Abstract
Considering that the solid wood, being a heterogeneous and anisotropic product, presents several disadvantages such as unsatisfactory mechanical properties for certain uses and limitations of wood due to dimensions of wood pieces, reconstituted wood products have been developed by gluing of veener, boards, lignocellulosic fibers, etc., which are joined using adhesives. It should be noted that changes in adhesion to wood are desirable in terms of performance improvement and adhesive economy. Within the constant search for better performance of adhesives, the use of nanocelluloses appears as a viable option. Further, identification of reinforcement of adhesives with nanocellulose is being considered as an opportunity among the several opportunities offered by nanotechnology for the forest products industry. Use of nanocelluloses as reinforcements in adhesives for the production of reconstituted wood panels has several benefits such as possibility of altering the properties of adhesives, gain in mechanical and physical properties of panels and reduction in formaldehyde emissions by panels using synthetic adhesives. Accordingly, this chapter discusses the main types of reconstituted wood panels, types and characteristics of the adhesives employed, aspects that influence the bonding and use of additives in the glue mixture. Besides, it also addresses the use of nanocellulose and its effects on the properties of reconstituted wood panels. Despite all the advantages emntioned above, the Chapter ends with the conclusion that there are still some problems to be looked into suggesting need for more research either in the application of nanocellulose and its modification in different types of resin, as well as application technologies appropriate to the new conditions of the adhesives.
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Abdul KHPS, Tye YY, Leh CP et al (2018) Cellulose reinforced biodegradable polymer composite film for packaging applications. In: Jawaid M, Swain S (eds) Bionanocomposites for packaging applications. Springer, Cham, pp 49–64
Albino VCS, Mori FA, Mendes LM (2012) Influence of anatomical features and extractives content wood of Eucalyptus grandis w. hill ex maiden in quality bonding. Cienc Florest 22(4):803–811
Albuquerque CEC, Latorraca JV (2000) Anatomic features, influence in penetration and adhesion of adhesives. Floresta Ambient 7(1):158–166
Almeida VC (2009) Assessment of the potential for the use of tropical wood waste for the production of laterally glued panels—EGP. Federal University of Parana, Thesis
American Society for Testing and Materials (2006) ASTM D 5456: standard specification for evaluation of structural composite lumber products. ASTM, West Conshohocken
Atta-Obeng E (2011) Characterization of phenol formaldehyde adhesive and adhesive-wood particle composites reinforced with microcrystalline cellulose. Dissertation, Auburn University
Ayrilmis N (2007) Effect of panel density on dimensional stability of medium and high density fiberboards. J Mater Sci 42:8551–8557
Ayrilmis N, Lee Y-K, Kwon JH et al (2016) Formaldehyde Emission and VOCs from LVLs Produced with Three Grades of Urea-Formaldehyde Resin Modified with Nanocellulose. Build Environ 97:82–87
Baghersad S (2016) Coating os silk fabrics by PVA/Ciprofloxain HCl nanofibers for biomedical applications. Iran J Polym Sci Tech 29(2):171–184
Baldwin RF, Kurpiel FT, Baldwin RW (2017) Growth and reinvention 2017: a north american perspective on the global wood-based panel industry. Forest Prod J 67(3–4):144–151
Bianche JJ (2014) Wood-adhesive interface and joints’ resistance bonded with different adhesives and weight. Federal University of Viçosa, Thesis
Bilodeau MA, Bousfield DW (2015) Composite building products bound with cellulose nanofibers. Patent US 20,150,033,983 A1, 05 Feb 2015
