High-Energy Method of Transformation of Casting Metals and Alloys to the Composite Materials

Yulia Usherenko; Sergey Usherenko; Javad Yazdani

doi:10.4028/www.scientific.net/KEM.721.290

Paper Titles

Synthesis of the Gadolinium-Yttrium-Aluminum Garnet Activated with Cerium by Spraying High Aqueous Salt Solutions
p.267

Compaction of Powdered Materials Reinforced with Milled W-B Fibers
p.275

Research of Laser Cladding of the Powder Materials for Die Repair
p.280

Synthesis of Fe-ZrO₂ Composite Powders by Thermochemical Method
p.285

High-Energy Method of Transformation of Casting Metals and Alloys to the Composite Materials
p.290

Properties of Nanosized Ferrite Powders and Sintered Materials Prepared by the Co-Precipitation Technology, Combined with the Spray-Drying Method
p.295

New Composite Materials Based on Intermetallics for Protection Details of Hydropower Equipment from Cavitation, Hydroabrasive and Corrosion Wear
p.300

Evaluation of Thermal Shock Influence on Cordierite Using Impulse Excitation Technique and Dynamic Mechanical Analysis
p.306

Synthesis of Eu²⁺ and Dy³⁺ Doped Strontium Aluminates and their Properties
p.311

HomeKey Engineering MaterialsKey Engineering Materials Vol. 721High-Energy Method of Transformation of Casting...

High-Energy Method of Transformation of Casting Metals and Alloys to the Composite Materials

Abstract:

Work related to the development of metal composite materials using effect of super-deep penetration (SDP) of powder particles. Composite materials are obtained from usual casting billets. During SDP process powder particles work as needles and the fibers are formed in metal matrix under dynamic interaction between powder particles and matrix material. Researchers showed high non-uniformity of the chemical composition of the processed material. Material was doped with a high amount of alloying elements at SDP. It may explain specific mechanical and chemical properties of the structure of this new composite material.

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Periodical:

Key Engineering Materials (Volume 721)

Pages:

290-294

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.721.290

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Online since:

December 2016

Authors:

Yulia Usherenko*, Sergey Usherenko, Javad Yazdani

Keywords:

Alloying Materials, Composites, Dopants, Powders, Super-Deep Penetration

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