Browse > Article
http://dx.doi.org/10.5658/WOOD.2022.50.2.93

Effect of Different Conditions of Sodium Chloride Treatment on the Characteristics of Kenaf Fiber-Epoxy Composite Board  

SETYAYUNITA, Tamaryska (Department of Forest Product Technology, Faculty of Forestry, Universitas Gadjah Mada Jl)
WIDYORINI, Ragil (Department of Forest Product Technology, Faculty of Forestry, Universitas Gadjah Mada Jl)
MARSOEM, Sri Nugroho (Department of Forest Product Technology, Faculty of Forestry, Universitas Gadjah Mada Jl)
IRAWATI, Denny (Department of Forest Product Technology, Faculty of Forestry, Universitas Gadjah Mada Jl)
Publication Information
Journal of the Korean Wood Science and Technology / v.50, no.2, 2022 , pp. 93-103 More about this Journal
Abstract
Currently, biofibers are used as a reinforcement in polymer composites for structural elements and construction materials instead of the synthetic fibers which cause environmental problems and are expensive. One of the chemicals with a pH close to neutral that can be potentially used as a modified fiber material is sodium chloride (NaCl). Therefore, this study aims to investigate the characteristics of a composite board made from NaCl-treated kenaf fiber. A completely randomized design method was used with consideration of two factors: the content of NaCl in the treatment solution (1 wt%, 3 wt%, and 5 wt%) and the duration of immersion of fibers in the solution (1 h, 2 h, and 3 h). The NaCl treatment was conducted by soaking the fibers in the solution for different durations. The fibers were then rinsed with water until the pH of the water reached 7 and subsequently dried inside an oven at 80℃ for 6 h. Kenaf fiber and epoxy were mixed manually with the total loading of 20 wt% based on the dry weight of the fiber. Physical and mechanical properties of the fibers were then evaluated based on JIS A 5908 particleboard standards. The results showed that increasing NaCl content in the fiber treatment solution can increase the physical and mechanical properties of the composite board. The properties of fibers treated with 5 wt% NaCl for 3 h were superior with a modulus of elasticity of 2.085 GPa, modulus of rupture of 19.77 MPa, internal bonding of 1.8 MPa, thickness swelling of 3%, and water absorption of 10.9%. The contact angle of untreated kenaf fibers was 104°, which increased to 80° and 73° on treatment with 1 wt% and 5 wt% NaCl for 3 h, respectively.
Keywords
composite board; epoxy; kenaf fiber; NaCl treatment;
Citations & Related Records
Times Cited By KSCI : 4  (Citation Analysis)
연도 인용수 순위
1 Rashdi, A.A.A., Sapuan, S.M., Ahmad, M.M.H.M., Khalina, A. 2009. Water absorption and tensile properties of soil buried kenaf fibre reinforced unsaturated polyester composites (KFRUPC). Journal of Food, Agriculture & Environment 7(3-42): 908-911.
2 Saba, N., Paridah, M.T., Abdan, K., Ibrahim, N.A. 2016. Effect of oil palm nano filler on mechanical and morphological properties of kenaf reinforced epoxy composites. Construction and Building Materials 123: 15-26.   DOI
3 Rashdi, A.A.A., Sapuan, S.M., Ahmad, M.M.H.M., Khalina, A. 2010. Combined effects of water absorption due to water immersion, soil buried and natural weather on mechanical properties of kenaf fibre unsaturated polyester composites (KFUPC). International Journal of Mechanical and Materials Engineering 5(1): 11-17.
4 Sapuan, S.M., Mustapha, F., Majid, D.L., Leman, Z., Ariff, A.H.M., Ariffin, M.K.A., Zuhri, M.Y.M., Ishak, M.R., Sahari, J. 2011. Water retention in kenaf/polypropylene composites due to repeated immersion and drying conditions. Key Engineering Materials 471-472: 438-443.   DOI
5 Sharba, M.J., Leman, Z., Sultan, M.T.H., Ishak, M.R., Azmah Hanim, M.A. 2015. Effects of kenaf fiber orientation on mechanical properties and fatigue life of glass/kenaf hybrid composites. BioResources 11(1): 1448-1465.
