Metal Additive Manufacturing

<ul><li>Preface</li><li>Chapter 1: Powder Bed Fusion (PBF)</li><li>Microstructure of Built Part Obtained by Powder Bed Fusion Process with Metal</li><li>Powder Bed Fusion of Biomedical Co-Cr-Mo and Ti-6Al-4V Alloys: Microstructure and Mechanical Properties</li><li>Impact Testing of H13 Tool Steel Processed with Use of Selective Laser Melting Technology</li><li>Comparison of Hardness of Surface 316L Stainless Steel Made by Additive Technology and Cold Rolling</li><li>Electrochemical Characterization of Ti6Al4V Components Produced by Additive Manufacturing</li><li>X-Ray CT Investigation of Graded Ti-Ti64 Material Produced by Selective Laser Melting</li><li>Effect of Selective Laser Melting Process Parameters and Heat Treatment on Microstructure and Properties of Titanium Alloys Produced from Elemental Powders</li><li>Investigation of Functional Graded Steel Parts Produced by Selective Laser Melting</li><li>Formation of Structure in Titanium Lightweight Structures Made by Selective Laser Melting</li><li>Physical and Tensile Properties of NiTi Alloy by Selective Electron Beam Melting</li><li>Metallic Materials Prepared by Selective Laser Melting: Part Orientation Issue</li><li>Microstructure and Mechanical Properties of Ti-6Al-4V Alloy Samples Fabricated by Selective Laser Melting</li><li>Selective Laser Melting of Multi-Principal NiCrWFeTi Alloy: Processing, Microstructure and Performance</li><li>Heat Transfer and Phase Formation through EBM 3D-Printing of Ti-6Al-4V Cylindrical Parts</li><li>Comparative Study of the Ultrafine-Grained Structure 316L Stainless Steel and Ti-6-4 Alloy Produced by Selective Laser Melting</li><li>Energy Absorbing Properties of the Cellular Structures with Different Wall Thickness, Produced by the Selective Laser Melting</li><li>Mechanical Properties and Fatigue Resistance of 3D Printed Inconel 718 in Comparison with Conventional Manufacture</li><li>Control of Deviations in Lattice Structures Manufactured by Selective Laser Melting</li><li>Selective Laser Melting of AlSi12 Powder</li><li>Single Track Formation during Selective Laser Melting of Ti-6Al-4V Alloy</li><li>Solidification and Microstructural Control in Selective Electron Beam Melting of Co-29Cr-10Ni-7W Alloy</li><li>Fabrication of the Beta-Titanium Alloy Rods from a Mixture of Pure Metallic Element Powders via Selected Laser Melting</li><li>Microstructure and Fatigue Properties of TiAl with Unique Layered Microstructure Fabricated by Electron Beam Melting</li><li>Melting and Solidification Behavior of High-Strength Aluminum Alloy during Selective Laser Melting</li><li>Fabrication of Cu-Al-Ni Shape Memory Alloy by Selective Laser Melting Process</li><li>Microstructure Characterization of AlSi10Mg Fabricated by Selective Laser Melting Process</li><li>Comparison of the Hot Working Behavior of Wrought, Selective Laser Melted and Electron Beam Melted Ti-6Al-4V</li><li>Laser Based Manufacturing of Ti6Al4V: A Comparison of LENS and Selective Laser Melting</li><li>Experimental Study on Pore-Defect by Selective Laser Melting of 316L Stainless Steel</li><li>Wettability Behavior of Ti6Al4V Electron Beam Melted Surfaces</li><li>Use of Selective Laser Melting for Manufacturing the Porous Stack of a Thermoacoustic Engine</li><li>Selective Laser Melting of Ti42Nb Composite Powder and the Effect of Laser Re-Melting</li><li>Laser Assisted High Entropy Alloy Coating on Low Carbon Steel</li><li>Contribution of Additive Manufacturing of Rare Earth Material to the Increase in Performance and Resource Efficiency of Permanent Magnets</li><li>Research on Forming Quality of AlSi10Mg Powder for SLM Process</li><li>Chapter 2: Direct Energy Deposition (DED)</li><li>Laser Cladding of Heat-Resistant Iron Based Alloy</li><li>Characteristics and Evolution