Verfügbarkeit: Smart Power Grids 2011

Smart Power Grids 2011:

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Bibliographische Detailangaben
Format:	Buch
Sprache:	English
Veröffentlicht:	Berlin [u.a.] Springer 2012
Schriftenreihe:	Power Systems
Schlagworte:	Dezentrale Elektrizitätserzeugung Elektrische Maschine Leistungselektronik Intelligentes Stromnetz Erneuerbare Energien Aufsatzsammlung
Online-Zugang:	Inhaltstext Inhaltsverzeichnis
Beschreibung:	XX, 674 S. Ill., graph. Darst.
ISBN:	3642215777 9783642215773

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MARC


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Datensatz im Suchindex

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adam_text	IMAGE 1 CONTENTS 1 SMART POWER GRIDS 1 ALI KEYHANI 1.1 INTRODUCTION 1 1.2 SOLAR ENERGY 2 1.3 WIND ENERGY 3 1.4 MICROGRID O F RENEWABLE AND GREEN ( M R G ) P O W E R GRIDS 6 1.5 CONTROL OPERATION O F INTERCONNECTED NETWORK BULK P O W E R GRIDS 6 1.6 SMART POWER GRID 10 1.7 CYBER CONTROLLED SMART P O W E R GRIDS 13 1.8 RESEARCH ISSUES 18 REFERENCES 2 0 2 INTEGRATION OF INTERMITTENT RESOURCE IN A REAL TIME SCHEDULING 27 M U H A M M A D MARWALI 2.1 INTRODUCTION 2 7 2.2 INTERMITTENT RESOURCE INTEGRATION IN SHORT T E R M GENERATION SCHEDULING 2 8 2.3 SCHEDULING PROBLEM FORMULATION 3 0 2.4 PROPOSED METHOD FOR SCHEDULING 3 3 2.4.1 INITIAL FEASIBLE SOLUTION 3 4 . 2 . 4 . 2 THERMAL UNIT C O M M I T M E N T 35 2.4.3 DYNAMIC ECONOMIC DISPATCH 3 8 2.4.4 BATTERY STORAGE MODEL 3 9 2.5 CASE STUDIES 4 2 LIST O F SYMBOLS 4 6 REFERENCES 4 8 3 LOAD FREQUENCY CONTROL IN A MICROGRID: CHALLENGES AND IMPROVEMENTS 49 RITWIK MAJUMDER, A R I N D A M GHOSH, GERARD L E D W I C H 3.1 INTRODUCTION 4 9 3.2 CONVENTIONAL DROOP CONTROL METHOD 5 0 3.3 ANGLE DROOP CONTROL FOR V S C INTERFACED D G S 51 3.3.1 ANGLE DROOP 5 1 3.3.2 ANGLE DROOP CONTROL AND P O W E R SHARING 5 2 HTTP://D-NB.INFO/1011530198 IMAGE 2 X C O N T E N T S 3.3.3 ANGLE DROOP AND FREQUENCY DROOP CONTROLLER 5 2 3.3.4 SIMULATION RESULTS 5 4 3.4 SUPPLEMENTARY CONTROL L O O P FOR IMPROVED P O W E R SHARING AND SYSTEM STABILITY 5 6 3.4.1 TEST SYSTEM 5 8 3.4.2 SIMULATION STUDIES WITH SUPPLEMENTARY DROOP CONTROLLER 5 9 3.4.2.1 CASE 1: FULL SYSTEM O F FIG. 3.11 WITH LOWER DROOP GAINS 5 9 3.4.2.2 CASE 2: REDUCED SYSTEM WITH L O W E R DROOP GAINS 5 9 3.4.2.3 CASE 3: SYSTEM STABILITY WITH HIGH DROOP GAIN 6 0 3.4.2.4 CASE 4: P O W E R SHARING WITH THE PROPOSED SUPPLEMENTARY CONTROLLER 6 0 3.5 DROOP CONTROL FOR RURAL AREA WITH HIGH R/X RATIO 6 3 3.5.1 SIMULATION STUDIES 6 5 3.6 T H E IMPROVEMENT IN LOAD SHARING WITH UNBALANCED LOADS AND APPLICATION O F BACK T O BACK CONVERTERS 6 8 3.6.1 P O W E R QUALITY ENHANCED OPERATION O F A MICROGRID 6 8 3.6.1.1 SYSTEM STRUCTURE AND REFERENCE GENERATION 6 9 3.6.1.2 SIMULATION STUDIES 7 0 3.6.2 APPLICATION O F BACK TO BACK CONVERTERS IN POWER SHARING AND POWER MANAGEMENT 7 5 