Understanding Wind Power Technology

Understanding Wind Power Technology

  • Producent: John Wiley
  • Rok produkcji: 2014
  • ISBN: 9781118647516
  • Ilość stron: 482
  • Oprawa: Twarda
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Opis: Understanding Wind Power Technology

Wind energy technology has progressed enormously over the last decade. In coming years it will continue to develop in terms of power ratings, performance and installed capacity of large wind turbines worldwide, with exciting developments in offshore installations. Designed to meet the training needs of wind engineers, this introductory text puts wind energy in context, from the natural resource to the assessment of cost effectiveness and bridges the gap between theory and practice. The thorough coverage spans the scientific basics, practical implementations and the modern state of technology used in onshore and offshore wind farms for electricity generation. Key features: * provides in-depth treatment of all systems associated with wind energy, including the aerodynamic and structural aspects of blade design, the flow of energy and loads through the wind turbine, the electrical components and power electronics including control systems * explains the importance of wind resource assessment techniques, site evaluation and ecology with a focus of project planning and operation * describes the integration of wind farms into the electric grid and includes a whole chapter dedicated to offshore wind farms * includes questions in each chapter for readers to test their knowledge Written by experts with deep experience in research, teaching and industry, this text conveys the importance of wind energy in the international energy-policy debate, and offers clear insight into the subject for postgraduates and final year undergraduate students studying all aspects of wind engineering. Understanding Wind Power Systems is also an authoritative resource for engineers designing and developing wind energy systems, energy policy makers, environmentalists, and economists in the renewable energy sector. "'Spanning the scientific basics, practical implementations and the state of modern technology, this title looks like an authoritative resource for anyone who needs to ensure their turbine knowledge is up to scratch." (Real Power, 1 April 2014)Preface xiii About the Authors xiv 1 The History of Wind Energy 1 Jos Beurskens 1.1 Introduction 1 1.2 The First Windmills: 600-1890 2 1.2.1 Technical Development of the First Horizontal Windmills 5 1.3 Generation of Electricity using Wind Farms: Wind Turbines 1890-1930 10 1.4 The First Phase of Innovation: 1930-1960 16 1.5 The Second Phase of Innovation and Mass Production: 1960 to Today 25 1.5.1 The State-Supported Development of Large Wind Turbines 28 1.5.2 The Development of Smaller Wind Turbines 36 1.5.3 Wind Farms, Offshore and Grid Connection 38 1.5.4 International Grids 41 1.5.5 To Summarise 43 References 43 2 The International Development of Wind Energy 45 Klaus Rave 2.1 The Modern Energy Debate 45 2.2 The Reinvention of the Energy Market 48 2.3 The Importance of the Power Grid 50 2.4 The New Value-added Chain 53 2.5 International Perspectives 55 2.6 Expansion into Selected Countries 58 2.7 The Role of the EU 59 2.8 International Institutions and Organisations 61 2.8.1 Scenarios 64 2.9 Global Wind Energy Outlook 2012 - The Global View into the Future 65 2.9.1 Development of the Market in Selected Countries 65 2.10 Conclusion 71 References 71 3 Wind Resources, Site Assessment and Ecology 73 Hermann van Radecke 3.1 Introduction 73 3.2 Wind