Magnesia composite materials for layered products

IF 0.8 Q4 METALLURGY & METALLURGICAL ENGINEERING
О. Miryuk
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引用次数: 0

Abstract

The article presents the results of experimental studies of magnesia composite materials of layered structure obtained from molding mixtures of various densities. The aim of the work is to synthesize and study the characteristics of three–layer magnesia materials. Molding mixtures were obtained from combined binders based on caustic magnesite and technogenic silica-containing materials. Specially synthesized porous aggregates from liquid-glass raw mixtures were used as fillers. Technological techniques of horizontal and vertical molding of three-layer products have been worked out. Composite magnesia material of three-layer variatropic structure is characterized by a density of 560 kg/m3, compressive strength of 6.1 MPa. Durability tests of layered composite materials have been carried out. Three-layer magnesia composite materials have shown satisfactory resistance in the conditions of an aqueous and aggressive salt environment. The developed magnesia material is comparable in physic-mechanical and cost parameters with an innovative block of encapsulated expanded clay. The low thermal conductivity of the developed magnesia material, equal to 0.115 W/(m·⁰c), will ensure a reduction in material and energy costs by 36.1% compared to the cement analogue.
层状制品用镁砂复合材料
本文介绍了用不同密度的模压混合物制备层状结构镁基复合材料的实验研究结果。本工作的目的是合成并研究三层氧化镁材料的特性。以碱性菱镁矿和含硅工艺材料为基础,制备了复合粘结剂。用液体-玻璃原料混合物特别合成的多孔骨料作为填料。研究了三层产品的水平和垂直成型工艺。三层变变结构复合镁砂材料的密度为560 kg/m3,抗压强度为6.1 MPa。对层状复合材料进行了耐久性试验。三层氧化镁复合材料在水环境和侵蚀性盐环境中表现出令人满意的耐蚀性。研制的氧化镁材料在物理力学参数和成本参数上与一种新型包封膨胀粘土块体相当。开发的氧化镁材料导热系数低,相当于0.115 W/(m·c),与水泥类似物相比,将确保材料和能源成本降低36.1%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
自引率
42.90%
发文量
55
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