Buligon EA (2015) Physical and mechanical properties of laminated veneer lumber reinforced gfrp. C Fl 25(3):731–741
Campos CI (2005) Physical-mechanical properties of MDF produced with wood fibers from reforestation and alternative adhesives at different levels. University of São Paulo, Thesis
Candan Z, Akbulut T (2015) Physical and mechanical properties of nanoreinforced particleboard composites. Maderas Cienc Tecnol 17(2):319–334
Cardoso GV, Pereira FT, Ferreira ES et al (2016) Nanocelulose occmo urea-formaldehyde catalyst for the production of agglomerated panels of Pinus sp. In: Paper presented at the XV EBRAMEM—Brazilian meeting on timber and timber structures, Brazilian Institute of Wood and Wood, Curitiba, Structures, Curitiba, 9–11 Mar 2016
Carlquist S (2001) Comparative wood anatomy. Springer, Berlim
Carvalho MZ (2016) Multivariate approach to the behavior of physical-chemical properties and characterization of natural adhesives based on tannins. Federal University of Lavras, Thesis
Carvalho L, Martins J, Costa C (2010) Transport phenomena. In: Thoemen H, Irle M, Sernek M (eds) Wood-based panels: an introduction for specialists. Brunel University Press, London, pp 123–295
Costa TG (2016) Characterization of synthetic adhesives with addition of silica nanoparticles as reinforcing filler. Federal University of Lavras, Thesis
Cui J, Lu X, Zhou X et al (2014). Enhancement of mechanical strength of particleboard using environmentally friendly pine (Pinus pinaster L.) tannin adhesives with cellulose nanofibers. Ann For Sci 72(1):27–32
Cunha RCB (2016) Implementation of a method for measuring Gel Time of formaldehyde-based resins. Dissertation, Higher Institute of Engineering of Porto
Damásio RAP, Carvalho FJB, Carneiro ACO et al (2017) Effect of CNC interaction with urea-formaldehyde adhesive in bonded joints of Eucalyptus sp. Sci For 45(113):169–176
Diem H, Mathias G, Wagner RA (2012) Amino resins. Ullmann’s Encyclopedia of Industrial Chemistry, Wiley-VCH, Weinheim
Din Z-U, Xiong H, Wang Z et al (2018) Effects of different emulsifiers on the bonding performance, freeze-thaw stability and retrogradation behavior of the resulting high amylose starch-based wood adhesive. Colloids Surf A 538(5):192–201
Ding X, Richter DL, Matuana LM et al (2011) Efficient one-pot synthesis and loading of self-assembled amphiphilic chitosan nanoparticles for low-leaching wood preservation. Carbohydr Polym 86:58–64
Ebnesajjad S, Landrock AH (2014) Adhesives technology handbook, 3rd edn. Elsevier, Amsterdã
Eckelman CA (1999) Brief survey of wood adhesives. Purdue University Cooperative Extension Service, West Lafayette
Eichhorn SJ, Dufresne A, Aranguren M et al (2010) Review: current international research into cellulose nanofibres and nanocomposites. J Mater Sci 45(1):1–33
Esteban L, Casasús AG, Oramas CP et al (2003) Wood and its anatomy. Fundación Conde de Valle de Salazar, Madrid
Ferreira JC (2017) Synthesis of urea-formaldehyde adhesives with the addition of kraft lignin and nanocrystalline cellulose. Federal University of Viçosa, Thesis
Fink J (2013) Reactive polymers Fundamentals and applications—a concise guide to industrial applications, 2nd edn. William Andrew, Norwich
Finnish Forest Industries Federation (2002) Handbook of finnish plywood. Kirjapaino Markprint Oy, Lahti
Fiorelli J (2002) Use of carbon fibers and glass fibers to reinforce wooden beams. Dissertation, São Paulo University
Food and Agriculture Organization (2018) Global production and trade of forest products in 2016. http://www.fao.org/forestry/statistics/80938/en/ Accessed 12 Mar 2018
Forestry Products Laboratory (1999) Wood handbook—wood as an engineering material. General Technical Reports FPL-GTR-113. USDA, Forest Service, Madison
Forestry Products Laboratory (2010) Wood handbook—wood as an engineering material. General Technical Reports FPL-GTR-190. USDA, Forest Service, Madison
