000			08263nam a2201285Ia 4500
000			06686cam a2200565Mi 4500
001			81142
003			0
005			20250920171902.0
006			m o d
007			cr |n|||||||||
008			160917s2016 xx o 000 0 eng d
010			_z _z _o _a _b
015			_22 _a
016			_2 _2 _a _z
019			_a958098555;960090998;960277079
020			_e _e _a9781119175391 _b _z _c _qelectronic book _x
022			_y _y _l _a2
024			_2 _2 _d _c _a _q
028			_a _a _b
029			_a _a _b
032			_a _a _b
035			_a _a(OCoLC)958385121;(OCoLC)ocn958385121 _b _z(OCoLC)958098555;(OCoLC)960090998;(OCoLC)960277079 _c _q
037			_n _n _c _a _b
040			_e _epn;rda _aEBLCP _dOCLCO;YDX;DG1;CSAIL;OCLCQ;OCLCO;OCLCQ;OCLCF;RECBK _beng _cEBLCP
041			_e _e _a _b _g _h _r
043			_a _a _b
045			_b _b _a
049			_aMAIN
050			_a _aTK1005 _d _b2 _c0
051			_c _c _a _b
055			_a _a _b
060			_a _a _b
070			_a _a _b
072			_2 _2bisacsh _d _aTEC _x9070
082			_a _a621.309999999999 _d _b2 _c
084			_2 _2 _a
086			_2 _2 _a
090			_a _a _m _b _q
092			_f _f _a _b
096			_a _a _b
097			_a _a _b
100			_e _e _a _d _b4 _u _c0 _q16
110			_e _e _a _d _b _n _c _k
111			_a _a _d _b _n _c
130			_s _s _a _p _f _l _k
210			_a _a _b
222			_a _a _b
240			_s _s _a _m _g _n _f _l _o _p _k
245		0	_a _aAdvanced solutions in power systems : _d _bHVDC, FACTS, and artificial intelligence / _n _cedited by Mircea Eremia, Chen-Ching Liu, Abdel-Aty Edris. _h6 _p
246			_a _a _b _n _i _f6 _p
249			_i _i _a
250			_6 _6 _a _b
260			_e _e _a _b _f _c _g
264			_3 _3 _aSomerset : _d _bWiley, _c[2016]46
300			_e _e _c _a1 online resource (1075 pages). _b
310			_a _a _b
321			_a _a _b
336			_btxt _atext _2rdacontent
337			_3 _30 _bc _acomputer _2rdamedia
338			_3 _30 _bcr _aonline resource _2rdacarrier
340			_2 _20 _g _n
344			_2 _2 _a0 _b
347			_2 _2 _a0
362			_a _a _b
385			_m _m _a2
410			_t _t _b _a _v
440			_p _p _a _x _v
490			_a _aIEEE Press Series on Power Engineering _x _v
500			_a _a4.7.2 Differences Resulting from the Converter Type. _d _b _c56
504			_a _aIncludes bibliographical references and index. _x
505			_a _aADVANCED SOLUTIONS IN POWER SYSTEMS; Contents; Contributors; Foreword; Acknowledgments; 1 Introduction; PART I HVDC Transmission; 2 Power Semiconductor Devices for HVDC and Facts Systems; 2.1 Power Semiconductor Overview; 2.1.1 Not-Controllable Power Semiconductor Devices; 2.1.2 Semicontrollable Power Semiconductor Devices; 2.1.3 Fully Controllable Power Semiconductor Devices; 2.1.4 Power Semiconductor Parameters; 2.1.5 Future Power Semiconductor Devices; 2.2 Converter Types; 2.3 HVDC Evolution; 2.3.1 Line-Commutated HVDC Converters (LCC/CSC-HVDC).;2.3.2 Capacitor-Commutated Converter (CCC-HVDC)2.3.3 Voltage Source Converter VSC-HVDC; 2.4 Facts Evolution; References; 3 CSC-HVDC Transmission; 3.1 Structure and Configurations; 3.1.1 Structure of HVDC Links; 3.1.2 HVDC Configurations; 3.2 Converter Bridge Modeling; 3.2.1 Rectifier Equations; 3.2.2 Inverter Equations; 3.3 Control of CSC-HVDC Transmission; 3.3.1 Equivalent Circuit and Control Characteristics; 3.3.2 HVDC Control Principles; 3.3.3 HVDC Control Strategies; 3.3.4 Hierarchical Control of a HVDC Link; 3.4 Reactive Power and Harmonics; 3.4.1 Reactive Power Requirements and Sources.;3.4.2 Harmonics and Filters3.5 Load Flow in Mixed HVAC/HVDC-CSC Systems; 3.5.1 Steady-State Model; 3.6 Interaction Between AC and DC Systems; 3.6.1 AC Systems Stabilization; 3.6.2 Influence of AC System Short-Circuit Ratio; 3.6.3 Effective Inertia Constant; 3.6.4 Reactive Power and the Strength of the AC System; 3.7 Comparison Between DC and ACTransmission; 3.8 Application on a CSC-HVDC Link; 3.8.1 Solution; Appendix 3.1 CSC-HVDC Systems in the World; References; 4 VSC-HVDC Transmission; 4.1 VSC CONVERTER STRUCTURES; 4.1.1 Half-Bridge VSC or Two-Level Pole; 4.1.2 Full-Bridge Single-Phase VSC.;4.1.3 Three-Phase Two-Level VSC4.1.4 Three-Level Pole VSC; 4.1.5 Multimodule VSC Systems; 4.1.6 Multilevel VSC Systems; 4.1.7 Modular Multilevel Converter; 4.1.8 