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Current Applied Polymer Science

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ISSN (Print): 2452-2716
ISSN (Online): 2452-2724

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Research Article

Study of Physicochemical, Flammability and Acoustic Properties of Hookeri raphia Natural from Cameroon

Author(s): Jean de Dieu Briand Minsongui Mveh*, Rosane Angélica Ligabue, Sandra Mara Oliveira Einloft and Jeane Estela Ayres de Lima

Volume 6, Issue 1, 2023

Published on: 04 October, 2023

Page: [26 - 38] Pages: 13

DOI: 10.2174/2452271606666230801161335

Price: $65

Abstract

Introduction: The development of new materials is ultimately associated with requirements such as strength, lightness, low production cost, and raw materials from renewable sources, seeking to meet the needs, research, and development of new technologies, which value the qualification of materials from vegetable sources as natural fibers.

Methods: In this context, this study aimed to characterize the main physicochemical properties of the natural raffia fiber and its flammability and thermo-acoustic characteristics. These characterizations were performed using several techniques, such as chemical composition analysis, density, moisture adsorption, SEM-EDS, FTIR, and TGA/DTG.

Results: The results showed that the morphology of the raffia fiber presents a similar shape to the beehive. The Elemental analysis of the natural fiber of raffia shows that carbon and oxygen contents are predominant, representing a proportion of more than 90%. Furthermore, the results suggest that the fiber is composed of lignin, hemicellulose, cellulose, tannin, and extractives, with cellulose in a proportion of 80%.

Conclusion: TGA presents a profile similar to large parts of untreated vegetable fibers. The acoustic test showed excellent sound absorption coefficient (α) values at high frequencies, while the flammability test showed that natural raffia fiber is a good flame retardant.

Keywords: Raffia hookeri, thermoacoustic, flammability, lightness, natural fiber, chemical composition analysis.