3.6.2.1 SYSTEM STRUCTURE AND OPERATION 7 5 3.6.3 BACK-TO-BACK CONVERTER REFERENCE GENERATION 7 6 3.6.3.1 VSC-1 REFERENCE GENERATION 7 6 3.6.3.2 VSC-2 REFERENCE GENERATION IN MODE-1 77 3.6.3.3 VSC-2 REFERENCE GENERATION IN MODE-2 7 7 3.6.4 REFERENCE GENERATION FOR D G SOURCES 7 8 3.6.5 SIMULATION STUDIES 7 8 3.6.5.1 CASE-1: LOAD SHARING O F THE DGS WITH UTILITY 7 9 3.6.5.2 CASE-2: CHANGE IN P O W E R SUPPLY FROM UTILITY 8 0 3.6.5.3 CASE-3: P O W E R SUPPLY FROM MICROGRID TO UTILITY 8 0 3.7 CONCLUSIONS 81 REFERENCES 81 4 FUZZY CONTROL OF MULTILEVEL INVERTERS FOR FUEL CELL GENERATOR SETS 83 CONCETTINA BUCCELLA, CARLO CECATI, ANTONIO PICCOLO, PIERLUIGI SIANO 4.1 INTRODUCTION 8 3 4.2 MATHEMATICAL MODEL O F THE SYSTEM AND ITS FUZZY LOGIC CONTROL 8 5 4.3 SIMULATION RESULTS 9 0 4.3.1 GENERAL DESCRIPTION 9 0 4.3.2 VARIATION O F THE ACTIVE P O W E R REFERENCE 91 4.3.3 VARIATION O F THE ACTIVE P O W E R REQUESTED BY THE L O A D 9 5 4.3.4 SYMMETRICAL VOLTAGE SAG 97 4.3.5 TRANSITION BETWEEN THE P Q CONTROL AND THE P V CONTROL 9 7 4.3.6 TRANSIENT RESPONSE O F THE FUEL CELL SYSTEM 9 8 IMAGE 3 CONTENTS X I 4.4 EXPERIMENTAL RESULTS 9 8 4.4.1 HARDWARE DESCRIPTION 9 8 4.5 CONCLUSION 100 REFERENCES 101 5 CONTROL OF THREE-PHASE INVERTERS IN MICROGRID SYSTEMS 103 SACHIN PURANIK, A L I KEYHANI, A B I R CHATTERJEE 5.1 PROBLEM STATEMENT 104 5.2 PROBLEM DESCRIPTION 105 5.2.1 STATE SPACE MODEL O F THREE-PHASE INVERTER SYSTEM 107 5.3 CONTROL DEVELOPMENT FOR THREE-PHASE INVERTER SYSTEM 116 5.3.1 DISCRETE-TIME P I D CONTROL DESIGN FOR THREE-PHASE INVERTER 116 5.3.1.1 PID CONTROLLER GAINS TUNING STEPS FOR THREE-PHASE INVERTER 119 5.3.2 DISCRETE-TIME ROBUST SERVOMECHANISM PROBLEM (RSP) CONTROL AND DISCRETE-TIME SLIDING M O D E CONTROL DESIGN FOR THREE-PHASE INVERTER 120 5.3.2.1 DESIGN STEPS FOR DISCRETE-TIME R S P CONTROL AND DISCRETE-TIME SLIDING M O D E CONTROL DESIGN FOR THREE-PHASE INVERTER 120 5.3.2.2 S T E P 1 - DESIGN O F DISCRETE-TIME SLIDING M O D E CURRENT CONTROL FOR THREE-PHASE INVERTER 121 5.3.2.3 S T E P II - FORMULATION O F THE PLANT FOR DISCRETE-TIME R S P VOLTAGE CONTROLLER 124 5.3.2.4 S T E P III- DESIGN O F DISCRETE-TIME ROBUST SERVOMECHANISM PROBLEM (RSP) VOLTAGE CONTROLLER FOR THREE-PHASE INVERTER 134 5.3.2.5 NECESSARY CONDITIONS FOR THE EXISTENCE O F SOLUTION O F ROBUST SERVOMECHANISM PROBLEM 135 5.3.2.6 INTERNAL MODEL PRINCIPLE 136 5.3.2.7 DESIGN STEPS FOR THE DISCRETE-TIME R S P VOLTAGE CONTROLLER FOR THREE-PHASE INVERTER 138 5.3.2.8 CURRENT LIMITER FOR THREE-PHASE INVERTER 155 5.4 COMPARISON AND TABULATION O F RESULTS FOR THE PROPOSED CONTROL TECHNIQUES FOR THREE-PHASE INVERTER 156 5.5 SIMULATION RESULTS O F THREE-PHASE INVERTER SYSTEM 158 5.6 CONCLUSION 174 REFERENCES 175 6 SIZING HIGH SPEED MICRO GENERATORS FOR SMART GRID SYSTEMS 177 A DEL EL SHAHAT, A L I KEYHANI 6.1 INTRODUCTION 177 6.2 BASIC SELECTIONS 178 6.2.1 PERMANENT MAGNETS 178 6.2.2 STATOR