Workshop Session 1: Resources, technology, performance

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IBC 3rd Annual Wind Energy Conference Adelaide February 2004 Workshop Session 1: Resources, technology, performance Iain MacGill and Hugh Outhred School of Electrical Engineering and Telecommunications The University of New South Wales Tel: 02 9385 4035; Fax: 02 9385 5993; Email: i.macgill@unsw.edu.au; h.outhred@unsw.edu.au www.ergo.ee.unsw.edu.au

Outline The nature of wind resources Technical characteristics of wind turbines & wind farms Predicting the output of wind farms and groups of wind farms 2

The nature of wind resources Drivers of wind energy at the earth s surface: Uneven solar heating of the earth The earth s rotation Weather phenomena Surface effects: Topography Surface roughness Land/sea interface www.windpower.org 3

Global temperature variation 4

The Coriolis effect 5

Example - Prevailing US winds 6

Surface winds Our interest is in winds near the surface Thermally induced winds: Sea breezes & land breezes Valley winds Surface roughness effects: Smooth surfaces give low turbulence & higher wind speeds near ground level Height effects: Wind speed increases with height above ground (shear) Tunnel, hill effects 7

The energy in the wind 8

The power in the wind Doubling the wind speed increases the power eightfold but doubling the turbine area only doubles the power. 9

Australian wind resource (Simple estimates of background wind AGO) 10

Wind shear 11

Tunnel + hill speedup effects 12

Surface effects on wind speed & turbulence (www.seda.nsw.gov.au) 13

Local wind resource Monitoring normally required 14

Spectral analysis of Danish long-term wind data (17 years of data) Spectral gap between weather and local turbulence phenomena (Sorensen, 2001, Fig 2.110, p194) 15

Measured Danish wind power characteristics (www.windpower.org) Diurnal, seasonal and annual variations in wind speed (diurnal effect stronger near coast & stronger in summer than winter) 16

A modern 1.3MW wind turbine (www.bonus.dk) Codrington wind farm (Vic): 14x1.3MW: 18.2MW Hub height: 50m Blade diameter: 60 m Pitch & stall regulation Gearbox ratio: 1:79 Generator: Two speed induction generator 17

Size of wind turbines used by Western Power (www.wpc.com.au) 18

Wind turbine design option: gearbox & induction generator (www.hydro.com.au) Variable speed induction generator (eg Codrington) Induction generator stator Supply frequency AC Switch IG with wound rotor Slip frequency inverter pf correction capacitor 19

Wind turbine design option: direct-drive variable speed alternator (www.enercon.de) Variable speed alternator & inverter (eg Albany) Alternator Rectifier DC Inverter Switch variable frequency AC Load bank supply frequency AC 20

Generators (cont) Variable speed (www.windpower.org) Variable rotor speed can store gusts Can improve grid quality (eg reactive power) higher efficiency from optimal Tip speed? 21

Wind turbine type comparison (Slootweg & Kling, TU Delft, 2003, http://local.iee.org/ireland/senior/wind%20event.htm) 22

Power curve for a 1.3 MW wind turbine (typically 30 minute average data) Controllable conversion efficiency Based on data from Bonus Cut-in wind speed Cut-out wind speed 23

Wind turbine dynamic behaviour (Slootweg & Kling, TU Delft, 2003, http://local.iee.org/ireland/senior/wind%20event.htm) Wind speed Output power Rotor speed Output voltage Blade angle 24

Technical characteristics of wind farms (1) Wind turbine electrical power output: Depends on wind power, swept area, blade pitch, rotational speed, supply voltage & frequency Fluctuates with wind speed & direction Wind farm power is aggregated & smoothed compared to turbine power: Depending on extent of correlation Short-term power forecast valuable for power system operation (average & extreme) 25

One-second power fluctuations at Esperance 2MW wind farm 9 x 225 kw turbines Solid line is proportional to N -0.5 Implies 1-second fluctuations are uncorrelated (Rosser, 1995) 26

Correlation across a wind farm depends on layout & wind regime Turbulence power fluctuations are likely to be more strongly correlated in the wind farm on the left than in that on the right 27

Hampton Wind Farm, NSW (2x660 kw Vestas, connected to different 11 kv feeders) Turbulence probably fairly high at this site 11kV feeders may be subject to outages & voltage dips Induction generators may not ride through voltage dips well. 28

Output of 8 small wind farms over 30 days (Bryans L, 2003, http://local.iee.org/ireland/senior/wind%20event.htm) KW 40000 Windfarms Profile December 2000 Slievenahanaghan 35000 Lendrum's bridge 30000 Slieve Rushen Owenreagh 25000 Bessy Bell 20000 Elliott's Hill Rigged Hill 15000 Corkey 10000 5000 0 5 10 15 20 25 30 Days 29

Combined output of 2 wind farms 80 km apart (Gardner et al, 2003) 30

Cross-correlation function between the output powers of 2 wind farms 80 km apart (Gardner et al, 2003) 31

Cross-correlations between measured power outputs of German wind farms (Giebel (2000) Riso National Lab, Denmark) 32

Prediction of wind smoothing effects for Northern Europe (Giebel (2000) Riso National Lab, Denmark) Size comparison with South Australia 33

Cross-correlations between 34 years of 12-hourly data for all grid points (Giebel (2000) Riso National Lab, Denmark) 34

Probability density function for relative change in wind power in 12 hours (Giebel (2000) Riso National Lab, Denmark) 35

Incremental Wind Change Density SA projections (ESPIC South Australia Wind Power Study, 2003) 36

Predicted capacity factor for wind farms in Northern Europe (Giebel (2000) Riso National Lab, Denmark) 37

Wind energy duration curve for Northern Europe (normalised to average) (Giebel (2000) Riso National Lab, Denmark) 38

Wind energy duration curve SA projections (ESPIC South Australia Wind Power Study, 2003) 39

CSIRO Windscape TM model (www.clw.csiro.au/products/windenergy) Windscape derives location-specific wind forecasts from a Numerical Weather Prediction model (Steggle et al, CSIRO, March 2002) 40

(Steggle et al, CSIRO, March 2002) Windscape predictions of annual mean wind speed at 65 m, showing nested model results More rapid changes in colour probably imply higher local turbulence 41

42

Wind prospecting with Windscape (www.clw.csiro.au/products/windenergy) (Steggle et al, CSIRO, March 2002) Windscape has been used to study a number of regions Accuracy better for > 3 hourly behaviour Could give valuable information on correlation between regions 43

Wind prospecting SA (www.clw.csiro.au/products/windenergy) 44

Conclusions Wind resources: Stochastic but useful predictions can be made eg Numerical Weather Prediction models Wind turbine technology: Several design options each with strengths & weaknesses Wind farm performance: Turbulence and weather spectra fluctuations Diversity between sites adds to value 45

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