Enhancement of delamination fracture resistance of composites by fiber bridging and mulitple cracks

Keyphrases

• Fiber Bridging 100%
• Fracture Resistance 100%
• Delamination Fracture 100%
• Steady State 33%
• Cohesive Law 33%
• Crack Bridging 33%
• Micromechanical Modeling 33%
• Ligament 33%
• Secondary Crack 33%
• Primary Cracks 33%
• Composite Materials 16%
• Numerical Simulation 16%
• Single Crack 16%
• Between-person 16%
• Fiber Composites 16%
• Crack Growth 16%
• Layer Thickness 16%
• Wind Turbine Rotor Blades 16%
• Delamination 16%
• Length Parameter 16%
• Damage Tolerance 16%
• Large-scale Structure 16%
• Traction-separation Law 16%
• Composite Structures 16%
• Multiple Fiber 16%
• Large Crack 16%
• Fiber Direction 16%
• Multiple Cracks 16%
• Large-scale Bridging 16%
• Bridging Law 16%
• One-piece 16%
• Fracture Process Zone 16%
• Fiber Radius 16%
• Aligned Fibers 16%
• Cohesive Traction 16%

Engineering

• Bridging 100%
• Impact Toughness 100%
• Delamination 100%
• Cohesive Law 33%
• Length Scale 33%
• Crack Bridging 33%
• Crossover 33%
• Computer Simulation 16%
• Rotor Blade 16%
• Micromechanical Model 16%
• Process Zone 16%
• Separation Law 16%
• Multiple Crack 16%
• Single Crack 16%
• Crack Face 16%
• Individual Layer 16%
• Damage Tolerance 16%
• Fiber Direction 16%
• Composite Fiber 16%
• Micromechanics Model 16%
• Aligned Fiber 16%
• Defects 16%
• Crack Growth 16%
• Cohesive Traction 16%
• Primary Crack 16%
• Composite Material 16%
• Wind Turbine 16%
• Composite Structure 16%

Material Science

• Fracture Toughness 100%
• Delamination 100%
• Crack Bridging 33%
• Composite Material 16%
• Crack Growth 16%
• Damage Tolerance 16%
• Micromechanics 16%