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[1]
Lustosa ECB, Del Menezzi CHS, Luz SM, et al. Thermal properties of acrylonitrile-butadiene-styrene (ABS) composites reinforced with silica nanoparticles (SiO2) modified cellulose. Rev Mater 2020; 25(3)
[2]
Viapiana RP. Integrated Vehicle Project including the project for recycling. Dissertation (Master in Automotive Engineering) Polytechnic School, University of São Paulo, Brazil 2005; 152.
[3]
Bressiani IJ, Keirnert AC, Ellenberger A, Beleini UL. Vegetal fibers and composites in automotive industry. Mix Sustent 2020; 6: 129-38.
[4]
Ell Hajj N, Dheilly M, Aboura Z, Benzenggagh ML. 100% Vegetable Composites Manufacturing Process: Effect of the Particle Size of Flax Tows and the Addition of Wood Binders In: Toulouse,France: Manuscrit auteur, publié dans JNC . 2009.
[5]
Joshi SV, Drzal LT, Mohanty AK. Are natural fiber composites environmentally superior to glass fiber reinforced composites? In:Part A: Appl Sci Manuf. 2019; 35: pp. (3)371-6.
[http://dx.doi.org/10.1016/j.compositesa.2003.09.016]
[6]
Souza MA, Valet AT, Mohanty AK. Survey of low flammability plants in burned areas of Cerrado in the Federal District and analysis of their physical properties. In: Ciência Florestal v. 2019; 29: pp. (1)181-92.
[7]
Ramos YA, Da Silva ADP, Oliveira RRA, et al. Evaluation of the flammability of six native species in the southern region of Tocantins. J Biotechnol Biodivers 2019; 7(4): 443-8.
[http://dx.doi.org/10.20873/jbb.uft.cemaf.v7n4.ramos]
[8]
Ribeiro M L, Ladchumanandasivam R, Galvão OA, Balarmino DD. Flammability and flame retardancy of the composite: Pineapple fiber reinforced unsaturated polyester (PALF). Holos 2013; 1(29)
[9]
Diogenes MS. Natural fibers as sound insulation. Rev Cienc Exatas Tecnol 2017; 12(12): 41-4.
[10]
Antoniassi SM, Neto FBP, Marques SAV, Filho OHR. Aplication of techniques to evaluate the acoustic quality of an auditorium. Rev Cereus 2019; 11(3)
[11]
Foadieng E, Talla P, Fogue K, Mabekou M, Sinju S. Contribution to the Study of the Anatomy and Physical Properties of Bamboo from Raphia Vinifera (Arecaceae). Scientif Techn J Forest Environ Congo Basin 2014; 3: 9-18.
[12]
Mann G, Wendl H. Raphia hookeri, Protabase Affichage In: france:Monpellier, cedex 2002.
[13]
Namondo VB, Etapape PE, Foba-Tendo J, Yollandev CF, Nsom VM. Nzegge Extraction and physicochemical characterization of lignin from Cameroon’s tree raffia palm species (raffia farinifera, raffia hookeri, and raffia vinífera) and Africa Oil Plam (OPEFB). J Mater Sci Appl 2019; 5(2): 18-28.
[14]
Kong-Win Chang J, Duret X, Berberi V, Zahedi-Niaki H, Lavoie JM. Two-step thermochemical cellulose hydrolysis with partial neutralization for glucose production. Front Chem 2018; 6: 117.
[http://dx.doi.org/10.3389/fchem.2018.00117] [PMID: 29740574]
[15]
Quintiere JG, Lyon RE, Dowey BP. An Investigation of the UL-94V Plastics Flammability Test. Sixth International Seminar on Fire and Explosion Hazards 2011.
[http://dx.doi.org/10.3850/978-981-08-7724-8_15-03]
[16]
AMERICAN SOCIETY FOR TESTING AND MATERIALS – ASTM Standard Test Method for Impedance and Absorption of Acoustical Materials by the Impedance Tube Method ASTM 2018.
[17]
AMERICAN SOCIETY FOR TESTING AND MATERIALS – ASTM Standard Test Method for Steady-State Thermal Transmission Properties by an average of the Heat Flow Meter Apparatus https://www.astm.org/c0518-21.html2010
[18]
Nisar M, Thue PS, Maghous MB, Geshev J, Lima EC, Einloft S. Polysulfone metal-activated carbon magnetic nanocomposites with enhanced CO2 capture. RSC Advances 2020; 10(57): 34595-604.
[http://dx.doi.org/10.1039/D0RA06805E] [PMID: 35514388]
[19]
Cailliez F, Gril J, Thibaut B. Wood, eco-material par excellence. Magazine the wood 2002; 578.
[20]
Monteiro O, Pereira PR, Abreu SH. Compositional analysis by infrared spectroscopy of the lignin of eucalyptus urophyptus s.t. blake treated with growth regulators. BBR-Biochemistry and Biotechnology Reports 2012; 1(2): 48-56.
[21]
Klock U, Moniz BG, Andrade SA. Wood chemistry. In: Curitiba: Universidade Federal do Paraná 2005.
[22]
Fang JM, Sun RC, Tomkinson J, Fowler P. Acetylation of wheat straw hemicellulose b in a new non-aqueous swelling system. Carbohydr Polym 2000; 41(4): 379-87.
