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Cellulose fiber and nano-fiber composites based on castor oil-polyurethane matrix

Hybrid cellulose composites comprising woven hemp fabric interspersed with microcrystalline cellulose in a matrix of castor oil based polyurethane. The compsoites were derived from natural resources except for the diisocyanate required for chain extension and crosslinking, together with likely inter...

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Bibliographic Details
Main Authors: Ansari M.N.M., Shanks R.A.
Other Authors: 55489853600
Format: Conference Paper
Published: 2023
Subjects:
Bio-composite
Biomaterial
Cellulose
Natural fiber
Natural resource
Urethane
Activation Energy
Bonding
Castor Oil
Cellulose Fibers
Composites
Cross Linking
Glass Transition Temperature
Gravimetry
Mechanical Properties
MicrOCRystalline Cellulose
Polyurethanes
Scanning Electron Microscopy
Tensile Strength
Activation energy
Biological materials
Biomaterials
Damping
Fluidics
Glass transition
Infrared spectroscopy
Mechanical properties
Medical nanotechnology
Nanotechnology
Natural fibers
Natural resources
Optical microscopy
Tensile strength
Vegetable oils
Castor oil
Cellulose fiber
Chain extension
Diisocyanates
Interfacial bonding
matrix
Microcrystalline cellulose
Scanning electrons
Strength and toughness
Thermo-mechanical analysis
Vibration-damping
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id my.uniten.dspace-30457
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spelling my.uniten.dspace-304572024-04-18T10:13:26Z Cellulose fiber and nano-fiber composites based on castor oil-polyurethane matrix Ansari M.N.M. Shanks R.A. 55489853600 35567552200 Bio-composite Biomaterial Cellulose Natural fiber Natural resource Urethane Activation Energy Bonding Castor Oil Cellulose Fibers Composites Cross Linking Glass Transition Temperature Gravimetry Mechanical Properties MicrOCRystalline Cellulose Polyurethanes Scanning Electron Microscopy Tensile Strength Activation energy Biological materials Biomaterials Damping Fluidics Glass transition Infrared spectroscopy Mechanical properties Medical nanotechnology Nanotechnology Natural fibers Natural resources Optical microscopy Polyurethanes Tensile strength Vegetable oils Bio-composite Castor oil Cellulose fiber Chain extension Diisocyanates Interfacial bonding matrix Microcrystalline cellulose Scanning electrons Strength and toughness Thermo-mechanical analysis Urethane Vibration-damping Cellulose Hybrid cellulose composites comprising woven hemp fabric interspersed with microcrystalline cellulose in a matrix of castor oil based polyurethane. The compsoites were derived from natural resources except for the diisocyanate required for chain extension and crosslinking, together with likely interfacial bonding with the cellulose components. The composites were characterised using scanning electron and optical microscopy, therrnogravimetry and infrared spectroscopy. Mechanical properties measured were creep, recovery and modulated force thermomechanical analysis. Multiplexed frequency was used to obtain activation energy for the glass transition. The composites were semi-flexible, with hiigh tensile strength and toughness, the main damping peak was centred on ambient temperature making the composites suitable for vibration damping application. Final 2023-12-29T07:48:03Z 2023-12-29T07:48:03Z 2011 Conference Paper 2-s2.0-81455139923 https://www.scopus.com/inward/record.uri?eid=2-s2.0-81455139923&partnerID=40&md5=c696f92a1d722486b7b8377351e50ad3 https://irepository.uniten.edu.my/handle/123456789/30457 3 179 182 Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Bio-composite
Biomaterial
Cellulose
Natural fiber
Natural resource
Urethane
Activation Energy
Bonding
Castor Oil
Cellulose Fibers
Composites
Cross Linking
Glass Transition Temperature
Gravimetry
Mechanical Properties
MicrOCRystalline Cellulose
Polyurethanes
Scanning Electron Microscopy
Tensile Strength
Activation energy
Biological materials
Biomaterials
Damping
Fluidics
Glass transition
Infrared spectroscopy
Mechanical properties
Medical nanotechnology
Nanotechnology
Natural fibers
Natural resources
Optical microscopy
Polyurethanes
Tensile strength
Vegetable oils
Bio-composite
Castor oil
Cellulose fiber
Chain extension
Diisocyanates
Interfacial bonding
matrix
Microcrystalline cellulose
Scanning electrons
Strength and toughness
Thermo-mechanical analysis
Urethane
Vibration-damping
Cellulose
spellingShingle Bio-composite
Biomaterial
Cellulose
Natural fiber
Natural resource
Urethane
Activation Energy
Bonding
Castor Oil
Cellulose Fibers
Composites
Cross Linking
Glass Transition Temperature
Gravimetry
Mechanical Properties
MicrOCRystalline Cellulose
Polyurethanes
Scanning Electron Microscopy
Tensile Strength
Activation energy
Biological materials
Biomaterials
Damping
Fluidics
Glass transition
Infrared spectroscopy
Mechanical properties
Medical nanotechnology
Nanotechnology
Natural fibers
Natural resources
Optical microscopy
Polyurethanes
Tensile strength
Vegetable oils
Bio-composite
Castor oil
Cellulose fiber
Chain extension
Diisocyanates
Interfacial bonding
matrix
Microcrystalline cellulose
Scanning electrons
Strength and toughness
Thermo-mechanical analysis
Urethane
Vibration-damping
Cellulose
Ansari M.N.M.
Shanks R.A.
Cellulose fiber and nano-fiber composites based on castor oil-polyurethane matrix
description Hybrid cellulose composites comprising woven hemp fabric interspersed with microcrystalline cellulose in a matrix of castor oil based polyurethane. The compsoites were derived from natural resources except for the diisocyanate required for chain extension and crosslinking, together with likely interfacial bonding with the cellulose components. The composites were characterised using scanning electron and optical microscopy, therrnogravimetry and infrared spectroscopy. Mechanical properties measured were creep, recovery and modulated force thermomechanical analysis. Multiplexed frequency was used to obtain activation energy for the glass transition. The composites were semi-flexible, with hiigh tensile strength and toughness, the main damping peak was centred on ambient temperature making the composites suitable for vibration damping application.
author2 55489853600
author_facet 55489853600
Ansari M.N.M.
Shanks R.A.
format Conference Paper
author Ansari M.N.M.
Shanks R.A.
author_sort Ansari M.N.M.
title Cellulose fiber and nano-fiber composites based on castor oil-polyurethane matrix
title_short Cellulose fiber and nano-fiber composites based on castor oil-polyurethane matrix
title_full Cellulose fiber and nano-fiber composites based on castor oil-polyurethane matrix
title_fullStr Cellulose fiber and nano-fiber composites based on castor oil-polyurethane matrix
title_full_unstemmed Cellulose fiber and nano-fiber composites based on castor oil-polyurethane matrix
title_sort cellulose fiber and nano-fiber composites based on castor oil-polyurethane matrix
publishDate 2023
_version_ 1806426184148320256
score 13.211869

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