Forestry Products Laboratory (2012) Nanocelluloses: potential materials for advanced forest products. In: Proceedings of nanotechnology in wood composites symposium. General Technical Reports FPL-GTR-218. USDA, Forest Service, Madison
Fratzl P, Weinkamer R (2007) Nature’s hierarchical materials. Prog Mater Sci 52(8):1263–1334
Fujisawa S, Okita Y, Fukuzumi H et al (2011) Preparation and characterization of TEMPO-oxidized cellulose nanofibrils films with free carboxyl groups. Carbohydr Polym 84(1):579–583
Gardziella A, Pilato LA, Knop A (2000) Phenolic resins: chemistry, applications, standardization, safety and ecology, 2nd edn. Springer, Heidelberg
Gavrilovic GI, Neskovic O, Diporovic MM et al (2010) Molar-mass distribution of urea-formaldehyde resins of different degrees of polymerisation by MALDI-TOF mass spectrometry. J Serb Chem Soc 75(5):689–99
Gindl-Altmutter W, Veigel S (2015) Nanocellulose-modified wood adhesives. In: Oksman K, Mathew AP, Bismarck A et al (eds) Handbook of green materials. World Scientific Publishing, Hackensack, pp 253–264
Gonçalvez FG (2012) Agglomerated panels of Acacia mangium wood with urea-formaldehyde adhesives and powdered tannin of Acacia mearnsii bark. Rural Federal University of Rio de Janeiro, Thesis
Gonçalvez FG, Lelis RCC (2009) Properties of two synthetic resins after addition of Modified tannin. Floresta Ambient 12(2):01–07
Grigsby WJ, Thumm A (2012) The interactions between wax and UF resin in medium density fiberboard. Eur J Wood Wood Prod 70(4):507–517
Gupta R, Kandasubramanian B (2015) Hybrid caged nanostructure ablative composites of octaphenyl-POSS/RF as heat Shields. RSC Adv 5:8757–8769
Haubrich JL, Gonçalves C, Tonet A (2007) Vinyl adhesives present solutions for wood. Rev Mad 103:66–70
Hellmeister V (2017) OSB panel of raft wood residue (Ochroma pyramidale). University of São Paulo, Thesis
Hu K, Kulkarni DD, Choi I et al (2014) Graphene-polymer nanocomposites for structural and functional applications. Prog Polym Sci 39(11):1934–1972
International Agency for Research on Cancer (2006) Formaldehyde, 2-butoxyethanol and 1-tertbutoxypropan-2-ol. IARC Monogr Eval Carcinog Risks Hum 88:1–478
International Agency for Research on Cancer (2012) Chemical agents and related occupations: a review of human carcinogens. IARC Monogr Eval Carcinog Risks Hum 100:1–628
Irle M, Barbu C (2010) Wood-based panel technology. In: Thoemen H, Irle M, Sernek (eds) Wood-based panels: an introduction for specialists. Brunel University Press, London, pp 1–94
Iwakiri S (2005) Painéis de madeira reconstituída. FUPEF, Curitiba
Iwamoto S (2009) Elastic modulus of single cellulose microfibrils from tunicate measured by atomic force microscopy. Biomacromol 10(9):2571–2576
Jonoobi M, Mathew AP, Oksman K (2012) Producing low-cost cellulose nanofiber from sludge as new source of raw materials. Ind Crops Prod 40:232–238
Kaboorani A, Riedl B, Blanchet P et al (2012) Nanocrystalline cellulose (NCC): a renewable nano-material for polyvinyl acetate (PVA) adhesive. Eur Polym J 48(11):1829–1837
Khalili SMR, Jafarkarimi MH, Abdollahi MA (2009) Creep analysis of fibre reinforced adhesives in single lap joints-experimental study. Int J Adhes Adhes 29(6):656–661
Khalili SMR, Shokuhfar A, Hoseini SD et al (2008) Experimental study of the influence of adhesive reinforcement in lap joints for composite structures subjected to mechanical loads. Int J Adhes Adhes 28(8):436–444
Khedari J, Nankongnab N, Hirunlabh J et al (2004) New low-cost insulation particleboards from mixture of durian peel and coconut coir. Build Environ 39(1):59–65
Kim MG (2000) Examination of selected synthesis parameters for typical wood adhesive-type urea-formaldehyde resins by 13C NMR spectroscopy. I. J Appl Polym Sci 75(10):1243–1254
Kinloch AJ (1987) Adhesion and adhesives: science and technology. Chapman & Hall, London
