Gust response of aeroelastically tailored wind turbines

S. Scott; M. Capuzzi; D. Langston; E. Bossanyi; G. McCann; Pm Weaver; A. Pirrera

doi:10.1088/1742-6596/753/4/042006

Gust response of aeroelastically tailored wind turbines

S. Scott, M. Capuzzi, D. Langston, E. Bossanyi, G. McCann, Pm Weaver, A. Pirrera

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

Abstract

Some interesting challenges arise from the drive to build larger, more durable rotors that produce cheaper energy. The rationale is that, with current wind turbine designs, the power generated is theoretically proportional to the square of blade length. One enabling technology is aeroelastic tailoring that offers enhanced combined energy capture and system durability. The design of two adaptive, aeroelastically tailored blade configurations is considered here. One uses material bend-twist coupling; the other combines both material and geometric coupling. Each structural design meets a predefined coupling distribution, whilst approximately matching the stiffness of an uncoupled baseline blade. A gust analysis shows beneficial flapwise load alleviation for both adaptive blades, with the additional benefits of smoothing variations in electrical power and rotational speed.

Original language	English
Article number	042006
Journal	Journal of Physics: Conference Series
Volume	753
Issue number	4
DOIs	https://doi.org/10.1088/1742-6596/753/4/042006
Publication status	Published - 3 Oct 2016
Externally published	Yes
Event	Science of Making Torque from Wind, TORQUE 2016 - Munich, Germany Duration: 5 Oct 2016 → 7 Oct 2016

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1088/1742-6596/753/4/042006

Cite this

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title = "Gust response of aeroelastically tailored wind turbines",

abstract = "Some interesting challenges arise from the drive to build larger, more durable rotors that produce cheaper energy. The rationale is that, with current wind turbine designs, the power generated is theoretically proportional to the square of blade length. One enabling technology is aeroelastic tailoring that offers enhanced combined energy capture and system durability. The design of two adaptive, aeroelastically tailored blade configurations is considered here. One uses material bend-twist coupling; the other combines both material and geometric coupling. Each structural design meets a predefined coupling distribution, whilst approximately matching the stiffness of an uncoupled baseline blade. A gust analysis shows beneficial flapwise load alleviation for both adaptive blades, with the additional benefits of smoothing variations in electrical power and rotational speed.",

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AU - Scott, S.

AU - Capuzzi, M.

AU - Langston, D.

AU - Bossanyi, E.

AU - McCann, G.

AU - Weaver, Pm

AU - Pirrera, A.

PY - 2016/10/3

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N2 - Some interesting challenges arise from the drive to build larger, more durable rotors that produce cheaper energy. The rationale is that, with current wind turbine designs, the power generated is theoretically proportional to the square of blade length. One enabling technology is aeroelastic tailoring that offers enhanced combined energy capture and system durability. The design of two adaptive, aeroelastically tailored blade configurations is considered here. One uses material bend-twist coupling; the other combines both material and geometric coupling. Each structural design meets a predefined coupling distribution, whilst approximately matching the stiffness of an uncoupled baseline blade. A gust analysis shows beneficial flapwise load alleviation for both adaptive blades, with the additional benefits of smoothing variations in electrical power and rotational speed.

AB - Some interesting challenges arise from the drive to build larger, more durable rotors that produce cheaper energy. The rationale is that, with current wind turbine designs, the power generated is theoretically proportional to the square of blade length. One enabling technology is aeroelastic tailoring that offers enhanced combined energy capture and system durability. The design of two adaptive, aeroelastically tailored blade configurations is considered here. One uses material bend-twist coupling; the other combines both material and geometric coupling. Each structural design meets a predefined coupling distribution, whilst approximately matching the stiffness of an uncoupled baseline blade. A gust analysis shows beneficial flapwise load alleviation for both adaptive blades, with the additional benefits of smoothing variations in electrical power and rotational speed.

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DO - 10.1088/1742-6596/753/4/042006

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ER -

Gust response of aeroelastically tailored wind turbines

Abstract

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