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NGUYEN, M. SOKOLÁŘ, R.
Originální název
Reduction of Firing Temperature by Utilization of Secondary Materials for the Synthesis of Forsterite Ceramics
Typ
článek ve sborníku ve WoS nebo Scopus
Jazyk
angličtina
Originální abstrakt
The main aim of this research was to investigate the effect of the addition of coal fly ash as a secondary waste material on the synthesis and properties of forsterite ceramics. The utilization of fly ash as a raw material, which contains flux oxides, reduce the necessary firing temperature for the synthesis of forsterite ceramics in comparison with forsterite ceramics synthetized from high purity or industrial materials, while preserving its refractory properties. The results revealed that forsterite was synthesized as a major crystalline phase in all samples. The optimal firing temperature for obtaining good physico-mechanical parameters was found to be between 1400-1600°C for high purity or industrial materials, while mixtures containing fly ash could achieve similar parameters at lower firing temperatures between 1200-1300°C. The decrease in refractoriness was found to be within acceptable limits for utilization as a refractory material. These findings demonstrate the potential for cost reduction and energy savings through the use of secondary waste materials and reduced firing temperature in the synthesis of forsterite ceramics.
Klíčová slova
Forsterite; spinel; synthesis; firing temperature; microstructure
Autoři
NGUYEN, M.; SOKOLÁŘ, R.
Vydáno
27. 10. 2023
Nakladatel
Trans Tech Publications Ltd.
Místo
Switzerland
ISSN
1662-9779
Periodikum
Solid State Phenomena
Ročník
351
Stát
Švýcarská konfederace
Strany od
21
Strany do
26
Strany počet
6
URL
https://www.scientific.net/SSP.351.21.pdf
BibTex
@inproceedings{BUT185016, author="Martin {Nguyen} and Radomír {Sokolář}", title="Reduction of Firing Temperature by Utilization of Secondary Materials for the Synthesis of Forsterite Ceramics", booktitle="Solid State Phenomena", year="2023", series="351", journal="Solid State Phenomena", volume="351", pages="21--26", publisher="Trans Tech Publications Ltd.", address="Switzerland", doi="10.4028/p-8gwiKt", issn="1662-9779", url="https://www.scientific.net/SSP.351.21.pdf" }