Noise Pollution Mitigation Study of Rice Husk-Ash Nanoparticle Reinforced Epoxy Resin Composites

  • O.I. Sekunowo Department of Metallurgical and Materials Engineering, University of Lagos, Akoka, Lagos. Nigeria.
  • B.O. Bolasodun Department of Metallurgical and Materials Engineering, University of Lagos, Akoka, Lagos. Nigeria.
  • G.T. Oyedepo Department of Metallurgical and Materials Engineering, University of Lagos, Akoka, Lagos. Nigeria.
  • J.Y. Oluwole Department of Metallurgical and Materials Engineering, University of Lagos, Akoka, Lagos. Nigeria.
Keywords: Environmental pollution, epoxy-resin-composite, noise, rice-husk-ash nanoparticles

Abstract

The menace of noise pollution to human health, knowledge dissemination and tranquil environment continues to
increase daily. This is not unconnected with industrialisation and multiplicity of human activities hence the need for
the development of eco-friendly materials capable of drastically reducing noise pollution. In this study, epoxy resin
composites were synthesised using rice husk ash nanoparticles (RHANP) as reinforcement varied from 5-25 wt. %.
The composites were characterised for acoustic capabilities and the results show desirable sound absorption of up
to 71.6% sound decibel mitigation at 5-15 wt. % RHANP addition. This was demonstrated by the Noise Reduction
Coefficient (NRC) of the composites in the range of 0.654-0.805 at sound frequencies of 2-6 kHz. This compare well
with most conventional acoustic panels installed on the ceiling of hospitals, conference centres and lecture
theatres. The composites were also characterised for relevant handling mechanical properties required to
guarantee damage-free installation. The outcomes indicate 35.8 MPa flexural strength, 4.3 J impact energy and
hardness of 25.1 HV. These levels of mechanical properties are adjudged sufficient for safe handling and durability
in service. The contributions of the study will significantly impart comfortability at facilities such as hospitals and
libraries that are prone to noise pollution. Furthermore, the outcomes of the study have the potential to engender
cleaner environment, value addition and a boost to the nation’s Gross Domestic Product (GDP)