AND ROTOR MATERIAL 178 IMAGE 4 XII C O N T E N T S 6.3 MACHINE DESIGN PARAMETERS 179 6.3.1 STATOR MECHANICAL DESIGN 179 6.3.2 ROTOR MECHANICAL DESIGN 179 6.3.3 N U M B E R O F POLES AND MAGNETS POLE DESIGN 180 6.3.4 MAGNETIC DIMENSIONS 181 6.3.5 SLOTS PER POLE, PER PHASE 181 6.3.6 STATOR WINDINGS 182 6.3.7 MACHINE CALCULATED PARAMETERS 182 6.3.8 WINDING RESISTANCES 183 6.3.9 WINDING AND MAGNET FACTORS 185 6.3.10 FLUX AND VOLTAGE 185 6.3.11 MACHINE INDUCTANCES 187 6.3.12 BASIC LOSSES 187 6.4 CLASSICAL SIZING RESULTS 189 6.4.1 MACHINE INITIAL SIZING 189 6.4.2 DETAILED SIZING 190 6.5 UNCONSTRAINED NON-LINEAR OPTIMIZATION 194 6.5.1 TRUST-REGION METHODS 194 6.5.2 FMINSEARCH ALGORITHM 195 6.5.3 TOTAL LOSSES MINIMIZATION SIZING 196 6.6 SIMPLE CONSTRAINED OPTIMIZATION 199 6.6.1 FMINCON ACTIVE SET ALGORITHM 199 6.6.2 LARGE-SCALE VS. MEDIUM-SCALE ALGORITHMS 2 0 0 6.6.3 TOTAL MASS MINIMIZATION SIZING 201 6.7 GENETIC ALGORITHM H S P M S G SIZING 2 0 5 6.7.1 H O W THE GENETIC ALGORITHM WORKS 2 0 5 6.7.2 DESCRIPTION O F THE NON-LINEAR CONSTRAINT SOLVER 2 0 6 6.8 EFFICIENCY MAXIMIZER GENETIC SIZING 2 0 6 6.9 MIN. MASS GENETIC SIZING, CONSTRAINED BY MIN. LOSSES 2 1 0 6.10 OPTIMUM T O R Q U E PER AMPERE GENETIC SIZING 2 1 1 6.11 COMPARATIVE ANALYTICAL MODELS 2 1 4 6.11.1 ROTATIONAL STRESS AND RETAINING SLEEVE 2 1 4 6.11.2 ROTOR LOSSES 2 1 5 6.11.2.1 MODEL FOR T I M E HARMONICS AND WINDING SPACE HARMONICS 2 1 5 6.11.2.2 MODEL FOR STATOR SLOT EFFECTS 2 1 8 6.11.3 COMPARISON RESULTS 2 1 9 6.11.3.1 T H D COMPARISONS 2 1 9 6.11.3.2 PARAMETERS COMPARISONS 2 2 3 6.12 CONCLUSIONS 2 3 0 REFERENCES 231 7 CONTROL OF SINGLE-PHASE DC-AC INVERTERS IN RESIDENTIAL MICROGRID SYSTEMS 235 SACHIN PURANIK, A L I KEYHANI, A B I R CHATTERJEE 7.1 INTRODUCTION 2 3 5 7.2 MODEL O F A SINGLE-PHASE FULL BRIDGE INVERTER 237 IMAGE 5 CONTENTS X I I I 7.3 CONTROL DEVELOPMENT FOR SINGLE-PHASE INVERTER SYSTEM 2 4 0 7.4 DISCRETE-TIME PID VOLTAGE AND CURRENT CONTROL DESIGN 2 4 0 7.5 DISCRETE-TIME ROBUST SERVOMECHANISM PROBLEM (RSP) CONTROL AND DISCRETE-TIME SLIDING M O D E CONTROL DESIGN 2 4 2 7.5.1 DESIGN STEPS FOR DISCRETE-TIME R S P VOLTAGE CONTROLLER AND DISCRETE-TIME SLIDING M O D E CURRENT CONTROLLER 2 4 3 7.5.2 STEP 1 - DESIGN O F DISCRETE-TIME SLIDING M O D E CURRENT CONTROL 2 4 3 7.5.3 STEP 2 - FORMULATION O F THE PLANT FOR DISCRETE-TIME R S P VOLTAGE CONTROLLER 2 4 5 7.5.4 STEP 3- DESIGN O F DISCRETE-TIME ROBUST SERVOMECHANISM PROBLEM (RSP) VOLTAGE CONTROLLER 2 4 8 7.6 NECESSARY CONDITIONS FOR THE EXISTENCE O F SOLUTION O F ROBUST SERVOMECHANISM PROBLEM 248 7.7 INTERNAL MODEL PRINCIPLE 2 4 9 7.7.1 DESIGN STEPS FOR R S P VOLTAGE CONTROLLER 2 5 0 7.7.2 STEP (I): SERVOCOMPENSATOR DESIGN 2 5 0 7.7.3 STEP (II): DETERMINATION O F THE AUGMENTED SYSTEM 2 5 2 7.7.4 STEP (III): DESIGN O F STABILIZING COMPENSATOR 2 5 4 7.8 SIMULATION RESULTS 2 5 6 7.8.1 SIMULATION RESULTS WITH DISCRETE-TIME PID