Temperature distribution and melt geometry in laser and electron-beam melting processes - A comparison among common materials

Keyphrases

• Temperature Distribution 100%
• Common Materials 100%
• Melt Geometry 100%
• Electron Beam Melting Process 100%
• Laser Beam Melting 100%
• Powder Bed 66%
• Aluminum Powder 66%
• In Situ 33%
• Rutile 33%
• Phase Change 33%
• Heat Dissipation 33%
• Microstructure 33%
• Low Power 33%
• Manufacturing Difficulty 33%
• Finite Element Modeling 33%
• Electron Beam 33%
• Melting Process 33%
• User Community 33%
• Ti-6Al-4V (Ti64) 33%
• Ultra-high Speed 33%
• Heat Source 33%
• Diffusivity 33%
• Transient Dynamics 33%
• Laser Beams 33%
• Local Temperature 33%
• Build Process 33%
• Stainless Steel 316 33%
• Melt Pool 33%
• Laser Model 33%
• Geometry Distribution 33%
• Additive Technologies 33%
• Part Quality 33%
• 7075 Aluminum Alloy 33%
• Heat Accumulation 33%
• Latent Heat of Fusion 33%
• Titanium Powder 33%
• Dynamic Finite Element Model 33%
• Metallic Powder 33%
• Electron Beam Melting 33%
• Melt Pool Geometry 33%
• Melt Pool Depth 33%
• Melt Pool Temperature 33%
• Powder Bed Additive Manufacturing 33%
• Thermal Aspects 33%
• Melt Pool Size 33%
• Continuous Melting 33%

Engineering

• Melt Pool 100%
• Powder Bed 100%
• Melting Process 100%
• Temperature Distribution 100%
• Melting Point 100%
• Electron Beam Melting 100%
• Aluminum Powder 66%
• Heat Losses 33%
• Microscale 33%
• Transients 33%
• Stainless Steel 33%
• Finite Element Modeling 33%
• Latent Heat 33%
• Diffusivity 33%
• Final Part 33%
• Additive Manufacturing Technology 33%
• Part Quality 33%
• Decreasing Order 33%
• Pool Size 33%
• Metallic Powder 33%
• Fem Model 33%
• Heat Sources 33%
• Actuator 33%

Material Science

• Aluminum 100%
• Titanium 66%
• Finite Element Modeling 66%
• Three Dimensional Printing 33%
• Diffusivity 33%
• Stainless Steel 33%
• Solidification 33%