References

Ali A. M., Mustafa A. R., Nawal A. and Salch M. (2013). Flexural Strength of Fiber Reinforced Composite.
International Journal of Enhanced Research in Science Technology and Engineering, 2 (1); 119-127.
Anovitz L. M. and Cole D. R. (2015). Characterisation and Analysis of Porousity and Pore Structure. Review in
Mineralogy and Geochemistry, 80 (1); 161-164.
Arenas C., Leiva, C., Luis F. and Jose V. (2010). Development of Acoustic Barriers mainly Composed of COCombustion Bottom Ash. World Coal Ash Conference, May 9-12, Denver, CO, USA.
http://www.flyash.info/ Retrieved on 16th June, 2019.
Elena V., Natalia A., Leonard A. and Alexander G. (2012). “Fly Ash Cenospheres: Composition, Morphology,
Structure and Helium Permeability”. World Coal Ash Conference, May 9-12, Denver, CO, USA.
http://www.flyash.info/ Retrieved on 15th June, 2019.
Ersoy S. and Kucuk H. (2009). Investigation of Industrial Tea-leaf Fibre Waste Material for its Absorption
Properties. Applied Acoustics, 70 (1); 215-220.
Jayamani E. and Bakri M. K. (2018). Lignocellulosic Fibres Reinforced Polymer Composites for Acoustical
Applications. Lignocellulosic Composite Materials, First Edition, Springer International Publishing,
Malaysia.
Kaila S., Singh B. K. and Kaur I. (2009). Pretreatments of Natural Fibres and their Applications as Reinforcing
Material in Polymer Composites-A Review. Polymer Engineering and Science, 49; 131-135.
Koizumi T. Tsujiuchi N. and Adachi A. (2002). The Development of Sound Absorbing Materials using Natural
Bamboo Fibres. High Performance Structures and Materials, 4; 157-166.
Kumar S., Sangwan P. R., Mor V., Dhankhar and Bidra S. (2013). Utilisation of Rice Husk and Their Ash: A Review.
Research Journal of Chemical and Environmental Sciences, 1(5); 126-129.
Laskin A., Bertram A. K., Sergey A. N. and Shiraiwa M. (2018). Predicting the Glass Transition Temperature and
Viscosity of Secondary Organic Material using Molecular Composition. Atmospheric Chemistry Physics,
18; 6331–6351.
Lazaro A. and Brouwers H. J. (2010). Nano-Silica Production by A Sustainable Process; Application In Building
Materials, 8th Symposium, Denmark.
Limi Y., Min L., Qing W. and Zhang Z. (2012). Comparison of Sizing of T700 Grade Carbon Fiber on Interfacial
Properties of Fiber/Epoxy Applied Surface Science, 263; 326-333.
Nordin M. N., Wan L. M., Zainulabidin M. N., Kassim A. S. and Aripin A. (2016). Research Finding in Natural Fibres
Sound Absorbing Material. ARPN Journal of Engineering and Applied Sciences, 11 (14); 79-85.
Oldham D., Egan C. and Cookson R. (2011). Sustainable Acoustic Absorbers from the Biomass. Applied Acoustics,
72 (6); 350-363.
Putra A., Abdullah Y. Effendy H., Farid M., Ayub R. and Py S. (2013). Utilising Sugarcane Wasted Fibres as a
Sustainable Acoustic Absorbers. Proceedia Engineering, 53; 632-638.
Rafiee E., Shahebrahimi S. Feyzi M. and Mahdi S. (2012). Optimization of Synthesis and Characterisation of Nano
Silica Produced From Rice Husk. International Nano Letters, 2; 1-8.
Rajappan, S., Bhaskaran, P., and Ravindran, P. (2017). An Insight into the Composite Materials for Passive Sound
Absorption. Journal of Applied Sciences, 17; 339-356.
Rizlan Z. and Mamat O. (2014). Process Parameters Optimisation of Silica Sand Nanoparticles Using Low Speed Ball
Milling Method. Chinese Journal of Engineering, Doi.10.1155/2014/802459.
Seddeq, H. S. (2009). Factors Influencing Acoustic Performance of Sound Absorptive Materials. Australian Journal
of Basic and Applied Science, 3; 4610-4617.
Subramani K., Rangaraj S. and Rajendran V. (2016). Influence of Ball Milling on the Particle Size and
Antomacrobial Property of Tridax Procumbens Leaf Nanoparticles. Journal of the Institution of
Engineering and Technology, Nanotechnology, 11 (1); 25-32.
Tarique A. M., Khanji H. and Mujeeb I. S. (2017). Assessment of Electricity Generation Potential and Emissions
from Rice Residues in Pakistan. 7th International Conference on Environmentally Sustainable
Development, Institute of Information Technology, Pakistan.
Wang C. and Torng J. (2001). Experimental Study of the Absorption Characteristics of some Porous Fibrous
Materials. Applied Acoustics, 62; 447-459.
Yang R., Luo C., Zhang G., Li X. and Shen Z. (2012). Extraction of Heavy Metals from E-Waste Contaminated Soils
using EDDS. Journal of Environmental Sciences, 24 (11); 1985-1994.
Yan M., Tohi S., Tomohiro Y. and Hiroyuki H. (2017). Investigation of the Flexural Properties and Failure Behaviour
of Unidirectional CF/Nylon 6 and CF/Epoxy Composites. Journal of Composite Materials, 7; 227-249.
Zhang E., Zhu M. and Wang C. (008). Parameters Optimisation in the Planetary Ball Milling of Nanostructured
Tungsten/Carbide/Cobalt Powder. International Journal of Refractory Metals and Hard Materials, 26 (4);
329-333.
Zulkifli R., Zulkarnain Z. and Nor J. (2010). Noise Control using Coconut Coir Fibre Sound Absorber with Porous
Layer Backing and Perforated Panel. American Journal of Applied Sciences, 7 (2); 260-264.
Published
2020-03-30
How to Cite
Sekunowo, O., Bolasodun , B., Oyedepo, G., & Oluwole, J. (2020). Noise Pollution Mitigation Study of Rice Husk-Ash Nanoparticle Reinforced Epoxy Resin Composites. Journal of Engineering Research, 25(1), 29-38. Retrieved from http://jer.unilag.edu.ng/article/view/980