Performance Comparison of the Forward and Inverse Metawedge for Ground-Borne Vibration Mitigation

A. B. Faragau; S. van Gaal; E Vlijm; A. Metrikine; A. Tsouvalas; K.N. van Dalen

doi:10.4203/ccc.7.13.8

Performance Comparison of the Forward and Inverse Metawedge for Ground-Borne Vibration Mitigation

A. B. Faragau, S. van Gaal, E Vlijm, A. Metrikine, A. Tsouvalas, K.N. van Dalen

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Abstract

This study examines the impact of railway-induced ground-borne vibrations on nearby structures and residents, focusing on the effectiveness of the metawedge, a novel mitigation measure. The metawedge consists of a series of periodically arranged resonators along the propagation path, either placed on the ground surface or embedded at various depths. Unlike classical locally-resonant metamaterials, the metawedge features resonators with smoothly varying resonance frequencies in the longitudinal direction. Two metawedge designs, the forward and inverse metawedge, have been proposed in the literature. Despite their similarities, they operate on different principles: the forward metawedge decelerates incoming surface waves, localizing energy, while the inverse metawedge accelerates the waves, converting Rayleigh waves into body waves. This study compares the performance of both designs in mitigating train-induced ground-borne vibrations. Results indicate that both the forward and inverse metawedge exhibit remarkably similar performance for the specific design adopted. If this similarity holds across different designs, it offers engineers flexibility in choosing the appropriate measure based on practical needs. More generally, this work demonstrates the potential and feasibility of using metamaterials to address current and future challenges in railway transportation.

Original language	English
Number of pages	12
DOIs	https://doi.org/10.4203/ccc.7.13.8
Publication status	Published - 2024
Event	The Sixth International Conference on Railway Technology 2024: Research, Development and Maintenance - Faculty of Civil Engineering, Czech Technical University, Prague, Czech Republic Duration: 1 Sept 2024 → 5 Sept 2024 https://www.civil-comp.info/2024/rl/

Conference

Conference	The Sixth International Conference on Railway Technology 2024
Abbreviated title	RAILWAYS 2024
Country/Territory	Czech Republic
City	Prague
Period	1/09/24 → 5/09/24
Internet address	https://www.civil-comp.info/2024/rl/

Bibliographical note

Green Open Access added to TU Delft Institutional Repository ‘You share, we take care!’ – Taverne project https://www.openaccess.nl/en/you-share-we-take-care
Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.

Keywords

ground-borne vibration
vibration mitigation
metamaterials
metawedge
railway-induced vibration
wave propagation

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10.4203/ccc.7.13.8

Performance Comparison of the Forward and Inverse Metawedge for Ground-Borne Vibration MitigationFinal published version, 1.44 MB

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title = "Performance Comparison of the Forward and Inverse Metawedge for Ground-Borne Vibration Mitigation",

abstract = "This study examines the impact of railway-induced ground-borne vibrations on nearby structures and residents, focusing on the effectiveness of the metawedge, a novel mitigation measure. The metawedge consists of a series of periodically arranged resonators along the propagation path, either placed on the ground surface or embedded at various depths. Unlike classical locally-resonant metamaterials, the metawedge features resonators with smoothly varying resonance frequencies in the longitudinal direction. Two metawedge designs, the forward and inverse metawedge, have been proposed in the literature. Despite their similarities, they operate on different principles: the forward metawedge decelerates incoming surface waves, localizing energy, while the inverse metawedge accelerates the waves, converting Rayleigh waves into body waves. This study compares the performance of both designs in mitigating train-induced ground-borne vibrations. Results indicate that both the forward and inverse metawedge exhibit remarkably similar performance for the specific design adopted. If this similarity holds across different designs, it offers engineers flexibility in choosing the appropriate measure based on practical needs. More generally, this work demonstrates the potential and feasibility of using metamaterials to address current and future challenges in railway transportation.",

keywords = "ground-borne vibration, vibration mitigation, metamaterials, metawedge, railway-induced vibration, wave propagation",

author = "Faragau, {A. B.} and {van Gaal}, S. and E Vlijm and A. Metrikine and A. Tsouvalas and {van Dalen}, K.N.",

note = "Green Open Access added to TU Delft Institutional Repository {\textquoteleft}You share, we take care!{\textquoteright} – Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public. ; The Sixth International Conference on Railway Technology 2024 : Research, Development and Maintenance , RAILWAYS 2024 ; Conference date: 01-09-2024 Through 05-09-2024",

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TY - CONF

T1 - Performance Comparison of the Forward and Inverse Metawedge for Ground-Borne Vibration Mitigation

AU - Faragau, A. B.

AU - van Gaal, S.

AU - Vlijm, E

AU - Metrikine, A.

AU - Tsouvalas, A.

AU - van Dalen, K.N.

N1 - Green Open Access added to TU Delft Institutional Repository ‘You share, we take care!’ – Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.

PY - 2024

Y1 - 2024

N2 - This study examines the impact of railway-induced ground-borne vibrations on nearby structures and residents, focusing on the effectiveness of the metawedge, a novel mitigation measure. The metawedge consists of a series of periodically arranged resonators along the propagation path, either placed on the ground surface or embedded at various depths. Unlike classical locally-resonant metamaterials, the metawedge features resonators with smoothly varying resonance frequencies in the longitudinal direction. Two metawedge designs, the forward and inverse metawedge, have been proposed in the literature. Despite their similarities, they operate on different principles: the forward metawedge decelerates incoming surface waves, localizing energy, while the inverse metawedge accelerates the waves, converting Rayleigh waves into body waves. This study compares the performance of both designs in mitigating train-induced ground-borne vibrations. Results indicate that both the forward and inverse metawedge exhibit remarkably similar performance for the specific design adopted. If this similarity holds across different designs, it offers engineers flexibility in choosing the appropriate measure based on practical needs. More generally, this work demonstrates the potential and feasibility of using metamaterials to address current and future challenges in railway transportation.

AB - This study examines the impact of railway-induced ground-borne vibrations on nearby structures and residents, focusing on the effectiveness of the metawedge, a novel mitigation measure. The metawedge consists of a series of periodically arranged resonators along the propagation path, either placed on the ground surface or embedded at various depths. Unlike classical locally-resonant metamaterials, the metawedge features resonators with smoothly varying resonance frequencies in the longitudinal direction. Two metawedge designs, the forward and inverse metawedge, have been proposed in the literature. Despite their similarities, they operate on different principles: the forward metawedge decelerates incoming surface waves, localizing energy, while the inverse metawedge accelerates the waves, converting Rayleigh waves into body waves. This study compares the performance of both designs in mitigating train-induced ground-borne vibrations. Results indicate that both the forward and inverse metawedge exhibit remarkably similar performance for the specific design adopted. If this similarity holds across different designs, it offers engineers flexibility in choosing the appropriate measure based on practical needs. More generally, this work demonstrates the potential and feasibility of using metamaterials to address current and future challenges in railway transportation.

KW - ground-borne vibration

KW - vibration mitigation

KW - metamaterials

KW - metawedge

KW - railway-induced vibration

KW - wave propagation

U2 - 10.4203/ccc.7.13.8

DO - 10.4203/ccc.7.13.8

M3 - Paper

T2 - The Sixth International Conference on Railway Technology 2024

Y2 - 1 September 2024 through 5 September 2024

ER -

Performance Comparison of the Forward and Inverse Metawedge for Ground-Borne Vibration Mitigation

Abstract

Conference

Bibliographical note

Keywords

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