Comparison of Activation Technologies Powder ECP-1 for the Synthesis of Products Using SLS

E.V. Babakova; A.V. Gradoboev; Alexandr Saprykin; E.A. Ibragimov; Vladimir I. Yakovlev; Alexey Sobachkin

doi:10.4028/www.scientific.net/AMM.756.220

Paper Titles

Modeling of Mechanical Behavior of Ceramic Nanocomposites
p.187

Multiscale Simulation of Porous Quasi-Brittle Ceramics Fracture
p.196

Mechanical Behavior of Light Alloys with Bimodal Grain Size Distribution
p.205

Influence of Layer-by-Layer Laser Sintering Modes on the Roughness and Thickness of Sintered Layer of Copper Powder
p.214

Comparison of Activation Technologies Powder ECP-1 for the Synthesis of Products Using SLS
p.220

An Application of Spark Plasma Sintering for Compaction of Refractory Oxides and Nitrides
p.225

A Cylindrical Shell Made of Glass-Metal Composite
p.230

Formation of Gradient Multiphase Nanostructured Surface Layers Using the Electron-Ion-Plasma Combined Method
p.236

Phase Formation in the Ti-Y-O System Formed Using High-Energy Methods
p.243

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 756Comparison of Activation Technologies Powder ECP-1...

Comparison of Activation Technologies Powder ECP-1 for the Synthesis of Products Using SLS

Abstract:

At present the development of methods of layer-by-layer and line-by-line synthesis of finished prototypes and functional products made of powder materials furthers introduction of these technologies into different areas of human activities from light to heavy industry and medicine. The research has been carried out to describe how gamma radiation of the Co⁶⁰ radioactive isotope and the mechanical activation makes an impact on the copper powder, as well as the nature of sintering by the layer-by-layer laser synthesis. The changes of the structure and properties of the powder, which generally affects the layer-by-layer laser process of products sintering, have been detected.

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Periodical:

Applied Mechanics and Materials (Volume 756)

Pages:

220-224

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.756.220

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Online since:

April 2015

Authors:

E.V. Babakova, A.V. Gradoboev, Alexandr Saprykin, E.A. Ibragimov, Vladimir I. Yakovlev, Alexey Sobachkin

Keywords:

Ionizing Radiation, Mechanical Activation, Metal Powder, Selective Laser Sintering

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