Biofiber Reinforcements in Composite Materials

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Informationen zum Autor Dr Omar Faruk! University of Toronto! Canada. Professor Mohini Sain works in the Faculty of Forestry! University of Toronto! Canada. Both are internationally-known for their research on wood-polymer composites. Klappentext Interest in natural fibres or biofibers as reinforcements in composites is growing as a way of making composite materials more sustainable. This comprehensive reference covers the use in composites of a broad range of bast fibres! leaf fibres! seed fibres! grass! reed and cane fibres and wood! cellulosic and other fibres. Inhaltsverzeichnis Part 1 Bast fibres: Jute; Flax; Kenaf. Part 2 Leaf fibres: Sisal/henequen; Pineapple leaf; Banana/abaca; Palm leaf. Part 3 Seed fibres: Coir/coconut; Cotton fibres; Oil palm fibres. Part 4 Grass! reed and cane fibres: Rice straw and husk; Wheat straw; Maize! oat! barley! rye and grass fibres; Bamboo fibres; Sugar cane/bagasse fibres. Part 5 Wood! cellulosic and other fibres: Cellulosic fibres; Wood fibres; Silk fibres; Biobased nanofibres.

List of contents

• Contributor contact details
• Editor biographies
• Woodhead Publishing Series in Composites Science and Engineering
• Preface
• Part I: Bast fibres
  • 1: The use of jute fibers as reinforcements in composites
    • Abstract
    • 1.1 Introduction
    • 1.2 Composition and properties of jute fibers
    • 1.3 Processing and properties of grafted jute fibers
    • 1.4 Processing and properties of alkali-treated jute fibers
    • 1.5 Characterization of jute fibers
    • 1.6 Manufacture of jute fiber composites
    • 1.7 Preparation and properties of irradiated jute composites
    • 1.8 Preparation and properties of oxidized jute composites
    • 1.9 Preparation and properties of mercerized jute composites
    • 1.10 Preparation and properties of jute composites modified by other processes
    • 1.11 Types and properties of hybrid jute composites
    • 1.12 Applications of jute composites
    • 1.13 Conclusion
  • 2: The use of flax fibres as reinforcements in composites
    • Abstract
    • 2.1 Introduction
    • 2.2 Key fibre properties
    • 2.3 Cultivation and quality issues
    • 2.4 Processing as a fibre reinforcement for composites
    • 2.5 Integration into the matrix
    • 2.6 Assessing the performance of the composites
    • 2.7 Applications
    • 2.8 Summary: strengths and weaknesses
    • 2.9 Future trends
    • 2.10 Sources of further information and advice
    • 2.11 Acknowledgements
  • 3: The use of hemp fibres as reinforcements in composites
    • Abstract
    • 3.1 Introduction
    • 3.2 Hemp fibre
    • 3.3 Key fibre properties
    • 3.4 Cultivation and quality issues
    • 3.5 Processing of hemp as fibre reinforcement for composites
    • 3.6 Surface modifications of hemp fibre and their effects on properties
    • 3.7 Fibre-matrix interaction
    • 3.8 Current applications of hemp fibres
    • 3.9 Future trends
    • 3.10 Summary
  • 4: The use of ramie fibers as reinforcements in composites
    • Abstract
    • 4.1 Introduction
    • 4.2 Ramie fiber properties
    • 4.3 Improving fiber/matrix interfacial bonding
    • 4.4 Ramie fiber-reinforced polymer composites
    • 4.5 Factors affecting composite mechanical properties
    • 4.6 Other studies of ramie fiber-reinforced composites
    • 4.7 Applications
    • 4.8 Conclusions
  • 5: The use of kenaf fibers as reinforcements in composites
    • Abstract
    • 5.1 Introduction
    • 5.2 Processing of kenaf fibers
    • 5.3 Matrices for kenaf fiber-reinforced composites
    • 5.4 Fabrication of kenaf fiber-reinforced composites (KFRC)
    • 5.5 Performance of KFRC
    • 5.6 Applications of KFRC
    • 5.7 Conclusion
• Part II: Leaf fibres
  • 6: The use of sisal and henequen fibres as reinforcements in composites
    • Abstract
    • 6.1 Introduction
    • 6.2 The microstructures of sisal fibres
    • 6.3 The mechanical properties of sisal fibres
    • 6.4 Manufacture of sisal fibre-reinforced composites
    • 6.5 Mechanical properties of sisal fibre-reinforced composites: interfacial properties
    • 6.6 Mechanical properties of sisal fibre-reinforced composites: interlaminar fracture toughness