Resources 73 3.2.1 Global Wind Systems and Ground Roughness 73 3.2.2 Topography and Roughness Length 75 3.2.3 Roughness Classes 76 3.2.4 Contour Lines and Obstacles 79 3.2.5 Wind Resources with WAsP, WindPRO, Windfarmer 81 3.2.6 Correlating Wind Potential with Mesoscale Models and Reanalysis Data 84 3.2.7 Wind in the Wind Farm 90 3.2.8 Wind Frequency Distribution 95 3.2.9 Site Classification and Annual Energy Production 96 3.2.10 Reference Yield and Duration of Increased Subsidy 99 3.3 Acoustics 101 3.3.1 The dB(A) Unit 101 3.3.2 Sources of Noise 103 3.3.3 Propagation through the Air 105 3.3.4 Imission Site and Benchmarks 105 3.3.5 Frequency Analysis, Tone Adjustment and Impulse Adjustment 106 3.3.6 Methods of Noise Reduction 106 3.3.7 Regulations for Minimum Distances 107 3.4 Shadow 107 3.5 Turbulence 109 3.5.1 Turbulence from Surrounding Environment 110 3.5.2 Turbulence Attributed to Turbines 111 3.6 Two Comprehensive Software Tools for Planning Wind Farms 111 3.7 Technical Guidelines, Fgw Guidelines and IEC Standards 112 3.8 Environmental Influences Bundes-Immissionsschutzgesetz (Federal Imission Control Act) and Approval Process 113 3.8.1 German Imission Protection Law (BImSchG) 114 3.8.2 Approval Process 115 3.8.3 Environmental Impact Assessment (Eia) 115 3.8.4 Specific Aspects of the Process 118 3.8.5 Acceptance 121 3.8.6 Monitoring and Clarifying Plant-Specific Data 121 3.9 Example Problems 121 3.10 Solutions to the Problems 123 References 124 4 Aerodynamics and Blade Design 126 Alois Schaffarczyk 4.1 Summary 126 4.2 Horizontal Plants 126 4.2.1 General 126 4.2.2 Basic Aerodynamic Terminology 127 4.3 Integral Momentum Theory 130 4.3.1 Momentum Theory of Wind Turbines: the Betz Limiting Value 130 4.3.2 Changes in Air Density with Temperature and Altitude 132 4.3.3 Influence of the Finite Blade Number 133 4.3.4 Swirl Losses and Local Optimisation of the Blades According to Glauert 134 4.3.5 Losses Due to Profile Drag 136 4.4 Momentum Theory of the Blade Elements 137 4.4.1 The Formulation 137 4.4.2 Example of an Implementation: WT-Perf 139 4.4.3 Optimisation and Design Rules for Blades 139 4.4.4 Extension of the Blade Element Method: The Differential Formulation 140 4.4.5 Three-Dimensional Computational Fluid Dynamics (Cfd) 141 4.4.6 Summary: Horizontal Plants 142 4.5 Vertical Plants 142 4.5.1 General 142 4.5.2 Aerodynamics of H Rotors 144 4.5.3 Aeroelastics of Vertical Axis Rotors 149 4.5.4 A 50 kW Rotor as an Example 150 4.5.5 Design Rules for Small Wind Turbines According to H-Darrieus Type A 150 4.5.6 Summary: Vertical Rotors 151 4.6 Wind-Driven Vehicles with a Rotor 151 4.6.1 Introduction 151 4.6.2 On the Theory of Wind-Driven Vehicles 152 4.6.3 Numerical Example 153 4.6.4 The Kiel Design Method 153 4.6.5 Evaluation 154 4.6.6 Completed Vehicles 155 4.6.7 Summary: Wind Vehicles 156 4.7 Exercises 157 References 158 5 Rotor Blades 162 Lothar Dannenberg 5.1 Introduction 162 5.2 Loads on Rotor Blades 163 5.2.1 Types of Loads 163 5.2.2 Fundamentals of the Strength Calculations 165 5.2.3 Cross-Sectional Values of Rotor Blades 167 5.2.4 Stresses and Deformations 172 5.2.5 Section Forces in the Rotor Blade 176 5.2.6 Bending and Inclination 178 5.2.7 Results According to Beam Theory 179 5.3 Vibrations and Buckling 180 5.3.1 Vibrations 180 5.3.2 Buckling and Stability Calculations 183 5.4 Finite Element Calculations 184 5.4.1 Stress Calculations 184 5.4.2 Fem Buckling Calculations 185 5.4.3 FEM Vibration Calculations 186 5.5 Fibre-Reinforced Plastics 187 5.5.1 Introduction 187 5.5.2 Materials (Fibres, Resins, Additives, Sandwich Materials) 188 5.5.3 