HVDC Power Transmission Systems: Technology and System InteractionsHvdc Transmission Technology Is Fast Advancing And Its Applications Are Rapidly Expanding. This Book Presents The Various Aspects Of Hvdc Technology In Sufficient Depth To A Beginner. In Addition, It Also Includes The Analysis And Simulation Of Ac-Dc System Interactions Which Are Of Importance In The Planning, Design And Operation Of Hvdc Systems. The Book Gives Up-To-Date Information And Integrates Material That Has Been Scattered In Several Journals.The Book Is Divided Into Two Parts. The First Part Has 9 Chapters And Covers The Techniques And Components Of Hvdc Systems In Detail. The Emphasis Is On The Unique Components Of Hvdc Systems, Such As Thyristor Valves, Converters, Control, Protection And Harmonic Filters. One Chapter Each Is Devoted To Each Of These Items. Reactive Power Control And Multiterminal Dc System Operation Are Also Included As Two Separate Chapters. Static Var Systems Used For Reactive Power Control In Converter Stations Are Also Discussed.The Second Part Of The Book Deals With The Modelling, Analysis And Simulation Of Ac/Dc Systems. Seven Chapters Are Included In This Part Which Cover Component Models, Power Flow, Transient Stability, Dynamic Stability And Power Modulation, Harmonic And Torsional Interactions, Simulation Of Converters And Hvdc Systems. The Coverage Is Fairly Detailed And Includes Some New Information Not Published Before.The Book Should Be Of Interest To Graduate Students, Researchers And Engineers From Utilities/Industries Who Are Involved With Hvdc Power Transmission. |
From inside the book
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Page xii
... Valve Model 264 16.3 Gate Pulse Generation 265 16.4 Generation of Control Voltage 266 16.5 Transformer Model 267 16.6 Converter Model 270 16.7 Transient Simulation of DC and AC Systems 278 264 Appendix A Index 284 287 1. DC Power ...
... Valve Model 264 16.3 Gate Pulse Generation 265 16.4 Generation of Control Voltage 266 16.5 Transformer Model 267 16.6 Converter Model 270 16.7 Transient Simulation of DC and AC Systems 278 264 Appendix A Index 284 287 1. DC Power ...
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Contents
Thyristor Valve | 21 |
Analysis of HVDC Converters | 42 |
Converter and HVDC System Control | 76 |
Converter Faults and Protection | 97 |
Smoothing Reactor and DC Line | 110 |
Reactive Power Control | 130 |
Harmonics and Filters | 145 |
Multiterminal DC Systems | 159 |
Power Flow Analysis in ACDC Systems | 188 |
Transient Stability Analysis | 199 |
Dynamic Stability and Power Modulation | 211 |
Harmonic and Torsional Interactions | 231 |
76 | 250 |
Simulation of HVDC Systems | 252 |
Digital Dynamic Simulation of Converters and DC Systems | 264 |
288 | |
Common terms and phrases
AC and DC AC system AC/DC AC/DC systems analysis bipolar capacitive capacitor characteristics CIGRE commutation failure components conductor constant converter bridge converter bus converter control converter model converter stations converter transformer current control damping DC current DC filter DC line DC network DC power DC voltage delay angle digital simulation direct current dynamic equations equivalent circuit extinction angle firing angle fundamental frequency gate pulse given harmonic HVDC converter HVDC systems HVDC transmission IEEE IEEE Trans impedance increase inductance inductor instability insulation inverter limit line faults load flow mercury arc valves method mode monopolar MTDC operation oscillations overlap angle overvoltages parallel parameters phase pole power flow power modulation power systems problem protection reactance reactive power rectifier resonance rotor shown in Fig signal smoothing reactor steady-state switching synchronous synchronous condensers thyristor torsional interactions transient stability V₁ valve conduction variables zero