Multi-scale study of tensile properties and large deformation mechanisms of polyethylene terephthalate/polypropylene knitted composites

Keyphrases

• Knitted Composites 100%
• Tensile Properties 100%
• Polypropylene 100%
• Large Deformation Mechanism 100%
• Large Deformation 100%
• Polyethylene Terephthalate 100%
• Matrix Cracking 100%
• Energy Absorption Mechanism 100%
• Plasma Treatment 50%
• Knitted Preforms 50%
• Compression Molding 50%
• Tensile Loading 50%
• Fabric Structure 50%
• Polyester 50%
• Fiber Surface 50%
• Fiber-matrix Debonding 50%
• Deformation Process 50%
• Fiber Volume Fraction 50%
• Crack Initiation 50%
• Morphological Changes 50%
• Composite Surface 50%
• Crack Propagation 50%
• In Meso 50%
• Extended Matrix 50%
• In-situ SEM Observation 50%
• Quasi-static Tensile Test 50%
• Tensile Energy 50%
• Brittle Matrix 50%
• Composite Fracture 50%
• Continuous-filament Yarn 50%
• Matrix Compression 50%
• Matrix Extension 50%
• Compression Matrix 50%
• Loading Direction 50%
• Weft-knitted Composites 50%

Engineering

• Multiscale 100%
• Large Deformation 100%
• Deformation Mechanism 100%
• Tensile Property 100%
• Fibre Surface 50%
• Energy Absorption Mechanism 50%
• Matrix Crack 50%
• Mesoscale 25%
• Microscale 25%
• Tensiles 25%
• Compression Molding 25%
• Fabric Structure 25%
• Plasma Treatment 25%
• Deformation Process 25%
• Loading Direction 25%
• Debonding 25%
• Crack Propagation 25%
• Crack Initiation 25%
• Continuous Filament Yarn 25%
• Fiber Volume Fraction 25%
• Critical Point 25%

Material Science

• Composite Material 100%
• Polypropylene 100%
• Polyethylene Terephthalate 100%
• Large Deformation 100%
• Deformation Mechanism 100%
• Tensile Property 100%
• Fiber Structure 25%
• Thermoplastics 25%
• Debonding 25%
• Volume Fraction 25%
• Scanning Electron Microscopy 25%
• Compression Molding 25%
• Crack Propagation 25%
• Crack Initiation 25%
• Surface (Surface Science) 25%
• Polyester 25%
• Morphology 25%