    • 6.7 Mechanical properties of unidirectional sisal fibre-reinforced composites
    • 6.8 Effect of fibre twist on the mechanical properties of sisal fibre-reinforced composites
    • 6.9 Durability of sisal fibre-reinforced composites: effects of moisture absorption
    • 6.10 Effects of ultraviolet (UV) light on the mechanical properties of sisal fibre-reinforced composites
    • 6.11 Applications of sisal fibre-reinforced composites
    • 6.12 Conclusion and future trends
    • 6.13 Acknowledgements
  • 7: The use of pineapple leaf fibers (PALFs) as reinforcements in composites
    • Abstract
    • 7.1 Introduction
    • 7.2 The pineapple plant
    • 7.3 Pineapple production
    • 7.4 Pineapple culture in Brazil and worldwide
    • 7.5 Fiber extraction
    • 7.6 Potential of fiber production plant
    • 7.7 Fiber properties
    • 7.8 Pineapple leaf fiber (PALF)-reinforced polymer composites
    • 7.9 Application of pineapple fibers and composites
    • 7.10 Conclusions
  • 8: The use of banana and abaca fibres as reinforcements in composites
    • Abstract
    • 8.1 Introduction
    • 8.2 Banana and abaca plants and their cultivation
    • 8.3 Fibre extraction
    • 8.4 Fibre structure and properties
    • 8.5 Disadvantages of banana and abaca fibres as reinforcement materials
    • 8.6 Surface modification of fibres
    • 8.7 Processing of banana/abaca fibre-reinforced composites
    • 8.8 Performance of banana/abaca fibre-reinforced thermoset polymer composites
    • 8.9 Performance of banana/abaca fibre-reinforced thermoplastic polymer composites
    • 8.10 Performance of banana/abaca fibre-reinforced biodegradable polymer composites
    • 8.11 Conclusions
  • 9: The use of palm leaf fibres as reinforcements in composites
    • Abstract
    • 9.1 Introduction
    • 9.2 Cultivation and uses of palm leaf fibres
    • 9.3 Properties of palm leaf fibres
    • 9.4 Surface modification of palm leaf fibres
    • 9.5 The use of palm leaf fibres as reinforcements in polymer nanocomposites
    • 9.6 Conclusion
• Part III: Seed fibres
  • 10: The use of coir/coconut fibers as reinforcements in composites
    • Abstract
    • 10.1 Introduction
    • 10.2 The coconut plant and its cultivation
    • 10.3 Preparation/extraction of coir fibers from coconut husk
    • 10.4 Surface modification of coconut fibers
    • 10.5 The properties of coir fiber-reinforced thermoset polymer composites
    • 10.6 The properties of coir fiber-reinforced thermoplastic polymer composites
    • 10.7 Characterization of coconut/coir fiber-reinforced composites
    • 10.8 Advantages of using coconut/coir fibers as reinforcement in composites
    • 10.9 Conclusions
    • 10.10 Acknowledgment
  • 11: The use of cotton fibers as reinforcements in composites
    • Abstract
    • 11.1 Introduction
    • 11.2 Physical properties of cotton fibers
    • 11.3 Chemical and other properties of cotton fibers
    • 11.4 Cultivation of and quality issues affecting cotton fibers
    • 11.5 Processing of cotton fibers as reinforcements in composites
    • 11.6 Assessing the antibacterial activity of biomedical composites reinforced with composite cotton fibers
    • 11.7 Assessing the mechanical properties of biomedical and other composites reinforced with cotton fibers
    • 11.8 Summary
  • 12: The use of oil palm biomass (OPB) fibers as reinforcements in composites
    • Abstract
    • 12.1 Introduction
    • 12.2 Oil palm biomass fibers
    • 12.3 Surface modifications of empty fruit bunch (EFB) fibers
    • 12.4 Processing methods for EFB reinforced composites
    • 12.5 Effects of fiber treatments on the structures and properties of composites
    • 12.6 Applications of EFB fiber-based composites
    • 12.7 Conclusions
• Part IV: Grass, reed and cane fibres
  • 13: The use of rice straw and husk fibers as reinforcements in composites
    • Abstract
    • 13.1 Introduction
    • 13.2 Cultivation and processing of rice straw and rice husk
    • 13.3 Key fiber properties
    • 13.4 Composite processing: surface treatment
    • 13.5 Critical issues for the integration of fibers into the matrix
    • 13.6 Processing of thermoset and thermoplastic composites incorporating rice straw/rice husk (RS/RH) fiber reinforcements
