Evaluating glass fiber reinforced composite sleepers to mitigate elastic fastening system spike fatigue failure: A finite element study

Keyphrases

• Composite Sleeper 100%
• Compressive Strength 50%
• Derailment 16%
• Engineered Composites 16%
• Fasteners 50%
• Fastening System 100%
• Fatigue Failure 100%
• Fatigue Limit 33%
• Finite Element Model 16%
• Finite Element Study 100%
• Glass Fiber Composite 100%
• High Elastic Modulus 16%
• Loading Path 16%
• Longitudinal Force 16%
• Longitudinal Load 33%
• Material Properties 16%
• Mechanistic-empirical Design 16%
• Mitigation Methods 16%
• Model Validation 16%
• North America 16%
• Operating Environment 16%
• Railroad 16%
• Sleeper 16%
• Spike-in 16%
• Stiffness 16%
• Strength Properties 16%
• Timber Sleeper 50%
• Tracking System 16%
• Values-led 16%

Engineering

• American Railroad 33%
• Compression Strength 100%
• Compressive Strength 100%
• Derailments 33%
• Fastening System 100%
• Fatigue Failure 100%
• Fatigue Limit 66%
• Fiber-Reinforced Composite 100%
• Finite Element Analysis 100%
• Finite Element Modeling 33%
• Led Value 33%
• Longitudinal Force 33%
• Longitudinal Load 66%
• Modulus of Elasticity 33%
• Operating Environment 33%

Material Science

• Composite Material 100%
• Compressive Strength 75%
• Elastic Moduli 25%
• Fastener 75%
• Fiber-Reinforced Composite 100%
• Finite Element Method 100%
• Finite Element Modeling 25%
• Glass Fiber 100%
• Materials Property 25%
• Timber 75%