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Control of power inverters in renewable energy and smart grid integration / / Qing-Chang Zhong, The University of Sheffield, UK and Tomas Hornik, Turbo Power Systems Ltd., UK
| Control of power inverters in renewable energy and smart grid integration / / Qing-Chang Zhong, The University of Sheffield, UK and Tomas Hornik, Turbo Power Systems Ltd., UK |
| Autore | Zhong Qing-Chang |
| Edizione | [1st edition] |
| Pubbl/distr/stampa | Chichester, West Sussex : , : Wiley, A John Wiley & Sons, Ltd., Publications, , 2013 |
| Descrizione fisica | 1 online resource (439 p.) |
| Disciplina |
621.042
621.31/042 621.31042 |
| Altri autori (Persone) | HornikTomas |
| Collana | Wiley - IEEE |
| Soggetto topico |
Electric inverters
Electric current converters Interconnected electric utility systems Smart power grids Renewable energy sources |
| ISBN |
1-118-48180-1
1-299-18736-6 1-118-48178-X 1-118-48179-8 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Dedication xv -- Preface xvii -- Foreword xix -- Acknowledgements xxi -- About the Authors xxiii -- List of Abbreviations xxvi -- List of Figures xxxviii -- List of Tables xl -- 1 Introduction 1 /1.1 Outline of the Book 1 /1.2 Basics of Power Processing 4 /1.3 Hardware Issues 24 /1.4 Wind Power Systems 43 /1.5 Solar Power Systems 52 /1.6 Smart Grid Integration 54 -- 2 Preliminaries 65 /2.1 Power Quality Issues 65 /2.2 Repetitive Control 69 /2.3 Reference Frames 72 -- Part One Power Quality Control 81 -- 3 Current H∞ Repetitive Control 83 /3.1 System Description 83 /3.2 Controller Design 84 /3.3 Design Example 88 /3.4 Experimental Results 90 /3.5 Summary 92 -- 4 Voltage and Current H∞ Repetitive Control 95 /4.1 System Description 95 /4.2 Modelling of an Inverter 96 /4.3 Controller Design 97 /4.4 Design Example 102 /4.5 Simulation Results 104 /4.6 Summary 108 -- 5 Voltage H∞ Repetitive Control with a Frequency-adaptiveMechanism 109 /5.1 System Description 109 /5.2 Controller Design 110 /5.3 Design Example 116 /5.4 Experimental Results 117 /5.5 Summary 123 -- 6 Cascaded Current-VoltageH∞ Repetitive Control 127 /6.1 Operation Modes in Microgrids 127 /6.2 Control Scheme 129 /6.3 Design of the Voltage Controller 131 /6.4 Design of the Current Controller 133 /6.5 Design Example 134 /6.6 Experimental Results 136 /6.7 Summary 145 -- 7 Control of Inverter Output Impedance 149 /7.1 Inverters with Inductive Output Impedances (L-inverters) 149 /7.2 Inverters with Resistive Output Impedances (R-inverters) 150 /7.3 Inverters with Capacitive Output Impedances (C-inverters) 152 /7.4 Design of C-inverters to Improve the Voltage THD 153 /7.5 Simulation Results for R-, L- and C-inverters 156 /7.6 Experimental Results for R-, L- and C-inverters 158 /7.7 Impact of the Filter Capacitor 161 /7.8 Summary 162 -- 8 Bypass of Harmonic Current Components 163 /8.1 Controller Design 163 /8.2 Physical Interpretation of the Controller 165 /8.3 Stability Analysis 167 /8.4 Experimental Results 169 /8.5 Summary 169.
9 Power Quality Issues in Traction Power Systems 171 /9.1 Introduction 171 /9.2 Description of the Topology 174 /9.3 Compensation of Negative-sequence Currents, Reactive Power and Harmonic Currents 174 /9.4 Special Case: cose = 1 178 /9.5 Simulation Results 180 /9.6 Summary 182 -- Part Two Neutral Line Provision 185 -- 10 Topology of a Neutral Leg 187 /10.1 Introduction 187 /10.2 Split DC Link 188 /10.3 Conventional Neutral Leg 189 /10.4 Independently-controlledNeutral Leg 190 /10.5 Summary 190 -- 11 Classical Control of a Neutral Leg 193 /11.1 Mathematical Modelling 193 /11.2 Controller Design 195 /11.3 Performance Evaluation 198 /11.4 Selection of the Components 200 /11.5 Simulation Results 201 /11.6 Summary 204 -- 12 H∞ Voltage-Current Control of a Neutral Leg 205 /12.1 Mathematical Modelling 205 /12.2 Controller Design 207 /12.3 Selection of Weighting Functions 211 /12.4 Design Example 212 /12.5 Simulation Results 213 /12.6 Summary 214 -- 13 Parallel PI Voltage-H∞ Current Control of a Neutral Leg 215 /13.1 Description of the Neutral Leg 215 /13.2 Design of an H∞ Current Controller 217 /13.3 Addition of a Voltage Control Loop 221 /13.4 Experimental Results 223 /13.5 Summary 226 -- 14 Applications in Single-phase to Three-phase Conversion 229 /14.1 Introduction 229 /14.2 The Topology under Consideration 231 /14.3 Basic Analysis 233 /14.4 Controller Design 235 /14.5 Simulation Results 240 /14.6 Summary 242 -- Part Three Power Flow Control 245 -- 15 Current Proportional-Integral Control 247 /15.1 Control Structure 247 /15.2 Controller Implementation 249 /15.3 Experimental Results 250 /15.4 Summary 254 -- 16 Current Proportional-Resonant Control 255 /16.1 Proportional-Resonant Controller 255 /16.2 Control Structure 256 /16.3 Controller Design 257 /16.4 Experimental Results 259 /16.5 Summary 262 -- 17 Current Deadbeat Predictive Control 265 /17.1 Control Structure 265 /17.2 Controller Design 265 /17.3 Experimental Results 267 /17.4 Summary 271 -- 18 Synchronverters: Grid-friendly Inverters that Mimic Synchronous Generators 273 /18.1 Mathematical Model of Synchronous Generators 274 /18.2 Implementation of a Synchronverter 277 /18.3 Operation of a Synchronverter 279 /18.4 Simulation Results 282 /18.5 Experimental Results 285 /18.6 Summary 290. 