Rotor‐tower interactions of DTU 10MW reference wind turbine with a non‐linear harmonic method

Horcas, Sergio González; Debrabandere, François; Tartinville, B.; Hirsch, Charles; Coussement, Grégory

doi:10.1002/we.2027

Cited by 15 publications

(10 citation statements)

References 37 publications

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“…In previous analysis of Geometry 2 (Zahle et al, 2014), a region of three-dimensional flow radially pumped from the root to r 0 /R = 0.36 was observed. Moreover, a separation bubble is also present from the root to almost r 0 /R = 0.40 (Horcas et al, 2017). These factors increase the flow three-dimensionality at the inner radial part of the blade, making it more difficult for the quasithree-dimensional BL model to capture the flow features correctly.…”

Section: Spanwise Edge Velocitymentioning

confidence: 99%

“…DNSs aim at exactly resolving the flow field, and they can thus provide detailed information about velocity fluctuations within the boundary layer, based on which results about transition and turbulence characteristics can be derived. At this moment, only a few studies of the transition process on wind-turbine blades using highresolution simulations are available (Jing et al, 2020). The DNS approach for transition prediction provides accurate results, but it implies a high computational cost.…”

Section: Introductionmentioning

confidence: 99%

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A simplified model for transition prediction applicable to wind-turbine rotors

et al. 2021

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Abstract. This work aims to develop a simple framework for transition prediction over wind-turbine blades, including effects of the blade rotation and spanwise velocity without requiring fully three-dimensional simulations. The framework is based on a set of boundary-layer equations (BLEs) and parabolized stability equations (PSEs), including rotation effects. An important element of the developed BL method is the modeling of the spanwise velocity at the boundary-layer edge. The two analyzed wind-turbine geometries correspond to a constant airfoil and the DTU 10-MW Reference Wind Turbine blades. The BL model allows an accurate prediction of the chordwise velocity profiles. Further, for regions not too close to the stagnation point and root of the blade, profiles of the spanwise velocity agree with those from Reynolds-averaged Navier–Stokes (RANS) simulations. The model also allows predicting inflectional velocity profiles for lower radial positions, which may allow crossflow transition. Transition prediction is performed at several radial positions through an “envelope-of-envelopes” methodology. The results are compared with the eN method of Drela and Giles, implemented in the EllipSys3D RANS code. The RANS transition locations closely agree with those from the PSE analysis of a 2D mean flow without rotation. These results also agree with those from the developed model for cases with low 3D and rotation effects, such as at higher radial positions and geometries with strong adverse pressure gradients where 2D Tollmien–Schlichting (TS) waves are dominant. However, the RANS and PSE 2D models predict a later transition in the regions where 3D and rotation effects are non-negligible. The developed method, which accounts for these effects, predicted earlier transition onsets in this region (e.g., 19 % earlier than RANS at 26 % of the radius for the constant-airfoil geometry) and shows that transition may occur via highly oblique modes. These modes differ from 2D TS waves and appear in locations with inflectional spanwise velocity. However, except close to the root of the blade, crossflow transition is unlikely since the crossflow velocity is too low. At higher radial positions, where 3D and rotation effects are weaker and the adverse pressure gradient is more significant, modes with small wave angles (close to 2D) are found to be dominant. Finally, it is observed that an increase in the rotation speed modifies the spanwise velocity and increases the Coriolis and centrifugal forces, shifting the transition location closer to the leading edge. This work highlights the importance of considering the blade rotation and the three-dimensional flow generated by that in transition prediction, especially in the inner part of the blade.

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Section: Spanwise Edge Velocitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A simplified model for transition prediction applicable to wind-turbine rotors

et al. 2021

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“…Rahmati et al [21][22] also developed a nonlinear frequency domain method for the multi-row aeromechanical analysis of turbomachines and showed that a fully coupled multi-row configuration should be considered rather than a simplified isolated one to produce better accuracy in predicting flutter behaviour of the blades. Despite the fact that the frequency domain methods are typically used in turbomachinery analysis, there are only a few recently conducted studies in the field of wind turbine research which employ such methods [23][24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Aeromechanical Analysis of a Complete Wind Turbine Using Nonlinear Frequency Domain Solution Method

Naung

Rahmati

Farokhi

2020

Volume 12: Wind Energy

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The high-fidelity computational fluid dynamics (CFD) simulations of a complete wind turbine model usually require significant computational resources. It will require much more resources if the fluid-structure interactions between the blade and the flow are considered, and it has been the major challenge in the industry. The aeromechanical analysis of a complete wind turbine model using a high-fidelity CFD method is discussed in this paper. The distinctiveness of this paper is the application of the nonlinear frequency domain solution method to analyse the forced response and flutter instability of the blade as well as to investigate the unsteady flow field across the wind turbine rotor and the tower. This method also enables the aeromechanical simulations of wind turbines for various inter blade phase angles in a combination with a phase shift solution method. Extensive validations of the nonlinear frequency domain solution method against the conventional time domain solution method reveal that the proposed frequency domain solution method can reduce the computational cost by one to two orders of magnitude.

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“…Although the aerodynamic knowledge achieved in the past decades has contributed greatly to increase the performance and efficiency of wind turbine rotors, it is evident that increasing the power efficiency is still a major task for designers of modern wind turbines. The success of the aerodynamic progress is best illustrated by the change in rotor design from the relatively over-dimensioned kW size turbines in the 1980's [1] to the slender MW size turbines developed in recent years [2], [3], [4]. An evaluation of the wind power planning in Denmark showed that there is clearly a tendency to exclude smaller turbines in future design developments [5].…”

Section: Introductionmentioning

confidence: 99%

Verification of a novel innovative blade root design for wind turbines using a hybrid numerical method

Zhu

Shen

Sørensen

et al. 2017

Energy

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Rotor‐tower interactions of DTU 10MW reference wind turbine with a non‐linear harmonic method

Cited by 15 publications

References 37 publications

A simplified model for transition prediction applicable to wind-turbine rotors

A simplified model for transition prediction applicable to wind-turbine rotors

Aeromechanical Analysis of a Complete Wind Turbine Using Nonlinear Frequency Domain Solution Method

Verification of a novel innovative blade root design for wind turbines using a hybrid numerical method

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