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Biocomposites for high-performance applications : current barriers and future needs towards industrial development / edited by Dipa Ray.

Contributor(s): Ray, Dipa [editor.]Material type: TextTextSeries: Woodhead Publishing series in composites science and engineeringPublisher: Duxford : Woodhead Publishing, [2017]Copyright date: �2017Description: 1 online resourceContent type: text Media type: computer Carrier type: online resourceISBN: 9780081007945; 0081007949Subject(s): Biopolymers | Polymeric composites | TECHNOLOGY & ENGINEERING / Chemical & Biochemical | Biopolymers | Polymeric compositesGenre/Form: Electronic books.Additional physical formats: No titleDDC classification: 668.9 LOC classification: TP248.65.P62Online resources: ScienceDirect
Contents:
Front Cover; Biocomposites for High-Performance Applications: Current Barriers and Future Needs Towards Industrial Development; Copyright; Contents; Contributors; Preface; 1 Plant fibre reinforcements; 1.1 Introduction; 1.2 Plant fibres; 1.2.1 Sources of plant fibres; 1.2.2 Chemistry of plant fibres; 1.2.3 Properties of plant fibres; 1.3 Major issues related with plant fibre reinforcements; 1.3.1 Variability in fibre properties; 1.3.2 Raw material supply; 1.3.3 Moisture absorption; 1.3.4 Compatibility with polymer matrices; 1.3.5 Flammability and thermal degradation; 1.3.6 Cost.
1.4 Commercially available plant fibre reinforcements1.5 Applications of plant fibres; 1.6 Future prospects; References; Further Reading; 2 Man-made cellulose fibre reinforcements (MMCFR); 2.1 Introduction; 2.2 MMCFR source and manufacturing; 2.2.1 Rayon; 2.2.2 Methods of preparation of rayon; 2.2.3 Lyocell; 2.2.4 Modification of lyocell to lyocell LF; 2.2.5 Modal; 2.3 Viscose rayon and other MMCFR; 2.4 MMCFR for industrial-scale manufacturing of biocomposites.
2.5 Plant fibres and MMCFR-mechanical properties, moisture absorbance, thermal stability, flammability, cost, and eco ...2.6 Reinforcement forms (unidirectional, woven and non-woven fabrics, hybrid fabrics, commingled fibres); 2.7 Literature review on MMCFR-based composites; 2.8 Application and future scope of MMCFR; 2.9 Future needs; References; 3 Thermosetting bioresins as matrix for biocomposites; 3.1 Introduction; 3.2 Thermosetting bioresins; 3.2.1 Thermosetting bioresins from vegetable oils; 3.3 Biocomposites based on bioresins; 3.4 Commercial bioresins.
3.4.1 Envirez (bio-unsaturated polyester resin)3.4.2 Super Sap (bio-epoxy resin); 3.4.3 Aropol S604 INF-60 infusion resin; 3.4.4 Biorez and furolite; 3.5 Bioresin research activities in lab; 3.5.1 Bioresin from banana sap; 3.5.2 Bioresin from lactic acid; 3.5.3 Plant oil-based alkyd resins; 3.6 Comparative study: Bioresins in market and bioresins synthesized in laboratories; 3.7 Advantages and disadvantages of bioresins; 3.8 Application areas and future pathways; References; Further Reading; 4 Thermoplastic biopolymer matrices for biocomposites; 4.1 Introduction.
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Holdings
Item type Current library Call number Status Date due Barcode
Ebooks Ebooks Mysore University Main Library
Not for loan EBKELV874

Includes bibliographical references and index.

Online resource, title from PDF title page (EBSCO, viewed June 4, 2017).

Front Cover; Biocomposites for High-Performance Applications: Current Barriers and Future Needs Towards Industrial Development; Copyright; Contents; Contributors; Preface; 1 Plant fibre reinforcements; 1.1 Introduction; 1.2 Plant fibres; 1.2.1 Sources of plant fibres; 1.2.2 Chemistry of plant fibres; 1.2.3 Properties of plant fibres; 1.3 Major issues related with plant fibre reinforcements; 1.3.1 Variability in fibre properties; 1.3.2 Raw material supply; 1.3.3 Moisture absorption; 1.3.4 Compatibility with polymer matrices; 1.3.5 Flammability and thermal degradation; 1.3.6 Cost.

1.4 Commercially available plant fibre reinforcements1.5 Applications of plant fibres; 1.6 Future prospects; References; Further Reading; 2 Man-made cellulose fibre reinforcements (MMCFR); 2.1 Introduction; 2.2 MMCFR source and manufacturing; 2.2.1 Rayon; 2.2.2 Methods of preparation of rayon; 2.2.3 Lyocell; 2.2.4 Modification of lyocell to lyocell LF; 2.2.5 Modal; 2.3 Viscose rayon and other MMCFR; 2.4 MMCFR for industrial-scale manufacturing of biocomposites.

2.5 Plant fibres and MMCFR-mechanical properties, moisture absorbance, thermal stability, flammability, cost, and eco ...2.6 Reinforcement forms (unidirectional, woven and non-woven fabrics, hybrid fabrics, commingled fibres); 2.7 Literature review on MMCFR-based composites; 2.8 Application and future scope of MMCFR; 2.9 Future needs; References; 3 Thermosetting bioresins as matrix for biocomposites; 3.1 Introduction; 3.2 Thermosetting bioresins; 3.2.1 Thermosetting bioresins from vegetable oils; 3.3 Biocomposites based on bioresins; 3.4 Commercial bioresins.

3.4.1 Envirez (bio-unsaturated polyester resin)3.4.2 Super Sap (bio-epoxy resin); 3.4.3 Aropol S604 INF-60 infusion resin; 3.4.4 Biorez and furolite; 3.5 Bioresin research activities in lab; 3.5.1 Bioresin from banana sap; 3.5.2 Bioresin from lactic acid; 3.5.3 Plant oil-based alkyd resins; 3.6 Comparative study: Bioresins in market and bioresins synthesized in laboratories; 3.7 Advantages and disadvantages of bioresins; 3.8 Application areas and future pathways; References; Further Reading; 4 Thermoplastic biopolymer matrices for biocomposites; 4.1 Introduction.

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