Mutual inductance instability of the tip vortices behind a wind turbine

Sarmast, Sasan; Dadfar, Reza; Mikkelsen, Robert Flemming; Schlatter, Philipp; Ivanell, Stefan; Sørensen, Jens Nørkær; Henningson, Dan S.

doi:10.1017/jfm.2014.326

Cited by 147 publications

(118 citation statements)

References 26 publications

(55 reference statements)

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“…The shear profile is implemented to match the profile given in the invitational document by Saetran and Bartl (2015). A more detailed description of the method can be found in Sarmast et al (2014).…”

Section: Uppsala University and Dtu (Uu-dtu)mentioning

confidence: 99%

“…The largest rotor investigated for wake comparison studies was the MEXICO rotor, with a diameter of 4.5 m (Schepers et al, 2010), in which the rotor performance as well as the wake flow were examined in detail. A second campaign investigating even more effects, including span-wise pressure distributions, yaw misalignment and unsteady effects, was realized at a large German-Dutch Wind Tunnel (DNW).…”

Section: Introductionmentioning

confidence: 99%

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Blind test comparison of the performance and wake flow between two in-line wind turbines exposed to different turbulent inflow conditions

Bartl

Sætran

2017

Wind Energ. Sci.

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Abstract. This is a summary of the results of the fourth blind test workshop that was held in Trondheim in October 2015. Herein, computational predictions on the performance of two in-line model wind turbines as well as the mean and turbulent wake flow are compared to experimental data measured at the wind tunnel of the Norwegian University of Science and Technology (NTNU). A detailed description of the model geometry, the wind tunnel boundary conditions and the test case specifications was published before the workshop. Expert groups within computational fluid dynamics (CFD) were invited to submit predictions on wind turbine performance and wake flow without knowing the experimental results at the outset. The focus of this blind test comparison is to examine the model turbines' performance and wake development with nine rotor diameters downstream at three different turbulent inflow conditions. Aside from a spatially uniform inflow field of very low-turbulence intensity (TI = 0.23 %) and high-turbulence intensity (TI = 10.0 %), the turbines are exposed to a grid-generated highly turbulent shear flow (TI = 10.1 %).Five different research groups contributed their predictions using a variety of simulation models, ranging from fully resolved Reynolds-averaged Navier-Stokes (RANS) models to large eddy simulations (LESs). For the three inlet conditions, the power and the thrust force of the upstream turbine is predicted fairly well by most models, while the predictions of the downstream turbine's performance show a significantly higher scatter. Comparing the mean velocity profiles in the wake, most models approximate the mean velocity deficit level sufficiently well. However, larger variations between the models for higher downstream positions are observed. Prediction of the turbulence kinetic energy in the wake is observed to be very challenging. Both the LES model and the IDDES (improved delayed detached eddy simulation) model, however, consistently manage to provide fairly accurate predictions of the wake turbulence.

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Section: Uppsala University and Dtu (Uu-dtu)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Blind test comparison of the performance and wake flow between two in-line wind turbines exposed to different turbulent inflow conditions

Bartl

Sætran

2017

Wind Energ. Sci.

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“…The initial derivations of the presented analysis follow the work of Ivanell et al [23] and Sarmast et al [28]. In these studies, the simulations are performed using the Tjaereborg wind turbine operating at the optimum power condition (Cp = 0.49) for a wind speed of U 0 = 10 m s −1 and tip speed ratio of λ = 7.…”

Section: (A) Stability Analysis Of Tip Vorticesmentioning

confidence: 99%

“…From the figure, it can be clearly seen that the amplitudes develop with an exponential growth rate. More information regarding the computations can be obtained from Ivanell et al [23] and Sarmast et al [28]. The curves are normalized by the amplitude at x/R = 0.5 to compare the growth from computations with different perturbations.…”

Section: (A) Stability Analysis Of Tip Vorticesmentioning

confidence: 99%

Simulation of wind turbine wakes using the actuator line technique

Sørensen

Mikkelsen

Henningson

et al. 2015

Phil. Trans. R. Soc. A.

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156

158

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The actuator line technique was introduced as a numerical tool to be employed in combination with large eddy simulations to enable the study of wakes and wake interaction in wind farms. The technique is today largely used for studying basic features of wakes as well as for making performance predictions of wind farms. In this paper, we give a short introduction to the wake problem and the actuator line methodology and present a study in which the technique is employed to determine the near-wake properties of wind turbines. The presented results include a comparison of experimental results of the wake characteristics of the flow around a three-bladed model wind turbine, the development of a simple analytical formula for determining the near-wake length behind a wind turbine and a detailed investigation of wake structures based on proper orthogonal decomposition analysis of numerically generated snapshots of the wake.

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“…Another dynamic approach, also followed in this work, is to analyse and model wind turbine wakes using modal decompositions [21,[35][36][37][38][39][40][41][42][43][44][45][46][47] which describe the velocity field as a linear superposition of spatial modes with time-dependent weighting coefficients. It has been shown that a few spatial modes can already capture important features of the wake flow [35][36][37][38][39]41,43,47].…”

Section: Introductionmentioning

confidence: 99%

Stochastic Wake Modelling Based on POD Analysis

et al. 2018

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Abstract:In this work, large eddy simulation data is analysed to investigate a new stochastic modeling approach for the wake of a wind turbine. The data is generated by the large eddy simulation (LES) model PALM combined with an actuator disk with rotation representing the turbine. After applying a proper orthogonal decomposition (POD), three different stochastic models for the weighting coefficients of the POD modes are deduced resulting in three different wake models. Their performance is investigated mainly on the basis of aeroelastic simulations of a wind turbine in the wake. Three different load cases and their statistical characteristics are compared for the original LES, truncated PODs and the stochastic wake models including different numbers of POD modes. It is shown that approximately six POD modes are enough to capture the load dynamics on large temporal scales. Modeling the weighting coefficients as independent stochastic processes leads to similar load characteristics as in the case of the truncated POD. To complete this simplified wake description, we show evidence that the small-scale dynamics can be captured by adding to our model a homogeneous turbulent field. In this way, we present a procedure to derive stochastic wake models from costly computational fluid dynamics (CFD) calculations or elaborated experimental investigations. These numerically efficient models provide the added value of possible long-term studies. Depending on the aspects of interest, different minimalized models may be obtained.

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Mutual inductance instability of the tip vortices behind a wind turbine

Cited by 147 publications

References 26 publications

Blind test comparison of the performance and wake flow between two in-line wind turbines exposed to different turbulent inflow conditions

Blind test comparison of the performance and wake flow between two in-line wind turbines exposed to different turbulent inflow conditions

Simulation of wind turbine wakes using the actuator line technique

Stochastic Wake Modelling Based on POD Analysis

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