VOLTAGE AND CURRENT CONTROLLERS 2 5 8 7.8.2 SIMULATION RESULTS WITH DISCRETE-TIME R S P VOLTAGE CONTROLLER AND DISCRETE-TIME SLIDING M O D E CURRENT CONTROLLER 261 7.9 CONCLUSION 2 6 2 ACKNOWLEDGMENTS 2 6 3 REFERENCES 2 6 3 8 INTELLIGENT POWER MANAGEMENT OF A HYBRID FUEL CELL/ENERGY STORAGE DISTRIBUTED GENERATOR 265 A M I N HAJIZADEH, A L I FELIACHI, M A S O U D A L I A K B A R GOLKAR 8.1 INTRODUCTION 2 6 5 8.2 DYNAMIC MODELING O F A HYBRID DISTRIBUTED GENERATION ( H D G ) SYSTEM 2 6 6 8.2.1 FUEL CELL MODEL 2 6 7 8.2.2 BATTERY ENERGY STORAGE MODEL 2 7 1 8.2.3 MODELING O F GRID CONNECTED INVERTER 2 7 2 8.3 INTELLIGENT P O W E R MANAGEMENT 2 7 3 8.3.1 NEURO-FUZZY CONTROL STRATEGY 2 7 6 8.4 CONTROL DESIGN FOR VOLTAGE SOURCE CONVERTER 2 7 8 8.5 SIMULATION RESULTS 2 7 9 8.6 SUMMARY 284 ACKNOWLEDGMENT 2 8 4 REFERENCES 2 8 5 IMAGE 6 X I V C O N T E N T S 9 ANALYSIS AND MINIMIZATION OF HARMONICS ON THE AC AND DC SIDES OF PWM INVERTERS 287 PEKIK ,4 RGO DAHONO 9.1 INTRODUCTION 2 8 7 9.1.1 ANALYSIS AND MINIMIZATION O F HARMONICS ON THE A C SIDE CURRENT 2 8 8 9.2 ANALYSIS AND MINIMIZATION O F RIPPLES ON THE D C SIDE CURRENT AND VOLTAGE 2 9 6 9.3 VALIDITY O F THE DERIVED EXPRESSIONS 3 0 2 REFERENCES 3 0 2 10 WORST CASE VOLTAGE VARIATION ON MICROGRID 305 M.A. MAHMUD, M.J. HOSSAIN, H.R. POTA 10.1 INTRODUCTION 3 0 6 10.2 VOLTAGE VARIATION IN CONVENTIONAL DISTRIBUTION NETWORK 3 0 8 10.3 VOLTAGE VARIATION ON MICROGRID 3 0 9 10.4 CASE STUDY: VALIDATION O F VOLTAGE VARIATION FORMULA 311 10.5 WORST CASE VOLTAGE VARIATION 313 10.6 MITIGATION O F VOLTAGE VARIATION BASED ON WORST CASE SCENARIO 3 1 5 10.6.1 MITIGATION O F VOLTAGE VARIATION B Y REGULATING PRIMARY D S VOLTAGE (VS) 3 1 5 10.6.2 MITIGATION O F VOLTAGE VARIATION BY REDUCING LINE RESISTANCE 3 1 6 10.6.3 MITIGATION O F VOLTAGE VARIATION B Y USING REACTIVE P O W E R CONTROL 3 1 6 10.7 VOLTAGE LEVEL AND CONNECTION COST 3 1 6 10.8 CONCLUSION 3 1 7 REFERENCES 3 1 7 11 IMPACT OF PLUG-IN HYBRID ELECTRIC VEHICLES ON ELECTRICITY DEMAND PROFILE 319 ZAHRA DARABI, M E H D I FERDOWSI 11.1 INTRODUCTION 3 1 9 11.2 PLUG-IN HYBRID ELECTRIC VEHICLES 3 2 3 11.2.1 ARCHITECTURES 3 2 3 11.2.2 BATTERIES 325 11.3 MARKET PENETRATION 3 2 6 11.4 STATISTICAL STUDY O F THE SIDES WHICH FORM THE BASE O F THE P C L P PRISM .' 3 2 8 11.4.1 VEHICLE DAILY MILEAGE ANALYSIS 3 2 8 11.4.2 VEHICLES ARRIVAL T I M E ANALYSIS 3 3 1 11.4.3 VEHICLES T Y P E ANALYSIS 331 11.5 OTHER FACTORS ASSOCIATED WITH THE P C L P PRISM 332 11.5.1 CHARGING INFRASTRUCTURE AND CHARGING LEVELS 3 3 2 11.5.2 PROPORTIONAL ENERGY NEEDED (PEN) 334 11.5.3 CHARGING SCHEDULE 3 3 5 IMAGE 7 CONTENTS X V 11.6 DEVELOPING THE P C L P CURVES 3 3 6 11.7 IMPROVING POLICIES AND COORDINATED CHARGING 340 11.7.1 OTHER CHARGING LEVELS 3 4 0 11.7.2 POLICY 1 341 11.7.3 POLICY 2 341 11.8 SMART P H E V AND SMART GRID 3 4 2 11.9 IMPACT ON EMISSION 344 SUMMARY 347 REFERENCES 347 12 MICROGRIDS