Binderless MDF from Hydroxymethylated Kenaf Pulp

https://doi.org/10.22146/jik.34031

Nyoman J Wistara(1*), Wulan Starini(2), Fauzi Febrianto(3), Gustan Pari(4)

(1) Department of Forest Products, Faculty of Forestry, Bogor Agricultural University (IPB)
(2) Department of Forest Products, Faculty of Forestry, Bogor Agricultural University (IPB)
(3) Department of Forest Products, Faculty of Forestry, Bogor Agricultural University (IPB)
(4) Forest Products Research Center, Ministry of Environment and Forestry, Republic Indonesia
(*) Corresponding Author

Abstract


Modified lignin with improved reactivity can be a potential alternative for synthetic phenol formaldehyde resin for the adhesive of wood composite. Direct hydroxymethylation of kenaf in the present experiments was intended to increase lignin reactivity, and therefore was expected to result in satisfying properties of binderless MDF. The stem of kenaf was refined in a disk refiner and the refined fibers were hydroxymethylated in various levels of alkalinity. The concentration of NaOH during hydroxymethylation was of 3%, 6% and 12%. Wet process was applied to produce MDF (30 cm x 30 cm x 1 cm) with target density of 0.65 g/cm³. Physical and mechanical properties of MDF were measured in accordance with the standard procedure of JIS A 5905: 2003. Chemical changes in the surface of pulp and the change of board crystallinity were evaluated by FTIR-KBr method and X-Ray Diffractometry (XRD), respectively. Density, moisture content, and screw withdrawal of the board increased with increasing of NaOH concentration. Thickness swelling, water absorption, MOE and MOR increased up to 3% concentration of NaOH. The IB and heat conductivity of MDF were not influenced by NaOH concentration. Increasing OH groups due to hydroxymethylation was thought to be the origin of high water absorption and thickness swelling of the resulting boards. Higher alkalinity during hydroxymethylation stage was likely increasing cellulose crystallinity that brought about increasing board density. However, chemical modification of the fiber was thought to be more influential to the bending strength and stiffness of the resulting fiberboard. Hydroxymethylation of kenaf pulp was successfully improved board properties. Except for the moisture content, thickness swelling and internal bonding (at 0% and 3% NaOH concentration), all properties of the MDF satisfied the requirement of JIS A 5905: 2003 (type 5) standard.

 

MDF Tanpa Perekat dari Pulp Kenaf Terhidroksimetilasi

Intisari

Lignin yang telah ditingkatkan reaktifitasnya dapat menjadi bahan alternatif perekat resin sintetis fenol formaldehida. Reaktivitas lignin dapat diperbaiki melalui hidroksimetilasi. Dalam penelitian ini, batang kenaf digiling menggunakan disk refiner, dan selanjutnya dilakukan hidroksimetilasi pada beragam alkalinitas. Konsentrasi NaOH yang digunakan dalam hidroksimetilasi bervariasi dari 3%, 6% dan 12%. Proses basah diterapkan untuk membuat MDF (30 cm x 30 cm x 1 cm) dengan target kerapatan 0,65 g/cm3. Sifat fisis dan mekanis MDF diukur mengikuti  prosedur standar JIS A 5905: 2003. Perubahan gugus fungsi permukaan pulp dan tingkat kristalinitas papan masing-masing dievaluasi menggunakan FTIR-metode KBr dan difraksi sinar X (XRD). Hasil penelitian menunjukkan bahwa konsentrasi NaOH tidak mempengaruhi IB dan konduktivitas panas MDF. Kerapatan, kadar air, dan kuat pegang sekrup cenderung meningkat dengan meningkatnya konsentrasi NaOH. Pengembangan tebal, daya serap air, MOE, dan MOR meningkat sampai dengan hidroksimetilasi dalam NaOH konsentrasi 3%. Peningkatan gugus OH serat akibat hidrosimetilasi diduga meningkatkan penyerapan air dan pengembangan tebal papan yang dihasilkan. Alkalinitas hidroksimetilasi yang lebih tinggi meningkatkan gugus cincin aromatik yang menunjukkan bahwa reaksi formaldehida berlangsung dengan lebih baik. Peningkatan alkalinitas dalam hidroksimetilasi meningkatkan kristalinitas selulosa. Peningkatan kristalinitas selulosa diduga berkontribusi dalam meningkatkan kerapatan, namun perubahan gugus kimia serat diduga lebih berpengaruh terhadap MOR dan MOE dari papan serat yang dihasilkan. Hidroksimetilasi pulp kenaf berhasil meningkatkan sifat papan. Kecuali untuk kadar air, pengembangan tebal dan IB (pada hidroksimetilasi dalam 0% dan 3% NaOH), semua sifat-sifat dari MDF yang dihasilkan memenuhi persyaratan standar JIS A 5905: 2003 (tipe 5).


Keywords


chemical modification; Hibiscus cannabinus L.; hydroxymethylation; lignin; MDF

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References

Akgül M, Tonzluoglu A. 2008. Utilizing peanut husk (Arachis hypogae L.) in the manufacture of medium density iberboards. BioResource Technology 99:5590-5594.

Alonso MV, Oliet M, Rodrìguez F, Garcia J, Gilarranz MA, Rodriguez JJ. 2005. Modification of ammonium ignosulfonate by phenolathion for use in phenolic resins. Bioresource Technology 96: 1013-1018.

Arias CM. 2008. Binderless fiberboard production from Cynara cardunculus and Vitis vinifera. Dissertation. Tarragona-Spain: Departemen of Mechanical Engineering Universitat Rovira I Virgili.

Benar P, Gonçalves AR, Mandelli D, Schuchardt U. 1999. Eucalyptus organosolv lignins: Study of the hydroxymethylation and use in resols. Bioresource Technology 68(1): 11-16.

