Flexnertia: A novel dissipation mechanism for structural vibration reduction through coupling of flexural motion with an inerter

Yuhao Liu; Jian Yang; Chen Zhou; Waiel Elmadih; Jian Zhu; Dimitrios Chronopoulos

doi:10.1080/15376494.2023.2226957

Flexnertia: A novel dissipation mechanism for structural vibration reduction through coupling of flexural motion with an inerter

Yuhao Liu, Jian Yang, Chen Zhou, Waiel Elmadih, Jian Zhu, Dimitrios Chronopoulos

Department of Mechanical, Materials and Manufacturing Engineering

Research output: Journal Publication › Article › peer-review

Abstract

This paper presents a novel Flexnertia metastructure concept to perform vibration suppression through coupling rotational inertia to structural flexural motion. Theoretical analysis and experimental test of the proposed metastructure with emphasis on dissipating structural flexural motion is exhibited, showing vibration control performance. The experimental and numerical results are in good agreement, both confirming that the average overall response of the metastructure is significantly reduced. The attenuation becomes most pronounced in the low-frequency range where structures tend to suffer most due to high response around the regime of the first flexural modes.

Original language	English
Pages (from-to)	6213-6222
Number of pages	10
Journal	Mechanics of Advanced Materials and Structures
Volume	31
Issue number	24
DOIs	https://doi.org/10.1080/15376494.2023.2226957
Publication status	Published - 2023

Keywords

inerter
metastructure
vibration analysis
Vibration suppression
wave dissipation

ASJC Scopus subject areas

Civil and Structural Engineering
General Mathematics
General Materials Science
Mechanics of Materials
Mechanical Engineering

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10.1080/15376494.2023.2226957

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title = "Flexnertia: A novel dissipation mechanism for structural vibration reduction through coupling of flexural motion with an inerter",

abstract = "This paper presents a novel Flexnertia metastructure concept to perform vibration suppression through coupling rotational inertia to structural flexural motion. Theoretical analysis and experimental test of the proposed metastructure with emphasis on dissipating structural flexural motion is exhibited, showing vibration control performance. The experimental and numerical results are in good agreement, both confirming that the average overall response of the metastructure is significantly reduced. The attenuation becomes most pronounced in the low-frequency range where structures tend to suffer most due to high response around the regime of the first flexural modes.",

keywords = "inerter, metastructure, vibration analysis, Vibration suppression, wave dissipation",

author = "Yuhao Liu and Jian Yang and Chen Zhou and Waiel Elmadih and Jian Zhu and Dimitrios Chronopoulos",

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T2 - A novel dissipation mechanism for structural vibration reduction through coupling of flexural motion with an inerter

AU - Liu, Yuhao

AU - Yang, Jian

AU - Zhou, Chen

AU - Elmadih, Waiel

AU - Zhu, Jian

AU - Chronopoulos, Dimitrios

PY - 2023

Y1 - 2023

N2 - This paper presents a novel Flexnertia metastructure concept to perform vibration suppression through coupling rotational inertia to structural flexural motion. Theoretical analysis and experimental test of the proposed metastructure with emphasis on dissipating structural flexural motion is exhibited, showing vibration control performance. The experimental and numerical results are in good agreement, both confirming that the average overall response of the metastructure is significantly reduced. The attenuation becomes most pronounced in the low-frequency range where structures tend to suffer most due to high response around the regime of the first flexural modes.

AB - This paper presents a novel Flexnertia metastructure concept to perform vibration suppression through coupling rotational inertia to structural flexural motion. Theoretical analysis and experimental test of the proposed metastructure with emphasis on dissipating structural flexural motion is exhibited, showing vibration control performance. The experimental and numerical results are in good agreement, both confirming that the average overall response of the metastructure is significantly reduced. The attenuation becomes most pronounced in the low-frequency range where structures tend to suffer most due to high response around the regime of the first flexural modes.

KW - inerter

KW - metastructure

KW - vibration analysis

KW - Vibration suppression

KW - wave dissipation

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JF - Mechanics of Advanced Materials and Structures

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ER -

Flexnertia: A novel dissipation mechanism for structural vibration reduction through coupling of flexural motion with an inerter

Abstract

Keywords

ASJC Scopus subject areas

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