Aluminosilicate Microsphere Synthesis in Plasma Flow

Valentin Shekhovtsov; O. Volokitin; N. Tsvetkov; G. Volokitin; N. Skripnikova

doi:10.4028/www.scientific.net/MSF.906.131

Paper Titles

Structural-Phase State and Strength Properties of Pressure-Synthesized Ni₃Al Intermetallic Compound
p.95

Structure and Properties of the Surface Layer of a Wear-Resistant Coating on Martensitic Steel after Electron-Beam Processing
p.101

Studying the Influence of Tungsten and Chromium Additives in Flux Cored Wire System Fe-C-Si-Mn-Mo-Ni-V-Co on Surfaced Metal Properties
p.107

The Change in the Thin Structure and Mechanical Properties of Aluminum Alloys at Intensive Plastic Deformation
p.114

Welding Technology in Additive Manufacturing Processes of 3D Objects
p.121

Aluminosilicate Microsphere Synthesis in Plasma Flow
p.131

Comparative Analysis of Hygiene and Sanitary Characteristics of Consumable Electrode Gas-Shielded Welding
p.137

Influence of Gas Dynamic Processes on Chemical Composition of Hardfaced Layer when Restoring Machine Parts Manufactured from 40H Steel
p.142

Scanning the Welded Seams of Titanium Alloys by Using Subminiature Eddy Current Transducers
p.147

HomeMaterials Science ForumMaterials Science Forum Vol. 906Aluminosilicate Microsphere Synthesis in Plasma...

Aluminosilicate Microsphere Synthesis in Plasma Flow

Abstract:

The paper presents theoretical and experimental results on the synthesis of ash-based microspheres using the high-temperature plasma treatment. The dynamic motion of particles and their melting are considered depending on the initial porosity of the raw material modified by 3200K plasma treatment. Physicochemical studies relate to the original raw material and microspheres produced therefrom.

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Periodical:

Materials Science Forum (Volume 906)

Pages:

131-136

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.906.131

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Online since:

September 2017

Authors:

Valentin Shekhovtsov*, O. Volokitin, N. Tsvetkov, G. Volokitin, N. Skripnikova

Keywords:

Electroplasma Stand, Heating of Particles, Melting of Particles, Microspheres, Particle Velocity, Physicochemical Research, Porous Particles

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