Sound absorption coefficient of coal bottom ash concrete for railway application

The potential utilization of boiler slag generated in large amounts from pulverized-coal-combustion (PCC) power plants has recently drawn much attention due to the serious problems caused to ecosystems. In order to make maximal use of the boiler slag and reduce the environmental risk it poses, this study focused on manufacturing acoustic materials using boiler slag from Chinese PCC power plants. Three promising acoustic materials were successfully manufactured from up to 80% boiler slag with different grain sizes, with the addition of 20% Portland cement. The density and compressive strength of the products were inversely proportional and the sound absorption coefficient was positively proportional to the grain size of the boiler slag. The best sound absorption coefficient was obtained in products made from the coarsest fraction of the boiler slag (MS-C). Nonetheless, all the boiler-slag-based acoustic products still demonstrated compressive strength and densities comparable to those of other acoustic materials made of Spanish bottom ash or other conventional/recycled materials. The acoustic products made from the coarsest fraction (MS-C) and medium fraction (MS-M) of the boiler slag presented good noise absorption characteristics, like those of the commercial coarse porous cement that is traditionally used as an acoustic product. Furthermore, the acoustic products were characterized by very low leach ability of potentially hazardous elements. Consequently, the manufacture of acoustic materials is a very promising application for boiler slag. On the one hand, it consumes huge amounts of boiler slag that is generated in large amounts in China. On the other hand, the acoustic products can be used extensively to produce road acoustic barriers with a high sound absorption efficiency, no significant physical or mechanical limitations and no environmental implication.

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Acoustic Panels Made of Paper Sludge and Clay Composites

Sustainability ◽

10.3390/su13020637 ◽

2021 ◽

Vol 13 (2) ◽

pp. 637

Author(s):

Tomas Astrauskas ◽

Tomas Januševičius ◽

Raimondas Grubliauskas

Keyword(s):

Absorption Coefficient ◽

Sound Absorption ◽

Composite Panel ◽

Sound Absorption Coefficient ◽

Core Material ◽

Paper Sludge ◽

Frequency Range ◽

Absorption Properties ◽

Air Gaps ◽

The Core

Studies on recycled materials emerged during recent years. This paper investigates samples’ sound absorption properties for panels fabricated of a mixture of paper sludge (PS) and clay mixture. PS was the core material. The sound absorption was measured. We also consider the influence of an air gap between panels and rigid backing. Different air gaps (50, 100, 150, 200 mm) simulate existing acoustic panel systems. Finally, the PS and clay composite panel sound absorption coefficients are compared to those for a typical commercial absorptive ceiling panel. The average sound absorption coefficient of PS-clay composite panels (αavg. in the frequency range from 250 to 1600 Hz) was up to 0.55. The resulting average sound absorption coefficient of panels made of recycled (but unfinished) materials is even somewhat higher than for the finished commercial (finished) acoustic panel (αavg. = 0.51).

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Air permeability and sound absorption coefficient changes from ultrasonic treatment in a cross section of Malas (Homalium foetidum)

Journal of Wood Science ◽

10.1186/s10086-020-01940-w ◽

2021 ◽

Vol 67 (1) ◽

Author(s):

Chun-Won Kang ◽

Eun-Suk Jang ◽

Nam-Ho Lee ◽

Sang-Sik Jang ◽

Min Lee

Keyword(s):

Absorption Coefficient ◽

Ultrasonic Treatment ◽

Sound Absorption ◽

Gas Permeability ◽

Treated Wood ◽

Untreated Wood ◽

Sound Absorption Coefficient ◽

Permeability Constant ◽

Average Value ◽

Permeability Increase

AbstractWe investigated the effect of ultrasonic treatment on Malas (Homalium foetidum) gas permeability and sound absorption coefficient using the transfer function method. Results showed a longitudinal average Darcy permeability constant of 2.02 (standard deviation SD 0.72) for untreated wood and 6.15 (SD 3.07) for ultrasound-treated wood, a permeability increase of 3.04 times. We also determined the average sound absorption coefficients in the range of 50 to 6.4 kHz and NRC (noise reduction coefficient: average value of sound absorption coefficient value at 250, 500, 1000, and 2000 Hz) of untreated Malas. Those values were 0.23 (SD 0.02) and 0.13 (SD 0.01), respectively, while those of ultrasonic-treated Malas were 0.28 (SD 0.02) and 0.14 (SD 0.02), a 19.74% increase in average sound absorption coefficient.