19 Parallel Operation of Inverters 293 /19.1 Introduction 293 /19.2 Problem Description 295 /19.3 Power Delivered to a Voltage Source 295 /19.4 Conventional Droop Control 297 /19.5 Inherent Limitations of Conventional Droop Control 299 /19.6 Robust Droop Control of R-inverters 304 /19.7 Robust Droop Control of C-inverters 311 /19.8 Robust Droop Control of L-inverters 318 /19.9 Summary 327 -- 20 Robust Droop Control with Improved Voltage Quality 329 /20.1 Control Strategy 329 /20.2 Experimental Results 331 /20.3 Summary 340 -- 21 Harmonic Droop Controller to Improve Voltage Quality 341 /21.1 Model of an Inverter System 341 /21.2 Power Delivered to a Current Source 343 /21.3 Reduction of Harmonics in the Output Voltage 344 /21.4 Simulation Results 347 /21.5 Experimental Results 349 /21.6 Summary 351 -- Part Four Synchronisation 353 -- 22 Conventional Synchronisation Techniques 355 /22.1 Introduction 355 /22.2 Zero-crossing Method 356 /22.3 Basic Phase-Locked Loops (PLL) 357 /22.4 PLL in the Synchronously Rotating Reference Frame (SRF-PLL) 358 /22.5 Second-Order Generalised Integrator-based PLL (SOGI-PLL) 360 /22.6 Sinusoidal Tracking Algorithm (STA) 361 /22.7 Simulation Results with SOGI-PLL and STA 363 /22.8 Experimental Results with SOGI-PLL and STA 365 /22.9 Summary 369 -- 23 Sinusoid-Locked Loops 373 /23.1 Single-phase SynchronousMachine (SSM) Connected to the Grid 373 /23.2 Structure of a Sinusoid-Locked Loop (SLL) 374 /23.3 Tracking of the Frequency and the Phase 375 /23.4 Tracking of the Voltage Amplitude 376 /23.5 Tuning of the Parameters 376 /23.6 Equivalent Structure 377 /23.7 Simulation Results 379 /23.8 Experimental Results 382 /23.9 Summary 385 -- References -- Bibliography 387. |
| Record Nr. | UNINA-9910141514503321 |
Zhong Qing-Chang
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| Chichester, West Sussex : , : Wiley, A John Wiley & Sons, Ltd., Publications, , 2013 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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Power electronics-enabled autonomous power systems : next generation smart grids / / Qing-Chang Zhong, Illinois Institute of Technology, Chicago, USA
| Power electronics-enabled autonomous power systems : next generation smart grids / / Qing-Chang Zhong, Illinois Institute of Technology, Chicago, USA |
| Autore | Zhong Qing-Chang |
| Pubbl/distr/stampa | Hoboken, New Jersey, USA : , : John Wiley & Sons Ltd, , 2020 |
| Descrizione fisica | 1 online resource (494 pages) |
| Disciplina | 621.3126 |
| Soggetto topico | Electric inverters |
| ISBN |
1-118-80350-7
1-118-80349-3 1-118-80351-5 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Theoretical Framework. Synchronized and Democratized (SYNDEM) Smart Grid -- Ghost Power Theory -- 1G VSM: Synchronverters. Synchronverter Based Generation -- Synchronverter Based Loads -- Control of Permanent Magnet Synchronous Generator (PMSG) Based Wind Turbines -- Synchronverter Based AC Ward Leonard Drive Systems -- Synchronverter without a Dedicated Synchronization Unit -- Synchronverter Based Loads without a Dedicated Synchronisation Unit -- Control of a DFIG Based Wind Turbine as a VSG (DFIG-VSG) -- Synchronverter Based Transformerless Photovoltaic Systems -- Synchronverter Based STATCOM without an Dedicated Synchronization Unit -- Synchronverters with Bounded Frequency and Voltage -- Virtual Inertia, Virtual Damping, and Fault Ride-through -- VSM: Robust Droop Controller. Synchronization Mechanism of Droop Control -- Robust Droop Control -- Universal Droop Control -- Self-synchronized Universal Droop Controller -- Droop-Controlled Loads for Continuous Demand Response -- Current-limiting Universal Droop Controller -- 3G VSM: Cybersync Machines. Cybersync Machines -- Case Studies. A Single-node System -- A 100% Power Electronics Based SYNDEM Smart Grid Testbed -- A Home Grid -- Texas Panhandle Wind Power System. |
| Record Nr. | UNINA-9910555196703321 |
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Zhong Qing-Chang
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| Hoboken, New Jersey, USA : , : John Wiley & Sons Ltd, , 2020 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
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