000 16502nam a2201189 i 4500
001 6047757
003 IEEE
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006 m o d
007 cr |n|||||||||
008 151221s2011 njua ob 001 eng d
020 _a9781118104965
_qebook
020 _z9780470768655
_qprint
020 _z111810496X
_qelectronic
024 7 _a10.1002/9781118104965
_2doi
035 _a(CaBNVSL)mat06047757
035 _a(IDAMS)0b00006481692cdd
040 _aCaBNVSL
_beng
_erda
_cCaBNVSL
_dCaBNVSL
050 4 _aTK1541
_b.D68 2011eb
082 0 4 _a621.312136
_222
245 0 0 _aDoubly fed induction machine :
_bmodeling and control for wind energy generation applications /
_cby Gonzalo Abad ... [et al.].
264 1 _aOxford :
_bWiley-Blackwell,
_c2011.
264 2 _a[Piscataqay, New Jersey] :
_bIEEE Xplore,
_c[2011]
300 _a1 PDF (xiv, 625 pages) :
_billustrations.
336 _atext
_2rdacontent
337 _aelectronic
_2isbdmedia
338 _aonline resource
_2rdacarrier
490 1 _aIEEE Press series on power engineering ;
_v84
500 _aIn Wiley online library
505 0 _aPreface xiii -- 1 Introduction to A Wind Energy Generation System 1 -- 1.1 Introduction 1 -- 1.2 Basic Concepts of a Fixed Speed Wind Turbine (FSWT) 2 -- 1.2.1 Basic Wind Turbine Description 2 -- 1.2.2 Power Control of Wind Turbines 5 -- 1.2.3 Wind Turbine Aerodynamics 7 -- 1.2.4 Example of a Commercial Wind Turbine 9 -- 1.3 Variable Speed Wind Turbines (VSWTs) 10 -- 1.3.1 Modeling of Variable Speed Wind Turbine 11 -- 1.3.2 Control of a Variable Speed Wind Turbine 15 -- 1.3.3 Electrical System of a Variable Speed Wind Turbine 22 -- 1.4 Wind Energy Generation System Based on DFIM VSWT 25 -- 1.4.1 Electrical Configuration of a VSWT Based on the DFIM 25 -- 1.4.2 Electrical Configuration of a Wind Farm 33 -- 1.4.3 WEGS Control Structure 34 -- 1.5 Grid Code Requirements 39 -- 1.5.1 Frequency and Voltage Operating Range 40 -- 1.5.2 Reactive Power and Voltage Control Capability 41 -- 1.5.3 Power Control 43 -- 1.5.4 Power System Stabilizer Function 45 -- 1.5.5 Low Voltage Ride Through (LVRT) 46 -- 1.6 Voltage Dips and LVRT 46 -- 1.6.1 Electric Power System 47 -- 1.6.2 Voltage Dips 50 -- 1.6.3 Spanish Verification Procedure 55 -- 1.7 VSWT Based on DFIM Manufacturers 57 -- 1.7.1 Industrial Solutions: Wind Turbine Manufacturers 57 -- 1.7.2 Modeling a 2.4 MW Wind Turbine 72 -- 1.7.3 Steady State Generator and Power Converter Sizing 79 -- 1.8 Introduction to the Next Chapters 83 -- Bibliography 85 -- 2 Back-to-Back Power Electronic Converter 87 -- 2.1 Introduction 87 -- 2.2 Back-to-Back Converter based on Two-Level VSC Topology 88 -- 2.2.1 Grid Side System 89 -- 2.2.2 Rotor Side Converter and dv/dt Filter 96 -- 2.2.3 DC Link 99 -- 2.2.4 Pulse Generation of the Controlled Switches 101 -- 2.3 Multilevel VSC Topologies 114 -- 2.3.1 Three-Level Neutral Point Clamped VSC Topology (3L-NPC) 116 -- 2.4 Control of Grid Side System 133 -- 2.4.1 Steady State Model of the Grid Side System 133 -- 2.4.2 Dynamic Modeling of the Grid Side System 139 -- 2.4.3 Vector Control of the Grid Side System 143.
