Frequency domain modeling of free yaw response of wind turbines to wind turbulence
Abstract
This paper reports on the frequency domain method that has been developed in order to study the yaw dynamics and its effect on energy capture under various turbulence regimes for free yaw wind turbines. It is assumed that t the primary focusing of the dynamic yaw originates from the variations from wind turbulence in the average wind direction and the horizontal gradient of the wind speed across the rotor. The horizontal components of the turbulence velocity are modeled as random processes with spectral characteristics calibrated from measurements. The corresponding statistics of the wind direction and the gradient are derived and used as input for an equivalent linear model of the system dynamics. The parameters in the simplified system model are identified from the results of a numerical test of a comprehensive yaw response and energy capture simulation model, developed at U.S. Windpower. The yaw response of the USW Model 56-100 machine to turbulence has been analyzed for a number of wind conditions and compared to test results with satisfactory agreement. The analysis shows that the effect on the yaw error from the horizontal wind gradient is twice the effect from wind direction changes.
- Authors:
-
- U.S. Windpower, Inc., Livermore, CA (US)
- Publication Date:
- OSTI Identifier:
- 5861616
- Resource Type:
- Journal Article
- Journal Name:
- Journal of Solar Energy Engineering; (United States)
- Additional Journal Information:
- Journal Volume: 113:2; Journal ID: ISSN 0199-6231
- Country of Publication:
- United States
- Language:
- English
- Subject:
- 17 WIND ENERGY; WIND TURBINES; ROTATION; CAPTURE; ENERGY; MATHEMATICAL MODELS; MOTION; TURBULENCE; VELOCITY; WIND; EQUIPMENT; MACHINERY; TURBINES; TURBOMACHINERY; 170602* - Wind Energy Engineering- Turbine Design & Operation
Citation Formats
Madsen, P H, and McNerney, G M. Frequency domain modeling of free yaw response of wind turbines to wind turbulence. United States: N. p., 1991.
Web. doi:10.1115/1.2929953.
Madsen, P H, & McNerney, G M. Frequency domain modeling of free yaw response of wind turbines to wind turbulence. United States. https://doi.org/10.1115/1.2929953
Madsen, P H, and McNerney, G M. 1991.
"Frequency domain modeling of free yaw response of wind turbines to wind turbulence". United States. https://doi.org/10.1115/1.2929953.
@article{osti_5861616,
title = {Frequency domain modeling of free yaw response of wind turbines to wind turbulence},
author = {Madsen, P H and McNerney, G M},
abstractNote = {This paper reports on the frequency domain method that has been developed in order to study the yaw dynamics and its effect on energy capture under various turbulence regimes for free yaw wind turbines. It is assumed that t the primary focusing of the dynamic yaw originates from the variations from wind turbulence in the average wind direction and the horizontal gradient of the wind speed across the rotor. The horizontal components of the turbulence velocity are modeled as random processes with spectral characteristics calibrated from measurements. The corresponding statistics of the wind direction and the gradient are derived and used as input for an equivalent linear model of the system dynamics. The parameters in the simplified system model are identified from the results of a numerical test of a comprehensive yaw response and energy capture simulation model, developed at U.S. Windpower. The yaw response of the USW Model 56-100 machine to turbulence has been analyzed for a number of wind conditions and compared to test results with satisfactory agreement. The analysis shows that the effect on the yaw error from the horizontal wind gradient is twice the effect from wind direction changes.},
doi = {10.1115/1.2929953},
url = {https://www.osti.gov/biblio/5861616},
journal = {Journal of Solar Energy Engineering; (United States)},
issn = {0199-6231},
number = ,
volume = 113:2,
place = {United States},
year = {Wed May 01 00:00:00 EDT 1991},
month = {Wed May 01 00:00:00 EDT 1991}
}