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Research of Possibilities of Using the Recycled Materials Based on Rubber and Textiles Combined with Vermiculite Material in the Area of Noise Reduction

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.1001.171 ◽

2014 ◽

Vol 1001 ◽

pp. 171-176 ◽

Cited By ~ 4

Author(s):

Pavol Liptai ◽

Marek Moravec ◽

Miroslav Badida

Keyword(s):

Absorption Coefficient ◽

Standing Wave ◽

Sound Pressure Level ◽

Sound Absorption ◽

Sound Pressure ◽

Sound Level ◽

Pressure Level ◽

Sound Absorption Coefficient ◽

Physical Parameters ◽

Materials Research

This paper describes possibilities in the use of recycled rubber granules and textile materials combined with vermiculite panel. The aim of the research is the application of materials that will be absorbing or reflecting sound energy. This objective is based on fundamental physical principles of materials research and acoustics. Method of measurement of sound absorption coefficient is based on the principle of standing wave in the impedance tube. With a sound level meter is measured maximum and minimum sound pressure level of standing wave. From the maximum and minimum sound pressure level of standing wave is calculated sound absorption coefficient αn, which can take values from 0 to 1. Determination of the sound absorption coefficient has been set in 1/3 octave band and in the frequency range from 50 Hz to 2000 Hz. In conclusion are proposed possibilities of application of these materials in terms of their mechanical and physical parameters.

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Using the acoustic method for measuring the sound absorption coefficient to predict the durability (heat resistance) of heat-resistant concretes

NOVYE OGNEUPORY (NEW REFRACTORIES) ◽

10.17073/1683-4518-2020-12-43-48 ◽

2021 ◽

pp. 43-48

Author(s):

R. Stonys ◽

A. Jagniatinskis ◽

J. Malaiškienė ◽

J. Škamat ◽

V. Antonovič ◽

...

Keyword(s):

Absorption Coefficient ◽

Heat Resistance ◽

Sound Absorption ◽

Acoustic Method ◽

Sound Absorption Coefficient ◽

Heat Resistant

.

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Performance Testing for Sound Absorption Coefficient by Using Impedance Tube

Research Journal of Applied Sciences Engineering and Technology ◽

10.19026/rjaset.11.1706 ◽

2015 ◽

Vol 11 (2) ◽

pp. 185-189 ◽

Cited By ~ 4

Author(s):

J. Niresh ◽

S. Neelakrishna ◽

S. Subharan ◽

R. Prabhakaran

Keyword(s):

Absorption Coefficient ◽

Sound Absorption ◽

Performance Testing ◽

Sound Absorption Coefficient ◽

Impedance Tube

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Study on the sound absorption behavior of multi-component polyester nonwovens: experimental and numerical methods

Textile Research Journal ◽

10.1177/0040517518811940 ◽

2018 ◽

Vol 89 (16) ◽

pp. 3342-3361 ◽

Cited By ~ 7

Author(s):

Tao Yang ◽

Ferina Saati ◽

Kirill V Horoshenkov ◽

Xiaoman Xiong ◽

Kai Yang ◽

...

Keyword(s):

Numerical Methods ◽

Absorption Coefficient ◽

Empirical Model ◽

Surface Impedance ◽

Sound Absorption ◽

Low Frequency ◽

Accurate Method ◽

Small Error ◽

Sound Absorption Coefficient ◽

Acoustical Properties

This study presents an investigation of the acoustical properties of multi-component polyester nonwovens with experimental and numerical methods. Fifteen types of nonwoven samples made with staple, hollow and bi-component polyester fibers were chosen to carry out this study. The AFD300 AcoustiFlow device was employed to measure airflow resistivity. Several models were grouped in theoretical and empirical model categories and used to predict the airflow resistivity. A simple empirical model based on fiber diameter and fabric bulk density was obtained through the power-fitting method. The difference between measured and predicted airflow resistivity was analyzed. The surface impedance and sound absorption coefficient were determined by using a 45 mm Materiacustica impedance tube. Some widely used impedance models were used to predict the acoustical properties. A comparison between measured and predicted values was carried out to determine the most accurate model for multi-component polyester nonwovens. The results show that one of the Tarnow model provides the closest prediction to the measured value, with an error of 12%. The proposed power-fitted empirical model exhibits a very small error of 6.8%. It is shown that the Delany–Bazley and Miki models can accurately predict surface impedance of multi-component polyester nonwovens, but the Komatsu model is less accurate, especially at the low-frequency range. The results indicate that the Miki model is the most accurate method to predict the sound absorption coefficient, with a mean error of 8.39%.

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