Land-based wind turbines with flexible rail-transportable blades – Part 1: Conceptual design and aeroservoelastic performance
-
Published:2021-09-23
Issue:5
Volume:6
Page:1277-1290
-
ISSN:2366-7451
-
Container-title:Wind Energy Science
-
language:en
-
Short-container-title:Wind Energ. Sci.
Author:
Bortolotti PietroORCID, Johnson Nick, Abbas Nikhar J., Anderson Evan, Camarena ErnestoORCID, Paquette Joshua
Abstract
Abstract. This work investigates the conceptual design and the aeroservoelastic performance of land-based wind turbines whose blades
can be transported on rail via controlled bending. The turbines have a nameplate power of 5 MW and a rotor diameter of 206 m,
and they aim to represent the next generation of land-based machines. Three upwind designs and two downwind designs are
presented, combining different design goals together with conventional glass and pultruded carbon fiber laminates in the spar
caps. One of the five blade designs is segmented and serves as a benchmark to the state of the art in industry. The results
show that controlled flexing requires a reduction in the flapwise stiffness of the blades, but it represents a promising pathway for
increasing the size of land-based wind turbine rotors. Given the required stiffness, the rotor can be designed either downwind with
standard rotor preconing and nacelle uptilt angles or upwind with higher-than-usual angles. A downwind-specific controller is
also presented, featuring a cut-out wind speed reduced to 19 m s−1 and a pitch-to-stall shutdown strategy to minimize
blade tip deflections toward the tower. The flexible upwind and downwind rotor designs equipped with pultruded carbon fiber
spar caps are found to generate the lowest levelized cost of energy, 2.9 % and 1.3 %, respectively, less than the segmented design.
The paper concludes with several recommendations for future work in the area of large flexible wind turbine rotors.
Publisher
Copernicus GmbH
Subject
Energy Engineering and Power Technology,Renewable Energy, Sustainability and the Environment
Reference38 articles.
1. Abbas, N., Zalkind, D., Pao, L., and Wright, A.: A Reference Open-Source Controller for Fixed and Floating Offshore Wind Turbines, Wind Energ. Sci. Discuss. [preprint], https://doi.org/10.5194/wes-2021-19, in review, 2021. a 2. Abbas, N. J., Wright, A., and Pao, L.: An Update to the National Renewable
Energy Laboratory Baseline Wind Turbine Controller, J. Phys.
Conf. Ser. 1452, 012002, https://doi.org/10.1088/1742-6596/1452/1/012002,
2020. a 3. Bertagnolio, F., Madsen, H. A., and Fischer, A.: Analysis of low-frequency
noise from wind turbines using a temporal noise code, Proceedings of the 23rd
International Congress on Acoustics, Aachen, Germany, 9 Sep 2019–13 September 2019, 4414–4421, 2019. a 4. Bir, G. S.: User’s Guide to PreComp (Pre-Processor for Computing Composite
Blade Properties), Tech. rep., National Renewable Energy Laboratory, https://doi.org/10.2172/876556, 2006. a, b 5. Bolinger, M., Lantz, E., Wiser, R., Hoen, B., Rand, J., and Hammond, R.:
Opportunities for and challenges to further reductions in the “specific
power” rating of wind turbines installed in the United States, Wind
Engineering, 45, 351–368, https://doi.org/10.1177/0309524X19901012, 2020. a
Cited by
17 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献
|
|