OPERATION AND CONTROL UNDER EMERGENCY CONDITIONS .351 C.L. MOREIRA, J.A. PEGAS L O P E S 12.1 INTRODUCTION 351 12.1.1 A N OVERVIEW O F M G OPERATION 352 12.2 MICROGRIDS DYNAMIC MODELLING 3 5 4 12.2.1 FUEL CELLS 355 12.2.1.1 SOLID OXIDE FUEL CELL MODELLING 3 5 6 12.2.2 MICROTURBINES 3 6 1 12.2.2.1 S S M T ACTIVE P O W E R CONTROL 3 6 3 12.2.2.2 S S M T ENGINE 3 6 4 12.2.2.3 PERMANENT MAGNET SYNCHRONOUS GENERATOR 3 6 4 12.2.2.4 P M S G SIDE CONVERTER 3 6 5 12.2.3 MICRO-WIND TURBINES 3 6 6 12.2.4 PHOTOVOLTAIC PANELS 367 12.2.5 POWER ELECTRONIC INTERFACES CONNECTED TO THE GRID 3 6 8 12.2.5.1 P Q INVERTER CONTROL 3 6 9 12.2.5.2 VOLTAGE SOURCE INVERTER CONTROL 371 12.2.5.3 INVERTER MODELLING DURING SHORT-CIRCUITS 3 7 3 12.3 MICROGRIDS EMERGENCY CONTROL STRATEGIES 374 12.3.1 MICROGRID CONTROL FOR ISLANDING OPERATION 3 7 5 12.3.1.1 SINGLE MASTER OPERATION 3 7 6 12.3.1.2 MULTI MASTER OPERATION 377 12.3.2 EMERGENCY STRATEGIES 377 12.3.2.1 FREQUENCY CONTROL 3 7 8 12.3.3 EXPLOITING L O W VOLTAGE MICROGRIDS FOR SERVICE RESTORATION 381 12.3.3.1 MICROGRID BLACK START 383 12.3.3.2 GENERAL REQUIREMENTS FOR MICROGRID BLACK START 384 12.3.3.3 SEQUENCE O F ACTIONS FOR MICROGRID BLACK START 3 8 5 12.4 APPLICATION EXAMPLE 3 8 6 12.4.1 MOVING TO ISLANDING OPERATION 3 8 6 12.4.2 MICROGRID BLACK START 391 12.5 FINAL REMARKS 3 9 5 REFERENCES 3 9 7 IMAGE 8 X V I CONTENTS 13 DECENTRALIZED STATCOM/ESS CONTROL FOR WIND GENERATORS 401 M.J. HOSSAIN, H.R. POTA, M.A. M A H M U D 13.1 INTRODUCTION 4 0 2 13.2 GRID-CODE REQUIREMENTS FOR WIND F A R M CONNECTIONS 4 0 4 13.2.1 FAULT RIDE-THROUGH 4 0 5 13.2.2 F R E Q U E N C Y - P O W E R VARIATIONS 4 0 5 13.2.3 FREQUENCY CONTROL 4 0 5 13.2.4 REACTIVE P O W E R RANGE CAPABILITY 4 0 5 13.2.5 VOLTAGE CONTROL 4 0 5 13.2.6 FAULT RIDE-THROUGH SCHEMES FOR W I N D TURBINES 4 0 6 13.3 P O W E R SYSTEM MODEL 4 0 7 13.3.1 MODELING O F SYNCHRONOUS GENERATORS 4 0 8 13.3.2 MODELING O F W I N D GENERATORS 4 0 9 13.2.3 MODELING O F S T A T C O M 4 1 0 13.3.4 MODELING O F SUPERCAPACITOR 4 1 1 13.3.5 CRITICAL CLEARING T I M E (CCT) AND CRITICAL VOLTAGE 4 1 2 13.4 TEST SYSTEM AND CONTROL T A S K 4 1 3 13.5 PROBLEM FORMULATION 4 1 4 13.6 DECENTRALIZED CONTROL DESIGN USING R A N K CONSTRAINED L M L S 4 1 8 13.7 CONTROL DESIGN ALGORITHM 4 1 9 13.8 CONTROLLER PERFORMANCE EVALUATION 4 2 1 13.8.1 ENHANCEMENT O F VOLTAGE AND TRANSIENT STABILITY MARGINS .421 13.8.2 REAL AND REACTIVE P O W E R OUTPUT DURING L O W VOLTAGES 4 2 2 13.8.3 COMPARISONS WITH STANDARD L V R T REQUIREMENTS 4 2 2 13.8.4 PERFORMANCE UNDER DIFFERENT OPERATING CONDITIONS 4 2 3 13.8.5 IMPACT O F ADDING SUPERCAPACITORS 4 2 3 13.9 CONCLUSIONS 4 2 3 APPENDIX-1 4 2 3 APPENDIX- II 4 2 5 APPENDIX-III 4 3 2 REFERENCES 4 3 6 14 STATE ESTIMATION IN SMART POWER GRIDS 439 A L I AREFI, MAHMOOD-REZA H A G H I F A M 14.1 INTRODUCTION 4 3 9 14.2 T H E ROLE O F STATE ESTIMATION IN SMART P O W E R GRIDS 4 