    • 13.7 Evaluating the performance of composites reinforced with RS/RH fibers
    • 13.8 Conclusion
  • 14: The use of wheat straw fibres as reinforcements in composites
    • Abstract
    • 14.1 Introduction
    • 14.2 Worldwide availability and economics
    • 14.3 Structure and composition of wheat straw
    • 14.4 Wheat straw as a polymer composite reinforcement
    • 14.5 Processing of wheat straw fibre-reinforced polymer composites
    • 14.6 Properties of wheat straw fibre-reinforced composites
    • 14.7 Potential applications of wheat straw fibre-reinforced composites
    • 14.8 Future trends
    • 14.9 Conclusions
  • 15: The use of maize, oat, barley and rye fibres as reinforcements in composites
    • Abstract
    • 15.1 Introduction
    • 15.2 Types of reinforcing fibre
    • 15.3 Fibre components and key properties
    • 15.4 Surface modification of fibres
    • 15.5 Processing and performance: maize and oat flour composites
    • 15.6 Processing and performance: barley and rye fibre composites
    • 15.7 Conclusion
  • 16: The use of bamboo fibres as reinforcements in composites
    • Abstract
    • 16.1 Introduction
    • 16.2 Structure of bamboo
    • 16.3 Chemical properties of bamboo
    • 16.4 Mechanical properties of bamboo
    • 16.5 Cultivation of bamboo, fibre extraction and surface modification
    • 16.6 Properties of bamboo fibre-reinforced polymer composites
    • 16.7 Applications of bamboo composites
    • 16.8 Sustainable and renewable products from bamboo composites
    • 16.9 Future trends
    • 16.10 Conclusions
  • 17: The use of sugarcane bagasse fibres as reinforcements in composites
    • Abstract
    • 17.1 Introduction
    • 17.2 Properties of sugarcane bagasse fibres
    • 17.3 Applications
    • 17.4 Surface treatment techniques
    • 17.5 Evaluation of fibre treatment techniques
    • 17.6 Assessing composite performance
    • 17.7 Future trends
    • 17.8 Conclusion
• Part V: Wood, cellulosic and other fibres
  • 18: Isolation and application of cellulosic fibres in composites
    • Abstract
    • 18.1 Introduction
    • 18.2 Types of cellulosic fibre reinforcement and their properties
    • 18.3 Cultivation and fibre separation processes
    • 18.4 Fibre processing
    • 18.5 Assessing performance
    • 18.6 Applications
    • 18.7 Conclusions
    • 18.8 Sources of further information and advice
  • 19: The use of biobased nanofibres in composites
    • Abstract
    • 19.1 Introduction
    • 19.2 Biobased nanoreinforcements
    • 19.3 Ultrastructure of cellulose nanoreinforcements
    • 19.4 Source materials for cellulose nanoreinforcements
    • 19.5 Classification of cellulose nanoreinforcements
    • 19.6 Synthesis/isolation of cellulose nanoreinforcements
    • 19.7 Surface modification of cellulose nanoreinforcements
    • 19.8 Characterization of cellulose nanoreinforcements
    • 19.9 Matrices
    • 19.10 Incorporation of biobased nanoreinforcements into matrices
    • 19.11 Nanocomposites
    • 19.12 Challenges
    • 19.13 Future trends
    • 19.14 Conclusions
  • 20: The use of wood fibers as reinforcements in composites
    • Abstract
    • 20.1 Introduction: characteristics of wood
    • 20.2 Fiber processing and composite manufacturing
    • 20.3 Mechanical performance of wood plastic composites (WPCs)
    • 20.4 The effect of moisture on composite performance
    • 20.5 The effect of temperature on composite performance
    • 20.6 The effect of weathering on composite performance
    • 20.7 The effect of biological attack on composite performance
    • 20.8 Trends in materials and manufacturing techniques
    • 20.9 Current and emerging applications
  • 21: The use of Luffa cylindrica fibres as reinforcements in composites
    • Abstract
    • 21.1 Introduction
    • 21.2 Properties and surface treatment of Luffa cylindrica fibres
    • 21.3 Applications and performance of Luffa cylindrica fibres as reinforcements in composites
    • 21.4 Nanocomposites incorporating Luffa cylindrica fibres
    • 21.5 Conclusion
  • 22: The use of curaua fibers as reinforcements in composites
    • Abstract
    • 22.1 Introduction
    • 22.2 Curaua fibers
    • 22.3 Composites using curaua fibers
    • 22.4 Curaua nanofibers
    • 22.5 Nanocomposites with curaua fibers
    • 22.6 Conclusion
• Index