Nonlinear inviscid aerodynamics of a wind turbine rotor in surge, sway, and yaw motions using a  free-wake panel method

Ribeiro, Andre F.; Casalino, Damiano; Ferreira, Carlos

doi:10.5194/wes-8-661-2023

Cited by 10 publications

(6 citation statements)

References 28 publications

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“…b vel > 15%) of the surging NREL 5 MW rotor around the design operation condition, Wen et al found that the rise of the power amplitude becomes slightly nonlinear. A similar observation was found by Ribeiro et al (2023) for the thrust force, where a FVW panel method was used to simulate the UNAFLOW rotor. In addition, a rising phase shift between the surge velocity and rotor thrust was reported independent from b vel , which was also observed by Mancini et al (2020) earlier.…”

Section: Numerical Investigationssupporting

confidence: 80%

“…A hint on such behaviour can also be found in Ribeiro et al (2023). Panel method simulations showed a lower-than-expected thrust amplitude at a rotor reduced frequency slightly below 5.…”

Section: Unaflow Rotormentioning

confidence: 63%

“…However, these assumptions are only valid for moderate b vel and the absolute limits are dependent on 200 the special case. In the FVW and RANS simulations of Mancini et al (2020) and Ribeiro et al (2023), a linear rise of the thrust amplitude ∆T , which is normalised by the motion amplitude A, with the motion frequency is present. This can be expressed as:…”

Section: Numerical Investigationsmentioning

confidence: 99%

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Wind turbine rotors in surge motion: New insights into unsteady aerodynamics of FOWT from experiments and simulations

Schulz,

Netzband,

Özinan

et al. 2023

Preprint

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Abstract. An accurate prediction of the unsteady loads acting on floating offshore wind turbines (FOWT) under consideration of wave excitation is crucial for a resource-efficient turbine design. Despite a considerable number of simulation studies in this area, it is still not fully understood, which unsteady aerodynamic phenomena have a notable influence on the loads acting on a wind turbine rotor in motion. In the present study, investigations are carried out to evaluate of the most relevant unsteady aerodynamic phenomena for a wind turbine rotor in surge motion. As a result, inflow conditions are determined for which a significant influence of these phenomena on the rotor loads can be expected. The experimental and numerical investigations are conducted on a two-bladed wind turbine rotor subjected to a tower top surge motion. A specialised wind tunnel test rig has been developed to measure the aerodynamic torque response of the rotor subjected to surge motions with moderate frequencies. The torque measurements are compared to two free vortex wake methods, namely a panel and a lifting-line method. Unsteady contributions that cannot be captured using quasi-steady modelling have not been detected in either the measurements or the simulations in the covered region of motion frequencies. The surge motion frequencies were limited to a moderate range due to vibrations occurring in the experiments. Therefore, a numerical study with an extended the range of motion frequencies using the panel and the lifting-line method was performed. The results reveal significant unsteady contributions of the surge motions to the torque and thrust response that cannot be modelled in a quasi-steady way. Furthermore, the results show the presence of the returning wake effect, which is known from helicopter aerodynamics. Additional simulations of the UNAFLOW scale model and the IEA 15 MW rotor demonstrate that the occurrence of the returning wake effect is independent from the turbine, but determined by the ratio of rotor speed and surge motion. In case of the IEA 15 MW, a notable impact of the returning wake effect was found at surge motion frequencies in the range of typical wave periods. Finally, a comparison with OpenFAST simulations reveals notable differences in the modelling of the unsteady aerodynamic behaviour in comparison to a FVW method.

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Section: Numerical Investigationssupporting

confidence: 80%

“…A hint on such behaviour can also be found in Ribeiro et al (2023). Panel method simulations showed a lower-than-expected thrust amplitude at a rotor reduced frequency slightly below 5.…”

Section: Unaflow Rotormentioning

confidence: 63%

Section: Numerical Investigationsmentioning

confidence: 99%

See 1 more Smart Citation

Wind turbine rotors in surge motion: New insights into unsteady aerodynamics of FOWT from experiments and simulations

Schulz,

Netzband,

Özinan

et al. 2023

Preprint

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show abstract

“…When assuming an inflow without shear and an axisymmetric wake, yaw can be considered equivalent to pitch; sway can be considered equivalent to heave, following a coordinate transformation. At small amplitude, the roll motion of FOWT can be approximated by the sway motion since the centre of gravity is far below the rotor hub centre (Ribeiro, Casalino & Ferreira 2023a). Here, we assume that the FOWT is forced to oscillate harmonically for each motion.…”

Section: Set-up Of Les Casesmentioning

confidence: 99%

Resolvent-based motion-to-wake modelling of wind turbine wakes under dynamic rotor motion

Li,

Yang

2024

J. Fluid Mech.

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We propose a linearized deterministic model for predicting coherent structures in the wake of a floating offshore wind turbine subject to platform motions. The model's motion-to-wake predictive capability is achieved through two building blocks: a motion-to-forcing (M2F) part and a forcing-to-wake (F2W) part. The M2F model provides a unified framework to parameterize the effects of arbitrary floating wind turbine motions as unsteady loads of a fixed actuator disk, requiring only the radial distribution of the aerodynamics force coefficient on the blade as input. The F2W model is derived based on a bi-global resolvent model obtained from the linearized Navier–Stokes equations, using the time-averaged wake of a fixed wind turbine as input. In addition to its capability of predicting sensitive frequency ranges, the model excels linear stability analysis by providing spatial modes of the wake response in a motion-specific and phase-resolved manner. The model successfully predicts the wake pulsing mode induced by surge, as well as the similarity and difference of the wake meandering modes caused by sway and yaw. Large-eddy simulations under different inflow turbulence intensities (TIs) and length scales are further conducted to analyse the wake meandering triggered by the simultaneous excitation of free-stream turbulence and sway motion. The results show distinct frequency signatures for the wake dynamics induced by ambient turbulence and sway motion. The inflow TI is found to have a stabilizing effect on the wake, reducing the motion-induced wake responses. Such a stabilizing effect is captured satisfactorily with the proposed model, provided that the effective viscosity is calibrated properly using the data from the fixed turbine wake under the corresponding turbulent inflow.

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“…Simulations that do not include flow separation, but include geometric nonlinear effects have been shown to capture the amplitude of the LCO associated with the first flutter mode of the Pazy wing (Riso and Cesnik, 2022), but not the subcritical effects. In the case of the present simulations, nonlinear geometry effects come from the structural model, while nonlinear inviscid aerodynamic effects (Ribeiro et al, 2023), come from the panel code. Flow separation is missing, meaning capturing the subcritical LCO is likely not possible, but achieving LCO for the first flutter mode should be.…”

Section: Limit Cycle Oscillationsmentioning

confidence: 99%

Free Wake Panel Method Simulations of a Highly Flexible Wing in Flutter and Gusts

2022

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Nonlinear inviscid aerodynamics of a wind turbine rotor in surge, sway, and yaw motions using a free-wake panel method

Cited by 10 publications

References 28 publications

Wind turbine rotors in surge motion: New insights into unsteady aerodynamics of FOWT from experiments and simulations

Wind turbine rotors in surge motion: New insights into unsteady aerodynamics of FOWT from experiments and simulations

Resolvent-based motion-to-wake modelling of wind turbine wakes under dynamic rotor motion

Free Wake Panel Method Simulations of a Highly Flexible Wing in Flutter and Gusts

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