Laminates and Laminate Properties 192 5.6 Production of Rotor Blades 195 5.6.1 Structural Parts of the Rotor Blades 195 5.6.2 Composite Manufacturing Methods 198 5.6.3 Assembly of the Rotor Blade 199 References 200 6 The Drive Train 202 Sonke Siegfriedsen 6.1 Introduction 202 6.2 Blade Angle Adjustment Systems 203 6.3 Wind Direction Tracking 209 6.3.1 General 209 6.3.2 Description of the Function 209 6.3.3 Components 210 6.3.4 Variations in Wind Direction Tracking Arrangements 213 6.4 Drive Train Components 215 6.4.1 Rotor Locking and Rotor Rotating Arrangements 216 6.4.2 Rotor Shaft and Mountings 217 6.4.3 Gears 220 6.4.4 Brake and Coupling 223 6.4.5 Generator 225 6.5 Drive Train Concepts 227 6.5.1 Direct-Driven - Double Mounting 228 6.5.2 Direct-Driven - Torque Support 230 6.5.3 One-Two Step Geared Drives - Double Bearings 232 6.5.4 One-Two Step Geared Drives - Torque Support 234 6.5.5 Three-Four Step Geared Drives - Double Mountings 235 6.5.6 Three-Four Step Geared Drives - Three-Point Mountings 237 6.5.7 Three-Four Step Geared Drives - Torque Support 239 6.6 Damage and Causes of Damage 240 6.7 Design of Drive Train Components 241 6.7.1 LDD 244 6.7.2 RFC 244 6.8 Intellectual Property in the Wind Industry 246 6.8.1 Example Patents of Drive Trains 247 Further Reading 251 7 Tower and Foundation 253 Torsten Faber 7.1 Introduction 253 7.2 Guidelines and Standards 255 7.3 Tower Loading 255 7.3.1 Fatigue Loads 255 7.3.2 Extreme Loads 257 7.4 Verification of the Structure 258 7.4.1 Proof of Load Capacity 258 7.4.2 Proof of Fitness for Use 259 7.4.3 Proof of Foundation 259 7.4.4 Vibration Calculations (Eigen Frequencies) 260 7.5 Design Details 261 7.5.1 Door Openings in Steel Tube Towers 262 7.5.2 Ring Flange Connections 262 7.5.3 Welded Connections 262 7.6 Materials for Towers 263 7.6.1 Steel 263 7.6.2 Concrete 263 7.6.3 Timber 264 7.6.4 Glass Fibre-Reinforced Plastic 265 7.7 Model Types 265 7.7.1 Tubular Towers 265 7.7.2 Lattice Masts 266 7.7.3 Guyed Towers 266 7.8 Foundations for Onshore WTs 267 7.8.1 Force of Gravity 267 7.8.2 Piles 267 7.8.3 Cables 267 7.9 Exercises 268 7.10 Solutions 269 References 272 8 Power Electronics and Generator Systems for Wind Turbines 273 Friedrich W. Fuchs 8.1 Introduction 273 8.2 Single-Phase AC Voltage and Three-Phase AC Voltage Systems 275 8.3 Transformer 278 8.3.1 Principle and Calculations 278 8.3.2 Equivalent Circuit Diagram, Phasor Diagram 279 8.3.3 Simplified Equivalent Circuit Diagram 281 8.3.4 Three-Phase Transformers 282 8.4 Generators for Wind Turbines 283 8.4.1 Induction Machine with Short-Circuit Rotor 284 8.4.2 Induction Machine with Slip Ring Rotor 295 8.5 Synchronous Machines 303 8.5.1 General Function 303 8.5.2 Voltage Equations and Equivalent Circuit Diagram 304 8.5.3 Power and Torque 306 8.5.4 Models of Externally Excited Synchronous Machines 307 8.5.5 Permanently Excited Synchronous Machines 308 8.5.6 Variable Speed Operation of Synchronous Machines 309 8.6 Converter Systems for Wind Turbines 310 8.6.1 General Function 310 8.6.2 Frequency Converter in Two-Level Topology 311 8.6.3 Frequency Converter with Multi-Level Circuits 317 8.7 Control of Variable-Speed Converter-Generator Systems 318 8.7.1 Control of the Converter-Fed Induction Generator with Short-Circuit Rotor 319 8.7.2 Control of the Doubly-Fed Induction Machine 325 8.7.3 Control of the Synchronous Machine 326 8.7.4 Control of the Grid-Side Converter 326 8.7.5 Design of the Controls 329 8.8 Compliance with the Grid Connection Requirements 329 8.9 Further Electronic Components 331 8.10 Features of the Power Electronics Generator System