Download ppt - WIND ENERGY Wind are produced by disproportionate solar heating of the earth’s land and sea surfaces. –It forms about 2% of the solar energy –Small % of

WIND ENERGYWIND ENERGYWind are produced by disproportionate solar Wind are produced by disproportionate solar heating of the earth’s land and sea surfaces.heating of the earth’s land and sea surfaces.

– It forms about 2% of the solar energy– Small % of the 2% is exploited

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Worldwide installed capacity:Worldwide installed capacity:10,000 MW10,000 MW

Wind EnergyWind Energy

• Needs:Needs:Good winds Good winds Coastal areas, hilltops, E-W valleysCoastal areas, hilltops, E-W valleys

• Minimum average windspeed :Minimum average windspeed : 4.5 m/s at 10 metres4.5 m/s at 10 metres

• 3 types of wind energy systems: 3 types of wind energy systems: central grid central grid isolated grid isolated grid off-gridoff-grid

750 kW machine750 kW machine

WIND RESOURCES IN USWIND RESOURCES IN US

WIND RESOURCES IN THE WORLDWIND RESOURCES IN THE WORLD

CONSTRAINTS TO THE APPLICATION OF CONSTRAINTS TO THE APPLICATION OF WIND ENERGYWIND ENERGY

• Wind vary in speed, hence incident energy flux, during the day from season to season, and not necessarily in concert with demand for electricity.

• This non-dispatchable nature limits the portion of wind power in a utility’s generator mix, with provision for spinning and standby reserve and grid stability being important concerns.

• Other than the fortuitous proximity of pumped storage hydro installation, there is no sufficiently inexpensive way, at present, to store energy for future use.

• The best wind fields may not be in reasonable proximity to large population centers, which necessitates the construction of expensive high-voltage transmission systems and results in large line losses of the input energy

WIND POWERWIND POWER

Power per unit area transported by fluid system is proportional to the cube of the fluid velocity.

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SPECTRUM AVERAGE POWERSPECTRUM AVERAGE POWER

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WEIBULL STATISTICS CONT.WEIBULL STATISTICS CONT.• Generally, measured wind speed is fitted to weibull statistics. The two

parameter weibull cumulative frequency distribution is given by;

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WEIBULL STATISTICS CONT.WEIBULL STATISTICS CONT.

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WEIBULL STATISTICS CONT.WEIBULL STATISTICS CONT.

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Weibull wind velocity frequency Weibull wind velocity frequency function for scale parameter c=1function for scale parameter c=1

Variation of wind speed with elevationVariation of wind speed with elevation• For an idealized smooth plane surface, the average wind speed

increases with height approximately as the 1/7th power:

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• Thus, wind turbine with a hub height of 50 m will experience about 7.6% rise in wind speed compared to one with a hub-height of 30 m and an increase in wind power of 24.5%

Factors Affecting Output of Wind turbineFactors Affecting Output of Wind turbine

• Topography and vegetation alter the wind field. Crest of treeless hills are advantageous; however, the flow above hills does not follow the 1/7th power law

• In general, there is less fluctuation in air flow at greater heights

• Adjacent wind turbines interfere to reduce the energy flow field.

• Air Density– The available power of fluid flow is directly

proportional to the density.– At 15oC and 1 atmosphere the value of ρ = 1.226

kg/m3 ; the value of the ρ at different temperature and pressure is estimated using the ideal gas relation

– The density can also be estimated from ρ(1-0.1Hs) where Hs the height above sea level

– The value of ρ is also decrease by water vapor by a factor of 1-0.005T(inoC)

Factors Affecting Output of Wind turbineFactors Affecting Output of Wind turbine

Maximum wind Turbine EfficiencyMaximum wind Turbine Efficiency

• Betz Ratio– From the Betz relation the maximum turbine efficiency

is ηmax=0.593

– Well-design modern turbine can achieve a maximum efficiency of 50%

– Net value of 40% after gearbox and electrical losses consideration

– In addition to all the factor mentioned above the number turbine blades enhance the performance of the turbine. More blades mean higher torque and functionality at lower speed.

Wind Machinery and Generating SystemsWind Machinery and Generating Systems

• Figure 15.6

Wind Turbine RatingWind Turbine Rating

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