4 1 14.3 OBSERVABILITY ANALYSIS 4 4 5 14.3.1 BACKGROUND 4 4 5 14.3.2 T H E EFFECT O F BRANCH IMPEDANCE VALUES O N OBSERVABILITY 4 4 6 14.3.2.1 EXAMPLE 1.1: IEEE-14 BUS TEST NETWORK 4 4 9 14.3.2.1 EXAMPLE 1.2: SIX-BUS N E T W O R K 4 5 3 14.3.3 RADIAL SYSTEM OBSERVABILITY ANALYSIS 4 5 6 14.3.3.1 EXAMPLE 1.3: 17-BUS RADIAL DISTRIBUTION SYSTEM 4 5 8 IMAGE 9 CONTENTS X V I I 14.4 DISTRIBUTION STATE ESTIMATION (DSE) 4 5 8 14.4.1 CONVENTIONAL WEIGHTED LEAST SQUARE ( W L S ) 4 6 0 14.4.2 L O A D CORRELATION IN A DISTRIBUTION NETWORKS 4 6 1 14.4.2.1 L O A D CORRELATION 4 6 1 14.4.2.2 T H E EFFECT O F LOAD CORRELATIONS ON D S E 4 6 3 14.4.2.3 E X A M P L E L . 3 : 6-BUS RADIAL DISTRIBUTION FEEDER 4 6 3 14.5 DISTRIBUTION HARMONIC STATE ESTIMATION (DHSE) 4 7 0 14.6 M E T E R PLACEMENT 471 REFERENCES 471 15 MODELING, CONTROL AND SIMULATION OF CASCADED 3-5-9 HYBRID INVERTER TOPOLOGY FOR GRID INTERFACE APPLICATION 479 T. WANJEKECHE, DAN V. NICOLAE, A D I S A A. J I M O H 15.1 INTRODUCTION 4 8 0 15.2 M A I N SYSTEM CONFIGURATION 481 15.3 PRINCIPLE O F OPERATION 4 8 2 15.3.1 PHASE SHIFTED P W M CONTROL TECHNIQUE 4 8 2 15.3.1.1 THEORETICAL ANALYSIS O F THE PROPOSED P W M CONTROL STRATEGY 4 8 5 15.3.2 DEVELOPMENT O F THE SWITCHING CONTROL L A W FOR THE 3-5-9 HYBRID TOPOLOGY MODEL 4 8 8 15.4 MODELING AND ANALYSIS THE CASCADED HYBRID MODEL 4 8 9 15.4.1 AVERAGE MODEL IN A B C CO-ORDINATES 4 8 9 15.4.2 DEVELOPMENT O F AVERAGE MODEL IN DQO CO-ORDINATES 4 9 4 15.4.3 SMALL SIGNAL ANALYSIS 4 9 7 15.5 CONVERTER CONTROL 4 9 8 15.5.1 FEEDBACK CONTROL 4 9 8 15.5.2 BALANCING O F THE D C CAPACITOR VOLTAGE 4 9 8 15.6 SIMULATION ANALYSIS O F A CASCADED 3-5-9 HYBRID INVERTER TOPOLOGY BASED GRID CONNECTED SYSTEM 5 0 0 15.6.1 SIMULATION RESULTS AND DISCUSSIONS 5 0 2 15.6.1.1 MODEL RESPONSE TO STEP C H A N G E IN LOAD 507 15.7 CONCLUSION 5 1 2 REFERENCES 5 1 3 16 INTELLIGENT MULTI-AGENT SYSTEM FOR SMART GRID POWER MANAGEMENT.515 A L I FELIACHI, RABIE BELKACEMI 16.1 INTRODUCTION 5 1 5 16.2 A MULTI-AGENT SYSTEM 5 1 6 16.3 IMMUNE BASED MULTI-AGENT SYSTEM 5 1 9 16.4 APPLICATION TO P O W E R DISTRIBUTION SYSTEMS 5 2 5 16.4.1 SHIPBOARD P O W E R DISTRIBUTION SYSTEM 5 2 5 16.4.2 ANALOG P O W E R DISTRIBUTION SYSTEM SIMULATOR 5 3 5 16.5 CONCLUSION 5 4 1 ACKNOWLEDGMENT 5 4 1 REFERENCES 5 4 2 IMAGE 10 XVIII CONTENTS 17 GRID-FAULT RIDE-THROUGH CONTROL METHOD FOR A WIND TURBINE INVERTER 543 A N A VLADAN STANKOVIC, DEJAN SCHREIBER, XIANGPENG ZHENG 17.1 INTRODUCTION 5 4 3 17.2 RECENT STUDIES ON GRID-FAULT RIDE-THROUGH CONTROL METHODS FOR WIND TURBINE INVERTER 544 17.3 GRID-SIDE CONVERTERS UNDER UNBALANCED OPERATING CONDITIONS 5 4 9 17.3.1 ANALYSIS O F THE GRID-SIDE CONVERTER UNDER UNBALANCED OPERATING CONDITIONS 5 5 0 17.4 GRID-FAULT RIDE-THROUGH GENERALIZED CONTROL METHOD FOR A W I N D TURBINE INVERTER 5 5 2 17.4.1 THEORETICAL APPROACH .553 17.4.1.1 DERIVATION 5 5 3 17.4.1.2 CRITICAL EVALUATION 