熔铸耐火材料抗盖板玻璃熔体侵蚀行为研究

硅酸盐通报 ›› 2023, Vol. 42 ›› Issue (1): 345-351.

所属专题：耐火材料

熔铸耐火材料抗盖板玻璃熔体侵蚀行为研究

司国栋¹, 易帅¹, 邓丽娜¹, 许谦¹, 陈美娜¹, 王长安¹, 潘传才¹, 林国伟¹, 周吉², 魏霞³, 薛飞¹, 谢金莉¹

1.中国国检测试控股集团股有限公司,国家耐火材料产品质量检验检测中心(北京),北京 100024;
2.北京通达耐火工程技术有限公司,北京 100085;
3.北京国建联信认证中心有限公司,北京 100037

收稿日期:2022-08-12 修订日期:2022-09-15 出版日期:2023-01-15 发布日期:2023-02-15
作者简介:司国栋(1992—),男,工程师。主要从事玻璃窑用耐火材料的研究。E-mail:siguodong66@163.com
基金资助:
中国建筑材料科学研究总院有限公司青年科学基金(ZD-17)

Corrosion Resistance of Fused-Cast Refractory Materials by Molten Cover Lens

SI Guodong¹, YI Shuai¹, DENG Lina¹, XU Qian¹, CHEN Meina¹, WANG Chang’an¹, PAN Chuancai¹, LIN Guowei¹, ZHOU Ji², WEI Xia³, XUE Fei¹, XIE Jinli¹

1. National Refractory Product Quality Supervision and Inspection Center (Beijing), China Testing & Certification International Group Co., Ltd., Beijing 100024, China;
2. Beijing Tongda Refractory Engineering Co., Ltd., Beijing 100085, China;
3. Beijing Guojian Lianxin Certification Center Co., Ltd., Beijing 100037, China

Received:2022-08-12 Revised:2022-09-15 Online:2023-01-15 Published:2023-02-15

摘要/Abstract

摘要： 本文以熔铸耐火材料为研究对象进行抗盖板玻璃熔体侵蚀试验,采用化学分析、岩相分析和电子显微镜能谱分析等测试分析方法,对比研究钠钙玻璃熔体、高铝玻璃熔体和锂铝玻璃熔体对熔铸耐火材料的侵蚀行为。结果表明,玻璃熔体中的碱金属离子向耐火材料中的玻璃相扩散,导致玻璃相黏度降低,同时耐火材料中刚玉相溶解,斜锆石分散,主体结构遭到破坏,并形成界面层。界面层内存在富铝含锆的玻璃相,由于高铝玻璃和锂铝玻璃氧化铝含量高,表面张力大,界面层内的玻璃相聚集在试样周围且扩散慢,从而阻止了侵蚀的发展。玻璃熔体的侵蚀速率为钠钙玻璃熔体＞高铝玻璃熔体＞锂铝玻璃熔体。

关键词: 钠钙玻璃, 高铝玻璃, 锂铝玻璃, 熔铸耐火材料, 抗侵蚀性能, 扩散, 微观形貌

Abstract: In this paper, corrosion resistance experiment on fused-cast refractory materials was performed to study the cast refractory materials. The erosion behaviors of soda-lime glass, high aluminum glass and lithium aluminum glass on fused-cast refractory materials were studied by chemical analysis, lithofacies analysis and electron microscopy spectroscopy analysis. The results show that the alkali metal ions in the molten glass diffuse to the glass phase of the refractory, which leads to the viscosity of the glass phase decrease. At the same time, the corundum phase dissolves and the inclined zircon disperses, then the main structure of the refractory is destroyed, and the interfacial layer is formed. There is a glass phase rich in aluminum and zirconium in the interface layer. Due to the high alumina content and high surface tension of high aluminum glass and lithium aluminum glass, the glass phase in the interface layer gathers around the sample and diffuses slowly, thus preventing the development of erosion. The erosion rate of the molten glass is: soda-lime glass>high aluminum glass>lithium aluminum glass.

Key words: soda-lime glass, high aluminum glass, lithium aluminum glass, fused-cast refractory material, corrosion resistance, diffusion, microstructure

中图分类号:

TQ175

司国栋, 易帅, 邓丽娜, 许谦, 陈美娜, 王长安, 潘传才, 林国伟, 周吉, 魏霞, 薛飞, 谢金莉. 熔铸耐火材料抗盖板玻璃熔体侵蚀行为研究[J]. 硅酸盐通报, 2023, 42(1): 345-351.

SI Guodong, YI Shuai, DENG Lina, XU Qian, CHEN Meina, WANG Chang’an, PAN Chuancai, LIN Guowei, ZHOU Ji, WEI Xia, XUE Fei, XIE Jinli. Corrosion Resistance of Fused-Cast Refractory Materials by Molten Cover Lens[J]. BULLETIN OF THE CHINESE CERAMIC SOCIETY, 2023, 42(1): 345-351.

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熔铸耐火材料抗盖板玻璃熔体侵蚀行为研究

Corrosion Resistance of Fused-Cast Refractory Materials by Molten Cover Lens

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