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This volume presents the results of numerous worldwide studies focusing on the implementation of natural polymers as engineering plastics and the use of their inherent properties. It discusses the processing and, more extensively, the applicati on of natural materials (cellulose and protein-based) as reinforcements for polymer composites. The structural, morphological, and thermal characteristics, as well as the mechanical behavior of the obtained materials are covered comprehensively. In addition, the book includes case studies and results of commercial relevance. All natural polymers used in the blending or reinforcement of synthetic polymers are discussed in an attempt to cover the isolation, pretreatment, blending, and manufacturing of the respective materials.
This unique volume covers the results of the world-wide efforts to implement natural polymers as engineering plastics and the use of their inherent properties. The processing opportunities and the applications of the natural materials as reinforcement of polymer composites are discussed, including the structural, morphological and thermal characterization as well as the mechanical behavior of the obtained materials. Also covered is the preparation of biodegradable homopolymers, blends and composites, which involves chemical reactions, regardless of the type of the starting material.
Natural fibre composites are increasingly being viewed as viable and environmentally responsible alternatives to synthetic fibre composites and plastics. Sugar Palm Biofibers, Biopolymers, and Biocomposites considers the use of sugar palm fibres for materials development and application. It offers original research on the properties and behavior of sugar palm’s fibres, polymers, and biocomposites, covering mechanical, physical, thermal, chemical, environmental, morphological properties, as well as optimal design. It discusses sugar palm fibre thermosetting composites, sugar palm fibre thermoplastic composites, impregnation of sugar palm fibre, various lengths of sugar palm fibres, forms and arrangements such as particulate, continuous roving, and woven fabrics. The book also discusses innovations in commercialized products derived from sugar palm.
Biopolymers and Biocomposites from Agro-waste for Packaging Applications looks at the utilization of biocomposites and biopolymers for packaging applications. The book focuses on the development of affordable, innovative, sustainable packaging products made from biopolymers and biocomposites derived from agricultural waste/biomass and how they that result in improved shelf-life performance. In addition, it explores how these affordable packaging products can reduce food loss across the supply chain, the future direction of setting-up platforms for broader uses, and how these products can also contribute to minimizing waste-to-landfill problems. - Focuses on the application and use of non-exploited cheap agricultural waste for food packaging applications - Contains information on the modeling and processing of biopolymers and biocomposites to predict thermal and mechanical behavior - Features a discussion of coatings on packaging products to enhance shelf life
Composites are materials made from two or more constituent materials with significantly different physical or chemical properties. The two materials combine together to give a new material with higher strength, toughness, stiffness, but also a higher resistance to creep, corrosion, wear or fatigue compared to conventional materials. It is composed primarily of a matrix i.e. a continuous phase which is armoured with secondary discontinues reinforcement phase. These materials have been used in a variety of products viz. spacecrafts, sporting goods, catalyst, sensors, actuators, biomedical materials, batteries, cars, furniture, aircraft components, etc. This book focusses on processing, properties of various types of composite materials, as well as their environmental engineering applications. This book examines the current state of art, new challenges, and opportunities of composites in environmental engineering. The chapters in this book covers nearly every topic related to composites in environmental engineering in four broad perspectives: (i) classification of composites (ii) green/hybrid synthesis and characterization of nano and biocomposites (iii) processing of composite materials (iv) state-of–the-art in fabricating the composites - nano and biocomposites - for environmental applications.
One of the major reasons for composite failure is a breakdown of the bond between the reinforcement fibres and the matrix. When this happens, the composite loses strength and fails. By engineering the interface between the natural fibres and the matrix, the properties of the composite can be manipulated to give maximum performance. Interface engineering of natural fibre composites for maximum performance looks at natural (sustainable) fibre composites and the growing trend towards their use as reinforcements in composites.Part one focuses on processing and surface treatments to engineer the interface in natural fibre composites and looks in detail at modifying cellulose fibre surfaces in the manufacture of natural fibre composites, interface tuning through matrix modification and preparation of cellulose nanocomposites. It also looks at the characterisation of fibre surface treatments by infrared and raman spectroscopy and the effects of processing and surface treatment on the interfacial adhesion and mechanical properties of natural fibre composites. Testing interfacial properties in natural fibre composites is the topic of part two which discusses the electrochemical characterisation of the interfacial properties of natural fibres, assesses the mechanical and thermochemical properties and moisture uptake behaviour of natural fibres and studies the fatigue and delamination of natural fibre composites before finishing with a look at Raman spectroscopy and x-ray scattering for assessing the interface in natural fibre compositesWith its distinguished editor and international team of contributors Interface engineering of natural fibre composites for maximum performance is an invaluable resource to composite manufacturers and developers, materials scientists and engineers and anyone involved in designing and formulating composites or in industries that use natural fibre composites. - Examines characterisation of fibre surface treatments by infrared and raman spectroscopy and the effects of processing and surface treatment - Reviews testing interfacial properties in natural fibre composites including the electrochemical characterisation of the interfacial properties of natural fibres - Assesses the mechanical and thermochemical properties and moisture uptake behaviour of natural fibres and studies the fatigue and delamination of natural fibre composites
This Handbook is the first to explore the extensive applications made with bioplastics & biocomposites for the packaging, automotive, biomedical, and construction industries. Bioplastics and biocomposites are becoming increasingly prominent because synthetic plastics and glass fiber composites are neither sustainable nor environmentally friendly. The Handbook of Bioplastics and Biocomposites Engineering Applications brings together scientists from academia and industry to report on current research and applications in the bioplastics and biocomposites arena. This new science is interdisciplinary and integrates pure and applied sciences such as chemistry, engineering and materials science. The Handbook focuses on five main categories of applications: Packaging; Civil Engineering; Biomedical; Automotive; General Engineering. The majority of the chapters review the properties, processing, characterization, synthesis and applications of the bio-based and biodegradable polymers and composites including: Polymers such as polylactic acid (PLA), polyhydroxybutyrate (PHB), guar gum based plastics, cellulose polyesters, starch based bioplastics, vegetable oil derived bioplastics, biopolyethylene, chitosan, etc. Thermoplastic and thermosetting bioplastics and biocomposites with a focus on the automobile industry. The ways how to improve the properties of bioplastics, polymer blends, and biocomposites by combining them with both synthetic and natural fillers and reinforcements such as nanoclays, nanotubes (CNTs), and natural fibers (both wood and plant fibers). Studies that expand the boundaries of bioplastics that will allow for the new materials to be applied to most generic engineering applications. The Handbook will be of central interest to engineers, scientists and researchers who are working in the fields of bioplastics, biocomposites, biomaterials for biomedical engineering, biochemistry, and materials science. The book will also be of great importance to engineers in many industries including automotive, biomedical, construction, and food packaging.
As an area of high topical interest, Biopolymers – New materials for Sustainable Films and Coatings covers the development and utilization of polymers derived from bioresources, with a particular focus on film and coating applications. With growing concern for the environment and the rising price of crude oil, there is increasing demand for non-petroleum-based polymers from renewable resources. Leading research groups worldwide in industry and academe are working on such technology with the objective of applying the latest advances in the field. Written by well-respected experts, this text systematically covers the extraction and production of selected biopolymers as well as their properties and application as films or coatings in a variety of uses. The areas addressed include food packaging, edible coatings, paper coatings and agricultural films. Intended for researchers and students, this book will also be of interest to industry, especially in terms of the practical applications.