Large-Amplitude Vibrations of a Slender Cantilevered Beam

Nicholas Vlajic; Fisher Ng; Timothy Fitzgerald

doi:10.1016/j.ifacol.2022.10.555

Large-Amplitude Vibrations of a Slender Cantilevered Beam

Nicholas Vlajic, Fisher Ng, Timothy Fitzgerald

Applied Research Laboratory (ARL)

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

Abstract

We present a geometrically exact beam model for a cantilevered beam undergoing large-amplitude motions, motivated by recent wind-energy capture systems that exploit vortex-induced vibrations. The derivation of this model leads to a single nonlinear 2nd-order ordinary differential equation that appears similar to a Duffing oscillator with additional nonlinear acceleration terms. For prismatic configurations, the formulation is characterized by its linear natural frequency and a normalization constant of the shape-function. A brief parametric study is conducted to demonstrate the softening effects of the nonlinear acceleration terms. Continuation methods are used to construct the amplitude versus forcing frequency plots to capture the nonlinear response.

Original language	English (US)
Pages (from-to)	460-465
Number of pages	6
Journal	IFAC-PapersOnLine
Volume	55
Issue number	27
DOIs	https://doi.org/10.1016/j.ifacol.2022.10.555
State	Published - Sep 1 2022
Event	9th IFAC Symposium on Mechatronic Systems, MECHATRONICS 2022 - Los Angeles, United States Duration: Sep 6 2022 → Sep 9 2022

All Science Journal Classification (ASJC) codes

Control and Systems Engineering

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10.1016/j.ifacol.2022.10.555

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title = "Large-Amplitude Vibrations of a Slender Cantilevered Beam",

abstract = "We present a geometrically exact beam model for a cantilevered beam undergoing large-amplitude motions, motivated by recent wind-energy capture systems that exploit vortex-induced vibrations. The derivation of this model leads to a single nonlinear 2nd-order ordinary differential equation that appears similar to a Duffing oscillator with additional nonlinear acceleration terms. For prismatic configurations, the formulation is characterized by its linear natural frequency and a normalization constant of the shape-function. A brief parametric study is conducted to demonstrate the softening effects of the nonlinear acceleration terms. Continuation methods are used to construct the amplitude versus forcing frequency plots to capture the nonlinear response.",

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AU - Ng, Fisher

AU - Fitzgerald, Timothy

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N2 - We present a geometrically exact beam model for a cantilevered beam undergoing large-amplitude motions, motivated by recent wind-energy capture systems that exploit vortex-induced vibrations. The derivation of this model leads to a single nonlinear 2nd-order ordinary differential equation that appears similar to a Duffing oscillator with additional nonlinear acceleration terms. For prismatic configurations, the formulation is characterized by its linear natural frequency and a normalization constant of the shape-function. A brief parametric study is conducted to demonstrate the softening effects of the nonlinear acceleration terms. Continuation methods are used to construct the amplitude versus forcing frequency plots to capture the nonlinear response.

AB - We present a geometrically exact beam model for a cantilevered beam undergoing large-amplitude motions, motivated by recent wind-energy capture systems that exploit vortex-induced vibrations. The derivation of this model leads to a single nonlinear 2nd-order ordinary differential equation that appears similar to a Duffing oscillator with additional nonlinear acceleration terms. For prismatic configurations, the formulation is characterized by its linear natural frequency and a normalization constant of the shape-function. A brief parametric study is conducted to demonstrate the softening effects of the nonlinear acceleration terms. Continuation methods are used to construct the amplitude versus forcing frequency plots to capture the nonlinear response.

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JO - IFAC-PapersOnLine

JF - IFAC-PapersOnLine

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T2 - 9th IFAC Symposium on Mechatronic Systems, MECHATRONICS 2022

Y2 - 6 September 2022 through 9 September 2022

ER -

Large-Amplitude Vibrations of a Slender Cantilevered Beam

Abstract

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