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Jute Composite Based Single-Leaf Structure For Sound Insulation


Affiliations
1 Department of Textile Technology, Government College of Engineering and Textile Technology, Serampore 712 201, India
2 Indian Jute Industries Research Association, Kolkata 700 088, India

The present study deals with the development of a mathematical equation that effectively predicts the sound insulation performance of a single-leaf structure constructed using jute composites with varying resin uptake ratios. The investigation employs a reference device to measure the transmission loss (TL) of sound energy as it propagates through a single-leaf structure. The objective is to investigate the impact of structural parameters, namely thickness, theoretical density, and compaction factor, on the attenuation of sound waves within the frequency range of 50–3150 Hz. It has been revealed that an increase in resin uptake, i.e. lower fibre content, is associated with a higher occurrence of voids inside the structure. The presence of voids inside the jute composites is inversely related to TL, while at a given fibre content, transmission loss is linearly related to the areal density of a single-leaf structure, regardless of the thickness of the jute composite. The derived equation for predicting the transmission loss of sound propagating through a single-leaf is expressed as the modified mass law of sound. This equation demonstrates that the mass of an individual leaf structure has a substantial effect on transmission loss, surpassing the influence of frequency. The study provides evidence that the jute composite can be engineered to achieve a degree of transmission loss that is comparable to the materials commonly used for sound insulation applications.

Keywords

Compaction factor, Jute composite, Mass law of sound, Resin transfer moulding, Single-leaf structure, Sound insulation, Transmission loss
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  • Jute Composite Based Single-Leaf Structure For Sound Insulation

Abstract Views: 63  | 

Authors

M Datta
Department of Textile Technology, Government College of Engineering and Textile Technology, Serampore 712 201, India
B Chatterjee
Department of Textile Technology, Government College of Engineering and Textile Technology, Serampore 712 201, India
P Ray
Indian Jute Industries Research Association, Kolkata 700 088, India
D Nath
Department of Textile Technology, Government College of Engineering and Textile Technology, Serampore 712 201, India

Abstract


The present study deals with the development of a mathematical equation that effectively predicts the sound insulation performance of a single-leaf structure constructed using jute composites with varying resin uptake ratios. The investigation employs a reference device to measure the transmission loss (TL) of sound energy as it propagates through a single-leaf structure. The objective is to investigate the impact of structural parameters, namely thickness, theoretical density, and compaction factor, on the attenuation of sound waves within the frequency range of 50–3150 Hz. It has been revealed that an increase in resin uptake, i.e. lower fibre content, is associated with a higher occurrence of voids inside the structure. The presence of voids inside the jute composites is inversely related to TL, while at a given fibre content, transmission loss is linearly related to the areal density of a single-leaf structure, regardless of the thickness of the jute composite. The derived equation for predicting the transmission loss of sound propagating through a single-leaf is expressed as the modified mass law of sound. This equation demonstrates that the mass of an individual leaf structure has a substantial effect on transmission loss, surpassing the influence of frequency. The study provides evidence that the jute composite can be engineered to achieve a degree of transmission loss that is comparable to the materials commonly used for sound insulation applications.

Keywords


Compaction factor, Jute composite, Mass law of sound, Resin transfer moulding, Single-leaf structure, Sound insulation, Transmission loss