Cãpraru AM, Ungureanu E, Trincã LC, Mãluþan T, Popa VI. 2012. Chemical and spectral characteristics of annual plant lignins modified by hydroxymethylation reaction. Cellulose Chemistry and Technology, 46(9-10): 589-597

Çetin NS, Özmen N. 2003. Studies on lignin-based adhesives for particleboard panels. Turk Journal of Agriculture and orestry 27: 183-189.

Chen Y, Wan J, Zhang X, Ma Y, Wang Y. 2011. Effect of beating on recycled properties of unbleached eucalyptus cellulose fiber. Carbohydrate Polymers 87(1):730-736. doi:10.1016/j.carbpol.2011.08.051.

Ciannamea EM, Stefani PM, Ruseckaite RA. 2010. Medium-density particleboards from modified rice husks and soybean protein concentrate-based adhesives. Bioresource Technology 101:818–825

Eroglu H, Istek A, Usta M. 2001. Medium density fiberboard (MDF) manufacturing from wheat straw (Triticum aestivum L.) and straw wood mixture. Journal of Engineering Science 7(2): 305-311.

George WO, McIntyre PS. 1987. Infrared spectroscopy: Analytical chemistry by open learning. John Wiley and Sons, London.

Gonçalves AR, Benar P. 2001. Hydroxymethylation and oxidation of organosolv lignins and utilization of the products. Bioresource Technology 79:103-111.

Han G, Cheng W, Deng J, Dai C, Zhang S, Wu Q. 2009. Effect of pressurized steam treatment on selected properties of wheat straws. Industrial Crops and Products 30:48-53.

Japanese Industrial Standard. 2003. JIS A5905-2003: Fibreboards. Japan.

Karina M, Indratmoko HP, Prasetya B, Subiyakto B. 1994. Pembuatan dan karakteristik perekat lignin-phenol- formaldehida (LRF). Prosiding Seminar Ilmiah Hasil-Hasil Penelitian dan Pengembangan Puslitbang Fisika Terapan-LIPI. pp. 85-98. Subang.

Kumar KSS, Nair CPR, Ninan KN. 2008. Effect of fiber length and composition on mechanical properties of carbon fiber-reinforced polybenzoxazine. Polymers for Advanced Technologies 19(7): 895–904

Kurokochi Y, Sato M. 2015. Properties of binderless board made from rice straw: The morphological effect of particles. Industrial Crops and Products 69:55–59. doi:10.1016/j.indcrop.2015.01.044

Malutan T, Nicu R, Popa VI. 2008. Lignin modification by epoxidation. BioResources 3(4): 1371-1376.

Mansouri NEE, Salvado J. 2006. Structural characterization of technical lignins for the production of adhesives: Application to lignosulfonate, kraft, sodaanthraquinone, organosolv, and ethanol process lignins. Industrial Crops and Products 24: 8-16.

Nada AMA, El-Sakhawy M, Kamel SM. 1997. Infra-red spectroscopic study of lignins. Polymer Degradation and Stability 60: 247-251.

Nimz HH. 1983. Lignin-based wood adhesives. pp. 219-241 in Pizzi A, editor. Wood adhesives chemistry and technology. Marcell Dekker Inc., New York.

Okuda N, Sato M. 2004. Manufacture and mechanical properties of binderless boards from kenaf core. Journal of Wood Scince 50:53-61.

Pande H, Roy DN, Kant S. 2000. Tear and tensile properties of soda pulp from kenaf bast fibers. TAPPI Journal 83(6): 47.

Pizzi A. 1994. Advanced wood adhesives technology.Marcel Dekker Inc., New York.

Quintana G, Velasquez J, Betancourt S, Ganan P. 2009. Binderless fiberboard from steam exploded banana bunch. Industrial Crops and Product 29:60-66.

Ramli R, Shaler S, Jamaludin MA. 2002. Properties of medium density fiberboard from oil palm empty fruit bunch fibre. Journal of Oil Palm Research 14(2): 34-40.

Sarumaha PSH. 2008. Kualitas komposit kayu plastik dari limbah serat buah sawit dan polipropilena daur ulang. Skripsi (Tidak dipublikasikan). Universitas Sumatera Utara, Medan.

Sjöström E. 1993. Wood Chemistry: Fundamentals and Application 2nd Edition. Academic Press, Helsinki, Finland.

Velásquez JA, Ferrando F, Salvado J. 2003. Effect of kraft lignin addition in the production of binderless fiberboard from steam exploded Miscanthus sinensis.Industrial Crops and Production 18: 17-23.

Vázquez G, Freire S, Rodriguez-Bona C, Gonzalez J, Antorrena G. 1999. Structures, and reactivities with formaldehyde of some acetosolv pine lignins. Journal of Wood Chemistry and Technology 19(4): 357-378.

Vázquez G, Gonzáez J, Freire S, Antorrena G. 1997. Effect of chemical modification of lignin on the gluebond performance of lignin-phenolic resins. Bioresource Technology 60:191-198.

Widyorini R, Xu J, Watanabe T, Kawai S. 2005. Chemical changes in steam-pressed kenaf core binderless particleboard. Journal of Wood Science 51:26-32.

Xu J, Widyorini R, Yamauchi H, Kawai S. 2006. Development of binderless fiberboards from kenaf core. Journal of Wood Science 52:236-243.

Xu J, Sugawara R, Widyorini R, Han G, Kawai S. 2004. Manufacture and properties of low-density binderless particleboard from kenaf core. Journal of Wood Science 50:62-67.

Ye XP, Julson J, Kuo M, Womac A, Myers D. 2007. Properties of medium density fiberboard made from renewable biomass. Bioresource Technology 98: 1077-1084.



DOI: https://doi.org/10.22146/jik.34031

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