Water-Glass-Assisted Foaming in Foamed Glass Production

IF 2.7 Q1 MATERIALS SCIENCE, CERAMICS Ceramics-Switzerland Pub Date : 2023-08-02 DOI:10.3390/ceramics6030101
Sonja Smiljanić, Uroš Hribar, Matjaž Spreitzer, Jakob König
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Abstract

The energy efficiency of buildings can be greatly improved by decreasing the energy embodied in installed materials. In this contribution, we investigated the possibility of foaming waste bottle glass in the air atmosphere with the addition of water glass, which would reduce the energy used in the production of foamed glass boards. The results show that with the increased addition of water glass, the crystallinity and the thermal conductivity decrease, however, the remaining crystal content prevents the formation of closed-porous foams. The added water glass only partly protects the carbon from premature oxidation, and the foaming mechanism in the air is different than in the argon atmosphere. The lowest obtained foam density in the air atmosphere is 123 kg m−3, while the lowest thermal conductivity is 53 mW m−1 K−1, with an open porosity of 50% for the sample obtained in the air, containing 12 wt% of water glass, 2 wt% of B2O3, 2 wt% AlPO4 and 2 wt% K3PO4.
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泡沫玻璃生产中的水玻璃辅助发泡
建筑的能源效率可以大大提高,通过减少能源体现在安装材料。在这篇文章中,我们研究了在空气中添加水玻璃使废瓶玻璃发泡的可能性,这将减少发泡玻璃板生产中使用的能源。结果表明,随着水玻璃加入量的增加,结晶度和导热系数降低,但剩余的晶体含量阻止了闭孔泡沫的形成。添加的水玻璃只能部分保护碳不过早氧化,而且空气中的发泡机制与氩气中的发泡机制不同。在空气气氛中获得的最低泡沫密度为123 kg m−3,而最低热导率为53 mW m−1 K−1,在空气中获得的样品的开放孔隙率为50%,其中含有12 wt%的水玻璃,2 wt%的B2O3, 2 wt%的AlPO4和2 wt%的K3PO4。
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来源期刊
CiteScore
3.00
自引率
7.10%
发文量
66
审稿时长
10 weeks
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