Control of Power Inverters in Renewable Energy and Smart Grid Integration

Qing-Chang Zhong received his Diploma in electrical engineering from Hunan Institute of Engineering, Xiangtan, China, in 1990, his MSc degree in electrical engineering from Hunan University, Changsha, China, in 1997, his PhD degree in control theory and engineering from Shanghai Jiao Tong University, Shanghai, China, in 1999, and his PhD degree in control and power engineering (awarded the Best Doctoral Thesis Prize) from Imperial College London, London, UK, in 2004, respectively. He holds the Chair Professor in Control and Systems Engineering at the Department of Automatic Control and Systems Engineering, The University of Sheffield, UK. He has worked at Hunan Institute of Engineering, Xiangtan, China; Technion¨CIsrael Institute of Technology, Haifa, Israel; Imperial College London, London, UK; University of Glamorgan, Cardiff, UK; The University of Liverpool, Liverpool, UK; and Loughborough University, Leicestershire, UK. He has been on sabbatical at the Cymer Center for Control Systems and Dynamics (CCSD), University of California, San Diego, USA; and the Center for Power Electronics Systems (CPES), Virginia Tech, Blacksburg, USA. He is the author or co-author of Robust Control of Time-Delay Systems (Springer-Verlag, 2006), Control of Integral Processes with Dead Time (Springer-Verlag, 2010) and Control of Power Inverters in Renewable Energy and Smart Grid Integration (Wiley-IEEE Press, 2013). His research focuses on advanced control theory and applications, including power electronics, renewable energy and smart grid integration, electric drives and electric vehicles, robust and H-infinity control, time-delay systems and process control. He is a Specialist recognised by the State Grid Corporation of China (SGCC), a Fellow of the Institution of Engineering and Technology (IET), a Senior Member of IEEE, the Vice-Chair of IFAC TC 6.3 (Power and Energy Systems) responsible for the Working Group on Power Electronics and was a Senior Research Fellow of the Royal Academy of Engineering/Leverhulme Trust, UK (2009¨C2010). He serves as an Associate Editor for IEEE Transactions on Power Electronics and the Conference Editorial Board of the IEEE Control Systems Society. Tomas Hornik received a Diploma in Electrical Engineering in 1991 from the Technical CollegeVUzlabine, Prague, the BEng and PhD degree in electrical engineering and electronics from The University of Liverpool, UK, in 2007 and 2010, respectively. He was a postdoctoral researcher at the same university from 2010 to 2011. He joined Turbo Power Systems as a Control Engineer in 2011. His research interests cover power electronics, advanced control theory and DSP-based control applications. He had more than ten years working experience in industry as a system engineer responsible for commissioning and software design in power generation and distribution, control systems for central heating and building management. He is a member of the IEEE and the IET.

Preface xvii Acknowledgments xix About the Authors xxi List of Abbreviations xxiii 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 44 1.5 Solar Power Systems 53 1.6 Smart Grid Integration 55 2 Preliminaries 63 2.1 Power Quality Issues 63 2.2 Repetitive Control 67 2.3 Reference Frames 71 PART I POWER QUALITY CONTROL 3 Current H Repetitive Control 81 3.1 System Description 81 3.2 Controller Design 82 3.3 Design Example 87 3.4 Experimental Results 88 3.5 Summary 91 4 Voltage and Current H Repetitive Control 93 4.1 System Description 93 4.2 Modelling of an Inverter 94 4.3 Controller Design 96 4.4 Design Example 100 4.5 Simulation Results 102 4.6 Summary 107 5 Voltage H Repetitive Control with a Frequency-adaptive Mechanism 109 5.1 System Description 109 5.2 Controller Design 110 5.3 Design Example 116 5.4 Experimental Results 117 5.5 Summary 126 6 Cascaded Current-Voltage H 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 147 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 