Mechanism of Solidification Microstructure for Laser Additive Manufactured Ti₂AlNb-Based Alloy</li><li>An Experimental Characterization of Powder/Substrate Interaction during Direct Metal Deposition for Additive Manufacturing</li><li>From Powder to Solid: The Material Evolution of Ti-6Al-4V during Laser Metal Deposition</li><li>Microstructure and Mechanical Properties of Ti-6.5Al-3.5Mo-1.5Zr-0.3Si Alloy Fabricated by Arc Additive Manufacturing with Post Heat Treatment</li><li>Optimization of Microstructural Evolution during Laser Cladding of Ni Based Powder on GCI Glass Molds</li><li>Air-Cooling Influence on Wire Arc Additive Manufactured Surfaces</li><li>Electron and Laser Beam Additive Manufacturing with Wire - Comparison of Processes</li><li>Influence of Technological Parameters of Direct Laser Deposition Process on the Structure and Properties of Deposited Products from Alloy Ti-6Al-4V</li><li>Experimental Investigation of Temperature Distribution during Wire-Based Laser Metal Deposition of the Al-Mg Alloy 5087</li><li>Microstructural Characteristics of Laser Metal Deposited Magnesium Alloy AZ31</li><li>Additive Manufacturing of Titanium Parts Using 3D Plasma Metal Deposition</li><li>Research of the Structure Defects at Wire-Feed Laser and Laser-Arc Deposition with AlMg6</li><li>Chapter 3: Cold Spray</li><li>Architectured Multi-Metallic Structures Prepared by Cold Dynamic Spray Deposition</li><li>Cold Spray for Additive Manufacturing: Possibilities and Challenges</li><li>Investigation of Aluminum Composite Produced by Laser-Assisted Cold Spray Additive Manufacturing</li><li>Additive Manufacturing of a CNT/Al6Si Composite with the Nanolaminated Architecture via Cold Spray Deposition</li><li>Cold Sprayed Additive Manufacturing of SiC/Al Metal Matrix Composite: Synthesis, Microstructure, Heat Treatment and Tensile Properties</li><li>Chapter 4: Metal Matrix Composites</li><li>Cladding of Stellite-6/WC Composites Coatings by Laser Metal Deposition</li><li>The Effect of Laser Power on the Microstructure of the Nb-Si Based <i>In Situ</i> Composite, Fabricated by Laser Metal Deposition</li><li>Microstructure and Mechanical Properties of TiB₂/ Al-Si Composites Fabricated by TIG Wire and Arc Additive Manufacturing</li><li>Selective Laser Melting of Nanocomposite Ti-6Al-4V and TiC Powder</li><li>Selective Laser Melting of Ti/cBN Composite</li><li>The Preparation of TiC/TiN Composites by Selective Laser Melting</li><li>Fabrication and Tailoring Interface Structure of Diamond/Al(and Al12Si) Composites for Heat Sink Applications by Vacuum Hot Pressing and Selective Laser Melting</li><li>Quasicrystalline Composites by Additive Manufacturing</li><li>Additive Manufacturing of Ti-6Al-4V with Added Boron: Microstructure and Hardness Modification</li><li>Selective Laser Melting of Mixed EP648-Alumina Powder</li><li>Selective Laser Fusion of Titanium Based Gradient Alloy Reinforced by Nano Sized TiC Ceramic</li><li>Chapter 5: Powder Characteristics</li><li>Effects of the Delivery Tube Diameter on the Qualities of Cu-9.7Sn-0.2P Alloy Powder Produced by Gas Atomization</li><li>Development of Bio-Compatible Beta Ti Alloy Powders for Additive Manufacturing for Application in Patient-Specific Orthopedic Implants</li><li>Research Progress of Preparation Technology of Nano Copper Powder for 3D Printing</li><li>Obtaining Spherical Powders of Grade 5 Alloy for Application in Selective Laser Melting Technology</li><li>The Study of the Characteristics of Metallic Powders after Electroerosion Dispersion</li><li>Water Atomized 17-4 PH Stainless Steel Powder as a Cheaper Alternative Powder Feedstock for Selective Laser Melting</li><li>Compositional Optimization of In718 Superalloy Powder for Additive Manufacturing</li><li>Characterization of Gas Atomized