Individual Blade Pitch Control for Extended Fatigue Lifetime of Multi-Megawatt Wind Turbines

H. Hoghooghi; N. Chokani; R. S. Abhari

doi:10.1088/1742-6596/1618/2/022008

Individual Blade Pitch Control for Extended Fatigue Lifetime of Multi-Megawatt Wind Turbines

H. Hoghooghi, N. Chokani, R. S. Abhari

ETH Zurich

Research output: Contribution to journal › Conference article › peer-review

4 Scopus citations

Abstract

A novel experimental study on the use of individual pitch control to extend the fatigue life of wind turbines is conducted. The experiment is accomplished using a sub-scale model of a multi-megawatt turbine in both upwind and downwind configurations in a water towing tank. It is shown that individual pitch control based on a sinusoidal pitching scheme that is locked to the phase of the rotor rotation can mitigate unsteady loads caused by the velocity variation that is induced by the effect of rotor tilt and therefore extends the fatigue lifetime of blades. A positive pitching amplitude in the case of upwind configuration and a negative pitching amplitude in the case of downwind configuration eliminate the cumulative damage fractions due to the velocity variation.

Original language	English
Article number	022008
Journal	Journal of Physics: Conference Series
Volume	1618
Issue number	2
DOIs	https://doi.org/10.1088/1742-6596/1618/2/022008
State	Published - 22 Sep 2020
Externally published	Yes
Event	Science of Making Torque from Wind 2020, TORQUE 2020 - Virtual, Online, Netherlands Duration: 28 Sep 2020 → 2 Oct 2020

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10.1088/1742-6596/1618/2/022008

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title = "Individual Blade Pitch Control for Extended Fatigue Lifetime of Multi-Megawatt Wind Turbines",

abstract = "A novel experimental study on the use of individual pitch control to extend the fatigue life of wind turbines is conducted. The experiment is accomplished using a sub-scale model of a multi-megawatt turbine in both upwind and downwind configurations in a water towing tank. It is shown that individual pitch control based on a sinusoidal pitching scheme that is locked to the phase of the rotor rotation can mitigate unsteady loads caused by the velocity variation that is induced by the effect of rotor tilt and therefore extends the fatigue lifetime of blades. A positive pitching amplitude in the case of upwind configuration and a negative pitching amplitude in the case of downwind configuration eliminate the cumulative damage fractions due to the velocity variation.",

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N2 - A novel experimental study on the use of individual pitch control to extend the fatigue life of wind turbines is conducted. The experiment is accomplished using a sub-scale model of a multi-megawatt turbine in both upwind and downwind configurations in a water towing tank. It is shown that individual pitch control based on a sinusoidal pitching scheme that is locked to the phase of the rotor rotation can mitigate unsteady loads caused by the velocity variation that is induced by the effect of rotor tilt and therefore extends the fatigue lifetime of blades. A positive pitching amplitude in the case of upwind configuration and a negative pitching amplitude in the case of downwind configuration eliminate the cumulative damage fractions due to the velocity variation.

AB - A novel experimental study on the use of individual pitch control to extend the fatigue life of wind turbines is conducted. The experiment is accomplished using a sub-scale model of a multi-megawatt turbine in both upwind and downwind configurations in a water towing tank. It is shown that individual pitch control based on a sinusoidal pitching scheme that is locked to the phase of the rotor rotation can mitigate unsteady loads caused by the velocity variation that is induced by the effect of rotor tilt and therefore extends the fatigue lifetime of blades. A positive pitching amplitude in the case of upwind configuration and a negative pitching amplitude in the case of downwind configuration eliminate the cumulative damage fractions due to the velocity variation.

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T2 - Science of Making Torque from Wind 2020, TORQUE 2020

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Individual Blade Pitch Control for Extended Fatigue Lifetime of Multi-Megawatt Wind Turbines

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