505 8 _a2.5 Summary 152 -- References 153 -- 3 Steady State of the Doubly Fed Induction Machine 155 -- 3.1 Introduction 155 -- 3.2 Equivalent Electric Circuit at Steady State 156 -- 3.2.1 Basic Concepts on DFIM 156 -- 3.2.2 Steady State Equivalent Circuit 158 -- 3.2.3 Phasor Diagram 163 -- 3.3 Operation Modes Attending to Speed and Power Flows 165 -- 3.3.1 Basic Active Power Relations 165 -- 3.3.2 Torque Expressions 168 -- 3.3.3 Reactive Power Expressions 170 -- 3.3.4 Approximated Relations Between Active Powers, Torque, and Speeds 170 -- 3.3.5 Four Quadrant Modes of Operation 171 -- 3.4 Per Unit Transformation 173 -- 3.4.1 Base Values 175 -- 3.4.2 Per Unit Transformation of Magnitudes and Parameters 176 -- 3.4.3 Steady State Equations of the DFIM in p.u 177 -- 3.4.4 Example 3.1: Parameters of a 2 MW DFIM 179 -- 3.4.5 Example 3.2: Parameters of Different Power DFIM 180 -- 3.4.6 Example 3.3: Phasor Diagram of a 2 MW DFIM and p.u. Analysis 181 -- 3.5 Steady State Curves: Performance Evaluation 184 -- 3.5.1 Rotor Voltage Variation: Frequency, Amplitude, and Phase Shift 185 -- 3.5.2 Rotor Voltage Variation: Constant Voltage-Frequency (V-F) Ratio 192 -- 3.5.3 Rotor Voltage Variation: Control of Stator Reactive Power and Torque 195 -- 3.6 Design Requirements for the DFIM in Wind Energy Generation Applications 202 -- 3.7 Summary 207 -- References 208 -- 4 Dynamic Modeling of the Doubly Fed Induction Machine 209 -- 4.1 Introduction 209 -- 4.2 Dynamic Modeling of the DFIM 210 -- 4.2.1 ab Model 212 -- 4.2.2 dq Model 214 -- 4.2.3 State-Space Representation of ab Model 216 -- 4.2.4 State-Space Representation of dq Model 229 -- 4.2.5 Relation Between the Steady State Model and the Dynamic Model 234 -- 4.3 Summary 238 -- References 238 -- 5 Testing the DFIM 241 -- 5.1 Introduction 241 -- 5.2 Off-Line Estimation of DFIM Model Parameters 242 -- 5.2.1 Considerations About the Model Parameters of the DFIM 243 -- 5.2.2 Stator and Rotor Resistances Estimation by VSC 245 -- 5.2.3 Leakage Inductances Estimation by VSC 250.