6 Sivakumar, D., Ng, L.F., Lau, S.M., Lim, K.T. 2018. Fatigue life behaviour of glass/kenaf woven-ply polymer hybrid biocomposites. Journal of Polymers and the Environment 26(2): 499-507.   DOI
7 Tajvidi, M., Najafi, S.K., Shekaraby, M.M., Motiee, N. 2006. Effect of chemical reagents on the mechanical properties of natural fiber polypropylene composites. Polymer Composites 27(5): 563-569.   DOI
8 Van de Weyenberg, I., Ivens, J., De Coster, A., Kino, B., Baetens, E., Verpoest, I. 2003. Influence of processing and chemical treatment of flax fibres on their composites. Composites Science and Technology 63(9): 1241-1246.   DOI
9 Yahaya, R., Sapuan, S.M., Jawaid, M., Leman, Z., Zainudin, E.S. 2015. Effect of layering sequence and chemical treatment on the mechanical properties of woven kenaf-aramid hybrid laminated composites. Materials & Design 67: 173-179.   DOI
10 Yousif, B.F., Shalwan, A., Chin, C.W., Ming, K.C. 2012. Flexural properties of treated and untreated kenaf/epoxy composites. Materials & Design 40: 378-385.   DOI
11 Yusoff, R.B., Takagi, H., Nakagaito, A.N. 2016. Tensile and flexural properties of polylactic acid-based hybrid green composites reinforced by kenaf, bamboo and coir fibers. Industrial Crops and Products 94: 562-573.   DOI
12 Azwa, Z.N., Yousif, B.F. 2013. Characteristics of kenaf fibre/epoxy composites subjected to thermal degradation. Polymer Degradation and Stability 98(12): 2752-2759.   DOI
13 Hamidon, M.H., Sultan, M.T.H., Ariffin, A.H., Shah, A.U.M. 2019. Effects of fibre treatment on mechanical properties of kenaf fibre reinforced composites: A review. Journal of Materials Research and Technology 8(3): 3327-3337.   DOI
14 Asim, M., Jawaid, M., Abdan, K., Ishak, M.R. 2018. The effect of silane treated fibre loading on mechanical properties of pineapple leaf/kenaf fibre filler phenolic composites. Journal of Polymers and the Environment 26(4): 1520-1527.   DOI
15 Aziz, S.H., Ansell, M.P. 2004. The effect of alkalization and fibre alignment on the mechanical and thermal properties of kenaf and hemp bast fibre composites: Part 1 - polyester resin matrix. Composites Science and Technology 64(9): 1219-1230.   DOI
16 El-Shekeil, Y.A., Sapuan, S.M., Abdan, K., Zainudin, E.S. 2012a. Influence of fiber content on the mechanical and thermal properties of kenaf fiber reinforced thermoplastic polyurethane composites. Materials & Design 40: 299-303.   DOI
17 Chandrasekar, M., Ishak, M.R., Sapuan, S.M., Leman, Z., Jawaid, M. 2017. A review on the characterisation of natural fibres and their composites after alkali treatment and water absorption. Plastics, Rubber and Composites 46(3): 119-136.   DOI
18 Ghori, S.W., Rao, G.S. 2021. Fiber loading of date palm and kenaf reinforced epoxy composites: Tensile, impact and morphological properties. Journal of Renewable Materials 9(7): 1283-1292.   DOI
19 Jamaludin, M.A., Bahari, S.A., Zakaria, M.N., Saipolbahri, N.S. 2020. Influence of rice straw, bagasse, and their combination on the properties of binderless particleboard. Journal of the Korean Wood Science and Technology 48(1): 22-31.   DOI
20 John, M.J., Francis, B., Varughese, K.T., Thomas, S. 2008. Effect of chemical modification on properties of hybrid fiber biocomposites. Composites Part A: Applied Science and Manufacturing 39(2): 352-363.   DOI
21 Liu, W., Mohanty, A.K., Askeland, P., Drzal, L.T., Misra, M. 2004. Influence of fiber surface treatment on properties of Indian grass fiber reinforced soy protein based biocomposites. Polymer 45: 7589-7596.   DOI
22 Mahjoub, R., Yatim, J.M., Mohd Sam, A.R., Hashemi, S.H. 2014. Tensile properties of kenaf fiber due to various conditions of chemical fiber surface modifications. Construction and Building Materials 55: 103-113.   DOI
23 Paul, A., Joseph, K., Thomas, S. 1997. Effect of surface treatments on the electrical properties of low-density polyethylene composites reinforced with short sisal fibers. Composites Science and Technology 57(1): 67-79.   DOI
24 Aziz, S.H., Ansell, M.P., Clarke, S.J., Panteny, S.R. 2005. Modified polyester resins for natural fibre composites. Composites Science and Technology 65(3-4): 525-535.   DOI
25 Mardin, H., Wardana, I.N.G., Kusno, K., Wahyono, P.S. 2016a. Sea water effects on surface morphology and interfacial bonding of sugar palm fiber to sago matrix. Key Engineering Materials 724: 39-42.   DOI
26 Mardin, H., Wardana, I.N.G., Pratikto, Suprapto, W., Kamil, K. 2016b. Effect of sugar palm fiber surface on interfacial bonding with natural sago matrix. Advances in Materials Science and Engineering 2016: 9240416.
