Books by Keyword: Delamination

Description: Volume is indexed by Thomson Reuters BCI (WoS).
This special-topic volume reports on new progress made in the analysis and understanding of fracture and damage mechanics. The Finite Element Method is a well-established analytical tool for theoretical fracture analysis. The development of interface elements which combine aspects of both fracture and damage mechanics has permitted the prediction of both crack initiation and propagation. A number of the papers presented here deal with their use and further development.

Description: Volume is indexed by Thomson Reuters CPCI-S (WoS).
Fracture, Fatigue and Strength are some of the most important properties of engineering materials.

Description: Volume is indexed by Thomson Reuters CPCI-S (WoS).
This volume comprises selected papers from the Asian Pacific Conference for Fracture and Strength (APCFS’04), held on Jeju Island, Korea during the 6th to 8th October, 2004. During this conference, participants from the Asian-Pacific region gathered in order to exchange the latest experimental, theoretical and computational research on the fracture, strength, integrity and reliability of materials and structures.

Description: Volume is indexed by Thomson Reuters CPCI-S (WoS).
The book will present materials researchers and users with a wealth of new information covering the entire spectrum of ecology, eco-materials, nano-materials, bio-materials, recycling, environmental protection and energy conversion related materials.

Description: This book contains the proceedings of Symposium L of the International Conference on Materials for Advanced Technologies, held from the 1st to the 6th of July , 2001 in Singapore. The aim of this important meeting was to bring together researchers and engineers having very different backgrounds, and thus promote free discussion and the exchange of ideas across many interdisciplinary boundaries.

Description: Volume is indexed by Thomson Reuters CPCI-S (WoS).
The present book represents a cooperative effort, by both experimentalists and designers, to seek out the best strategies for effecting improvements in the quality and the reliability of composite materials and to widen their application.

Description: This book presents ten chapters on the science and engineering of durable surfaces. The first section focusses on various types of surfaces and advanced coating processes, while the second part concentrates particularly on thermal barrier coatings. The book covers both, in-depth state-of-the-art reviews as well as cutting-edge new information emerging from ongoing research:

Description: Volume is indexed by Thomson Reuters CPCI-S (WoS).
Fracture, Fatigue and Strength are among the most important properties of engineering materials. The present volume covers all aspects of Fracture Mechanics, Computational Mechanics, Dynamic Fracture, Damage Mechanics, Fracture Physics, Fatigue and Creep of advanced materials, special emphasis being placed on Polymer and Polymer Composites, Metal Matrix and Ceramic Matrix Composites, Advanced Ferrous and Nonferrous Alloys and Nonmetallic Materials. Also covered are various Structural Aspects, Welding and Joining Properties, Stress Corrosion, Dynamic Loading Effects and other aspects limiting the Application of High-Tech Materials.

Description: In many engineering applications of composite and laminate materials, damage and failure can be caused by impact of various types. Low-velocity impact is potentially dangerous because it can produce extensive sub-surface delamination that may not be visible on the surface. High-velocity impact produced by projectiles, shock waves and fragments from exploding ammunition is a highly dynamic event, leading to the penetration or perforation of composites.
All impact damage is detrimental to the mechanical and structural performance of composites. Accurate evaluation of the damaged state, and a fundamental understanding of the effect of damage upon the resultant properties are therefore essential for the proper design and application of composite materials. The strain-rate dependence of material behavior, fracture propagation and energy-absorbing capacity are also of paramount importance from both the materials science and structural mechanics perspectives.

Description: The potential of composites cannot be fully realized unless their fracture modes and failure mechanisms are fully understood, and appropriate design tools for failure prediction are developed and verified.