Kolakovic R, Peltonel L, Laaksonen T et al (2011) Spray-dried cellulose nanofibers as novel tablet excipient. AAPS Pharm Sci Tech 12(4):1366–1373
Lahiji RR, Xu X, Reifenberger R, Raman A, Rudie A, Moon RJ (2010) Atomic Force Microscopy Characterization of Cellulose Nanocrystals. Langmuir 26(6):4480–4488
Lam F (2001) Modern structural wood products. Prog Struct Eng Mat 3(4):238–245
Lengowski EC (2016) Formation and characterization of films with nanocellulose. Federal University of Paraná, Thesis
Lima CKP, Mori FA, Mendes LM et al (2007) Anatomic and chemical characteristics of eucalyptus clones wood and its influence upon bonding. Cerne 13(2):123–129
Liu Z, Zhang Y, Wang X et al (2015) Reinforcement of lignin-based phenol-formaldehyde adhesive with nano-crystalline cellulose (NCC): curing behavior and bonding property of plywood. Mater Sci Appl 6:567–575
Liu Y, Laks P, Heiden P (2002) Controlled release of biocides in solid wood. II. Efficacy against Trametes versicolor and Gloeophyllum trabeum wood decay fungi. J Appl Polym Sci 86(3):608–614
Lubis MAR, Hong MK, Park BD (2017) Hydrolytic removal of cured urea–formaldehyde resins in medium-density fiberboard for recycling. J Wood Chem Technol. https://doi.org/10.1080/02773813.2017.1316741
López-Suevos F, Eyholzer C, Bordeanu N et al (2010) DMA analysis and wood bonding of PVAc latex reinforced with cellulose nanofibrils. Cellulose 17(2):387–398
Mahrdt E, Pinkl S, Schmidberger C et al (2016) Effect of addition of microfibrillated cellulose to Ureaformaldehyde on selected adhesive characteristics and distribution in particle board. Cellulose 23(1):571–580
Meng Q-X, Zhu G-Q, Yu M-M et al (2018) The effect of thickness on plywood vertical fire spread. Procedia Eng 211:555–564
Messmer A (2015) Life cycle assessment (LCA) of adhesives used in wood consructions. Master thesis (Ecological System Design), Swiss Federal Institute of Technology Zurich, Swiss, Zurich p 82
Molina JC, Calil Neto C, Calil Junior C et al (2013) Evaluation of the behavior of rectangular beams (LVL) with horizontal and vertical lamination. Mad Arq Eng 14(35):1–13
Mondragon G, Peña-Rodriguez C, Gonzáles A et al (2015) Bionanocomposites based on gelatin matrix and nanocellulose. Eur Polym J 62:1–9
Motta JP, Oliveira JTS, Alves RC (2012) Influence of moisture content on the adhesion properties of eucalyptus wood. Construindo 4(2):96–103
National Institute of Industrial Research (2017) The complete technology book on wood and its derivatives. NIIR, Delhi
Nelson K, Restina T, Iakovlev M et al (2016) American process: production of low cost nanocellulose for renewable, advanced materials applications. In: Madsen L, Svedberg E (eds) Materials research for manufacturing. Springer Series in Materials Science, vol 224. Springer, Cham
Nguyen DM, Grillet A-C, Diep TMH et al (2018) Influence of thermo-pressing conditions on insulation materials from bamboo fibers and proteins based bone glue. Ind Crops Prod 111:834–845
Nitthiyah A (2013) Optimization and characterization of melamine urea formaldehyde (MUF) based adhesive with waste rubber powder (WRP) as filler. University Malaysia Pahang, Thesis
Olorunnisola AO (2018) Design of wood connections. In: Olorunnisola AO (ed) Design os structural elements with tropical hardwoods. Springer, Berlim, pp 209–236
Ozarska B (1999) A review of the utilization of hardwoods for LVL. Woood Sci Technol 33(4):341–351
Park B-D, Kang E-C, Park S-B et al (2011) Empirical correlations between test methods of measuring formaldehyde emission of plywood, particleboard and medium density fiberboard. Eur J Wood Wood Prod 69(2):311–316
Périchaud AA, Isakakov RM, Kurbatov A et al (2012) Auto-reparation of polyimide film coatings for aerospace applications challenges and perspectives. In: Abadie MJM (ed) High performance polymers—polyimides based—from chemistry to applications. InTech, London, pp 215–244
