Tehran University of Medical Sciences

Science Communicator Platform

Stay connected! Follow us on X network (Twitter):
Share this content! On (X network) By
Impact of Layout Sequence of the Natural and Synthetic Adsorbents in Double-Layered Composites on Improving the Natural Fiber Acoustic Performance Using the Numerical Finite Element Method



Keyvani S1 ; Esmaielpour MM1 ; Fasihramandi F1 ; Asour AA1, 2 ; Kolahdouzi M1 ; Hashemi Z3
Authors
Show Affiliations
Authors Affiliations
  1. 1. Department of Occupational Health Engineering, School of Health, Tehran University of Medical Sciences, Tehran, Iran
  2. 2. Department of Occupational Health Engineering, School of Health, Sabzevar University of Medical Sciences, Razavi Khorasan, Iran
  3. 3. Department of Occupational Health Engineering, School of Health, Behbahan University of Medical Sciences, Khuzestan, Iran

Source: Journal of Health and Safety at Work Published:2021

Abstract

Introduction: The acoustic performance of natural fiber adsorbents has been investigated in numerous studies. A part of these materials show a poor adsorption within the frequency range of less than 1000 Hz. In the present study, attempts were made to investigate the effect of layout sequence of double-layered composites consisting of natural and synthetic fibers on improving the acoustic adsorption coefficient of natural fiber in the low-frequency range (63 to 1000 Hz) using the numerical finite element method. Material and Methods: In this study, the finite element method and the Johnson-Champoux-Allard model in COMSOL software version 5.3a were used to investigate the acoustic performance of the double-layered composites consisting of natural and synthetic adsorbents. The acoustic absorbers under study included date palm fiber, polyurethane foam and cellular rubber. Each double-layered composite included a date palm fiber with 10mm in thickness and a synthetic adsorbent (polyurethane foam or cellular rubber) with 10mm in thickness. In sum, four double-layered composite structures with different layouts of adsorbents in each structure were studied. Results: The location of natural fiber can play a critical role in the acoustic performance of the double-layered composite structures such that comparing the studied double-layered composites revealed that when the natural fiber was the first layer exposed to the normal sound in the double-layered composites with 20mm in thickness, the trend of acoustic performance was approximately the same as the single-layered composite of natural fiber with 20mm in thickness; but in the composite structures, when the synthetic adsorbent was the first layer exposed to the sound, the trend of acoustic absorption was improved. Conclusion: On the basis of the results, the double-layered composite structure with a higher-density and lower-porosity upper layer showed a better acoustic absorption trend than the single-layered composite including the natural adsorbent. © 2021, Tehran University of Medical Sciences. All rights reserved.
Related Docs
View other Related Docs
1. Mathematical and Experimental Investigation of Sound Absorption Behavior of Sustainable Kenaf Fiber at Low Frequency, International Journal of Environmental Science and Technology (2021)
2. Acoustical, Thermal, and Mechanical Performance of Typha Latifolia Fiber Panels: Experimental Evaluation and Modeling for Sustainable Building Applications, Journal of Building Engineering (2025)
3. Estimation of Sound Absorption Behavior of Combined Panels Comprising Kenaf Fibers and Micro-Perforated Plates Below 2500 Hertz, Journal of Health and Safety at Work (2022)
Experts (# of related papers)
View all Related Experts
Mohammad Reza Monazzam-Esmaeelpour (8)
Farideh Golbabaei (1)
Other Related Docs
4. Use of Date Palm Waste Fibers As Sound Absorption Material, Journal of Building Engineering (2021)
5. Pistachio Shell Waste As a Sustainable Sound Absorber: An Experimental and Empirical Investigation, International Journal of Environmental Science and Technology (2024)
6. Sound Absorption Performance of Natural Fiber Composite From Chrome Shave and Coffee Silver Skin, Applied Acoustics (2021)
7. Sound Absorption Characteristics of Aluminosilicate Fibers, International Journal of Environmental Science and Technology (2022)
8. Sound Absorption of Wood-Wool Cement Absorbers, Journal of Health and Safety at Work (2023)
9. Sound Absorption and Thermal Insulation Performance of Sustainable Fruit Stone Panels, Applied Acoustics (2024)
10. Acoustic and Thermal Performance of Luffa Fiber Panels for Sustainable Building Applications, Building and Environment (2024)
11. A Novel Acoustic Micro-Perforated Panel (Mpp) Based on Sugarcane Fibers and Bagasse, Journal of Materials Science: Materials in Engineering (2024)
12. Effect of Production and Application Parameters on Acoustic Performance of Wood Wool Cement Panels, Journal of Health and Safety at Work (2024)
13. Determining the Optimal Mesh for Making Acoustic Absorber From Arundo Donax Reed Stem, Journal of Health and Safety at Work (2023)
14. Study of the Effect of Shape on Acoustic Performance of Micro Perforated Absorbent at Low Frequencies, Journal of Health and Safety at Work (2022)
15. Waste Corn Husk Fibers for Sound Absorption Applications, Canadian Acoustics - Acoustique Canadienne (2023)
16. Wood Chip Sound Absorbers: Measurements and Models, Applied Acoustics (2024)
17. Investigating the Acoustic and Morphological Performance of Arundo Donax Reed Particles Treated by Using Sodium Hydroxide (Naoh), International Journal of Environmental Science and Technology (2024)
18. Acoustic and Thermal Performance of Wood Strands-Rock Wool-Cement Composite Boards As Eco-Friendly Construction Materials, Construction and Building Materials (2024)
19. Feasibility Study of Silica Aerogel Nanocomposites Application to Enhance Acoustic Properties, Iranian Journal of Health and Environment (2020)
20. Estimation of Sound Absorption Performance of Complex Perforated Panel Absorbers by Numerical Finite Element Method and Examinining the Role of Different Layouts Behind It, Fluctuation and Noise Letters (2019)
21. Providing an Optimal Porous Absorbent Pattern to Reduce Mid to Low-Frequency Sounds, Journal of Environmental Health Science and Engineering (2018)
22. Enhancing Sound Absorption in Micro-Perforated Panel and Porous Material Composite in Low Frequencies: A Numerical Study Using Fem, Sound and Vibration (2024)