Ti-6Al-4V Powders for Additive Manufacturing</li><li>Developing New Materials for Electron Beam Melting: Experiences and Challenges</li><li>Metallographic Analysis of the Suitability of a WC-Co Powder Blend for Selective Laser Melting Technology</li><li>The Influence of Powder Particle and Grain Size on Parts Manufacturing by Powder Bed Fusion</li><li>Effect of Powder Type and Particles Size on Microstructure of Selective Laser Sintered Parts</li><li>Chapter 6: Process Parameters</li><li>The Energy Density as a Reliable Parameter for Characterization of Selective Laser Melting of Various Alloys</li><li>Selective Laser Melting of Inconel 718 under High Power and High Scanning Speed Conditions</li><li>Effects of Process Parameters on Morphologies and Microstructures of Laser Melting Deposited V-5Cr-5Ti Alloys</li><li>Optimizing HIP and Printing Parameters for EBM Ti-6Al-4V</li><li>The Challenges Associated with the Formation of Equiaxed Grains during Additive Manufacturing of Titanium Alloys</li><li>Preliminary Analysis of Soft Magnetic Material Properties for Additive Manufacturing of Electrical Machines</li><li>Influence of Building Parameters on Surface Aspect and Roughness in Additive Manufactured Metal Parts</li><li>Chapter 7: Post-Processing and Machining</li><li>Influence of Abrasive Materials in Fluidised Bed Machining of AlSi10Mg Parts Made through Selective Laser Melting Technology</li><li>Secondary Machining Characteristics of Additive Manufactured Titanium Alloy Ti-6Al-4V</li><li>Effects of Heat Treatment on Compressive Behavior of Porous Aluminum Manufactured by SLM</li><li>Effects of Heat Treatment on Unique Layered Microstructure and Tensile Properties of TiAl Fabricated by Electron Beam Melting</li><li>Heat Treatment Behavior of the 18Ni300 Maraging Steel Additively Manufactured by Selective Laser Melting</li><li>Influence of Heat Treatment on Microstructure and Mechanical Properties of Selective Laser Melted TiAl6V4 Alloy</li><li>Effect of Optimized Heat Treatments on the Tensile Behavior and Residual Stresses of Selective Laser Melted AlSi10Mg Samples</li><li>Assessment of Heat Treatment Effect on AlSi10Mg by Selective Laser Melting through Indentation Testing</li><li>In-Process Laser Re-Melting of Thin Walled Parts to Improve Surface Quality after Laser Metal Deposition</li><li>Improving the Surface Finish and other Properties of Engineering Metal Parts</li><li>Evolution of the Lattice Structures Properties Manufactured by Selective Laser Melting and Subsequent Hot Isostatic Pressing</li><li>Efficiency of Hybrid Cyclic Processing with the Use of Additive Technologies on CNC Machines for the Manufacture of Composite Aviation Parts due to the Reduction of Processing Errors</li><li>Chapter 8: Modelling of Additive Manufacturing Processes</li><li>Properties Anisotropy of Additive Manufactured High-Porous Titanium Alloy with Non-Equiaxial Cellular Structure</li><li>Designing of Topology Optimized Parts for Additive Manufacturing</li><li>Current Issues of Developing Methodology and Software Solutions Used in Different Phases of Modelling Additive Production Processes</li><li>Evaluation of the Thermal Processes and Simulation Methods for Additive Manufacturing Based on the Geometry Voxel Representation</li><li>Numerical Modeling of Thermal Processes while Depositing Layers in Additive Production</li><li>Cold Gas Dynamic Spray Technology: The Simulation of Aerodynamics of Flow</li><li>Thermo-Mechanical Analysis of Laser Additive Manufacturing for Metals</li><li>Industry 4.0 - Digital Twin Applied to Direct Digital Manufacturing</li><li>3D Printing of Parts with Intra-Layer Variable Density</li><li>Numerical Simulations and Experimental Studies on the Quasi-State Axial Compression Behavior of Steel-Based Porous Materials</li></ul>