LEADER 00000cam a2200577Ii 4500 001 908199946 003 OCoLC 005 20240129213017.0 006 m o d 007 cr unu|||||||| 008 150430s2014 enka ob 001 0 eng d 020 9781118960530 020 111896053X 020 1118729102 020 9781118729106 029 1 DEBBG|bBV042683257 029 1 DEBSZ|b446584622 029 1 GBVCP|b835873730 035 (OCoLC)908199946 037 CL0500000583|bSafari Books Online 040 UMI|beng|erda|epn|cUMI|dDEBBG|dOCLCF|dDEBSZ|dGBVCP|dCEF |dTKN|dUAB|dUKAHL|dOCLCO|dOCLCQ|dOCLCO|dOCLCL 049 INap 082 04 621.312 082 04 621.312 099 eBook O'Reilly for Public Libraries 100 1 Chaudhuri, Nilanjan Ray,|d1981-|eauthor.|1https:// id.oclc.org/worldcat/entity/E39PCjJgDgpdwvm4JBGTR3Xq33 245 10 Multi-terminal direct-current grids :|bmodeling, analysis, and control /|cNilanjan Ray Chaudhuri, Balarko Chaudhuri, Rajat Majumder, Amirnaser Yazdani.|h[O'Reilly electronic resource] 264 1 Chichester :|bJohn Wiley & Sons :|bIEEE Press,|c[2014] 264 4 |c©2014 300 1 online resource (1 volume) :|billustrations 336 text|btxt|2rdacontent 337 computer|bc|2rdamedia 338 online resource|bcr|2rdacarrier 504 Includes bibliographical references and index. 505 0 Cover -- Title Page -- Copyright -- Dedication -- Foreword -- Preface -- Acronyms -- Symbols -- Chapter 1: Fundamentals -- 1.1 Introduction -- 1.2 Rationale Behind MTDC Grids -- 1.3 Network Architectures of MTDC Grids -- 1.4 Enabling Technologies and Components of MTDC Grids -- 1.5 Control Modes in MTDC Grid -- 1.6 Challenges for MTDC Grids -- 1.7 Configurations of MTDC Converter Stations -- 1.8 Research Initiatives on MTDC Grids -- 1.9 Focus and Scope of the Monograph -- Chapter 2: The Voltage-Sourced Converter (VSC) -- 2.1 Introduction -- 2.2 Ideal Voltage- Sourced Converter -- 2.3 Practical Voltage-Sourced Converter -- 2.4 Control -- 2.5 Simulation -- 2.6 Symbols of the VSC -- Chapter 3: Modeling, Analysis, and Simulation of AC-MTDC Grids -- 3.1 Introduction -- 3.2 MTDC Grid Model -- 3.3 AC Grid Model -- 3.4 AC-MTDC Load flow Analysis -- 3.5 AC-MTDC Grid Model for Nonlinear Dynamic Simulation -- 3.6 Small-signal Stability Analysis of AC-MTDC Grid -- 3.7 Transient Stability Analysis of AC- MTDC Grid -- 3.8 Case Studies -- 3.9 Case Study 1: The North Sea Benchmark System -- 3.10 Case Study 2: MTDC Grid Connected to Equivalent AC Systems -- 3.11 Case Study 3: MTDC Grid Connected to Multi-machine AC System -- Chapter 4: Autonomous Power Sharing -- 4.1 Introduction -- 4.2 Steady-state Operating Characteristics -- 4.3 Concept of Power Sharing -- 4.4 Power Sharing in MTDC Grid -- 4.5 AC- MTDC Grid Load flow Solution -- 4.6 Post-contingency Operation -- 4.7 Linear Model -- 4.8 Case Study -- Chapter 5: Frequency Support -- 5.1 Introduction -- 5.2 Fundamentals of Frequency Control -- 5.3 Inertial and Primary Frequency Support from Wind Farms -- 5.4 Wind Farms in Secondary Frequency Control (AGC) -- 5.5 Modified Droop Control for Frequency Support -- 5.6 AC-MTDC Load Flow Solution -- 5.7 Post-Contingency Operation -- 5.8 Case Study. 505 8 Chapter 6: Protection of MTDC Grids -- 6.1 Introduction -- 6.2 Converter Station Protection -- 6.3 DC Cable Fault Response -- 6.4 Fault-blocking Converters -- 6.5 DC Circuit Breakers -- 6.6 Protection Strategies -- References -- Index -- End User License Agreement. 520 A generic DC grid model that is compatible with the standard AC system stability model is presented and used to analyse the interaction between the DC grid and the host AC systems. A multi-terminal DC (MTDC) grid interconnecting multiple AC systems and offshore energy sources (e.g. wind farms) across the nations and continents would allow effective sharing of intermittent renewable resources and open market operation for secure and cost-effective supply of electricity. However, such DC grids are unprecedented with no operational experience. Despite lots of discussions and specific visions for setting up such MTDC grids particularly in Europe, none has yet been realized in practice due to two major technical barriers: Lack of proper understanding about the interaction between a MTDC grid and the surrounding AC systems. Commercial unavailability of efficient DC side fault current interruption technology for conventional voltage sourced converter systems This book addresses the first issue in details by presenting a comprehensive modeling, analysis and control design framework. Possible methodologies for autonomous power sharing and exchange of frequency support across a MTDC grid and their impact on overall stability is covered. An overview of the state-of- the-art, challenges and on-going research and development initiatives for DC side fault current interruption is also presented. 588 Description based on print version record. 590 O'Reilly|bO'Reilly Online Learning: Academic/Public Library Edition 650 0 Electric power distribution|xDirect current. 650 6 Électricité|xDistribution|xCourant continu. 650 7 Electric power distribution|xDirect current|2fast 700 1 Chaudhuri, Balarko,|d1977-|eauthor.|1https://id.oclc.org/ worldcat/entity/E39PCjrpghgmQHfFq8RxFmjJym 700 1 Majumder, Rajat,|d1977-|eauthor.|1https://id.oclc.org/ worldcat/entity/E39PCjy6Ffk3ggbbyTkJxHt4mb 700 1 Yazdani, Amirnaser,|d1972-|eauthor.|1https://id.oclc.org/ worldcat/entity/E39PCjrpj83RgYWTTtqXyyFywK 710 2 IEEE Press 776 08 |iPrint version:|aChaudhuri, Nilanjan Ray, 1981-|tMulti- terminal direct-current grids|z9781118729106 |w(OCoLC)885445608 856 40 |uhttps://ezproxy.naperville-lib.org/login?url=https:// learning.oreilly.com/library/view/~/9781118960530/?ar |zAvailable on O'Reilly for Public Libraries 938 Askews and Holts Library Services|bASKH|nAH27080472 938 Askews and Holts Library Services|bASKH|nAH27113090 994 92|bJFN