Real-time measurement of shear fatigue crack propagation at high-temperature using the potential drop technique

Keyphrases

• High Temperature 100%
• Fatigue Crack Propagation 100%
• Crack Length 100%
• Time Measurement 100%
• Potential Drop Method 100%
• Shear Fatigue 100%
• Shear Specimens 66%
• Stress Intensity Factor 66%
• Nickel-based Superalloy 33%
• Finite Element Analysis 33%
• Long Distance 33%
• Loading Conditions 33%
• Two-electrode 33%
• Electrical Resistance 33%
• Central Region 33%
• Electrical Field 33%
• Crack Tip 33%
• Optical Measurement 33%
• Electrical Data 33%
• Resistance Potential 33%
• Direct Method 33%
• In-plane Shear 33%
• Crack Propagating 33%
• Potential Drop 33%
• High Temperature Test 33%
• Uniform Shear 33%
• Closed Crack 33%
• Shear Field 33%
• Electrically Conductive Materials 33%

Engineering

• Fatigue Crack Propagation 100%
• Crack Length 100%
• Measurement Time 100%
• Potential Drop 100%
• Stress-Intensity Factor 66%
• Finite Element Method 33%
• Loading Condition 33%
• Conductive Material 33%
• Progression 33%
• Electrical Field 33%
• In-Plane Shear 33%
• Crack Tip 33%
• Central Region 33%
• Propagating Crack 33%
• Gauge Area 33%
• High Temperature Testing 33%

Material Science

• Crack Propagation 100%
• Fatigue Crack 100%
• Stress Intensity Factor 100%
• Nickel-Based Superalloys 50%
• Finite Element Method 50%
• Electrical Resistance 50%
• Crack Tip 50%
• Optical Measurement 50%
• Conductive Material 50%