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Materials Sciences and Applications

Materials Sciences and Applications

Materials Sciences and Applications

ISSN Print: 2153-117X
ISSN Online: 2153-1188
www.scirp.org/journal/msa
E-mail: msa@scirp.org
"Effect of Melt Scan Rate on Microstructure and Macrostructure for Electron Beam Melting of Ti-6Al-4V"
written by Karina Puebla, Lawrence E. Murr, Sara M. Gaytan, Edwin Martinez, Francisco Medina, Ryan B. Wicker,
published by Materials Sciences and Applications, Vol.3 No.5, 2012
has been cited by the following article(s):
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[3] A Design of Experiment Approach for Development of Electron Beam Powder Bed Fusion Process Parameters and Improvement of Ti-6Al-4V As-Built Properties
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[4] Online Monitoring Technology of Metal Powder Bed Fusion Processes: A Review
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[5] Additive manufacturing of Ti-6Al-4V alloy-A review
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[6] A critical review on additive manufacturing of Ti-6Al-4V alloy: microstructure and mechanical properties
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[7] Performance of High-Layer-Thickness Ti6Al4V Fabricated by Electron Beam Powder Bed Fusion under Different Accelerating Voltage Values
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[8] Types of 3D Printers Applied in Industrial Pharmacy and Drug Delivery
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[9] High speed in-process defect detection in metal additive manufacturing
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[10] Investigation and Mitigation of Powder Anomalies Induced Porosity in Powder Bed Additive Manufacturing
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[11] Консолидация металлических порошков на основе Cu и Ti методом послойного точечного электроимпульсного спекания
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[12] Ottimizzazione della finestra di processo dell'acciaio AISI H13 prodotto via Electron Beam Melting (EBM)
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[13] Structural integrity III: energy-based fatigue prediction for complex parts
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[14] Additive Manufacturing of Titanium Alloys-A Review
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[15] An Analysis on the Advanced Research in Additive Manufacturing
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[16] Electron Beam Melting: From Shape Freedom to Material Properties Control at Macro-and Microscale
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[17] Performance Improvement of Piston Engine in Aeronautics by Means of Additive Manufacturing Technologies
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[18] Analysis of geometrical defects in overhang fabrications in Electron Beam Melting based on thermomechanical simulations and experimental validations
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[19] The effect of beam scan strategies on microstructural variations in Ti-6Al-4 V fabricated by electron beam powder bed fusion
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[20] Influence of scan strategy on porosity and microstructure of Ti-6Al-4V fabricated by electron beam powder bed fusion
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[21] Comparison of wear properties of Ti6Al4V fabricated by wrought and electron beam melting processes in simulated body fluids
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[22] An Innovative Approach on Directed Energy Deposition Optimization: A Study of the Process Environment's Influence on the Quality of Ti-6Al-4V Samples
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[23] Improving mechanical properties of wire‐based EBAM Ti‐6Al‐4V parts by adding TiC powders
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[24] Finite element framework for electron beam melting process simulation
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[25] Metal additive manufacturing: Technology, metallurgy and modelling
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[26] Consolidation of Cu-and Ti-based metal powders using layer-by-layer, spot pulsed electric current sintering
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[27] Cell Behavior on 3D Ti-6Al-4 V Scaffolds with Different Porosities
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[28] Experimental Study on the Porosity of Electron Beam Melting-Manufactured Ti6Al4V
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[29] Continuous Electron Beam Post-Treatment of EBF3-Fabricated Ti–6Al–4V Parts
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[30] Micro-Macro Relationship between Microstructure, Porosity, Mechanical Properties, and Build Mode Parameters of a Selective-Electron-Beam-Melted Ti-6Al-4V Alloy
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[31] Additive manufacturing of Ti6Al4V alloy: A review
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[33] Contour design to improve topographical and microstructural characteristics of Alloy 718 manufactured using electron beam-powder bed fusion
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[34] In-situ Electron Imaging for the Electron Beam Melting Process.
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[35] In-situ Electron Imaging for the Electron Beam Melting Process
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[36] Illuminating the mechanisms that control the fatigue performance of additively manufactured Ti-6Al-4V
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[37] A review of on-line monitoring techniques in metal powder bed fusion processes
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[38] Geometrical accuracy of metallic objects produced with additive or subtractive manufacturing: A comparative in vitro study
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[39] Prediction of tensile strength of 3D printed part using response surface methodology
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[40] Processing windows for Ti-6Al-4V fabricated by selective electron beam melting with improved beam focus and different scan line spacings
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[41] Fatigue properties of Ti-6.5 Al-3.5 Mo-l. 5Zr-0.3 Si alloy produced by direct laser deposition
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[42] Optimisation of process parameters to address fundamental challenges during selective laser melting of Ti-6Al-4V: A review
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[43] Quantification and certification of additive manufacturing materials and processes
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[44] Influence of Manufacturing Parameters on Microstructure and Hydrogen Sorption Behavior of Electron Beam Melted Titanium Ti-6Al-4V Alloy
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[45] The Influence of Selective Laser Melting (SLM) Process Parameters on In-Vitro Cell Response.
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[46] The influence of selective laser melting (SLM) process parameters on in-vitro cell response
