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Wind Power Part 4: Components and Maintenance Small Wind

Wind Power Part 4: Components and Maintenance Small Wind. San Jose State University FX Rongère February 2009. Inside a Wind turbine. GE Wind 1.5 MW. Inside a Wind turbine. Generator. Tri-phase Synchronous Generator. The central magnet rotates with the rotor shaft of the turbine.

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Wind Power Part 4: Components and Maintenance Small Wind

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  1. Wind Power Part 4:Components and MaintenanceSmall Wind San Jose State University FX Rongère February 2009

  2. Inside a Wind turbine GE Wind 1.5 MW

  3. Inside a Wind turbine

  4. Generator • Tri-phase Synchronous Generator The central magnet rotates with the rotor shaft of the turbine A variable Magnetic Field is inducted in the stator generating an Alternative Current • When connected to the grid the generator is forced to rotate at constant speed • To gain flexibility, the connection to the grid will be indirect with a double conversion AC-DC, DC-AC

  5. Generator • Tri-phase synchronous Generator • Central magnet may be electromagnets fed by the grid • Central magnet may be permanent using Rare Earth Metals* • Increasing the number of poles one can reduce the rotation speed of the generator * In fact, the rare earth metals are not rare and new technologies are based on permanent magnets

  6. Generator • Tri-phase Asynchronous Generator • The magnet of the rotor is replaced by a squirrel cage • When the cage turns faster than the magnetic field in the stator it generates a high current in it and then a magnetic field which will play the same role as the magnet • The current generated will depend of the difference of rotation between the rotor and the magnetic field in the stator: it is called the slip (typically 1%) • To gain flexibility on the rotation speed of the shaft the slip will be varied using a variation of its electrical resistance Rotor of an asynchronous generator

  7. Gear Box • Tip speed ratio issue for large turbines • Tip speed ratio (λ) is limited Typically, for a 3 blade turbine is: 3<λ<5

  8. Gearbox • Rotation speed decrease with the size of the turbine 100 kW 500 kW 1,000 kW 2,500 kW 5,000 kW

  9. Gearbox • Torque increases a lot with power

  10. Gearbox • Converts few rotation/mn in 1,500 rpm • The gear ratio may be 50, 100 or more 1.5 MW gearbox and drive train Causes of wind turbine failures Source:Condition Monitoring of Wind Turbines, David Infield

  11. Gearbox • Cost of repairs

  12. Gearbox • Multi-stage gearbox • Planetary gearbox High speed stage Generator Low speed mainshaft Intermediate speed stage

  13. Gearbox • Multi-drive train Multi-drive train developed by Clipper Windpower in 2002-2004 with eight generators around the main shaft. The Liberty turbine currently commercialized has four generators

  14. Yaw Drive and Pitch Drive • The yaw drive maintains the wind turbine facing into the wind • It is similar to a tracker for a solar panel • The pitch is the angle of attack of the blades in the wind flow • Optimizing the pitch allows to improve efficiency for different wind speeds

  15. NREL wind lab: NWTC • Located in Denver (Co) Field testing Environment chamber at -60oF 2.5 MW Dynamo-meter Structural blade testing

  16. Offshore Wind • Technology for the Offshore oil industry

  17. Solano 415 MW Altamont Pass 586 MW Wind resource in California

  18. San Gorgonio 619 MW Tehachapi 665 MW Pacheco 16 MW Wind resource in California

  19. Offshore Wind • Offshore projects in Europe Source: Offshore Wind Experiences - IEA About 1,200 MW installed in 2007 Source: EWEA Delivering Offshore Wind Power in Europe, December 2007

  20. Offshore wind farms • Middelgrunden (Denmark) 20 2.0 MW Turbines (Bonus-Siemens) height: 64 m. diameter: 76m. (2001)

  21. Offshore Wind farms • Inner Dowsing (UK) 54 3.6 MW Turbines (Siemens) height: 80 m. diameter: 108m. (2008)

  22. Offshore Wind • Projects in the USA (2007) • Cape Wind (Cape Cod / Nantucket Sound) • Bluewater Wind (Long Island) • Nai Kun (Hecate Strait) • Galveston Offshore Wind (Texas)

  23. Cost of a wind turbine • Project cost including connection • Turbine cost

  24. Component costs • Cost of the components of a wind turbine REpower MM99 wind turbine Ref: M. Gower Mat UK Energy Materials Review Material R&D Priorities for Wind Power Generation June 15, 2007

  25. O&M costs • O&M costs represent 10% to 12% of the cost per kWh

  26. Price /kWh • The prices in the LB database reflect the price of electricity as sold by the project owner reduced by the receipt of any available state and federal incentives (e.g., the PTC Power Tax Credit), and by the value that might be received through the separate sale of renewable energy certificates (RECs)

  27. Comparison to the market price of electricity • With incentive wind power is competitive with market average price

  28. Off-take • Traditionally over long contract PPA with utilities • Increasingly sold on market

  29. Environmental Issues • Noise • Visual impact • Construction impact • Avian impact 250 m 350 m Source: www.omafra.gov.on.ca

  30. Avian Impact • Source: National Wind Coordination Committee, Fact sheet Nov. 2004

  31. Avian Impact • Source: National Wind Coordination Committee, Fact sheet Nov. 2004

  32. Avian Impact • Source: National Wind Coordination Committee, Fact sheet Nov. 2004

  33. Avian Impact • Main accidental death causes for birds Source: Mick Sagrillo PUTTING WIND POWER'S EFFECT ON BIRDS IN PERSPECTIVE 2003 * Number estimated using the ratio per MW provided by the NWCC multiplied by the installed wind power in the USA in 2006 (15,575 MW)

  34. Small Wind Wind Turbine (400 W-100 kW) Guyed or Tilt-Up Tower (60-120 ft) Cumulative Production Meter AC Load Center Safety Switch Power Processing Unit (Inverter)

  35. Factors to consider • Good wind resource: Class 2 or better • Home or business located on 1 acre or more of land • Average monthly electricity bills >$100 for 10 kW system, >$50 for 5 kW system • Zoning restrictions, economic incentives

  36. Modern Small Wind Turbines • Small turbines range from 20 W to 100 kW • Only 3-4 moving parts means very low maintenance • 20- to 40-year design life • Proven technology – 150,000 installed; over a billion operational hours 1.8 kW

  37. Installation Cost • Estimate $2-4/installed watt for typical system • Smaller systems require smaller initial outlay, but cost more per watt • Taller towers cost more, but usually reduce the payback period A 4-10 kW system can meet the needs of a typical home Customers paying 12 cents/kWh or more for electricity with average wind speeds of 10 mph or more can expect a payback period of 8-16 years

  38. Example

  39. Building integration Examples of projects integrating wind power in buildings

  40. Wind development worldwide • Major Wind Development countries

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