Pervan D (2018) Mechanical locking system for panels and method of installing same. US Patent 2018/0,030,738 A1, 1 Feb 2018
Peschel P, Hornhardy E, Nennewitz I et al (2016) Tabellenbuch Holztechnik. Europa-Lehrmittel Nourney, Vollmer GmbH & Co. KG, Haan
Petrie EW (2000) Handbook of adhesives andokl sealents, 2nd edn. McGraw-Hill, New York
Pizzi A (2015) Synthetic adhesives for wood panels: chemistry and technology. In: Mittal KL (ed) Progress in adhesion and adhesives. Wiley, Hoboken, pp 85–126
Polymer Properties Database (2015) Melamine-formaldehyde resins. http://polymerdatabase.com/polymer%20classes/MelamineFormaldehyde%20type.html. Accessed 30 Mar 2018
Prolongo SG, Gude MR, Ureña A (2009) Synthesis and characterisation of epoxy resins reinforced with carbon nanotubes and nanofibers. J Nanosci Nanotechnol 9(10):6181–6187
Prolongo SG, Gude MR, Ureña A (2010) Rheological behaviour of nanoreinforced epoxy adhesives of low electrical resistivity for joining carbon fiber/epoxy laminates. J Adhes Sci Technol 24(6):1097–1112
Ramage MH, Burridge H, Busse-Wicher M et al (2017) The wood from the trees: the use of timber in construction. Renew Sustain Energy Rev 68:333–359
Richter K, Bordeanu N, Lópes-Suevos F et al (2009) Performance of cellulose nanofibrils in wood adhesives. In: Schindel-Bidinelli E (ed) Proceedings of the swiss bonding. Rapperswil-Jona, Switzerland, pp 239–246
Risholm-Sundman M, Larsen A, Vestin E et al (2007) Formaldehyde emission—comparison of different standard methods. Atmospheric Environ 41(15):3193–3202
Rojas J, Bedoya M, Ciro Y (2015) Current trends in the production of cellulose nanoparticles and nanocomposites for biomedical applications. In: Polleto M (ed) Cellulose—fundamental aspects and current trends. InTech, Rijeka, pp 193–228
Rumble JR (2018) CRC handbook of chemistry and physics, 98th edn. CRC Press, Boca Raton
Salajková M, Berglund LA, Zhou Q (2012) Hydrophobic cellulose nanocrystals modified with quaternary ammonium salts. J Mater Chem 22(37):19798–19805
Samyn P, Barhoum A, Öhlund T et al (2018) Review: nanoparticles and nanostructured materials in papermaking. J Mater Sci 53(1):146–184
Schultz J, Nardin M (2003) Theories and mechanisms of adhesion. In: Pizzi A, Mittal KL (eds) Handbook of adhesive technology. Marcel Decker, New York, pp 61–75
Sehaqui H, Allais M, Zhou Q et al (2011) Wood cellulose biocomposites with fibrous structures at micro-and nanoscale. Compos Sci Technol 71(3):382–387
Sheykhi ZH, Tabarsa T, Mashkour M (2016) Effects of nano-cellulose and resine on MDF properties produced from recycled mdf using electrolise method. J Wood Forest Sci Technol 23(3):271–288
Singh A, Dawson B, Rickard C et al (2008) Light, confocal and scanning electron microscopy of wood-adhesive interface. Microsc Analy 22(3):5–8
Song J, Chen C, Zhu S et al (2018) Processing bulk natural wood into a high-performance structural material. Nature 554:224–228
Syverud K, Chinga-Carrasco G, Toledo J et al (2011) A comparative study of Eucalyptus and Pinus radiata pulp fibres as raw materials for production of cellulose nanofibrils. Carbohydr Polym 84(3):1033–1038
Tanpichai S, Quero F, Nogi M et al (2012) Effective young’s modulus of bacterial and microfibrillated cellulose fibrils in fibrous networks. Biomacromol 13(5):1340–1349
Thoemen H, Irle M, Sernek M (eds) (2010) Wood-based panels: an introduction for specialists. Brunel University Press, London
Toquarto S (2002) Random heterogeneous materials. Springer, Berlim
Turbak AF, Snyder FW, Sandberg KR (1983) Microfibrillated cellulose, a new cellulose product: Properties, uses and commercial potential. J Appl Polym Sci: Appl Polym Symp 37:815–827
Urbinati CV (2013) Influence of anatomical characteristics on cast joints of Schizolobium parayba var. Amazonicum (hyber ex. Ducke) barneby (Paricá). Thesis, Federal University of Lavras
