Investigation of the floating IEA Wind 15 MW RWT using vortex methods Part I: Flow regimes and wake recovery

Ramos‐García, Néstor; Kontos, Stavros; Pegalajar‐Jurado, Antonio; Horcas, Sergio González; Bredmose, Henrik

doi:10.1002/we.2682

Cited by 29 publications

(30 citation statements)

References 40 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…They investigated two concepts, a spar‐buoy and a barge platform, and found that the motion of the barge platform induced a faster wake recovery in both laminar and turbulent inflow conditions. Note that their spar‐buoy concept showed a quite similar wake recovery as their bottom‐fixed case, contrary to what was observed in study 19 . Manolas et al 20 used vortex‐based techniques to perform aero‐hydro‐servo‐elastic simulations of floating wind turbines in laminar inflow and compared them with unsteady blade element momentum (BEM) predictions, concluding that in terms of loads, the engineering method was conservative in comparison with vortex‐based modeling, similarly to what we have seen in the present study.…”

Section: Introductioncontrasting

confidence: 92%

Investigation of the floating IEA wind 15‐MW RWT using vortex methods Part II: Wake impact on downstream turbines under turbulent inflow

et al. 2022

Self Cite

View full text Add to dashboard Cite

The manuscript presents a novel numerical investigation on the impact of the wake of a floating IEA wind 15-MW reference wind turbine (RWT) on downstream machines using a state-of-the-art vortex solver coupled to a multi-body code. The coupling enables to account for the flexibility of the different turbine components as well as to include the effect of the controller and the dynamics of the floating support structure. First, the turbine is mounted on the WindCrete spar-buoy platform, and the wake impact on a second turbine positioned at different downstream positions is investigated and compared with the impact of the wake generated by a bottom-fixed machine. It is found that the faster breakdown of the vortex structures triggered by the motion of the floater in the upstream turbine increases the power

show abstract

Section: Introductioncontrasting

confidence: 92%

Investigation of the floating IEA wind 15‐MW RWT using vortex methods Part II: Wake impact on downstream turbines under turbulent inflow

et al. 2022

Self Cite

View full text Add to dashboard Cite

show abstract

“…Recently, modelling tools have been incorporating a mid-fidelity approach for aerodynamic modelling, the FVW method. [95][96][97] With increasing turbine rotor sizes, there is a greater need to accurately capture aerodynamic effects due to large blade deflections. The FVW method satisfies this need with a level of fidelity and computational efficiency between that of BEMT and CFD methods.…”

Section: Aerodynamicsmentioning

confidence: 99%

“…Recently, modelling tools have been incorporating a mid‐fidelity approach for aerodynamic modelling, the FVW method 95–97 . With increasing turbine rotor sizes, there is a greater need to accurately capture aerodynamic effects due to large blade deflections.…”

Section: Numerical Modellingmentioning

confidence: 99%

A review of modelling techniques for floating offshore wind turbines

et al. 2021

View full text Add to dashboard Cite

Modelling floating offshore wind turbines (FOWTs) is challenging due to the strong coupling between the aerodynamics of the turbine and the hydrodynamics of the floating platform. Physical testing at scale is faced with the additional challenge of the scaling mismatch between Froude number and Reynolds number due to working in the two fluid domains, air and water. In the drive for cost-reduction of floating wind energy, designers may be seeking to move towards high-fidelity numerical modelling as a substitute for physical testing. However, the numerical engineering tools typically used for FOWT modelling are considered as mid-fidelity to low-fidelity tools, and currently lack the level of accuracy required to do so. Furthermore, there is a lack of operational FOWT data available for further development and validation.High-fidelity tools, such as CFD, have greater accuracy but are cumbersome tools and still require validation. Physical scale model testing therefore continues to play an essential role in the development of FOWTs both as a source of validation data for numerical models and as an important development step along the path to commercialization of all platform concepts. The aim of this paper is to provide an overview of both numerical modelling and physical FOWT scale model testing approaches and to provide guidance on the selection of the most appropriate approach (or combination of approaches). The current state-of-the-art will be discussed along with current research trends and areas for further investigation.

show abstract

“…This work uses a highly idealised scenario in order to isolate the impact of the inflow length scale, and demonstrate that it can be the sole cause of wake flow differences similar to that achieved through dynamic control strategies [12] or floater motion [13]. Therefore, the results presented here should be considered a proof of concept of the potential impact of turbulent scales on wake recovery, and demonstrates the need to look past global quantities such as turbulence intensity to describe wake development.…”

Section: Discussionmentioning

confidence: 84%

“…Beneficial routines of dynamic induction and yaw control are also identified in the works of Munters and Meyers [11,12], using the adjoint method combined with LES of a wind farm. Without additional control, the wake recovery behind a turbine undergoing floater motion was seen to be significantly improved compared to a fixed bottom case [13], with the frequency and amplitude of the turbine oscillations having a significant impact.…”

Section: Introductionmentioning

confidence: 95%

Impact of Turbulent Time Scales on Wake Recovery and Operation

Hodgson

Madsen

Troldborg

et al. 2022

J. Phys.: Conf. Ser.

View full text Add to dashboard Cite

Enhancing wake recovery behind wind turbines has the potential to significantly improve the power production and efficiency of large wind farms. Rather than investigating turbine control strategies, floater motion or global turbulent quantities such as turbulence intensity, this work aims to study wake stability and recovery through a focus on the turbulent scales of the inflow. Using Large Eddy Simulations of a single turbine, sinusoidal streamwise forcing is applied to the inflow with a constant amplitude and mean flow velocity, but differing time scales between 80s and 140s. For all applied time scales the turbine wake is characterised by the rolling-up of the near wake into the periodic shedding of vortex rings, and an excitation of the applied forcing frequency resulting in velocity fluctuations in the wake several times larger than that at the inflow. For shorter time scales (80s - 90s) a more aggressive and earlier wake roll-up led to a shorter near wake region, faster overall recovery and significantly improved the expected power output from 6R downstream onwards. An inflow time period of 80s gave rise to more than a 50% increase in power output of a fictive downstream turbine placed at 14R downstream, compared to an inflow time scale of 140s.

show abstract

Investigation of the floating IEA Wind 15 MW RWT using vortex methods Part I: Flow regimes and wake recovery

Cited by 29 publications

References 40 publications

Investigation of the floating IEA wind 15‐MW RWT using vortex methods Part II: Wake impact on downstream turbines under turbulent inflow

Investigation of the floating IEA wind 15‐MW RWT using vortex methods Part II: Wake impact on downstream turbines under turbulent inflow

A review of modelling techniques for floating offshore wind turbines

Impact of Turbulent Time Scales on Wake Recovery and Operation

Contact Info

Product

Resources

About