SHS Ferroaluminum Obtained from the Disperse Waste of Engineering

G.N. Safronov; N.N. Safronov; L.R. Kharisov

doi:10.4028/www.scientific.net/MSF.870.437

Paper Titles

Kinetic Description of (Cr, Fe)₇C₃ Carbide Dissolution in Austenite of High-Carbon Fe-Cr-C Ternary Alloys
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Plasma-Electrolytic Treatment as an Innovative and Resource-Saving Technology of Metal Surface Treatment
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X-Ray Microanalysis of Hardmetal Powder, Produced by Electroerosion Dispersion of VK8 Alloy in Kerosene Environment
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Investigation of the Surface Layer Structure of High-Chromium and High-Strength Steels at the Variation of the Heating Temperature
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SHS Ferroaluminum Obtained from the Disperse Waste of Engineering
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Changing the Arc Efficiency during Melting of a Charge in Arc Steel Melting Furnaces
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Energy Reduction Technologies Based on the Lubricant Supply in the Roll Contact System "Quarto" during the Hot Strip Rolling
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Technology of Packing Materials for Metal Products
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Effect of Stress-Strain State during Combined Deformation on Microstructure Evolution of High Carbon Steel Wire
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HomeMaterials Science ForumMaterials Science Forum Vol. 870SHS Ferroaluminum Obtained from the Disperse Waste...

SHS Ferroaluminum Obtained from the Disperse Waste of Engineering

Abstract:

This article provides a method of disposing of a particulate waste that allows treatment to produce ferroaluminum. In this work the optimization of the charge composition was carried out by the planned experiment to obtain the maximum performance properties of the SHS ferroaluminum. The article presents the analysis of the conditions of formation of the ferroaluminum microstructure in the process of the self-propagating high-temperature synthesis. The SHS process is initiated in the mixture composed of the dispersed waste engineering. The factors influencing the formation of the alloy structure were brought out.

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Periodical:

Materials Science Forum (Volume 870)

Pages:

437-440

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.870.437

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Online since:

September 2016

Authors:

G.N. Safronov, N.N. Safronov, L.R. Kharisov*

Keywords:

Disperse Waste, Ferroaluminum, SHS Process

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