Advanced Composites - Books on Google Play

Nanocomposites are currently defined "as a multiphase solid material where one of the phases has one, two or three dimensions of less than 100 nanometers or structures having nano-scale repeat distances between the different phases that make up the material".
The use of nanocomposites with polymer, metal or ceramic matrices has increased in various areas of engineering and technology due to their special properties, with applications in bioengineering, battery cathodes, automotives, sensors and computers, as well other advanced industries. The present volume aims to provide recent information on nanocomposites (materials manufacturing and engineering) in six chapters. The chapter 1 of the book provides information on synthesis and characterization of ceramic hollow nanocomposites and nanotraps. Chapter 2 is dedicated to recent advances on preparation, properties and applications polyurathene nanocomposites. Chapter 3 described preparation, characterization and properties of organoclays, carbon nanofibers and carbon nanotubes based polymer nanocomposites. Chapter 4 contains information on mechanical and wear properties of multi-scale phase reinforced composites. Chapter 5 described modeling mechanical properties of nanocomposites Finally, chapter 6 is dedicated to polyanaline derivates and carbon nanotubes and their characterization.
This book is the essential reference for academics, materials and physics researchers, materials, mechanical and manufacturing engineers, and professionals in nanocomposite-related industries.

Biomedical Composites: Materials, Manufacturing and Engineering

Book 2·Nov 2013

5.0

·

$300.00

Composite materials are engineered materials, made from two or more constituents with significantly different physical or chemical properties which remain separate on a macroscopic level within the finished structure. Due to their special mechanical and physical properties they have the potential to replace conventional materials in various fields such as the biomedical industry.

Metal Matrix Composites: Materials, Manufacturing and Engineering

Metal Matrix Composites (MMC's) have found an increased use in various industries due to their special mechanical and physical properties. They are a composite material with at least two constituent parts, one being a metal and are made by dispersing a reinforcing material into a metal matrix. The markets are: telecommunications, automotive, power semiconductor, opto-electronics, military and aerospace, heavy transportation, space systems and satellites, medical, and industrial lighting. Applications within these markets include microwave, micro-electronic packaging, laser diode, HB-LED’s, and advanced radar.

Metal Matrix Composites: Materials, Manufacturing and Engineering

Metal Matrix Composites (MMC's) have found an increased use in various industries due to their special mechanical and physical properties. They are a composite material with at least two constituent parts, one being a metal and are made by dispersing a reinforcing material into a metal matrix. The markets are: telecommunications, automotive, power semiconductor, opto-electronics, military and aerospace, heavy transportation, space systems and satellites, medical, and industrial lighting. Applications within these markets include microwave, micro-electronic packaging, laser diode, HB-LED’s, and advanced radar.

Machinability of Fibre-Reinforced Plastics

Presents polymer-based fibre reinforced composite materials and addresses the characteristics of these widely used materials like low density and coefficient of thermal expansion, specific strength with better fatigue resistance and modulus. The topics discussed are laser-based material machining, high-speed robotic end milling and LFRP modeling, including definitions, features, machine elements (system set-up) as well as experimental and theoretical investigations. These investigations include effects of input variables (tool rotation speed, feed rate and ultrasonic power) on cutting force, torque, cutting temperature, edge quality, surface roughness, burning of machined surface, tool wear, material removal rate, power consumption and feasible regions. Further a detailed literature review on drilling polymer composites with a focus on delamination is included. Aspects such as delamination mechanisms, fabrication methods, the type of drilling process adopted by various researchers, cutting parameters employed during drilling, mathematical delamination modelling, effect of thrust force, spindle speed, thermal loads, tool wear, surface roughness, tool geometry and tool materials on delamination and hole quality are summarized. In addition an approach of digital image processing in delamination assessment completes the approach.

- Discusses Carbon Fiber Reinforced Plastics modern technologies for automated, highly productive and cost efficient processing.
- Great value for final undergraduate engineering courses or as a topic on manufacturing with FRPs at the postgraduate level as well as a useful reference for academics, researchers, manufacturing, mechanical and materials engineers, professionals in machining of FRPs and related industries.

Machinability of Fibre-Reinforced Plastics

Presents polymer-based fibre reinforced composite materials and addresses the characteristics of these widely used materials like low density and coefficient of thermal expansion, specific strength with better fatigue resistance and modulus. The topics discussed are laser-based material machining, high-speed robotic end milling and LFRP modeling, including definitions, features, machine elements (system set-up) as well as experimental and theoretical investigations. These investigations include effects of input variables (tool rotation speed, feed rate and ultrasonic power) on cutting force, torque, cutting temperature, edge quality, surface roughness, burning of machined surface, tool wear, material removal rate, power consumption and feasible regions. Further a detailed literature review on drilling polymer composites with a focus on delamination is included. Aspects such as delamination mechanisms, fabrication methods, the type of drilling process adopted by various researchers, cutting parameters employed during drilling, mathematical delamination modelling, effect of thrust force, spindle speed, thermal loads, tool wear, surface roughness, tool geometry and tool materials on delamination and hole quality are summarized. In addition an approach of digital image processing in delamination assessment completes the approach.

- Discusses Carbon Fiber Reinforced Plastics modern technologies for automated, highly productive and cost efficient processing.
- Great value for final undergraduate engineering courses or as a topic on manufacturing with FRPs at the postgraduate level as well as a useful reference for academics, researchers, manufacturing, mechanical and materials engineers, professionals in machining of FRPs and related industries.