000 04388cam a22003257a 4500
003 OSt
005 20220715091336.0
020 _a9781855739369 (hard)
020 _a9781855739369
040 _aUKM
_cUKM
_dC#P
_dBAKER
_dDLC
_bEng
_erda
041 _aEng
050 0 0 _aTA418.9.C6
_bMUL
245 0 0 _aMulti-scale modelling of composite material systems :
_bthe art of predictive damage modelling /
_cedited by C. Soutis and P.W.R. Beaumont.
260 _aCambridge :
_bWoodhead Publishing ;
_c2005.
300 _axviii, 506 pages :
_billustrations ;
_c24 cm.
336 _2rdacontent
_atext
_btxt
337 _2rdamedia
_aunmediated
_bn
338 _2rdacarrier
_avolume
_bnc
504 _aIncludes bibliographical references and index.
505 _a1 Molecular modelling of composite matrix properties; 1.1 Introduction; 1.2 Group interaction modelling for the prediction of polymer properties; 1.3 Applying group interaction modelling to polymer matrix composites; 1.4 Conclusions; 1.5 Acknowledgements; 1.6 References; 2 Interfacial damage modelling of composites; 2.1 Introduction: definition of the interface; 2.2 The interface and composite properties. 2.3 Analytical modelling of the shear transfer2.4 Interfacial damage modelling; 2.5 Experimental measurement of the stress field at the interface; 2.6 Modelling of the experimentally measured stress transfer; 2.7 Overview and conclusions; 2.8 References; 3 Multi-scale predictive modelling of cracking in laminate composites; 3.1 Introduction; 3.2 Predicting undamaged ply properties; 3.3 Undamaged laminate properties; 3.4 Prediction of ply cracking in laminates; 3.5 Prediction of laminate failure; 3.6 Future trends; 3.7 References; 4 Modelling the strength of fibre-reinforced composites. 4.1 Introduction4.2 Mechanical and thermal response of the polymer matrix; 4.3 Modelling first ply failure by FEA using the partial discretisation approach; 4.4 Stress-strain response and fracture morphology in UD composites; 4.5 Conclusions; 4.6 Future trends; 4.7 Further reading; 4.8 References; 5 Cracking models; 5.1 Introduction; 5.2 Empirical and physical modelling; 5.3 Choosing between continuum and physical modelling; 5.4 Combining empirical and physical models; 5.5 Modelling fatigue cracking by delamination; 5.6 Modelling coupled mechanisms in composite cracking. 5.7 Cracking at stress concentrators5.8 Bridging cracks: de-bonding's critical role; 5.9 Modelling stress-corrosion cracking; 5.10 Model implementation; 5.11 Conclusions; 5.12 Acknowledgements; 5.13 References; 6 Multi-scale modelling of cracking in cross-ply laminates; 6.1 Introduction; 6.2 Microstructural randomness of cross-ply laminates; 6.3 Damage accumulation; 6.4 Multi-scale modelling; 6.5 Future trends; 6.6 Further information; 6.7 References; 7 Modelling damage in laminate composites; 7.1 Introduction; 7.2 Stress analysis. 7.3 Predicting stiffness degradation due to intra-and interlaminar damage7.4 Predicting onset and growth of intra-and interlaminar damage; 7.5 Conclusions; 7.6 Acknowledgements; 7.7 References; 7.8 Appendices; 8 Progressive multi-scale modelling of composite laminates; 8.1 Introduction; 8.2 Brief review of failure theories of fibre composites; 8.3 Multi-scale failure theory; 8.4 Phase degradation approach; 8.5 Validation of analysis against experiment; 8.6 Conclusion; 8.7 References; 8.8 Appendices; 9 Predicting fracture of laminated composites.
520 _aOne of the most important and exciting areas of composites research is the development of modelling techniques to predict the response of composite materials to different types of stress. Predictive modelling provides the opportunity both to understand better how composites behave in different conditions and to develop materials with enhanced performance for particular industrial applications. Multi-scale modelling of composite material systems summarises the key research in this area and its implications for industry.
650 0 _aComposite materials.
650 0 _aStrains and stresses.
700 1 _aSoutis, C.
_q(Costas)
_eEditor
700 1 _aBeaumont, Peter W. R.
_eEditor
856 4 2 _uhttp://www.loc.gov/catdir/enhancements/fy0648/2006365169-d.html
906 _a7
_bcbc
_ccopycat
_d2
_encip
_f20
_gy-gencatlg
942 _2lcc
_cBK
999 _c3129
_d3129