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Full Description
Fiber-reinforced polymer composites exhibit better damping characteristics than conventional metals due to the viscoelastic nature of the polymers. There has been a growing interest among research communities and industries in the use of natural fibers as reinforcements in structural and semi-structural applications, given their environmental advantages. Knowledge of the vibration and damping behavior of biocomposites is essential for engineers and scientists who work in the field of composite materials. Vibration and Damping Behavior of Biocomposites brings together the latest research developments in vibration and viscoelastic behavior of composites filled with different natural fibers.
Features:
Reviews the effect of various types of reinforcements on free vibration behavior
Emphasizes aging effects, influence of compatibilizers, and hybrid fiber reinforcement
Explores the influence of resin type on viscoelastic properties
Covers the use of computational modeling to analyze dynamic behavior and viscoelastic properties
Discusses viscoelastic damping characterization through dynamic mechanical analysis.
This compilation will greatly benefit academics, researchers, advanced students, and practicing engineers in materials and mechanical engineering and related fields who work with biocomposites.
Editors
Dr. Senthil Muthu Kumar Thiagamani, Kalasalinagam Academy of Research and Education (KARE), India
Dr. Md Enamul Hoque, Military Institute of Science and Technology (MIST), Bangladesh
Dr. Senthilkumar Krishnasamy, King Mongkut's University of Technology North Bangkok KMUTNB, Thailand
Dr. Chandrasekar Muthukumar, Hindustan Institute of Technology & Science (HITS), India
Dr. Suchart Siengchin, King Mongkut's University of Technology North Bangkok KMUTNB, Thailand
Contents
Part I: Free Vibration and Damping. 1. Free Vibration and Damping Characterization of the Biocomposites: An Overview. 2. Free Vibration and Damping Characteristics of Wood Polymer Composites. 3. Influence of Fibre Loading on the Free Vibration and Damping Characteristics of Grass Fibre Based Polymer Composites. 4. Influence of Hybridization on the Free Vibration and Damping Characteristics of Bast Fibre Based Polymer Composites. 5. Free Vibration and Damping Properties of the Pineapple Leaf Fibre/Sisal Fibre Based Polymer Composites. 6. Fibre Length and Their Influence on the Free Vibration and Damping Characteristics of Fruit Fibre Based Polymer Composites. 7. Free Vibration and Damping Characteristics of Completely Biodegradable Polymer-based Composites. 8. Effect of Organic Nanofillers on the Free Vibration and Damping Characteristics of Polymer-based Nanocomposites. 9. Influence of Fibre Treatment on the Free Vibration and Damping Characteristics of Polymer Composites. 10. Influence of Compatibilizer on Free Vibration and Damping Characteristics of Polymer-based Biocomposites. 11. Aging Effects on Free Vibration and Damping Characteristics of Polymer-based Biocomposites. 12. Computational Modeling of Free Vibration and Damping Characteristic of Polymer-based Biocomposites. Part II: Viscoelastic Properties. 13. Characterization of Viscoelastic Properties of Biocomposites Through Dynamic Mechanical Analysis: An Overview. 14. Viscoelastic Properties of Completely Biodegradable Polymer-based Composites. 15. Effect of Hybridization on the Viscoelastic Properties of Polymer Based Biocomposites. 16. Viscoelastic Properties of the Polymer Based Composite Reinforced with Various Species of Wood Fillers. 17. Viscoelastic Properties of Polymer-based Bionanocomposites Reinforced with the Inorganic Fillers. 18. Influence of Fibre Treatment on Viscoelastic Properties of the Biocomposites. 19. Influence of Compatibilizer on Viscoelastic Properties of the Thermoplastic Polymer-based Biocomposites. 20. Recent Developments on Computational Modeling of Viscoelastic Properties of the Biocomposites