Veigel S, Rathke J, Weigl M et al (2012) Particle board and oriented strand board prepared with nanocellulose-reinforced adhesive. J Nanomater. https://doi.org/10.1155/2012/158503
Veronez D, Farias ELP, Fraga R et al (2010) Potential for occupacional health rish for those teachers, researchers and technical workers of anatomy who are exposed to formaldehyde. InterfacEHS 5(2):63–76
Wang XM, Casilla R, Zhang Y et al (2016) Effect of extreme ph on bond durability of selected structural wood adhesives. Wood Fiber Sci 48(4):1–15
Wang X, Huang Z, Cooper P et al (2010) The ability of wood to buffer highly acidic and alkaline adhesives. Wood Fiber Sci 42(3):398–405
Wang X, Huang Z, Cooper P et al (2013) Effects of pH on lap-shear strength for aspen veneer. Wood Fiber Sci 45(3):294–302
Wegner T, Skog KE, Ince PJ et al (2010) Uses and desirable properties of wood in the 21st century. J Forest 108(4):165–173
Xu X, Yao F, Wu Q et al (2009) The influence of wax-sizing on dimension stability and mechanical properties of bagasse particleboard. Industrial Crops Produ 29(1):80–85
Yoon SH, Kim BC, Lee KH et al (2010) Improvement of the adhesive fracture toughness of bonded aluminum joints using e-glass fibers at cryogenic temperature. J Adhes Sci Technol 24(2):429–444
Yuce B, Mastrocinque E, Packianather MS et al (2014) Neural network design and feature selection using principal component analysis and Taguchi method for identifying wood veneer defects. Produm Manufac Res 2(1):291–308
Zeni M, Favero D, Pacheci K et al (2015) Preparation of microcellulose (Mcc) and nanocellulose (Ncc) from eucalyptus kraft ssp pulp. Polym Sci 1:1–5
Zeppenfeld G, Grunwald D (2005) Klebstoffe in der Holz-und Möbelindustrie. DRW-Verlag, Weinbrenner
Zhang Y, You B, Huang H et al (2008) Preparation of nanosilica reinforced waterborne silylated polyether adhesive with high shear strength. J Appl Polym Sci 109(4):2434–2441
Zhang H, Zhang J, Song S et al (2011) Modified nanocrystalline cellulose from two kinds of modifiers used for improving formaldehyde emission and bonding strength of urea-formaldehyde resin adhesive. BioResources 6:4430–4438
Zhong Y, Jing X, Wang S et al (2016) Behavior investigation of phenolic hydroxyl groups during the pyrolysis of cured phenolic resin via molecular dynamics simulation. Polym Degrad Stab 125:97–104
Zhou J, Chen J, He M et al (2016) Cellulose acetate ultrafiltration membranes reinforced by cellulose nanocrystals: preparation and characterization. J Appl Polym Sci 133(39):1–7. https://doi.org/10.1002/app.43946
Acknowledgements
At the outset, the authors express their sincere thanks to the Editors of the book (Inamuddin, Sabu Thomas, Raguvendra Mishra and Abdullah M. Asiri), particularly Prof. Inamuddin for inviting us to contribute this Chapter. The authors place on record and appreciate the kind permission given by some of the authors (who have given permission to use their figures), M/s. Elsevier Inc Publishers, IN TECH d.o.o., Rijeka (Croatia), Iran Polymer and Petrochemical Institute with the scientific cooperation of Iran Polymer Society, Royal Society of Chemistry, UK, Chemical Retrieval on the Web (CROW), Springer and Wiley Publishers to reproduce some of the figures from their publications free of charges. One of the authors (KGS) would like to thank the PPISR, Bangalore-India with whom he is associated with presently for their encouragement and interest in this collaboration.
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Lengowski, E.C., Bonfatti Júnior, E.A., Kumode, M.M.N., Carneiro, M.E., Satyanarayana, K.G. (2019). Nanocellulose-Reinforced Adhesives for Wood-Based Panels. In: Inamuddin, Thomas, S., Kumar Mishra, R., Asiri, A. (eds) Sustainable Polymer Composites and Nanocomposites. Springer, Cham. https://doi.org/10.1007/978-3-030-05399-4_35
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