (Single Area Case) 8.3 Load Frequency Control and Economic Despatch Control 8.4 Two-Area Load Frequency Control 8.5 Optimal (Two-Area) Load Frequency Control 8.6 Automatic Voltage Control 8.7 Load Frequency Control with Generation Rate Constraints (GRCs) 8.8 Speed Governor Dead-Band and Its Effect on AGC 8.9 Digital LF Controllers 8.10 Decentralized Control Problems References 9. Symmetrical Fault Analysis 9.1 Introduction 9.2 Transient on a Transmission Line 9.3 Short Circuit of a Synchronous Machine (On No Load) 9.4 Short Circuit of a Loaded Synchronous Machine 9.5 SeIection of Circuit Breakers 9.6 Algorithm for Short Circuit Studies 9.7 ZBusFormulation Problems References 10. Symmetrical Components 10.1 Introduction 10.2 Symmetrical Component Transformation 10.3 Phase Shift in Star-Delta Transformers 10.4 Sequence Impedances of Transmission Lines 10.5 Sequence Impedances and Sequence Network of Power System 10.6 Sequence Impedances and Networks of Synchronous Machine 10.7 Sequence Impedances of Transmission Lines 10.8 Sequence Impedances and Networks of Transformers 10.9 Construction of Sequence Networks of a Power System Problems References 11. Unsymmetrical Fault Analysis 11.1 Introduction 11.2 Symmetrical Component Analysis of Unsymmetrical Faults 11.3 Single Line-To-Ground (LG) Fault 11.4 Line-To-Line (LL) Fault 11.5 Double Line-To-Ground (LLG) Fault 11.6 Open Conductor Faults 11.7 Bus Impedance Matrix Method For Analysis of Unsymmetrical Shunt Faults Problems References 12. Power System Stability 12.1 Introduction 12.2 Dynamics of a Synchronous Machine 12.3 Power Angle Equation 12.4 Node Elimination Technique 12.5 Simple Systems 12.6 Steady State Stability 12.7 Transient Stability 12.8 Equal Area Criterion 12.9 Numerical Solution of Swing Equation 12.10 Multimachine Stability 12.11 Some Factors Affecting Transient Stability Problems References 13. Power System Security 13.1 Introduction 13.2 System State Classification 13.3 Security Analysis 13.4 Contingency Analysis 13.5 Sensitivity Factors 13.6 Power System Voltage Stability References 14. An Introduction to State Estimation of Power Systems 14.1 Introduction 14.2 Least Squares Estimation: The Basic Solution 14.3 Static State Estimation of Power Systems 14.4 Tracking State Estimation of Power Systems 14.5 Some Computational Considerations 14.6 External System Equivalencing 14.7 Treatment of Bad Data 14.8 Network Observability and Pseudo-Measurements 14.9 Application of Power System State Estimation 5.5 Problems References 15. Compensation in Power Systems 15.1 Introduction 15.2 Loading Capability 15.3 Load Compensation 15.4 Line Compensation 15.5 Series Compensation 15.6 Shunt Compensators 15.7 Comparison between STATCOM and SVC 15.8 Flexible AC Transmission Systeins (FACTS) 56~ 15.9 Principle and Operation of Converters 15.10 Facts Controllers References 16. Load Forecasting Technique 16.1 Introduction 16.2 Forecasting Methodology 16.3 Estimation of Average and Trend Terms 16.4 Estimation of Periodic Components 16.5 Estimation of Ys (k): Time Series Approach 16.6 Estimation of Stochastic Component: Kalman Filtering Approach 16.7 Long-Term Load Predictions Using Econometric Models 16.8 Reactive Load Forecast References 17. Voltage Stability 17.1 Introduction 17.2 Comparison of Angle and Voltage Stability 17.3 Reactive Power Flow and Voltage Collapse 17.4 Mathematical Formulation of Voltage Stability Problem 17.5 Voltage Stability Analysis 17.6 Prevention of Voltage Collapse 17.7 State-of-the-Art, Future Trends and Challenges References Appendix A: Introduction to Vector and Matrix Algebra Appendix B: Generalized Circuit Constants Appendix C: Triangular Factorization and Optimal Ordering Appendix D: Elements of Power System Jacobian Matrix Appendix E: Kuhn.Tucker Theorem Appendix F: Real-time Computer Control of Power Systems Appendix G: Introduction to MATLAB and SIMULINK Answers to Problems Index |
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