157 7.6 Experimental Results for R-, L- and C-inverters 159 7.7 Impact of the Filter Capacitor 162 7.8 Summary 163 8 Bypassing Harmonic Current Components 165 8.1 Controller Design 165 8.2 Physical Interpretation of the Controller 167 8.3 Stability Analysis 169 8.4 Experimental Results 171 8.5 Summary 172 9 Power Quality Issues in Traction Power Systems 173 9.1 Introduction 173 9.2 Description of the Topology 175 9.3 Compensation of Negative-sequence Currents, Reactive Power and Harmonic Currents 175 9.4 Special Case: cos = 1 180 9.5 Simulation Results 181 9.6 Summary 184 PART II NEUTRAL LINE PROVISION 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-controlled Neutral Leg 190 10.5 Summary 191 11 Classical Control of a Neutral Leg 193 11.1 Mathematical Modelling 193 11.2 Controller Design 195 11.3 Performance Evaluation 199 11.4 Selection of the Components 201 11.5 Simulation Results 202 11.6 Summary 205 12 H Voltage-Current Control of a Neutral Leg 207 12.1 Mathematical Modelling 207 12.2 Controller Design 210 12.3 Selection of Weighting Functions 214 12.4 Design Example 215 12.5 Simulation Results 216 12.6 Summary 217 13 Parallel PI Voltage-H Current Control of a Neutral Leg 219 13.1 Description of the Neutral Leg 219 13.2 Design of an 13.3 Addition of a Voltage Control Loop 226 13.4 Experimental Results 226 13.5 Summary 230 14 Applications in Single-phase to Three-phase Conversion 233 14.1 Introduction 233 14.2 The Topology under Consideration 236 14.3 Basic Analysis 237 14.4 Controller Design 239 14.5 Simulation Results 244 14.6 Summary 248 PART III POWER FLOW CONTROL 15 Current Proportional Integral Control 251 15.1 Control Structure 251 15.2 Controller Implementation 254 15.3 Experimental Results 254 15.4 Summary 258 16 Current Proportional-Resonant Control 259 16.1 Proportional-resonant Controller 259 16.2 Control Structure 260 16.3 Controller Design 261 16.4 Experimental Results 263 16.5 Summary 268 17 Current Deadbeat Predictive Control 269 17.1 Control Structure 269 17.2 Controller Design 269 17.3 Experimental Results 271 17.4 Summary 275 18 Synchronverters: Grid-friendly Inverters that Mimic Synchronous Generators 277 18.1 Mathematical Model of Synchronous Generators 278 18.2 Implementation of a Synchronverter 282 18.3 Operation of a Synchronverter 284 18.4 Simulation Results 287 18.5 Experimental Results 290 18.6 Summary 296 19 Parallel Operation of Inverters 297 19.1 Introduction 297 19.2 Problem Description 299 19.3 Power Delivered to a Voltage Source 300 19.4 Conventional Droop Control 301 19.5 Inherent Limitations of Conventional Droop Control 304 19.6 Robust Droop Control of R-inverters 309 19.7 Robust Droop Control of C-inverters 319 19.8 Robust Droop Control of L-inverters 326 19.9 Summary 330 20 Robust Droop Control with Improved Voltage Quality 335 20.1 Control Strategy 335 20.2 Experimental Results 337 20.3 Summary 346 21 Harmonic Droop Controller to Improve Voltage Quality 347 21.1 Model of an Inverter System 347 21.2 Power Delivered to a Current Source 349 21.3 Reduction of Harmonics in the Output Voltage 351 21.4 Simulation Results 353 21.5 Experimental Results 355 21.6 Summary 358 PART IV SYNCHRONISATION 22 Conventional Synchronisation Techniques 361 22.1 Introduction 361 22.2 Zero-crossing Method 362 22.3 Basic Phase-locked Loops (PLL) 363 22.4 PLL in the Synchronously Rotating Reference Frame (SRF-PLL) 364 22.5 Second-order Generalised Integrator-based PLL (SOGI-PLL) 366 22.6 Sinusoidal Tracking Algorithm (STA) 368 22.7 Simulation Results with SOGI-PLL and STA 369 22.8 Experimental Results with SOGI-PLL and STA 372 22.9 Summary 378 23 Sinusoid-locked Loops 379 23.1 Single-phase Synchronous Machine (SSM) Connected to the Grid 379 23.2 Structure of a Sinusoid-locked Loop (SLL) 380 23.3 Tracking of the Frequency and the Phase 382 23.4 Tracking of the Voltage Amplitude 382 23.5 Tuning of the Parameters 382 23.6 Equivalent Structure 383 23.7 Simulation Results 384 23.8 Experimental Results 386 23.9 Summary 390 References 393 Index 407