In order to continue cost-optimization of modern large wind turbines, it is important to continuously increase the knowledge of wind field parameters relevant to design loads. This paper presents a general statistical model that offers site-specific prediction of the probability density function (PDF) of turbulence driven short-term extreme wind shear events, conditioned on the mean wind speed, for an arbitrary recurrence period. The model is based on an asymptotic expansion, and only a few and easily accessible parameters are needed as input. The model of the extreme PDF is supplemented by a model that, on a statistically consistent basis, describes the most likely spatial shape of an extreme wind shear event. Predictions from the model have been compared with results from an extreme value data analysis, based on a large number of full-scale measurements recorded with a high sampling rate. The measurements have been extracted from ”Database on Wind Characteristics” (http:∕∕www.winddata.com∕), and they refer to a site characterized by a flat homogeneous terrain. The comparison has been conducted for three different mean wind speeds in the range of 15-19ms, and model predictions and experimental results are consistent, given the inevitable uncertainties associated with the model as well as with the extreme value data analysis.

1.
IEC 61400-1 Wind Turbine Generator Systems: part 1
, Safety Requirements.
2.
Nielsen
,
M.
,
Larsen
,
G. C.
,
Mann
,
J.
,
Ott
,
S.
,
Hansen
,
K. S.
, and
Pedersen
,
B. J.
, 2003,
Wind Simulation for Extreme and Fatigue Loads
. Risø-R-1437(EN).
3.
Panofsky
,
H. A.
and
Dutton
,
J. A.
, 1984,
Atmospheric Turbulence - Models and Methods for Engineering Applications
,
Wiley
, New York.
4.
Cramér
,
H.
, 1991,
Mathematical methods of Statistics
,
Princeton University Press
, Princeton, New Jersey.
5.
Papoulis
,
A.
, 1965,
Probability, Random Variables and Stochastic Processes
,
McGraw-Hill
, New York.
6.
Rice
,
S. O.
, 1958,
Mathematical analysis of random noise
, Bell Syst. Techn. J.,
23
(’44); Reprinted in
N.
Wax
(ed.), Selected papers on noise and stochastic processes,
Dover
, New York.
7.
Cartwright
,
D. E.
and
Longuet-Higgins
,
M. S.
, 1956, “
The statistical distribution of the maxima of a random function
,”
Proc. R. Soc. London, Ser. A
1364-5021
237
, pp.
212
232
.
8.
Davenport
,
A. G.
, 1964,
Note on the Distribution of the Largest Value of a random Function with Application to Gust Loading
,
Proc. Inst. of Civ. Eng. (UK)
0307-8353,
28
, pp.
187
196
.
9.
Mann
,
J.
, 1994, “
The spatial structure of neutral atmospheric surface-layer turbulence
,”
J. Fluid Mech.
0022-1120,
273
, pp.
141
168
.
10.
Larsen
,
G. C.
and
Hansen
,
K. S.
, 2003,
Spatial Coherence of the Longitudinal Turbulence Component (2003)
,
European Wind Energy Conference
,
Madrid
, June 16–19.
11.
Database on Wind Characteristics
”. ”http:∕∕www.winddata.com∕http:∕∕www.winddata.com∕
12.
Gumbel
,
E. J.
, 1966,
Statistics of Extremes
,
Columbia University Express
, New York.
13.
Snedecor
,
G. W.
and
Cochran
,
W. G.
, 1989,
Statistical Methods
, 8th ed.,
Iowa State University
, AMES.
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