in Overview 332 8.11 Exercises 333 References 338 9 Control of Wind Energy Systems 340 Reiner Johannes Schutt 9.1 Fundamental Relationships 341 9.1.1 Allocation of the WTS Automation 341 9.1.2 System Properties of Energy Conversion in WTs 344 9.1.3 Energy Transformation at the Rotor 344 9.1.4 Energy Transformation at the Drive Train 347 9.1.5 Energy Conversion at the Generator-Converter System 348 9.1.6 Idealised Operating Characteristic Curves of WTs 351 9.2 WT Control Systems 352 9.2.1 Yaw Angle Control 352 9.2.2 Blade Angle Control 353 9.2.3 Active Power Control 354 9.2.4 Reactive Power Control 357 9.2.5 Summary of the Control Behaviour and Extended Operating Ranges of the WT 358 9.3 Operating Management Systems for WTs 358 9.3.1 Control of the Operating Sequence of WTs 359 9.3.2 Safety Systems 362 9.4 Wind Farm Control and Automation Systems 363 9.5 Remote Control and Monitoring 365 9.6 Communication Systems for WTS 366 References 368 10 Grid Integration 369 Sven Wanser and Frank Ehlers 10.1 Energy Supply Grids in Overview 369 10.1.1 General 369 10.1.2 Voltage Level of Electrical Supply Grids 370 10.1.3 Grid Structures 370 10.2 Grid Control 372 10.2.1 Controlling the Power Range 373 10.2.2 Compensating Power and Balancing Grids 373 10.2.3 Base Load, Medium Load and Peak Load 374 10.2.4 Frequency Stability 375 10.2.5 Primary Control, Secondary Control and Tertiary Control 376 10.2.6 Voltage Stability 378 10.2.7 System Services by means of Wind Turbines 378 10.3 Basic Terminology of Grid Integration of Wind Turbines 380 10.3.1 Basic Electrical Terminology 380 10.3.2 Grid Quality 384 10.4 Grid Connections for WTs 387 10.4.1 Rating the Grid Operating Media 388 10.4.2 Checking the Voltage Changes/Voltage Band 390 10.4.3 Checking the Grid Reaction 'Fast Voltage Change' 395 10.4.4 Checking the Short-Circuit Strength 396 10.5 Grid Connection of WTs 397 10.5.1 Switchgear 398 10.5.2 Protective Equipment 399 10.5.3 Integration into the Grid System 401 10.6 Further Developments in Grid Integration and Outlook 401 10.6.1 Grid Expansion 402 10.6.2 Load Displacement 404 10.6.3 Energy Storage 404 References 405 11 Offshore Wind Energy 406 Lothar Dannenberg 11.1 Offshore Wind Turbines 406 11.1.1 Introduction 406 11.1.2 Differences between Offshore and Onshore WTs 407 11.1.3 Environmental Conditions and Nature Protection 409 11.2 Currents and Loads 409 11.2.1 Currents 409 11.2.2 Current Loads 410 11.2.3 Vortex Shedding of Bodies Subject to Flows 412 11.3 Waves, Wave Loads 413 11.3.1 Wave Theories 413 11.3.2 Superposition of Waves and Currents 423 11.3.3 Loads Due to Waves (Morison Method) 425 11.4 Swell 430 11.4.1 Regular Swell 430 11.4.2 Irregular or Natural Swells 430 11.4.3 Statistics 431 11.4.4 Swell Spectra 432 11.4.5 Influence of Currents 436 11.4.6 Long-Term Statistics of the Swell 436 11.4.7 Extreme Waves 436 11.5 Scouring Formation, Growth, Corrosion and Ice 437 11.5.1 Scouring 437 11.5.2 Marine Growth 438 11.5.3 Ice Loads 439 11.5.4 Corrosion 439 11.6 Foundations for OWTs 441 11.6.1 Introduction 441 11.6.2 Fixed Foundations 442 11.6.3 Floating Foundations 447 11.6.4 Operating Strength 448 11.7 Soil Mechanics 450 11.7.1 Introduction 450 11.7.2 Soil Properties 450 11.7.3 Calculation of Load-Bearing Behaviour of the Sea Bed 451 References 454 Index 455


Szczegóły: Understanding Wind Power Technology

Tytuł: Understanding Wind Power Technology
Producent: John Wiley
ISBN: 9781118647516
Rok produkcji: 2014
Ilość stron: 482
Oprawa: Twarda
Waga: 0.88 kg


Recenzje: Understanding Wind Power Technology

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