Cascaded Two-Level Converters; 4.2 MODULATION TECHNIQUES; 4.2.1 PWM Techniques; 4.2.2 Modulation Techniques for Multilevel Converters; 4.3 DCAC CONVERTER ANALYSIS; 4.3.1 Operation Modes of the Switched-Inductor Cell; 4.3.2 Ideal DCAC Half-Bridge Converter; 4.3.3 Averaging Models; 4.3.4 Detailed and Averaged Models for MMC-HVDC Systems; 4.4 VSC TRANSMISSION SCHEME AND OPERATION; 4.4.1 Power Equipment.;4.4.2 Principles of Active and Reactive Power Control4.4.3 VSC Transmission Control; 4.5 MULTITERMINAL VSC-HVDC SYSTEMS AND HVDC GRIDS; 4.5.1 On the Conventional Multiterminal HVDC Configurations; 4.5.2 Multiterminal HVDC Grid Configurations; 4.5.3 Meshed HVDC Grid Configurations; 4.5.4 Need for Fast and Low Loss HVDC Breakers; 4.5.5 HVDC Grid Protection; 4.6 LOAD FLOW AND STABILITY ANALYSIS; 4.6.1 Load Flow in Meshed AC/DC Grids; 4.6.2 Dynamic Stability in Meshed AC/DC Grids; 4.7 COMPARISON OF CSC-HVDC VERSUS VSC-HVDC TRANSMISSION; 4.7.1 Differences Resulting from the Commutation Principle. _b _t _g _r
506			_a _a5
510			_a _a _x
520			_b _b _c _aProvides insight on both classical means and new trends in the application of power electronic and artificial intelligence techniques in power system operation and control This book presents advanced solutions for power system controllability improvement, transmission capability enhancement and operation planning. The book is organized into three parts. The first part describes the CSC-HVDC and VSC-HVDC technologies, the second part presents the FACTS devices, and the third part refers to the artificial intelligence techniques. All technologies and tools approached in this book are essential for power system development to comply with the smart grid requirements. -Discusses detailed operating principles and diagrams, theory of modeling, control strategies and physical installations around the world of HVDC and FACTS systems -Covers a wide range of Artificial Intelligence techniques that are successfully applied for many power system problems, from planning and monitoring to operation and control -Each chapter is carefully edited, with drawings and illustrations that helps the reader to easily understand the principles of operation or application Advanced Solutions in Power Systems: HVDC, FACTS, and Artificial Intelligence is written for graduate students, researchers in transmission and distribution networks, and power system operation. This book also serves as a reference for professional software developers and practicing engineers. _u
521			_a _a _b
533			_e _e _a _d _b _n _c
540			_c _c _a5
542			_g _g _f
546			_a _a _b
583			_5 _5 _k _c _a _b
588			_aPrint version record.
590			_a _a _b
600			_b _b _v _t _c2 _q _a _x0 _z _d _y
610			_b _b _v _t2 _x _a _k0 _p _z _d6 _y
611			_a _a _d _n2 _c0 _v
630			_x _x _a _d _p20 _v
648			_2 _2 _a
650			_x#NAME? _aPower resources;Power resources.;Interconnected electric utility systems;Electric power distribution. _d _b _z _y _2fast;sears;sears _0(OCoLC)fst01074275 _vCongresses.
651			_x _x _a _y20 _v _z
655			_0 _0(OCoLC)fst01423772 _aElectronic books.;Conference papers and proceedings. _y _2fast _z
700			_i _i _t _c _b _s1 _q _f _k40 _p _d _e _aEremia, Mircea.;Liu, Chen-Ching.;Edris, Abdel-Aty. _l _n6
710			_b _b _t _c _e _f _k40 _p _d5 _l _n6 _a
711			_a _a _d _b _n _t _c
730			_s _s _a _d _n _p _f _l _k
740			_e _e _a _d _b _n _c6
753			_c _c _a
767			_t _t _w
770			_t _t _w _x
773			_a _a _d _g _m _t _b _v _i _p
775			_t _t _w _x
776			_s _s _aEremia, Mircea. _dSomerset : Wiley, ©2016 _b _z9781119035695 _iPrint version: _tAdvanced Solutions in Power Systems : HVDC, FACTS, and Artificial Intelligence. _x _h _c _w
780			_x _x _a _g _t _w
785			_t _t _w _a _x
787			_x _x _d _g _i _t _w
800			_a _a _d _l _f _t0 _q _v
810			_a _a _b _f _t _q _v
830			_x _x _aIEEE Press series on power engineering. _p _n _l0 _v
942			_a _alcc _cBK
999			_c20921 _d20921