505 8 _a5.2.4 Magnetizing Inductance and Iron Losses Estimation with No-Load Test by VSC 256 -- 5.3 Summary 262 -- References 262 -- 6 Analysis of the DFIM Under Voltage Dips 265 -- 6.1 Introduction 265 -- 6.2 Electromagnetic Force Induced in the Rotor 266 -- 6.3 Normal Operation 267 -- 6.4 Three-Phase Voltage Dips 268 -- 6.4.1 Total Voltage Dip, Rotor Open-Circuited 268 -- 6.4.2 Partial Voltage Dip, Rotor Open-Circuited 273 -- 6.5 Asymmetrical Voltage Dips 278 -- 6.5.1 Fundamentals of the Symmetrical Component Method 278 -- 6.5.2 Symmetrical Components Applied to the DFIM 281 -- 6.5.3 Single-Phase Dip 283 -- 6.5.4 Phase-to-Phase Dip 286 -- 6.6 Influence of the Rotor Currents 290 -- 6.6.1 Influence of the Rotor Current in a Total Three-Phase Voltage Dip 291 -- 6.6.2 Rotor Voltage in a General Case 294 -- 6.7 DFIM Equivalent Model During Voltage Dips 297 -- 6.7.1 Equivalent Model in Case of Linearity 297 -- 6.7.2 Equivalent Model in Case of Nonlinearity 299 -- 6.7.3 Model of the Grid 300 -- 6.8 Summary 300 -- References 301 -- 7 Vector Control Strategies for Grid-Connected DFIM Wind Turbines 303 -- 7.1 Introduction 303 -- 7.2 Vector Control 304 -- 7.2.1 Calculation of the Current References 305 -- 7.2.2 Limitation of the Current References 307 -- 7.2.3 Current Control Loops 308 -- 7.2.4 Reference Frame Orientations 311 -- 7.2.5 Complete Control System 313 -- 7.3 Small Signal Stability of the Vector Control 314 -- 7.3.1 Influence of the Reference Frame Orientation 314 -- 7.3.2 Influence of the Tuning of the Regulators 320 -- 7.4 Vector Control Behavior Under Unbalanced Conditions 327 -- 7.4.1 Reference Frame Orientation 328 -- 7.4.2 Saturation of the Rotor Converter 328 -- 7.4.3 Oscillations in the Stator Current and in the Electromagnetic Torque 328 -- 7.5 Vector Control Behavior Under Voltage Dips 331 -- 7.5.1 Small Dips 333 -- 7.5.2 Severe Dips 336 -- 7.6 Control Solutions for Grid Disturbances 340 -- 7.6.1 Demagnetizing Current 340 -- 7.6.2 Dual Control Techniques 346 -- 7.7 Summary 358.
505 8 _aReferences 360 -- 8 Direct Control of the Doubly Fed Induction Machine 363 -- 8.1 Introduction 363 -- 8.2 Direct Torque Control (DTC) of the Doubly Fed Induction Machine 364 -- 8.2.1 Basic Control Principle 365 -- 8.2.2 Control Block Diagram 371 -- 8.2.3 Example 8.1: Direct Torque Control of a 2 MW DFIM 377 -- 8.2.4 Study of Rotor Voltage Vector Effect in the DFIM 379 -- 8.2.5 Example 8.2: Spectrum Analysis in Direct Torque Control of a 2 MW DFIM 384 -- 8.2.6 Rotor Flux Amplitude Reference Generation 386 -- 8.3 Direct Power Control (DPC) of the Doubly Fed Induction Machine 387 -- 8.3.1 Basic Control Principle 387 -- 8.3.2 Control Block Diagram 390 -- 8.3.3 Example 8.3: Direct Power Control of a 2 MW DFIM 395 -- 8.3.4 Study of Rotor Voltage Vector Effect in the DFIM 395 -- 8.4 Predictive Direct Torque Control (P-DTC) of the Doubly Fed Induction Machine at Constant Switching Frequency 399 -- 8.4.1 Basic Control Principle 399 -- 8.4.2 Control Block Diagram 402 -- 8.4.3 Example 8.4: Predictive Direct Torque Control of 15kW and 2 MW DFIMs at 800 Hz Constant -- Switching Frequency 411 -- 8.4.4 Example 8.5: Predictive Direct Torque Control of a 15kW DFIM at 4 kHz Constant Switching Frequency 415 -- 8.5 Predictive Direct Power Control (P-DPC) of the Doubly Fed Induction Machine at Constant Switching Frequency 416 -- 8.5.1 Basic Control Principle 417 -- 8.5.2 Control Block Diagram 419 -- 8.5.3 Example 8.6: Predictive Direct Power Control of a 15 kW DFIM at 1 kHz Constant Switching Frequency 424 -- 8.6 Multilevel Converter Based Predictive Direct Power and Direct Torque Control of the Doubly Fed Induction Machine at Constant Switching Frequency 425 -- 8.6.1 Introduction 425 -- 8.6.2 Three-Level NPC VSC Based DPC of the DFIM 428 -- 8.6.3 Three-Level NPC VSC Based DTC of the DFIM 447 -- 8.7 Control Solutions for Grid Voltage Disturbances, Based on Direct Control Techniques 451 -- 8.7.1 Introduction 451 -- 8.7.2 Control for Unbalanced Voltage Based on DPC 452 -- 8.7.3 Control for Unbalanced Voltage Based on DTC 460.
