MgO - Al2O3 - TiO2体系中亚固体结构的几何拓扑特征

Bulletin of the National Technical University "KhPI". Series: Chemistry, Chemical Technology and Ecology Pub Date : 2021-05-15 DOI:10.20998/2079-0821.2021.01.03

O. Borysenko, Sergii Logvinkov, H. Shabanova, Igor Остапенко, Vita Шумейко

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引用次数: 1

摘要

从制造耐热耐火产品的角度来看，在引起关注的材料中，可以挑选出基于MgO - Al2O3 - TiO2体系组成的材料。通过对MgO - Al2O3 - TiO2体系的热力学分析，发现在1537 K以下和1537 - 2076 K及2076 K以上三个温度范围内，MgO - Al2O3 - TiO2体系的初等三角形划分会发生变化。结果表明，在2076 K以下存在一个尖晶石相的浓度范围:铝酸镁尖晶石-宽方石。在1537 K以上，有一个浓度范围:钛石- karroite，满足对高耐热材料的要求。利用初等三角形TiO2 - Al2TiO5 - MgTi2O5可以得到由MgTi2O5稳定的Al2TiO5为基体的耐热材料。为了获得耐热的方长石尖晶石材料，推荐采用Mg2TiO4 - MgAl2O4 - MgO等初等三角形结构，其中只存在立方晶格的化合物。因此，将MgO - Al2O3 - TiO2体系划分为初等三角形，并分析体系相的几何拓扑特征，可以在所研究的体系中选择具有最佳性能的成分区域，从而获得具有指定最佳性能的材料。

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GEOMETRICAL–TOPOLOGICAL CHARACTERISTICS OF THE SUBSOLIDUS STRUCTURE IN THE MgO – Al2O3 – TiO2 SYSTEM

Among the materials that attract attention from the point of view of creating refractory products with increased heat resistance, one can single out materials based on compositions of the MgO – Al2O3 – TiO2 system. As a result of the thermodynamic analysis of the MgO – Al2O3 – TiO2 system, it was found that the partition of the system into elementary triangles will change in three temperature ranges: I – up to 1537 K, II – in the temperature range 1537 – 2076 K and above 2076 K. It has been established that up to a temperature of 2076 K there is a concentration range of spinel phases: magnesium aluminate spinel – quandylite. Above 1537 K, there is a concentration range: tialite – karroite, which meets the requirements for materials with high heat resistance. The elementary triangle TiO2 – Al2TiO5 – MgTi2O5 can be used to obtain heat–resistant materials based on Al2TiO5 stabilized by MgTi2O5. To obtain heat–resistant periclase–spinel materials, an elementary triangle Mg2TiO4 – MgAl2O4 – MgO is recommended, in which only compounds with a cubic crystal lattice are present. Thus, the division of the MgO – Al2O3 – TiO2 system into elementary triangles and the analysis of the geometrical–topological characteristics of the phases of the system made it possible to select in the system under study the regions of compositions that have optimal properties for obtaining materials with the specified optimal properties.

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Bulletin of the National Technical University "KhPI". Series: Chemistry, Chemical Technology and Ecology

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