Efficiency of Thermal Plasma Treatment of Aluminosilicate Particles

The paper studies the efficiency of plasma-assisted synthesis of bottom ash-based microspheres in the light of the liquid phase formation. The studies also include the assessment of morphology of obtained microspheres. It is shown that microspheres with high sphericity can be obtained with thermal p...

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Veröffentlicht in:	Key engineering materials 2018-04, Vol.769, p.23-28
Hauptverfasser:	Gafarov, Ruslan E., TSVETKOV, Nikolai, Volokitin, Gennadii G., Volokitin, Oleg, Shekhovtsov, Valentin, Skripnikova, Nelly
Format:	Artikel
Sprache:	eng
Schlagworte:	Aluminosilicates Aluminum oxide Aluminum silicates Heat treatment Liquid phases Magnesium Microspheres Morphology Organic chemistry Plasma Silicon dioxide Thermal plasmas Thermal resistance
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creator	Gafarov, Ruslan E. TSVETKOV, Nikolai Volokitin, Gennadii G. Volokitin, Oleg Shekhovtsov, Valentin Skripnikova, Nelly
description	The paper studies the efficiency of plasma-assisted synthesis of bottom ash-based microspheres in the light of the liquid phase formation. The studies also include the assessment of morphology of obtained microspheres. It is shown that microspheres with high sphericity can be obtained with thermal plasma treatment. During thermal plasma treatment, the amount of silicon and aluminum relatively grows due to the decrease in the amount of calcium, titanium, magnesium, potassium, and natrium. The high content of silica and alumina in obtained microspheres indicates to their high thermal, chemical, and mechanical resistance.
doi_str_mv	10.4028/www.scientific.net/KEM.769.23
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subjects	Aluminosilicates Aluminum oxide Aluminum silicates Heat treatment Liquid phases Magnesium Microspheres Morphology Organic chemistry Plasma Silicon dioxide Thermal plasmas Thermal resistance
title	Efficiency of Thermal Plasma Treatment of Aluminosilicate Particles
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