Three-Dimensional Modeling of Impact Fractures in Brittle Materials via Peridynamics

Keyphrases

• Brittle Materials 100%
• Three-dimensional Modeling 100%
• Impact Fracture 100%
• Peridynamics 100%
• Three-dimensional (3D) 66%
• Fracture Model 66%
• Impact Fracture Behavior 44%
• Glass Panel 22%
• Peridynamic Method 22%
• Computational Techniques 11%
• Prediction Accuracy 11%
• Numerical Model 11%
• Numerical Simulation 11%
• Computational Effort 11%
• Efficient Simulation 11%
• Impact Resistance 11%
• Model Validation 11%
• Computational Resources 11%
• Fracture Phenomena 11%
• Material Response 11%
• Time Resources 11%
• Overpass 11%
• Mesh-based 11%
• Saving Time 11%
• Impact Area 11%
• Impact Loading 11%
• Practical Engineering Application 11%
• Design Parameter Optimization 11%
• Float Glass 11%
• Impact Scenarios 11%
• Tempered Glass 11%
• Impact Collision 11%
• Panel Thickness 11%
• Fracture Simulation 11%
• High Efficiency 11%
• Impact Projectile 11%
• Projectile Velocity 11%
• Real-world Impact 11%

Engineering

• Peridynamics 100%
• Dimensional Modeling 100%
• Brittleness 100%
• Fracture Behavior 44%
• Glass Panel 22%
• Experimental Observation 11%
• Simulation Tool 11%
• Computational Resource 11%
• Experimental Measurement 11%
• Accurate Prediction 11%
• Design Parameter 11%
• Computational Technique 11%
• Computational Effort 11%
• Material Response 11%
• Impact Scenario 11%
• Panel Thickness 11%
• Impact Loads 11%
• Engineering Application 11%
• Overpasses 11%
• Numerical Model 11%
• Collision Impact 11%
• Float Glass 11%
• Projectile Velocity 11%
• Impact Resistance 11%

Material Science

• Brittleness 100%
• Fracture Behavior 66%
• Impact Loads 16%
• Poly Methyl Methacrylate 16%
• Impact Resistance 16%