27 Mat Taib, R., Ramarad, S., Ishak, M., Rozman, H.D. 2009. Effect of immersion time in water on the tensile properties of acetylated steam-exploded acacia mangium fibers-filled polyethylene composites. Journal of Thermoplastic Composite Materials 22(1): 83-98.   DOI
28 d'Almeida, J.R.M. 2006. Analysis of cost and flexural strength performance of natural fiber-polyester composites. Polymer-Plastics Technology and Engineering 40(2): 205-215.   DOI
29 Munawar, S.S., Umemura, K., Tanaka, F., Kawai, S. 2008. Effects of alkali, mild steam, and chitosan treatments on the properties of pineapple, ramie, and sansevieria fiber bundles. Journal of Wood Science 54(1): 28-35.   DOI
30 Davoodi, M.M., Sapuan, S.M., Ahmad, D., Ali, A., Khalina, A., Jonoobi, M. 2010. Mechanical properties of hybrid kenaf/glass reinforced epoxy composite for passenger car bumper beam. Materials & Design 31(10): 4927-4932.   DOI
31 El-Shekeil, Y.A., Sapuan, S.M., Khalina, A., Zainudin, E.S., Al-Shuja'a, O.M. 2012b. Influence of chemical treatment on the tensile properties of kenaf fiber reinforced thermoplastic polyurethane composite. Express Polymer Letters 6(12): 1032-1040.   DOI
32 Geethamma, V.G., Thomas, S. 2005. Diffusion of water and artificial seawater through coir fiber reinforced natural rubber composites. Polymer Composites 26(2): 136-143.   DOI
33 Hong, C.K., Hwang, I., Kim, N., Park, D.H., Hwang, B.S., Nah, C. 2008. Mechanical properties of silanized jute-polypropylene composites. Journal of Industrial and Engineering Chemistry 14(1): 71-76.   DOI
34 Hwang, J.W., Oh, S.W. 2020. Properties of board manufactured from sawdust, ricehusk and charcoal. Journal of the Korean Wood Science and Technology 48(1): 61-75.   DOI
35 Iswanto, A.H., Hakim, A.R., Azhar, I., Wirjosentono, B., Prabuningrum, D.S. 2020. The physical, mechanical, and sound absorption properties of sandwich particleboard (SPb). Journal of the Korean Wood Science and Technology 48(1): 32-40.   DOI
36 Khan, J.A., Khan, M.A. 2015. 1 The Use of Jute Fibers as Reinforcements in Composites. In: Biofiber Reinforcements in Composite Materials, Ed. by Faruk, O. and Sain, M., Woodhead, Oxford, UK.
37 Mwaikambo, L.Y., Ansell, M.P. 2006. Mechanical properties of alkali treated plant fibres and their potential as reinforcement materials. I. Hemp fibres. Journal of Materials Science 41(8): 2483-2496.   DOI
38 Akhtar, M.N., Sulong, A.B., Radzi, M.K.F., Ismail, N.F., Raza, M.R., Muhamad, N., Khan, M.A. 2016. Influence of alkaline treatment and fiber loading on the physical and mechanical properties of kenaf/polypropylene composites for variety of aplications. Progress in Natural Science: Materials International 26(6): 657-664.   DOI
39 Anuar, H., Zuraida, A. 2011. Improvement in mechanical properties of reinforced thermoplastic elastomer composite with kenaf bast fibre. Composites Part B: Engineering 42(3): 462-465.   DOI
40 Nosbi, N., Md Akil, H., Mohd Ishak, Z.A., Abu Bakar, A. 2011. Behavior of kenaf fibers after immersion in several water conditions. BioResources 6(2): 950-960.
41 Osman, E., Vakhguelt, A., Sbarski, I., Mutasher, S. 2011. Mechanical properties of kenaf unsaturated polyester composites: Effect of fiber treatment and fiber length. Advanced Materials Research 311-313: 260-271.   DOI
42 Rai, B., Kumar, G., Diwan, R.K., Khandal, R.K. 2011. Study on effect of euphorbia coagulum on physicomechanical and fire retardant properties of polyester-banana fiber composite. Indian Journal of Science and Technology 4(4): 443-446.   DOI
43 Ramanaiah, K., Ratna Prasad, A.V., Hema Chandra Reddy, K. 2012. Effect of fiber loading on mechanical properties of borassus seed shoot fiber reinforced polyester composites. Journal of Materials and Environmental Science 3(2): 374-378.
44 Wibowo, E.S., Lubis, M.A.R., Park, B.D. 2021. Simultaneous improvement of formaldehyde emission and adhesion of medium-density fiberboard bonded with low-molar ratio urea-formaldehyde resins modified with nanoclay. Journal of the Korean Wood Science and Technology 49(5): 453-461.   DOI
45 Yousif, B.F., Wong, K.J., El-Tayeb, N.S.M. 2007. An investigation on tensile, compression and flexural properties of natural fibre reinforced polyester composites. In: Seattle, WA, USA, ASME 2007 International Mechanical Engineering Congress and Exposition (IMECE 2007), pp. 619-624.
46 Japanese Standard Association. 2003. Japanese Industrial Standard for Particleboard: JIS A 5908. Japanese Standard Association, Tokyo, Japan.
47 Ishak, M., Leman, Z., Sapuan, S., Salleh, M., Misri, S. 2009. The effect of sea water treatment on the impact and flexural strength of sugar palm fibre reinforced epoxy composites. International Journal of Mechanical and Materials Engineering 4(3): 316-320.
48 Horvath, T., Kalman, E., Kutsan, G., Rauscher, A. 1994. Corrosion of mild steel in hydrochloric acid solutions containing organophosphonic acids. British Corrosion Journal 29(3): 215-218.   DOI