Publisher DOI: 10.1088/1742-6596/2018/1/012035
Title: A procedure to redesign a comparable blade structure of a two-bladed turbine based on a three-bladed reference
Language: 
Authors: Schütt, Marcel 
Anstock, Fabian 
Schorbach, Vera  
Issue Date: 21-Sep-2021
Publisher: IOP Publishing
Journal or Series Name: Journal of physics / Conference Series 
Volume: 2018
Issue: 1
Project: Zweiblättrige Offshore-Windenergieanlagen 
Conference: Deep Sea Offshore Wind R&D Conference 2021 
Abstract: 
Two-bladed turbines might be an alternative for future offshore wind turbine installations due to the promising opportunity to be more economical compared to threebladed turbines. Looking at the rotor blades, two-bladed turbines with a comparable design either rotate 22.5 % faster or have up to 50 % increased chord lengths. The latter result in a significantly higher second moment of area, which enables rotor mass savings and thus fewer costs while withstanding ∼50 % higher flapwise loads per blade. Unfortunately, such a design could also cause buckling issues. Increasing the design tip speed reduces stability issues but lowers the rotor mass savings. Consequently, the challenging task is to find an optimal compromise between preventing buckling and saving rotor mass, and thus to ensure a fair comparison of two- and three-bladed turbines' blades. To overcome this challenge, a procedure for redesigning a comparable blade structure is introduced. The procedure is exemplarily demonstrated for large 20 MW offshore wind turbines. Compared to the three-bladed reference, the overall rotor mass reduction of the two-bladed turbine is 13.5 % for the most beneficial compromise detected. Simultaneously, the blades showing good accordance with the reference concerning static stresses and buckling characteristics under their respective loads.
URI: http://hdl.handle.net/20.500.12738/11861
ISSN: 1742-6596
Institute: Department Maschinenbau und Produktion 
Fakultät Technik und Informatik 
Competence Center Erneuerbare Energien und Energieeffizienz 
Type: Chapter/Article (Proceedings)
Funded by: Bundesministerium für Bildung und Forschung 
Siemens Gamesa Renewable Energy 
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