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Decoupled simulations of offshore wind turbines with reduced rotor loads and aerodynamic damping (2017)

Schafhirt, Sebastian ; Muskulus, Michael

Copernicus

In: Wind Energy Science Discussions. 2017; 1-25. Published 2017 Jul 27. doi: 10.5194/wes-2017-29. [early online release]

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Publication Date: 2017-07-27

Description: Decoupled load simulations are a computationally efficient method to perform a dynamic analysis of an offshore wind turbine. Modelling the dynamic interactions between rotor and support structure, especially the damping caused by the rotating rotor, is of importance, since it influences the structural response significantly and has a major impact on estimating fatigue lifetime. Linear damping is usually used for this purpose, but experimentally and analytically derived formulas to calculate an aerodynamic damping ratio often show discrepancies to measurement and simulation data. In this study decoupled simulation methods with reduced and full rotor loads are compared to an integrated simulation. The accuracy of decoupled methods is evaluated and an optimization is performed to obtain aerodynamic damping ratios for different wind speeds that provide the best results with respect to variance and equivalent fatigue loads at distinct output locations. Results show that aerodynamic damping is not linear, but that it is possible to match desired output using decoupled models. Moreover, damping ratios obtained from the empirical study suggest that aerodynamic damping increases for higher wind speeds.

Electronic ISSN: 2366-7621

Topics: Energy, Environment Protection, Nuclear Power Engineering

Published by Copernicus on behalf of European Academy of Wind Energy.

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Decoupled simulations of offshore wind turbines with reduced rotor loads and aerodynamic damping (2018)

Schafhirt, Sebastian ; Muskulus, Michael

Copernicus

In: Wind Energy Science. 2018; 3(1): 25-41. Published 2018 Feb 21. doi: 10.5194/wes-3-25-2018.

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Publication Date: 2018-02-21

Description: Decoupled load simulations are a computationally efficient method to perform a dynamic analysis of an offshore wind turbine. Modelling the dynamic interactions between rotor and support structure, especially the damping caused by the rotating rotor, is of importance, since it influences the structural response significantly and has a major impact on estimating fatigue lifetime. Linear damping is usually used for this purpose, but experimentally and analytically derived formulas to calculate an aerodynamic damping ratio often show discrepancies to measurement and simulation data. In this study decoupled simulation methods with reduced and full rotor loads are compared to an integrated simulation. The accuracy of decoupled methods is evaluated and an optimization is performed to obtain aerodynamic damping ratios for different wind speeds that provide the best results with respect to variance and equivalent fatigue loads at distinct output locations. Results show that aerodynamic damping is not linear, but it is possible to match desired output using decoupled models. Moreover, damping ratios obtained from the empirical study suggest that aerodynamic damping increases for higher wind speeds.

Print ISSN: 2366-7443

Electronic ISSN: 2366-7451

Topics: Energy, Environment Protection, Nuclear Power Engineering

Published by Copernicus on behalf of European Academy of Wind Energy.

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