Fiber-reinforced composites in milling and grinding: machining bottlenecks and advanced strategies

Keyphrases

• Fiber-reinforced Composites 100%
• Milling Machining 100%
• Grinding Machine 100%
• Advanced Strategies 100%
• Surface Damage 50%
• Surface Integrity 50%
• Minimum Quantity Lubrication 50%
• Suppression Strategy 50%
• Cryogenic Cooling 50%
• Conventional Machining 25%
• Cutting Tool 25%
• Near-net-shape 25%
• High Strength 25%
• Design Optimization 25%
• Aerospace 25%
• Composite Component 25%
• Tool Wear 25%
• Delamination 25%
• Material Removal Mechanism 25%
• Effective Method 25%
• Tears 25%
• Cutting Technology 25%
• Aviation 25%
• Formation Mechanism 25%
• Ultrasonic Vibration 25%
• Covering Material 25%
• Friction Coefficient 25%
• Difficult-to-machine 25%
• Finishing Process 25%
• Strength Performance 25%
• Grinding Mechanism 25%
• Formation Damage Mechanisms 25%
• Assembly Tolerance 25%
• Surface Machining 25%
• Burr 25%
• Tool Optimization 25%
• Undesirable Results 25%
• Precision Surface 25%
• Machining Force 25%
• Precision Processing 25%
• Unit Weight 25%
• Friction Reduction 25%
• Dimensional Tolerance 25%
• Thermomechanical Behavior 25%
• Exploration Direction 25%
• Ultrasonic Vibration Machining 25%

Engineering

• Grinding (Machining) 100%
• Fiber-Reinforced Composite 100%
• Ultrasonics 50%
• Minimum Quantity Lubrication 50%
• Cryogenic Cooling 50%
• Surface Integrity 25%
• Conventional Machining 25%
• Damage Surface 25%
• Fits and Tolerances 25%
• Near Net Shape 25%
• Engineering 25%
• Anisotropic 25%
• Design Optimization 25%
• Assisted Machining 25%
• Delamination 25%
• Material Removal Mechanism 25%
• Friction Coefficient 25%
• Formation Damage 25%
• Burrs 25%
• Strength Performance 25%
• Finishing Operation 25%
• Machining Force 25%

Material Science

• Machining 100%
• Fiber-Reinforced Composite 100%
• Lubrication 40%
• Surface Damage 20%
• Cutting Tool 20%
• Mechanical Strength 20%
• Composite Material 20%
• Mechanical Property 20%
• Delamination 20%