5 5 6 17.4.2 GENERALIZED METHOD FOR GRID-FAULT RIDE THROUGH CONTROL FOR A W I N D TURBINE INVERTER 5 5 7 17.5 EXAMPLE 5 5 8 17.6 CONCLUSION 561 REFERENCES 561 18 SYNCHRONIZED PHASOR MEASUREMENT IN SMART GRID SITUATIONAL AWARENES 565 YONG JIA, R. M A T T H E W GARDNER, TAO XIA, YILU LIU 18.1 INTRODUCTION 565 18.2 EVENT DETECTION AND LOCATION 5 6 6 18.2.1 EVENT TRIGGER AND SIZE ESTIMATION 5 6 7 18.2.2 EVENT LOCATION 5 7 0 18.3 INTER-AREA OSCILLATION ANALYSIS 5 7 6 18.3.1 OSCILLATION DETECTION 5 7 6 18.3.2 OSCILLATION M O D E ANALYSIS 5 7 9 18.4 WIDE-AREA FREQUENCY AND ANGLE VISUALIZATION 5 8 2 18.4.1 WIDE-AREA FREQUENCY VISUALIZATION 5 8 3 18.4.2 WIDE-AREA ANGLE VISUALIZATION 5 8 6 18.5 SUMMARY 5 8 9 REFERENCES 5 8 9 19 SYNTHESIS OF DROOP-BASED DISTRIBUTED GENERATORS IN A MICRO GRID SYSTEM 593 MAHESH S. ILLINDALA 19.1 INTRODUCTION 594 19.2 DROOP-BASED GENERATION CONTROL IN A DISTRIBUTED GENERATOR 5 9 5 19.3 MICRO GRID SYSTEM WITH SERIES CONNECTION O F DISTRIBUTED GENERATORS 5 9 8 19.3.1 SMALL-SIGNAL DYNAMIC BEHAVIOR 5 9 8 19.3.2 DESIGN GUIDELINES 6 0 4 IMAGE 11 CONTENTS X I X 19.4 MICRO GRID SYSTEM WITH PARALLEL CONNECTION O F DISTRIBUTED GENERATORS 6 0 6 19.4.1 SMALL-SIGNAL DYNAMIC BEHAVIOR 6 0 6 19.4.2 DESIGN RECOMMENDATIONS 617 19.5 EFFECT O F VARIATION IN TIE-LINE R/X RATIO ON THE D Y N A M I C BEHAVIOR O F MICRO GRID SYSTEM 6 1 9 19.5.1 DESIGN RECOMMENDATIONS 6 2 2 19.6 SUMMARY 6 2 2 REFERENCES 6 2 3 20 MODELING AND CONTROL OF FUEL CELLS AS DISTRIBUTED GENERATORS IN SMART GRIDS 625 KOUROSH SEDGHISIGARCHI, A L I FELIACHI 20.1 INTRODUCTION 6 2 5 20.2 S O F C AND P E M DYNAMIC MODELS 6 2 6 20.2.1 LITERATURE SURVEY 6 2 6 20.2.2 P E M AND S O F C PRINCIPLES 6 2 7 20.2.2.1 PEM: PROTON EXCHANGE M E M B R A N E FUEL CELLS 627 20.2.2.2 SOFC: SOLID OXIDE FUEL CELLS 6 2 8 20.2.3 S O F C DYNAMIC MODELING 6 2 9 20.2.3.1 C O M P O N E N T MATERIAL BALANCE EQUATIONS 6 2 9 20.2.3.2 ENERGY BALANCE EQUATIONS (THERMAL MODEL) 631 20.2.3.3 NERNST'S VOLTAGE EQUATIONS 6 3 2 20.2.3.4 DEVELOPED S O F C DYNAMIC MODEL 6 3 3 20.2.4 COMPARISON O F S O F C AND P E M DYNAMIC MODELS 6 3 6 20.2.5 SIMULATION RESULTS FOR A STANDALONE S O F C 6 3 7 20.3 POWER FLOW CONTROL STRATEGIES 6 3 9 20.3.1 LITERATURE SURVEY 6 3 9 20.3.2 ACTIVE AND REACTIVE P O W E R FLOW CONTROL 6 4 0 20.3.2.1 FUEL CELL CONTROL (PRIMARY CONTROL LOOP) 6 4 1 20.3.2.2 STANDALONE M O D E O F OPERATION (SECONDARY CONTROL LOOP) 6 4 2 20.3.2.3 GRID-CONNECTED M O D E O F OPERATION (SECONDARY CONTROL LOOP) 6 4 3 20.3.3 SIMULATION RESULTS 6 4 6 20.3.3.1 SINGLE PHASE CONNECTION 6 4 6 20.3.3.2 THREE PHASE CONNECTION 6 4 7 20.4 CONCLUSION 6 5 0 REFERENCES 651 21 PREDICTIVE SMART GRID CONTROL WITH EXACT AGGREGATED POWER CONSTRAINTS 655 KLAUS TRANGBAEK, METTE PEDERSEN, J A N BENDTSEN, J A K O B STOUSTRUP 21.1 INTRODUCTION 6 5 5 21.2 SYSTEM DESCRIPTION 6 5 8 21.3 INTELLIGENT CONSUMERS 6 5 9 IMAGE 12 X X C O N T E N