Sonic Crystal Noise Barrier with Resonant Cavities for Train Brake Noise Mitigation

David Ramírez-Solana; Jaime Galiana-Nieves; Rubén Picó; Javier Redondo; Valentino Sangiorgio; Angelo Vito Graziano; Nicola Parisi

doi:10.3390/app14072753

Sonic Crystal Noise Barrier with Resonant Cavities for Train Brake Noise Mitigation

David Ramírez-Solana, Jaime Galiana-Nieves, Rubén Picó, Javier Redondo, Valentino Sangiorgio, Angelo Vito Graziano, Nicola Parisi

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

6 Citas (Scopus)

Resumen

In an experimental investigation, the development of sonic crystal noise barriers (SCNBs) is undertaken to address the issue of train brake noise (TBN), focusing on the use of local resonances in scatterers of sonic crystals. Recent research has shown that the inclusion of cavity resonators in the crystal scatterers allows for the modification of their insulating properties. In those works, it has been demonstrated that this interaction can be used to build highly insulating structures. The study proposes an SCNB design that includes a resonant cavity specifically to mitigate TBN and validates this design through experimental measures. The experiments confirm the enhanced sound insulation capabilities of SCNBs, compare them to the conventional noise barriers ones and demonstrate the applicability and effectiveness of the proposed design in real-world scenarios.

Idioma original	Inglés
Número de artículo	2753
Publicación	Applied Sciences (Switzerland)
Volumen	14
N.º	7
DOI	https://doi.org/10.3390/app14072753
Estado	Publicada - abr. 2024
Publicado de forma externa	Sí

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title = "Sonic Crystal Noise Barrier with Resonant Cavities for Train Brake Noise Mitigation",

abstract = "In an experimental investigation, the development of sonic crystal noise barriers (SCNBs) is undertaken to address the issue of train brake noise (TBN), focusing on the use of local resonances in scatterers of sonic crystals. Recent research has shown that the inclusion of cavity resonators in the crystal scatterers allows for the modification of their insulating properties. In those works, it has been demonstrated that this interaction can be used to build highly insulating structures. The study proposes an SCNB design that includes a resonant cavity specifically to mitigate TBN and validates this design through experimental measures. The experiments confirm the enhanced sound insulation capabilities of SCNBs, compare them to the conventional noise barriers ones and demonstrate the applicability and effectiveness of the proposed design in real-world scenarios.",

keywords = "3D printed, local resonances, noise barrier, numerical methods, sonic crystals",

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T1 - Sonic Crystal Noise Barrier with Resonant Cavities for Train Brake Noise Mitigation

AU - Ramírez-Solana, David

AU - Galiana-Nieves, Jaime

AU - Picó, Rubén

AU - Redondo, Javier

AU - Sangiorgio, Valentino

AU - Graziano, Angelo Vito

AU - Parisi, Nicola

PY - 2024/4

Y1 - 2024/4

N2 - In an experimental investigation, the development of sonic crystal noise barriers (SCNBs) is undertaken to address the issue of train brake noise (TBN), focusing on the use of local resonances in scatterers of sonic crystals. Recent research has shown that the inclusion of cavity resonators in the crystal scatterers allows for the modification of their insulating properties. In those works, it has been demonstrated that this interaction can be used to build highly insulating structures. The study proposes an SCNB design that includes a resonant cavity specifically to mitigate TBN and validates this design through experimental measures. The experiments confirm the enhanced sound insulation capabilities of SCNBs, compare them to the conventional noise barriers ones and demonstrate the applicability and effectiveness of the proposed design in real-world scenarios.

AB - In an experimental investigation, the development of sonic crystal noise barriers (SCNBs) is undertaken to address the issue of train brake noise (TBN), focusing on the use of local resonances in scatterers of sonic crystals. Recent research has shown that the inclusion of cavity resonators in the crystal scatterers allows for the modification of their insulating properties. In those works, it has been demonstrated that this interaction can be used to build highly insulating structures. The study proposes an SCNB design that includes a resonant cavity specifically to mitigate TBN and validates this design through experimental measures. The experiments confirm the enhanced sound insulation capabilities of SCNBs, compare them to the conventional noise barriers ones and demonstrate the applicability and effectiveness of the proposed design in real-world scenarios.

KW - 3D printed

KW - local resonances

KW - noise barrier

KW - numerical methods

KW - sonic crystals

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DO - 10.3390/app14072753

M3 - Article

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JO - Applied Sciences (Switzerland)

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Sonic Crystal Noise Barrier with Resonant Cavities for Train Brake Noise Mitigation

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