Noise reduction with 3D printed acoustic metamaterial

Harmful effects of noise pollution on people’s mental and physical health have been on the rise in densely populated cities such as Singapore and Hong Kong. This noise pollution commonly originates from vehicular and traffic noises and construction. This is particularly prevalent in tropical cities...

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Main Author: Wong, Yi Kuan
Other Authors: Fan Zheng, David
Format: Final Year Project
Language:English
Published: Nanyang Technological University 2021
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Online Access:https://hdl.handle.net/10356/150679
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1506792021-06-09T13:58:28Z Noise reduction with 3D printed acoustic metamaterial Wong, Yi Kuan Fan Zheng, David School of Mechanical and Aerospace Engineering ZFAN@ntu.edu.sg Engineering::Mechanical engineering Harmful effects of noise pollution on people’s mental and physical health have been on the rise in densely populated cities such as Singapore and Hong Kong. This noise pollution commonly originates from vehicular and traffic noises and construction. This is particularly prevalent in tropical cities where houses tend to have casement windows which is opened to provide ventilation for people’s homes and closed to prevent external noise pollution from entering their homes. However, there has not been a commercially viable method where both ventilation and noise attenuation can be achieved. With this in mind, the Noise Reducing Ventilation Unit (NRVU) is conceived. By making use of 3D printed metamaterials to harness the Helmholtz Resonance Principle, the NRVU is cost-effective product that provides ventilation with noise reduction capability. The Helmholtz Resonance Principle works by assigning a negative effective bulk modulus to air, which creates an evanescent wave. This wave does not propagate thus sound waves cannot propagate through the NRVU, resulting in sound attenuation. The NRVU will be made up of an array of cells that can be tessellated such as triangles, squares and hexagons. Each cell will then be assigned with different resonant frequencies to provide a low frequency broadband noise attenuation effect. Experiments and simulations were first done using a hexagonal NRVU cell with 4-mm and 6-mm diameter holes. Subsequently, square and triangular NRVU of 6mm diameter holes were used. The results showed that hexagonal, square and triangle NRVU cells with 6mm holes were capable of achieving sound attenuation levels 6%, 4% and 7% of source output in RMS Voltage. Bachelor of Engineering (Mechanical Engineering) 2021-06-09T13:58:28Z 2021-06-09T13:58:28Z 2021 Final Year Project (FYP) Wong, Y. K. (2021). Noise reduction with 3D printed acoustic metamaterial. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/150679 https://hdl.handle.net/10356/150679 en application/pdf Nanyang Technological University
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Mechanical engineering
spellingShingle Engineering::Mechanical engineering
Wong, Yi Kuan
Noise reduction with 3D printed acoustic metamaterial
description Harmful effects of noise pollution on people’s mental and physical health have been on the rise in densely populated cities such as Singapore and Hong Kong. This noise pollution commonly originates from vehicular and traffic noises and construction. This is particularly prevalent in tropical cities where houses tend to have casement windows which is opened to provide ventilation for people’s homes and closed to prevent external noise pollution from entering their homes. However, there has not been a commercially viable method where both ventilation and noise attenuation can be achieved. With this in mind, the Noise Reducing Ventilation Unit (NRVU) is conceived. By making use of 3D printed metamaterials to harness the Helmholtz Resonance Principle, the NRVU is cost-effective product that provides ventilation with noise reduction capability. The Helmholtz Resonance Principle works by assigning a negative effective bulk modulus to air, which creates an evanescent wave. This wave does not propagate thus sound waves cannot propagate through the NRVU, resulting in sound attenuation. The NRVU will be made up of an array of cells that can be tessellated such as triangles, squares and hexagons. Each cell will then be assigned with different resonant frequencies to provide a low frequency broadband noise attenuation effect. Experiments and simulations were first done using a hexagonal NRVU cell with 4-mm and 6-mm diameter holes. Subsequently, square and triangular NRVU of 6mm diameter holes were used. The results showed that hexagonal, square and triangle NRVU cells with 6mm holes were capable of achieving sound attenuation levels 6%, 4% and 7% of source output in RMS Voltage.
author2 Fan Zheng, David
author_facet Fan Zheng, David
Wong, Yi Kuan
format Final Year Project
author Wong, Yi Kuan
author_sort Wong, Yi Kuan
title Noise reduction with 3D printed acoustic metamaterial
title_short Noise reduction with 3D printed acoustic metamaterial
title_full Noise reduction with 3D printed acoustic metamaterial
title_fullStr Noise reduction with 3D printed acoustic metamaterial
title_full_unstemmed Noise reduction with 3D printed acoustic metamaterial
title_sort noise reduction with 3d printed acoustic metamaterial
publisher Nanyang Technological University
publishDate 2021
url https://hdl.handle.net/10356/150679
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