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[47] Corrosion of 3D-Printed Orthopaedic Implant Materials
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[48] Особенности консолидации металлических порошков в результате послойного электроимпульсного спекания
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[49] The features of metal powders consolidation by layer-by-layer electric discharge sintering
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[50] 金属粉末床熔融工艺在线监测技术综述
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[51] Laser and Electron Beam Additive Manufacturing Methods of Fabricating Titanium Bone Implants
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[53] Effect of energy input on microstructure and mechanical properties of titanium aluminide alloy fabricated by the additive manufacturing process of electron beam …
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[54] Optimising the Dynamic Process Parameters in Electron Beam Melting (EBM) to Achieve Internal Defect Quality Control
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[55] Structure and properties of parts produced by electron-beam additive manufacturing
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[56] A study on microhardness and microstructural evolution of titanium/zirconium diboride cermet coatings with varying scan speeds during laser cladding on Ti6Al4V …
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[57] Effect of Energy Input on Microstructure and Mechanical Properties of Titanium Aluminide Alloy Fabricated by the Additive Manufacturing Process of Electron …
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[61] Effect of energy input on microstructure and mechanical properties of titanium aluminide alloy fabricated by the additive manufacturing process of electron …
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[62] XCT Analysis of the Defect Distribution and its Effect on the Static and Dynamic Mechanical Properties in Ti-6Al-4V Components Manufactured by Electron …
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[63] Effects of fabrication conditions on mechanical properties of Ti-6Al-4V fabricated by powder bed fusion additive manufacturing
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[64] Metal Additive Manufacturing: A Review of Mechanical Properties (Postprint)
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[65] Metallic materials for 3D printing
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[66] Metal scaffolds processed by electron beam melting for biomedical applications
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[67] An Investigation of Sintering Parameters on Titanium Powder for Electron Beam Melting Processing Optimization
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[68] The Effectiveness of Hot Isostatic Pressing for Closing Porosity in Titanium Parts Manufactured by Selective Electron Beam Melting
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[69] Epitaxy and Microstructure Evolution in Metal Additive Manufacturing
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[70] Correlation between porosity and processing parameters in TiAl6V4 produced by selective laser melting
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[71] Additive manufacturing of metallic components by selective electron beam melting—a review
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[73] Critical assessment of the fatigue performance of additively manufactured Ti–6Al–4V and perspective for future research
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[74] Effect of scanning speed and powder flow rate on the evolving properties of laser metal deposited Ti-6Al-4V/Cu composites
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[75] Effect of processing parameters of electron beam melting machine on properties of Ti-6Al-4V parts
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[76] On the Fatigue Performance of Additively Manufactured Ti-6Al-4V to Enable Rapid Qualification for Aerospace Applications
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[80] Solid/Powder Clad Ti-6Al-4V Alloy with Low Young's Modulus and High Toughness Fabricated by Electron Beam Melting
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[81] Improvement of fatigue resistance and ductility of TiAl6V4 processed by selective laser melting
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[82] XCT analysis of the influence of melt strategies on defect population in Ti–6Al–4V components manufactured by Selective Electron Beam Melting
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[83] The Micro‐Mechanical Behavior of Electron Beam Melted Ti‐6A1‐4V Alloy
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[84] Influence of the Scanning Strategy on the Microstructure and Mechanical Properties in Selective Electron Beam Melting of Ti–6Al–4V
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[86] Methodology for Studying Effect of Cooling Rate During Laser Deposition on Microstructure
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[87] Scanning Speed Effect on Mechanical Properties of Ti-6Al-4V Alloy Processed by Electron Beam Additive Manufacturing
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[88] The Fabrication of Integrated Strain Sensors for “Smart” Implants using a Direct Write Additive Manufacturing Approach
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[89] The micro-mechanical behavior of electron beam melted Ti-6Al-4V alloy
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[90] Additive Manufacturing: Will it be a potential game changer for the aerospace manufacturing industry? A qualitative study of technology adoption
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[94] AM: Technologies: Process Window for Electron Beam Melting of Ti-6Al-4V
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[95] Process Window for Electron Beam Melting of Ti-6Al-4V
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[96] Integrated Control of Solidification Microstructure and Melt Pool Dimensions in Electron Beam Wire Feed Additive Manufacturing of Ti-6Al-4V
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[97] Analysis of defect generation in Ti–6Al–4V parts made using powder bed fusion additive manufacturing processes
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[98] Automatic Feedback Control in Electron Beam Melting Using Infrared Thermography
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[99] Understanding Ti-6Al-4V microstructure control in additive manufacturing via process maps
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[100] Process study and control of electron beam melting technology using infrared thermography
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[103] The influence of build parameters on the microstructure during electron beam melting of Ti6Al4V
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[104] Thermal Modeling and Simulation of Electron Beam Melting for Rapid Prototyping on Ti6Al4V Alloys.
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