505 8 _a8.7.4 Control for Voltage Dips Based on DTC 467 -- 8.8 Summary 473 -- References 474 -- 9 Hardware Solutions for LVRT 479 -- 9.1 Introduction 479 -- 9.2 Grid Codes Related to LVRT 479 -- 9.3 Crowbar 481 -- 9.3.1 Design of an Active Crowbar 484 -- 9.3.2 Behavior Under Three-Phase Dips 486 -- 9.3.3 Behavior Under Asymmetrical Dips 488 -- 9.3.4 Combination of Crowbar and Software Solutions 490 -- 9.4 Braking Chopper 492 -- 9.4.1 Performance of a Braking Chopper Installed Alone 492 -- 9.4.2 Combination of Crowbar and Braking Chopper 493 -- 9.5 Other Protection Techniques 495 -- 9.5.1 Replacement Loads 495 -- 9.5.2 Wind Farm Solutions 496 -- 9.6 Summary 497 -- References 498 -- 10 Complementary Control Issues: Estimator Structures and Start-Up of Grid-Connected DFIM 501 -- 10.1 Introduction 501 -- 10.2 Estimator and Observer Structures 502 -- 10.2.1 General Considerations 502 -- 10.2.2 Stator Active and Reactive Power Estimation for Rotor Side DPC 503 -- 10.2.3 Stator Flux Estimator from Stator Voltage for Rotor Side Vector Control 503 -- 10.2.4 Stator Flux Synchronization from Stator Voltage for Rotor Side Vector Control 506 -- 10.2.5 Stator and Rotor Fluxes Estimation for Rotor Side DPC, DTC, and Vector Control 507 -- 10.2.6 Stator and Rotor Flux Full Order Observer 508 -- 10.3 Start-up of the Doubly Fed Induction Machine Based Wind Turbine 512 -- 10.3.1 Encoder Calibration 514 -- 10.3.2 Synchronization with the Grid 518 -- 10.3.3 Sequential Start-up of the DFIM Based Wind Turbine 523 -- 10.4 Summary 534 -- References 535 -- 11 Stand-Alone DFIM Based Generation Systems 537 -- 11.1 Introduction 537 -- 11.1.1 Requirements of Stand-alone DFIM Based System 537 -- 11.1.2 Characteristics of DFIM Supported by DC Coupled Storage 540 -- 11.1.3 Selection of Filtering Capacitors 541 -- 11.2 Mathematical Description of the Stand-Alone DFIM System 544 -- 11.2.1 Model of Stand-alone DFIM 544 -- 11.2.2 Model of Stand-alone DFIM Fed from Current Source 549 -- 11.2.3 Polar Frame Model of Stand-alone DFIM 551.
505 8 _a11.2.4 Polar Frame Model of Stand-alone DFIM Fed from Current Source 554 -- 11.3 Stator Voltage Control 558 -- 11.3.1 Amplitude and Frequency Control by the Use of PLL 558 -- 11.3.2 Voltage Asymmetry Correction During Unbalanced Load Supply 567 -- 11.3.3 Voltage Harmonics Reduction During Nonlinear Load Supply 569 -- 11.4 Synchronization Before Grid Connection By Superior PLL 573 -- 11.5 Summary 576 -- References 577 -- 12 New Trends on Wind Energy Generation 579 -- 12.1 Introduction 579 -- 12.2 Future Challenges for Wind Energy Generation: What must be Innovated 580 -- 12.2.1 Wind Farm Location 580 -- 12.2.2 Power, Efficiency, and Reliability Increase 582 -- 12.2.3 Electric Grid Integration 583 -- 12.2.4 Environmental Concerns 583 -- 12.3 Technological Trends: How They Can be Achieved 584 -- 12.3.1 Mechanical Structure of the Wind Turbine 585 -- 12.3.2 Power Train Technology 586 -- 12.4 Summary 599 -- References 600 -- Appendix 603 -- A.1 Space Vector Representation 603 -- A.1.1 Space Vector Notation 603 -- A.1.2 Transformations to Different Reference Frames 606 -- A.1.3 Power Expressions 609 -- A.2 Dynamic Modeling of the DFIM Considering the Iron Losses 610 -- A.2.1 ab Model 611 -- A.2.2 dq Model 614 -- A.2.3 State-Space Representation of ab Model 616 -- References 618 -- Index 619 -- The IEEE Press Series on Power Engineering.