T S 21.4 MINKOWSKI ADDITION O F RESOURCE POLYTOPES 6 6 0 21.5 DISTRIBUTION 6 6 4 21.5.1 MID-RANGING 6 6 6 21.6 SIMULATION EXAMPLE 6 6 6 21.6.1 PROBLEM FORMULATION 6 6 7 21.6.2 SIMULATION DATA AND PARAMETERS 6 6 8 21.6.3 T H E CAUTIOUS METHOD 6 6 9 21.6.4 SIMULATION RESULTS 6 6 9 21.6.5 PARAMETER DEPENDENCY 6 6 9 21.6.6 COMPUTATIONAL BURDEN 6 7 2 21.6.7 COMMUNICATION L O A D 6 7 3 21.7 DISCUSSION 6 7 3 REFERENCES 6 7 4 AUTHOR INDEX 675
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spelling	Smart Power Grids 2011 Ali Keyhani, ... Eds. Berlin [u.a.] Springer 2012 XX, 674 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Power Systems Dezentrale Elektrizitätserzeugung (DE-588)7656449-6 gnd rswk-swf Elektrische Maschine (DE-588)4014308-9 gnd rswk-swf Leistungselektronik (DE-588)4035235-3 gnd rswk-swf Intelligentes Stromnetz (DE-588)7708028-2 gnd rswk-swf Erneuerbare Energien (DE-588)4068598-6 gnd rswk-swf (DE-588)4143413-4 Aufsatzsammlung gnd-content Intelligentes Stromnetz (DE-588)7708028-2 s Erneuerbare Energien (DE-588)4068598-6 s Dezentrale Elektrizitätserzeugung (DE-588)7656449-6 s Elektrische Maschine (DE-588)4014308-9 s Leistungselektronik (DE-588)4035235-3 s DE-604 Keyhani, Ali 1942- Sonstige (DE-588)140359362 oth Erscheint auch als Online-Ausgabe 978-3-642-21578-0 X:MVB text/html http://deposit.dnb.de/cgi-bin/dokserv?id=3766147&prov=M&dok_var=1&dok_ext=htm Inhaltstext DNB Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=024995101&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Smart Power Grids 2011 Dezentrale Elektrizitätserzeugung (DE-588)7656449-6 gnd Elektrische Maschine (DE-588)4014308-9 gnd Leistungselektronik (DE-588)4035235-3 gnd Intelligentes Stromnetz (DE-588)7708028-2 gnd Erneuerbare Energien (DE-588)4068598-6 gnd
subject_GND	(DE-588)7656449-6 (DE-588)4014308-9 (DE-588)4035235-3 (DE-588)7708028-2 (DE-588)4068598-6 (DE-588)4143413-4
title	Smart Power Grids 2011
title_auth	Smart Power Grids 2011
title_exact_search	Smart Power Grids 2011
title_full	Smart Power Grids 2011 Ali Keyhani, ... Eds.
title_fullStr	Smart Power Grids 2011 Ali Keyhani, ... Eds.
title_full_unstemmed	Smart Power Grids 2011 Ali Keyhani, ... Eds.
title_short	Smart Power Grids 2011
title_sort	smart power grids 2011
topic	Dezentrale Elektrizitätserzeugung (DE-588)7656449-6 gnd Elektrische Maschine (DE-588)4014308-9 gnd Leistungselektronik (DE-588)4035235-3 gnd Intelligentes Stromnetz (DE-588)7708028-2 gnd Erneuerbare Energien (DE-588)4068598-6 gnd
topic_facet	Dezentrale Elektrizitätserzeugung Elektrische Maschine Leistungselektronik Intelligentes Stromnetz Erneuerbare Energien Aufsatzsammlung
url	http://deposit.dnb.de/cgi-bin/dokserv?id=3766147&prov=M&dok_var=1&dok_ext=htm http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=024995101&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
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