Effect of SiC content on viscosity and thermal properties of foam ceramic prepared from molybdenum tailings

A foam ceramic was prepared using molybdenum tailings (97–99.5 wt%) as the raw material and SiC as the foaming agent. The results showed that with increasing SiC content, the liquid-phase viscosity decreased, which in turn enhanced the overall expansion of the system, leading to a decrease in the th...

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Published inJournal of non-crystalline solids Vol. 513; pp. 15 - 23
Main Authors Tang, Zhiheng, Zhang, Mingxing, Zhang, Xuefeng, He, Jianli, Jia, Xiaolin, Deng, Leibo
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.06.2019
Subjects
Foam ceramic
Liquid-phase viscosity
Molybdenum tailing
Thermal conductivity
Molybdenum tailing
Thermal conductivity
Liquid-phase viscosity
Foam ceramic
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Abstract A foam ceramic was prepared using molybdenum tailings (97–99.5 wt%) as the raw material and SiC as the foaming agent. The results showed that with increasing SiC content, the liquid-phase viscosity decreased, which in turn enhanced the overall expansion of the system, leading to a decrease in the thermal conductivity. The effects of the SiC content on the bulk density, porosity, pore size, and thermal conductivity were investigated in detail. Moreover, the experimental results were compared with several analytical models, and we found that the parallel model closely agreed with the predictions. The sample prepared via sintering at 1150 °C using 2.5 wt% SiC and molybdenum tailings exhibited a low bulk density of 0.37 g/cm3, high porosity of 85.14%, and low thermal conductivity of 0.22W/m·K. Thus, the application of molybdenum tailings in the production of foamed materials is considered to have potential economic and environmental advantages. •The foam ceramic with high content (97–99.5 wt%) of molybdenum tailings.•The viscosity of molybdenum tailings with SiC during sintering process was characterized by high temperature microscope.•Effect of SiC content on the thermal conductivity of foam ceramic was investigated by theoretical models and actual test method.
AbstractList A foam ceramic was prepared using molybdenum tailings (97–99.5 wt%) as the raw material and SiC as the foaming agent. The results showed that with increasing SiC content, the liquid-phase viscosity decreased, which in turn enhanced the overall expansion of the system, leading to a decrease in the thermal conductivity. The effects of the SiC content on the bulk density, porosity, pore size, and thermal conductivity were investigated in detail. Moreover, the experimental results were compared with several analytical models, and we found that the parallel model closely agreed with the predictions. The sample prepared via sintering at 1150 °C using 2.5 wt% SiC and molybdenum tailings exhibited a low bulk density of 0.37 g/cm3, high porosity of 85.14%, and low thermal conductivity of 0.22W/m·K. Thus, the application of molybdenum tailings in the production of foamed materials is considered to have potential economic and environmental advantages. •The foam ceramic with high content (97–99.5 wt%) of molybdenum tailings.•The viscosity of molybdenum tailings with SiC during sintering process was characterized by high temperature microscope.•Effect of SiC content on the thermal conductivity of foam ceramic was investigated by theoretical models and actual test method.
Author Deng, Leibo
Jia, Xiaolin
He, Jianli
Zhang, Mingxing
Tang, Zhiheng
Zhang, Xuefeng
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Keywords Molybdenum tailing
Thermal conductivity
Liquid-phase viscosity
Foam ceramic
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Snippet A foam ceramic was prepared using molybdenum tailings (97–99.5 wt%) as the raw material and SiC as the foaming agent. The results showed that with increasing...
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elsevier
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SubjectTerms Foam ceramic
Liquid-phase viscosity
Molybdenum tailing
Thermal conductivity
Title Effect of SiC content on viscosity and thermal properties of foam ceramic prepared from molybdenum tailings
URI https://dx.doi.org/10.1016/j.jnoncrysol.2019.02.024
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