Using wind speed from a blade-mounted flow sensor for power and load assessment on modern wind turbines

Pedersen, Martin Wæver; Larsen, Torben J.; Madsen, Helge Aagaard; Larsen, Gunner Chr.

doi:10.5194/wes-2-547-2017

Cited by 10 publications

(22 citation statements)

References 12 publications

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“…Some field measurement campaigns were punctually performed for research purposes using pressure probes around the blades on dedicated blade manufacturing with however only weak potential of these sensors to be used in a day-to-day operation of wind turbines [26]. Some solutions were explored such as tufts or stall flags glued on the blade correlated with positions of the flow separation [25,20] [7]. However, these methods need a mounted camera on the turbine with its associated drawbacks (fragility of the camera, vision at night ...).…”

Section: Introductionmentioning

confidence: 99%

Ability of the e-TellTale sensor to detect flow features over wind turbine blades: flow stall/reattachment dynamics

Soulier¹,

Braud²,

Voisin³

et al. 2020

Preprint

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Monitoring the flow features over wind turbine blades is a challenging task that has become more and more crucial. This paper is devoted to demonstrate the ability of the e-TellTale sensor to detect the flow separation/reattachment dynamics over wind turbine blades. This sensor is made of a strip with a strain gauge sensor at its base. The velocity field was acquired using TR-PIV measurements over an oscillating thick blade section equipped with an e-TellTale sensor. PIV images were post-processed to detect movements of the strip, which was compared to movements of flow. Results show good agreement between the measured velocity field and movements of the strip regarding the separation/reattachment dynamics.

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Section: Introductionmentioning

confidence: 99%

Ability of the e-TellTale sensor to detect flow features over wind turbine blades: flow stall/reattachment dynamics

Soulier¹,

Braud²,

Voisin³

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…Shen et al (2006Shen et al ( , 2009, Guntur and Sørensen (2014) and Rahimi et al (2017) present several methods to calculate the flow near the airfoil that also take 3D effects into account, but the methods require information that cannot be obtained directly from a BMFS. Pedersen et al (2017) describes how to obtain the effective 3D inflow from the relative wind speed and two perpen- From the relative velocity, V rel , the wind speed at the rotor plane, V r , is found by subtracting the velocity of the sensor, V s :…”

Section: Wind Speed From a Bmfsmentioning

confidence: 99%

“…These relative curves can be used to investigate e.g. aerodynamic modifications or detect performance 20 issues (Pedersen et al, 2017).…”

mentioning

confidence: 99%

Free flow wind speed from a blade-mounted flow sensor

Pedersen¹,

Larsen²,

Madsen³

et al. 2018

Preprint

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Abstract. This paper presents a method for obtaining the free inflow velocities from a 3D flow sensor mounted on the blade of a wind turbine.From its position on the rotating blade, e.g. one third from the tip, a blade mounted flow sensor (BMFS) is able to provide valuable information about the turbulent sheared inflow in different regions of the rotor. At the rotor, however, the inflow is affected by the wind turbine, and in most cases the wind of interest is the inflow that the wind turbine is exposed to; i.e. the 5 free inflow velocities.The current method applies a combination of aerodynamic models and procedures to estimate the induced velocities, i.e. the disturbance of the flow field caused by the wind turbine. These velocities are subtracted from the flow velocities measured by the BMFS to obtain the free inflow velocities. Aeroelastic codes, like HAWC2, typically use a similar approach to calculate the induction, but they use it for the reversed process, i.e. they add the induction to the free inflow to get the flow velocities at 10 the blades which are required to calculate the resulting aerodynamic forces.The aerodynamic models included in the current method comprise blade-element-momentum (BEM) based models for axial and tangential induction, a radial induction model and tip loss correction as well as models for skew and dynamic inflow.It is shown that the method is able to calculate the free inflow velocities with high accuracy when applied to aeroelastic HAWC2 simulations with a stiff structural model while some deviations are seen in simulations with a flexible structure. 15Furthermore, the method is tested on simulations performed by a flexible structural model coupled with a large eddy simulation (LES) flow solver. The results of this higher fidelity verification confirm the HAWC2-based conclusion.

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“…Shen et al (2006Shen et al ( , 2009, Guntur and Sørensen (2014), and Rahimi et al (2018) present several methods to calculate the flow near the airfoil that also take 3-D effects into account, but the methods require information that cannot be obtained directly from a BMFS. Pedersen et al (2017) describes how to obtain the effective 3-D inflow from the relative wind speed and two perpendicular angles measured by a blade-mounted five-hole pitot, including compensation for bound circulation. The compensation method uses a look-up table generated by 2-D computational fluid dynamic (CFD) simulations, thus neglecting 3-D effects and tip and root vortices.…”

Section: Wind Speed From a Bmfsmentioning

confidence: 99%

“…Furthermore, the load distribution along the blade should be taken into account, such that the sensor measures the inflow where the largest loads occur. In Pedersen et al (2017), different radial positions are investigated and 50-67 was found to be optimal.…”

Section: Introductionmentioning

confidence: 99%

Free-flow wind speed from a blade-mounted flow sensor

et al. 2018

Self Cite

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Abstract. This paper presents a method for obtaining the free-inflow velocities from a 3-D flow sensor mounted on the blade of a wind turbine.From its position on the rotating blade, e.g. one-third from the tip, a blade-mounted flow sensor (BMFS) is able to provide valuable information about the turbulent sheared inflow in different regions of the rotor. At the rotor, however, the inflow is affected by the wind turbine, and in most cases the wind of interest is the inflow that the wind turbine is exposed to, i.e. the free-inflow velocities.The current method applies a combination of aerodynamic models and procedures to estimate the induced velocities, i.e. the disturbance of the flow field caused by the wind turbine. These velocities are subtracted from the flow velocities measured by the BMFS to obtain the free-inflow velocities. Aeroelastic codes, like HAWC2, typically use a similar approach to calculate the induction, but they use it for the reversed process, i.e. they add the induction to the free inflow to get the flow velocities at the blades, which are required to calculate the resulting aerodynamic forces.The aerodynamic models included in the current method comprise models based on blade element momentum (BEM) for axial and tangential induction, a radial induction model and tip loss correction, and models for skew and dynamic inflow.It is shown that the method is able to calculate the free-inflow velocities with high accuracy when applied to aeroelastic HAWC2 simulations with a stiff structural model while some deviations are seen in simulations with a flexible structure.Furthermore, the method is tested on simulations performed by a flexible structural model coupled with a large-eddy simulation (LES) flow solver. The results of this higher-fidelity verification confirm the HAWC2-based conclusion.

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Using wind speed from a blade-mounted flow sensor for power and load assessment on modern wind turbines

Cited by 10 publications

References 12 publications

Ability of the e-TellTale sensor to detect flow features over wind turbine blades: flow stall/reattachment dynamics

Ability of the e-TellTale sensor to detect flow features over wind turbine blades: flow stall/reattachment dynamics

Free flow wind speed from a blade-mounted flow sensor

Free-flow wind speed from a blade-mounted flow sensor

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