Physical and mechanical properties of nanoreinforced particleboard composites

Novel composite materials having desired performance properties can be developed by nanotechnology. The major objective of this research was to produce nanomaterial- reinforced particleboard composites with enhanced physical and mechanical performance. Urea formaldehyde adhesive used to produce part...

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Autores principales: Candan,Zeki, Akbulut,Turgay
Lenguaje:English
Publicado: Universidad del Bío-Bío 2015
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Acceso en línea:http://www.scielo.cl/scielo.php?script=sci_arttext&pid=S0718-221X2015000200010
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spelling oai:scielo:S0718-221X20150002000102015-06-17Physical and mechanical properties of nanoreinforced particleboard compositesCandan,ZekiAkbulut,Turgay Nanoparticles nanoreinforced adhesives nanoscience nanotechnology particleboard wood composites Novel composite materials having desired performance properties can be developed by nanotechnology. The major objective of this research was to produce nanomaterial- reinforced particleboard composites with enhanced physical and mechanical performance. Urea formaldehyde adhesive used to produce particleboard composites was reinforced with nanoSiO2, nanoAl2O3, and nanoZnO at loading level of 0%, 1%, and 3%. To evaluate physical properties density, thickness swelling, water absorption, and equilibrium moisture content were determined while modulus of rupture, modulus of elasticity, bonding strength, and screw withdrawal strength tests were carried out to evaluate mechanical properties of the particleboard composites. The results acquired in this work revealed that nanomaterial reinforcement technique significantly affected the physical and mechanical performance properties of the particleboard composites. The findings showed that the modulus of rupture, modulus of elasticity, bonding strength, and screw withdrawal resistance of the composites improved by all the nanomaterials used in this study, except 3% nanoZnO. It was also determined that using 1% nanoSiO2 or 1% nanoAl2O3 in the composites had the best results in the bonding strength and screw withdrawal resistance. The findings indicate that it is possible to produce novel wood composites by using proper nanomaterial type and loading level.info:eu-repo/semantics/openAccessUniversidad del Bío-BíoMaderas. Ciencia y tecnología v.17 n.2 20152015-04-01text/htmlhttp://www.scielo.cl/scielo.php?script=sci_arttext&pid=S0718-221X2015000200010en10.4067/S0718-221X2015005000030
institution Scielo Chile
collection Scielo Chile
language English
topic Nanoparticles
nanoreinforced adhesives
nanoscience
nanotechnology
particleboard
wood composites
spellingShingle Nanoparticles
nanoreinforced adhesives
nanoscience
nanotechnology
particleboard
wood composites
Candan,Zeki
Akbulut,Turgay
Physical and mechanical properties of nanoreinforced particleboard composites
description Novel composite materials having desired performance properties can be developed by nanotechnology. The major objective of this research was to produce nanomaterial- reinforced particleboard composites with enhanced physical and mechanical performance. Urea formaldehyde adhesive used to produce particleboard composites was reinforced with nanoSiO2, nanoAl2O3, and nanoZnO at loading level of 0%, 1%, and 3%. To evaluate physical properties density, thickness swelling, water absorption, and equilibrium moisture content were determined while modulus of rupture, modulus of elasticity, bonding strength, and screw withdrawal strength tests were carried out to evaluate mechanical properties of the particleboard composites. The results acquired in this work revealed that nanomaterial reinforcement technique significantly affected the physical and mechanical performance properties of the particleboard composites. The findings showed that the modulus of rupture, modulus of elasticity, bonding strength, and screw withdrawal resistance of the composites improved by all the nanomaterials used in this study, except 3% nanoZnO. It was also determined that using 1% nanoSiO2 or 1% nanoAl2O3 in the composites had the best results in the bonding strength and screw withdrawal resistance. The findings indicate that it is possible to produce novel wood composites by using proper nanomaterial type and loading level.
author Candan,Zeki
Akbulut,Turgay
author_facet Candan,Zeki
Akbulut,Turgay
author_sort Candan,Zeki
title Physical and mechanical properties of nanoreinforced particleboard composites
title_short Physical and mechanical properties of nanoreinforced particleboard composites
title_full Physical and mechanical properties of nanoreinforced particleboard composites
title_fullStr Physical and mechanical properties of nanoreinforced particleboard composites
title_full_unstemmed Physical and mechanical properties of nanoreinforced particleboard composites
title_sort physical and mechanical properties of nanoreinforced particleboard composites
publisher Universidad del Bío-Bío
publishDate 2015
url http://www.scielo.cl/scielo.php?script=sci_arttext&pid=S0718-221X2015000200010
work_keys_str_mv AT candanzeki physicalandmechanicalpropertiesofnanoreinforcedparticleboardcomposites
AT akbulutturgay physicalandmechanicalpropertiesofnanoreinforcedparticleboardcomposites
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