Structural health monitoring of biocomposites, fibre-ieinforced composites and hybrid composites /

Structural Health Monitoring of Biocomposites, Fibre-Reinforced Composites and Hybrid Composites provides detailed information on failure analysis, mechanical and physical properties, structural health monitoring, durability and life prediction, modelling of damage processes of natural fiber, synthe...

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Détails bibliographiques
Cote:Libro Electrónico
Autres auteurs: Jawaid, Mohammad (Éditeur intellectuel), Thariq, Mohamed (Éditeur intellectuel), Saba, Naheed (Éditeur intellectuel)
Format: Électronique eBook
Langue:Inglés
Publié: Kidlington, United Kingdom : Woodhead Publishing, [2019]
Édition:First edition.
Collection:Woodhead Publishing series in composites science and engineering.
Sujets:
Composite materials.
Fibrous composites.
Biomass.
Biomass
Composites.
Composites �a fibres.
Biomasse.
composite material.
fibrous composite.
TECHNOLOGY & ENGINEERING > Engineering (General)
TECHNOLOGY & ENGINEERING > Reference.
Composite materials
Fibrous composites
Accès en ligne:Texto completo
Table des matières:
  • Front Cover; Structural Health Monitoring of Biocomposites, Fibre-Reinforced Composites and Hybrid Composites; Structural Health Monitoring of Biocomposites, Fibre-Reinforced Composites and Hybrid Composites; Copyright; Dedication; Contents; List of contributors; About the editors; Preface; 1
  • The effect of different fiber loading on flexural and thermal properties of banana/pineapple leaf (PALF)/glass hybrid c ... ; 1.1 Introduction; 1.2 Material and method; 1.3 Morphology analysis; 1.4 Thermal stability analysis; 1.5 Results and discussion; 1.5.1 Flexural test; 1.5.2 Image analyzer
  • 1.5.3 Scanning Electron Microscopy1.5.4 Thermogravimetric analysis; 1.5.5 Dynamic mechanical analysis; 1.6 Conclusion; Acknowledgments; References; 2
  • Biomass valorization for better aviation environmental impact through biocomposites and aviation biofuel; 2.1 Introduction; 2.1.1 Aviation environmental impact; 2.1.2 Sustainable biomass for aviation; 2.1.3 Biocomposites; 2.1.4 Jet biofuel; 2.2 Summary; References; Further reading; 3
  • Structural health monitoring of aerospace composites; 3.1 Introduction; 3.2 Failures and damages in composites; 3.3 Micro-level failure mechanisms
  • 3.3.1 Fiber-level failure mechanism3.3.1.1 Fiber fracture; 3.3.1.2 Fiber buckling; 3.3.1.3 Fiber bending; 3.3.1.4 Fiber splitting and radial cracking; 3.3.2 Matrix-level failure mechanisms; 3.3.2.1 Matrix cracking; 3.3.2.2 Fiber interfacial cracking; 3.3.3 Coupled fiber-matrix-level failure mechanism; 3.3.3.1 Fiber pullout; 3.3.3.2 Fiber breakage and interfacial debonding; 3.3.3.3 Transverse matrix cracking; 3.3.3.4 Fiber failure due to matrix cracking; 3.3.4 Macro-level failure mechanisms; 3.3.4.1 Manufacturing defects; 3.3.4.2 Loading-generated transverse stresses
  • 3.3.5 Coupled micro-macro failure mechanism3.3.6 Structural health monitoring; 3.3.7 Operational evaluation; 3.3.8 Data accession, fusion and cleansing; 3.3.9 Feature extraction and information condensation; 3.3.10 Statistical modal development; 3.4 Techniques used for aerospace composites; 3.4.1 Visual inspection; 3.4.2 Shearography method; 3.4.3 Transient thermographic technique; 3.4.4 Eddy current inspection; 3.4.5 Ultrasonic inspection technique; 3.4.6 Vibration-based damage identification technique; 3.4.7 Optical inspection method; 3.5 Conclusion; References
  • 4
  • Recent advances and trends in structural health monitoring4.1 Introduction; 4.2 State of the practice in bridge monitoring systems; 4.3 Factors affecting measurement data; 4.3.1 Environmental factors; 4.3.2 On-site construction defects; 4.3.3 Misinterpretations due to mixing of data by different monitoring techniques; 4.4 Benefits of structural health monitoring; 4.4.1 Enhanced public safety; 4.4.2 Early risk detection; 4.4.3 Improved life spans; 4.4.4 Cost effectiveness; 4.5 Challenges for structural health monitoring; 4.6 Advantages of structural health monitoring

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