Numerical Modelling of Failure in Advanced Composite Materials comprehensively examines the most recent analysis techniques for advanced composite materials. Advanced composite materials are becoming increasingly important for lightweight design in aerospace, wind energy, and mechanical and civil engineering. Essential for exploiting their potential is the ability to reliably predict their mechanical behaviour, particularly the onset and propagation of failure.
Part One investigates numerical modeling approaches to interlaminar failure in advanced composite materials. Part Two considers numerical modelling approaches to intralaminar failure. Part Three presents new and emerging advanced numerical algorithms for modeling and simulation of failure.
Part Four closes by examining the various engineering and scientific applications of numerical modeling for analysis of failure in advanced composite materials, such as prediction of impact damage, failure in textile composites, and fracture behavior in through-thickness reinforced laminates.
Numerical Modelling of Failure in Advanced Composite Materials comprehensively examines the most recent analysis techniques for advanced composite materials. Advanced composite materials are becoming increasingly important for lightweight design in aerospace, wind energy, and mechanical and civil engineering. Essential for exploiting their potential is the ability to reliably predict their mechanical behaviour, particularly the onset and propagation of failure.
Part One investigates numerical modeling approaches to interlaminar failure in advanced composite materials. Part Two considers numerical modelling approaches to intralaminar failure. Part Three presents new and emerging advanced numerical algorithms for modeling and simulation of failure.
Part Four closes by examining the various engineering and scientific applications of numerical modeling for analysis of failure in advanced composite materials, such as prediction of impact damage, failure in textile composites, and fracture behavior in through-thickness reinforced laminates.
A comprehensive review by leading authors of the most recent failure analysis models for advanced composite materials, covering basic fundamentals through applications.
Part One: Numerical modelling approaches to interlaminar failure in
advanced composite materials
1 The virtual crack closure technique for modelling interlaminar
failure and delamination in advanced composite materials
2 Modelling delamination with cohesive interface elements
3 Interface elements for fatigue-driven delaminations in advanced
composite materials
4 A level set model for delamination in advanced composite
materials
Part Two: Numerical modelling approaches to intralaminar failure in
advanced composite materials
5 Three-dimensional invariant-based failure criteria for
transversely isotropic fibre-reinforced composites
6 An overview of continuum damage models used to simulate
intra-laminar failure mechanisms in advanced composite
materials
7 Numerical modelling of matrix cracking and intralaminar failure
in advanced composite materials
8 Fibre failure modelling
Part Three: Advanced numerical algorithms for modelling and
simulation of failure in advanced composite materials
9 Mesh independent matrix cracking and delamination modelling in
advanced composite materials
10 A new augmented finite element method (A-FEM) for analysis of
failure in advanced composite materials
11 Isogeometric modelling
12 Peridynamics for analysis of failure in advanced composite
materials
13 Multiscale modeling of the response and life prediction of
composite materials
Part Four: Engineering and scientific applications of numerical
modelling for analysis of failure in advanced composite
materials
14 Micro-mechanical failure analysis of advanced composite
materials
15 Computational micromechanics strategies for the analysis of
failure in unidirectional composites
16 Numerical modelling for predicting failure in textile
composites
17 Multi-scale modelling for predicting fracture behaviour in
through-thickness reinforced
laminates
18 Numerical modelling of impact and damage tolerance in aerospace
composite structures
19 Strength prediction methods for composite structures: ensuring
aeronautical design office requirements
Pedro P. Camanho is a professor at the department of mechanical engineering of the University of Porto. His main research interests are the mechanics of deformation and fracture of polymer composite materials, and new concepts for advanced composite materials for aerospace applications such as hybrid, variable stiffness and ultra-thin composites. Professor Camanho has been a visiting scientist at NASA-Langley Research Center since 2000, was a visiting scientist at the U.S. Air Force Research Laboratory, and has coordinated several research projects funded by the European Space Agency, Airbus, NASA, Daimler AG, Aernnova, European Union and US Air Force. He was the recipient of the 2006 NASA H.J.E. Reid Award for Outstanding Scientific Paper, the 2005 Young Researcher in Applied and Computational Mechanics Award from the Portuguese Association of Theoretical, Applied and Computational Mechanics, and the 2005-2009 Engineering Fracture Mechanics Most Cited Articles Award. He has published over 70 papers in international peer reviewed journals and is a member of the Council of the European Mechanics Society (EUROMECH). Stephen R. Hallett is Professor in Composite Structures in the Advanced Composites Centre for Innovation and Science at the University of Bristol, UK. One of his main research interests is the development of physically based damage models for composite materials and their deployment for new and challenging applications. He has worked with on research projects for many of the major aerospace companies and is Technical Director for the Rolls-Royce Composites University Technology Centre at the University of Bristol. He has published over 70 scientific papers in international peer reviewed journals.
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