We use cookies to enhance your experience. By continuing to browse this site you agree to our use of cookies. More info.

In a recent study published in the journal Applied Acoustics, researchers from Brazil analyzed pseudostem fibers extracted from banana plants as a potential sound-absorbing material.

Study:  Acoustic performance of the banana pseudostem fiber . Image Credit: PICJON/Shutterstock.com

The fibers were glued together using a natural adhesive without the use of any binders. The sound absorption coefficients were measured using an impedance tube and transfer function technique for a frequency range of 100-6300 Hz. The fibers demonstrated a coefficient of 0.89 at 6300 Hz, which was better than coconut fibers and similar to yucca fiber.

Noise pollution is a growing concern in urban and metropolitan cities. It directly or indirectly, physically or psychologically, affects human beings and their activities. This requires well-planned construction designs and efficient acoustic materials.

Acoustic materials can be classified into soundproofing materials and sound-absorbing materials. The fundamental difference between both types of materials is that soundproofing materials reflect incoming acoustic waves, whereas sound-absorbing materials absorb acoustic waves and transform them into another form of energy, such as heat.

The most commonly used sound-absorbing materials are fiberglass and rockwool. However, these materials are known to deteriorate their surrounding environment during extraction. Thus, readily available natural fibrous materials have garnered a lot of attention as sound-absorbing materials.

There are three types of sound absorbers viz. porous absorbers, membrane absorbers, and resonance absorbers. In the case of porous absorbers, sound waves flowing into the cellular or fibrous structure gradually dampen and convert into heat. Membrane absorbers are non-porous and effective below the brass frequency range. They are placed in front of a rigid wall with a certain amount of air gap. The waves pass through the membrane towards the airgap but get trapped inside. Resonance absorbers are similar to membrane absorbers except that they are rigid and perforated.

Banana plants only flower once in their lifetime. After that, they are cut down to make space for new plants. For tropical regions like Brazil, banana plants are abundant and the fibers extracted from their pseudostem are being used in paper and textile industries. Additionally, their high watery body is a result of highly porous fibers that may absorb sound effectively.

In this study, researchers fabricated three types of samples made up of banana pseudostem fibers to analyze their sound-absorbing potential. The first type of sample, sample A, consisted of only fibers of length 10 mm and 70 mm. Their sample thicknesses were 7 and 10 mm, and sample densities were 80 and 120 kg/m3, respectively. In B-type samples, fibers were glued together using natural cassava starch and water. In C-type samples, the glued samples obtained in samples B were sandwiched between two sheets made up of gypsum and water. The upper layer was perforated while the bottom layer was not.

More from AZoM: What are Photonic Coatings?

Subsequently, all three types of samples were tested in SW466 impedance tubes. The transfer function method was used to calculate the sound absorption coefficients and transmission loss coefficients. Several microphones were placed on both sides of the sample inside the tube with a sound source on one side. The analysis was performed in the frequency range of 100-6300 Hz.

All samples exhibited similar results with a maximum absorption coefficient of 0.20 up to the frequency of 1600 Hz. Above 2500 Hz, samples with higher density and higher thickness showed better sound absorption. However, with similar standards, glued samples exhibited a lower sound absorption coefficient than samples without glue.

This could be due to the reduction in the porous structure. C samples demonstrated variable coefficients at different frequency ranges without any direct correlation with the density or thickness of samples. However, C samples with equal gypsum layer thickness on either side exhibited better performance than samples with unequal gypsum layer thicknesses.

The unglued and glued samples with the highest densities and thicknesses i.e A7 and B7, respectively, demonstrated the highest sound absorption coefficient. Both samples demonstrated lower sound absorption than sisal fiber and fiberglass. However, they exhibited higher sound absorption than coconut fiber at frequencies above 4000 Hz. The C samples had the highest noise reduction coefficient.

In summary, the researchers of this study tested the sound absorption potential of banana pseudostem fiber. They prepared three types of samples with varying density and thickness viz. unglued, glued with natural cassava starch, and both unglued and glued samples sandwiched in between two gypsum sheets.

Out of two gypsum sheets, one was perforated and the other one was not perforated. The impedance tube and transfer function method revealed that the sandwiched sample with the highest sample density and thickness demonstrated the highest sound absorption coefficient. Thus, banana pseudostem fibers with high density and resonance absorber configuration i.e covered by a rigid perforated layer can be an efficient natural and eco-friendly noise reduction material.

Mendes, C., Nunes, M., Acoustic performance of the banana pseudostem fiber, Applied Acoustics 191, 2022, 108657, https://www.sciencedirect.com/science/article/abs/pii/S0003682X22000317

Disclaimer: The views expressed here are those of the author expressed in their private capacity and do not necessarily represent the views of AZoM.com Limited T/A AZoNetwork the owner and operator of this website. This disclaimer forms part of the Terms and conditions of use of this website.

Bismay is a technical writer based in Bhubaneshwar, India. His academic background is in Engineering and he has extensive experience in content writing, journal reviewing, mechanical designing. Bismay holds a Masters in Materials Engineering and BE in Mechanical Engineering and is passionate about science & technology and engineering. Outside of work, he enjoys online gaming and cooking.

Please use one of the following formats to cite this article in your essay, paper or report:

Prakash Rout, Bismay. (2022, February 15). Banana Fiber Sound Insulation. AZoM. Retrieved on March 12, 2022 from https://www.azom.com/news.aspx?newsID=58237.

Prakash Rout, Bismay. "Banana Fiber Sound Insulation". AZoM. 12 March 2022. <https://www.azom.com/news.aspx?newsID=58237>.

Prakash Rout, Bismay. "Banana Fiber Sound Insulation". AZoM. https://www.azom.com/news.aspx?newsID=58237. (accessed March 12, 2022).

Prakash Rout, Bismay. 2022. Banana Fiber Sound Insulation. AZoM, viewed 12 March 2022, https://www.azom.com/news.aspx?newsID=58237.

Do you have a review, update or anything you would like to add to this news story?

AZoM speaks to Michael Jewett, a researcher at Northwestern University, about a novel process using bacteria to capture CO2 and convert it into the useful commercial chemicals acetone and isopropanol. This could bring us closer to a circular bioeconomy in the chemical sector.

In this interview, AZoM talks to Anna Walkiewicz, Applications Specialist at Quorum Technologies, about sample coating and how it can help improve SEM imaging.

In this interview, AZoM talks to Anna Walkiewicz, Applications Specialist at Quorum Technologies, about sample coating and how it can help improve SEM imaging.

Discover the mechanical rotary level indicator, model BMR-100.

Superior Sensor’s ND Middle Pressure Series utilize Superior Sensor’s advanced Nimblesense technology, making them extremely accurate, reliable, and precise.

TESCAN’s UniTOM HR is the only micro-CT system that allows sub-micron spatial resolution as well as high temporal resolution dynamic CT, for all your materials science and earth science needs.

This article provides an end-of-life assessment of lithium-ion batteries, focusing on the recycling of an ever-growing amount of spent Li-Ion batteries in order to work toward a sustainable and circular approach to battery use and reuse.

This article provides an overview of the materials that are used to produce photovoltaic cells for the production of renewable energy, as well as new research that proposes the use of novel materials.

This article considers laser-based 3D printing, or additive manufacturing, looking at different types of lasers in the fabrication process.

AZoM.com - An AZoNetwork Site

Owned and operated by AZoNetwork, © 2000-2022