Finite element modelling of abrasive waterjet milled footprints

Keyphrases

• Abrasive Water Jet 100%
• Finite Element Modeling 100%
• Traverse Speed 60%
• Garnet 40%
• Workpiece Material 40%
• Target Surface 40%
• Abrasive Particles 40%
• Plume 40%
• Sharp Cutting Edge 20%
• Ti-6Al-4V (Ti64) 20%
• Order of Accuracy 20%
• Generated Data 20%
• Possible Sources 20%
• Model Validation 20%
• Finite Element Model 20%
• Modeling Approach 20%
• Finite Element Method 20%
• Abrasive Waterjet Milling 20%
• Erosion Rate 20%
• Error Sources 20%
• Aerospace Industry 20%
• Model Simulation 20%
• Superalloy 20%
• Friction 20%
• Gaussian Distribution 20%
• Particle Shape 20%
• Jet Power 20%
• Finite Element Simulation 20%
• Adiabatic Heating 20%
• Elastic-plastic 20%
• Kinematic Parameters 20%
• Kerf 20%
• Material Description 20%
• Strain Rate Sensitivity 20%
• Milling Mode 20%
• Maximum Depth 20%
• Strain Rate Effect 20%
• Material Erosion 20%
• Particle Flow 20%
• Pump Pressure 20%
• Non-spherical Shape 20%
• Effect of Mass Flow Rates 20%
• Johnson-Cook Failure Criterion 20%
• Tensile Failure Criterion 20%
• Accuracy Error 20%
• Real Interaction 20%
• Titanium Base 20%
• Energy Parameters 20%
• Abrasive Mass Flow 20%

Engineering

• Finite Element Modeling 100%
• Target Surface 100%
• Abrasive Particle 100%
• Failure Criterion 100%
• Energy Engineering 50%
• Cutting Edge 50%
• Finite Element Method 50%
• Ti-6al-4v 50%
• Computer Simulation 50%
• Gaussians 50%
• Acceptable Level 50%
• Finite Element Simulation 50%
• Tensiles 50%
• Mass Flowrate 50%
• Effect of Strain 50%
• Material Erosion 50%
• Pump Pressure 50%
• Accuracy-Error 50%
• Material Description 50%
• Strain Rate Sensitivity 50%
• Particle Flow 50%

Material Science

• Garnet 100%
• Finite Element Method 100%
• Finite Element Modeling 100%
• Ti-6Al-4V 50%
• Titanium 50%
• Strain Rate 50%
• Superalloys 50%
• Effect of Strain 50%