Biaxial fatigue failure of short glass fiber reinforced polyamide 6,6: An in-depth investigation of stiffness drop and microstructural evolution

Engineering

• Fatigue Failure 100%
• Damage Accumulation 100%
• Microstructural Evolution 100%
• Polyamide 100%
• Biaxial Fatigue 100%
• Mechanical Fatigue Test 66%
• Fatigue Loading 66%
• Fatigue Damage 66%
• Thermal Degradation 66%
• Creep 66%
• Internal Friction 66%
• Automotives 33%
• Damage Mechanism 33%
• Digital Image Correlation Technique 33%
• Heat Generation 33%
• Strain Energy 33%
• Major Part 33%
• Polymer Matrix 33%
• Mechanical Damage 33%
• Fracture Surface 33%
• Strain Field 33%
• Debonding 33%
• Remaining Portion 33%
• Fibre End 33%
• Fibre Break 33%
• Vibration Dynamics 33%
• Porosity 33%
• Dynamic Mechanical Analysis 33%

Keyphrases

• Stiffness 100%
• Polyamide 66 (PA66) 100%
• Fatigue Failure 100%
• Glass Fiber Reinforced Polyamide 6 100%
• Microstructural Evolution 100%
• Multiaxial Fatigue 100%
• Damage Accumulation 50%
• Fatigue Test 33%
• Internal Friction 33%
• Thermal Degradation 33%
• Cyclic Creep 33%
• Dynamic Mechanical Analysis 16%
• Scanning Electron Microscopy 16%
• Porosity 16%
• Increased Temperature 16%
• Reinforced 16%
• Digital Image Correlation Technique 16%
• Automotive Industry 16%
• Heat Generation 16%
• Strain Energy 16%
• Polymer Matrix 16%
• Mechanical Damage 16%
• Varying Temperature 16%
• Fiber Breakage 16%
• Thermal Damage 16%
• Fracture Surface 16%
• Fatigue Load 16%
• Fatigue Damage 16%
• Cavitation 16%
• Short Glass Fiber 16%
• Temperature Stabilization 16%
• External Temperature 16%
• Debonding 16%
• Being Observed 16%
• Thermography 16%
• Fatigue Mechanism 16%
• Dynamic Vibration 16%
• Crazing 16%
• Strain Field 16%
• Multiple Directions 16%
• In Situ Strain 16%
• Short Glass Fibre Reinforced Thermoplastics 16%
• PA66GF30 16%
• Thermal Evolution 16%
• Fiber Ends 16%
• Biaxial Fatigue Loading 16%

Material Science

• Polyamide 100%
• Biaxial Fatigue 100%
• Microstructural Evolution 100%
• Glass Fiber 100%
• Creep 66%
• Internal Friction 66%
• Thermal Degradation 66%
• Fatigue Damage 66%
• Dynamic Mechanical Analysis 33%
• Scanning Electron Microscopy 33%
• Thermoplastics 33%
• Vibration Dynamics 33%
• Debonding 33%
• Polymer Matrix 33%