[http://dx.doi.org/10.1016/S0144-8617(99)00102-2]
[23]
Catto AL. Resistance to Natural Weathering and Fungal Attack of Polymer Composites - wood, Porto Alegre. In: Thesis (Doctorate in Materials Science and Engineering) School of Engineering, Federal University of Rio Grande do Sul, Brazil 2015.
[24]
Morais SAL, Nascimento EA, Melo DC. Analysis of Pinus oocarpa wood part I: Study of macromolecular constituents and volatile extractives. Rev Arvore 2005; 29(3): 461-70.
[http://dx.doi.org/10.1590/S0100-67622005000300014]
[25]
Franco JP. Use of Babassu Coconut Epicarp Fiber in Epoxy Matrix Composite. In: Natal: Study done on fiber treatment . 2010.
[26]
Smith B. Infrared Spectral Interpretation. In: A Systematic Approach. Boca Raton, FL: CRC Press 1999.
[27]
Thue PS, Adebayo MA, Lima EC, et al. Preparation, characterization and application of microwave-assisted activated carbons from wood chips for removal of phenol from aqueous solution. J Mol Liq 2016; 223: 1067-80.
[http://dx.doi.org/10.1016/j.molliq.2016.09.032]
[28]
Thue PS, dos Reis GS, Lima EC, et al. Activated carbon obtained from Sapelli wood sawdust by microwave heating for O-cresol adsorption. Res Chem Intermed 2016; 43: 1063-87.
[http://dx.doi.org/10.1007/s11164-016-2683-8]
[29]
Thue PS, Lima EC, Sieliechi JM, et al. Effects of first-row transition metals and impregnation ratios on the physicochemical properties of microwave-assisted activated carbons from wood biomass. J Colloid Interface Sci 2017; 486: 163-75.
[http://dx.doi.org/10.1016/j.jcis.2016.09.070] [PMID: 27697654]
[30]
Bianchi O, Dal Castel C, Ricardo V B O, Beruoli TP, Hilling E. Evaluation of non-isothermic wood degradation through thermogravimetry- TGA/ polymers 2010; 20(10): 20.
[31]
Wu Y, Dollimore D. Kinetic studies of thermal degradation of natural cellulosic materials. Thermochim Acta 1998; 324(1-2): 49-57.
[http://dx.doi.org/10.1016/S0040-6031(98)00522-X]
[32]
Dallel M. Evaluation of the textile potential of Alfa fibers (Stipa TenacissimaL.): Physico-chemical characterization of the yarn fiber. Mulhouse Doctorate Theses in Process Engineering Physics and Textile Mechanics Laboratory (LPMT) 2012.
[33]
Kandemir A, Pozegic TR, Hamerton I, Eichhorn SJ, Longana ML. Characterisation of natural fibres for sustainable discontinuous fibre composite materials. Materials 2020; 13(9): 2129.
[http://dx.doi.org/10.3390/ma13092129] [PMID: 32375396]
[34]
Longuetaud F, Mothe F, Santenoise P, et al. Exploratory study of density - Influence of the "filling rate" of water in fresh wood. Technical appointments Méthodes
[35]
Tita SPS, De Paiva JMF. Impact resistance and other properties of lignocellulosic composites: phenolic thermosetting matrices reinforced with sugar bagasse fibrs. Polymers Science and technology 2002; 12(4): 228-39.
[36]
Feitosa D, Pereira B, Bastos C. Characterization of polypropylene-based composites reinforced with sugarcane bagasse fiber. Congresso Brasileiro de Poliméros 2012.
[37]
Silveira LHC, Rezende AV, Vale AT. Moisture content and basic wood density of nine commercial Amazonian species. Acta Amazon 2013; 43(2): 179-84.
[http://dx.doi.org/10.1590/S0044-59672013000200007]
[38]
Greff de Lima P. Sound absorption of coated materials rio de janeiro. Dissertation (Master of Science in Mechanical Engineering) 1999.
[39]
Bonduelle MG. Thermal Properties of Wood. Convection 2008.
[40]
Etuk SE, Apkabio LE, Apkabio KE. Investigation of raphia hookeri trunk as potential ceiliving material for passively cooled building design. J Ghana Sci 2003; (43): 3-7.
[41]
FINSA Fireproof Solution. 2014. Available From : http://www.finsa.com [Accessed on: 20 April 2014].
[42]
Petriccione M. Flammability of the litter of various plant species in the mediterranean environment. In: Thesis (Doctorate in Applied Biology) Napoli: Federico II University of Naples 2006.
[43]
Gallo BJ, Agnelli M. Aspects of the behavior of polymers in fire conditions. In: Polym Sci Technol. 1998; pp. 23-38.
[44]
Valette JC. Inflammabilities of mediterranean species. In: Research and Development of the European Commission European School of Climatology and Natural Hazards . 1992.

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