506 1 _aRestricted to subscribers or individual electronic text purchasers.
520 _aA practical, hands-on guide to capturing the potential of DFIM technologyDoubly Fed Induction Machine (DFIM)-based wind turbines have proven to be a cost-effective, efficient, and reliable method for generating power. Readers interested in DFIM technology can turn to this text to discover not only the current state of the technology and future directions for research and development, but also learn the tools they need to devise their own innovations and solutions.Doubly Fed Induction Machine offers clear mathematical descriptions of basic dynamic DFIM models as well as a detailed steady-state analysis. The authors provide a more sophisticated model of a DFIM that takes into account grid disturbances such as voltage dips and balance disruptions.The second part of the book surveys DFIM control strategies. Readers will learn about standard solutions used by wind turbine manufacturers, new developments designed to improve the behavior of high-power wind turbines, as well as hardware-based solutions that address faulty grid scenarios. The book concludes with a forecast of the future of DFIMs.This book is an ideal, practical reference for engineers, researches, and students interested in fully learning the power generation capabilities of DFIM technology. This book helps readers grasp and apply complex concepts by using numerous aids throughout including:. Diagrams and graphs. Step-by-step calculations. Illustrations and photos of DFIM components and systems.
530 _aAlso available in print.
538 _aMode of access: World Wide Web
588 _aDescription based on PDF viewed 12/21/2015.
650 0 _aInduction generators
_xMathematical models.
650 0 _aInduction generators
_xAutomatic control.
650 0 _aWind turbines
_xEquipment and supplies.
655 0 _aElectronic books.
695 _aAC machines
695 _aAerospace electronics
695 _aBlades
695 _aCapacitors
695 _aComputational modeling
695 _aControl systems
695 _aCurrent measurement
695 _aDifferential equations
695 _aElectromagnetic forces
695 _aElectronics packaging
695 _aEnergy storage
695 _aEquations
695 _aEstimation
695 _aFacsimile
695 _aGenerators
695 _aHardware
695 _aIce
695 _aIndexes
695 _aInductance
695 _aInduction machines
695 _aIron
695 _aMachine vector control
695 _aMathematical model
695 _aPoles and towers
695 _aPower control
695 _aPower conversion
695 _aReliability
695 _aResistance
695 _aResistors
695 _aRotors
695 _aSensors
695 _aShafts
695 _aSpace stations
695 _aStator windings
695 _aStators
695 _aSteady-state
695 _aSwitching frequency
695 _aTopology
695 _aTorque
695 _aTorque control
695 _aVoltage control
695 _aVoltage fluctuations
695 _aVoltage measurement
695 _aWarranties
695 _aWind
695 _aWind energy
695 _aWind energy generation
695 _aWind farms
695 _aWind power generation
695 _aWind turbines
695 _aWindings
700 1 _aAbad, G.
_q(Gonzalo),
_d1976-
710 2 _aIEEE Xplore (Online Service),
_edistributor.
710 2 _aJohn Wiley & Sons,
_epublisher.
776 0 8 _iPrint version:
_z9780470768655
830 0 _aIEEE Press series on power engineering ;
_v84
856 4 2 _3Abstract with links to resource
_uhttps://ieeexplore.ieee.org/xpl/bkabstractplus.jsp?bkn=6047757
999 _c42374
_d42374