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Southern Taiwan University
Department of Electrical engineering
A statistical analysis of wind power density
based on the Weibull and Rayleigh models at
he southern region of Turkey
Author : Ali Naci Celik
( Received 21 April 2003;
accepted 27 July 2003)
Present: Bui Trong Diem
Information part
 Abstract
 Distributional parameters of the wind data used
 Wind speed probability distributions
 Power density distributions and mean power density
 Conclusions
ABSTRACT
- Studies show that Iskenderun (360N; 360E) located on the
Mediterranean coast of Turkey.
- The wind energy potential of the region is statistically
analyzed based on 1-year measured hourly time series wind
speed data.
- Two probability density functions are fitted to the measured
probability distributions on a monthly basis.
- The wind energy potential of the location is studied based on
the Weibull and the Rayleigh models.
Introduction
-The electric generating capacity of Turkey as of 1999 was 26226
Gwe
- As of 2000, electricity generation in turkey is mainly
hydroelectric (40%) and conventional thermal power plants
(60%, coal, natural, gas…)
- The renew energy of Turkey will reach approximately 18500Mwe
by the year 2010.
- The total installed wind power generation capacity of Turkey is
19.1Mwe in three wind power stations.
Distributional parameters of the
wind data used
- the monthly mean wind speed values and standard deviation
calculator for the available times data using Eqs.1 and 2
d
- Alternatively, the mean wind speed can be determined from
Distributional parameters of the
wind data used
Wind speed probability
distributions
- The wind speed data in time-series format is usually
arranged in the frequency distribution format since it is
more convenient for statistical analysis.
Wind speed probability
distributions
- Probability density function of the Weibull distribution is
given by.
Wind speed probability
distributions
- The corresponding cumulative probability function of
the Weibull distribution is,
Wind speed probability
distributions
- v, the following is obtained for the mean wind speed,
Wind speed probability
distributions
Note that the gamma function has the properties of
- The probability density and the cumulative distribution
functions of the Rayleigh model are given by,
Wind speed probability
distributions
- The correlation coefficient values are used as the measure
of the goodness of the fit of the probability density
distributions obtained from the Weibull and Rayleigh
models.
Power density distributions and
mean power density
- If the power of the wind per unit area is given by
- The referent mean wind power density determine by
- The most general equation to calculate the mean wind
power density is,
- The mean wind power density can be calculated directly
from the following equation if the mean value of v3 s,(
v3)m, is already known,
Power density distributions and
mean power density
- From Eq. (3), the mean value of v3s can be determined as
- Integrating Eq. (13), the following is obtained for the
Weibull function,
- Introducing Eqs. (6) and (14) into Eq. (12), the mean power
density for the Weibull function becomes:
Power density distributions and
mean power density
- For k =2, the following is obtained from Eq. (6)
- By extracting c from Eq. (16) and setting k equal to
2, the power density for the Rayleigh model is
found to be,
- The minimum power densities occur in February and
November, with 7.54 and 9.77 W/m2, respectively. It is
interesting to note that the highest power density values
occur in the summer months of June, July and August, with
the maximum value of 63.69 W/m2 in June.
Power density distributions and
mean power density
- The errors in calculating the power densities using the
models in comparison to those using the measured
probability density distributions are presented in Fig.
6, using the following formula:
Power density distributions and
mean power density
- The highest error value occurs in July with 11.4% for the
Weibull model. The power density is estimated by the
Weibull model with a very small error value of 0.1% in
April. The yearly average error value in calculating the
power density using the Weibull function is 4.9%,
using the following equation
Power density distributions and
mean power density
Conclusions
- Even though Iskenderun is shown as one of the most
potential wind energy generation regions in Turkey.
This is shown by the low monthly and yearly mean
wind speed and power density values.
- As the yearly average wind power density value of 30.20
W/m2 indicates,
- However, the diurnal variations of the seasonal wind
speed and the wind powerdensity have to be further
studied, since the diurnal variation may show a
significant difference.
Conclusions
- The Weibull model is better in fitting the measured
monthly probability density distributions than the
Rayleigh model. This is shown from the monthly
correlation efficiency values of the fits.
- The Weibull model provided better power density
estimations in all 12 months than the Rayleigh model.
Southern Taiwan University
Department of Electrical engineering
Thank you very much