Methodology to determine coefficients of effective thermal conductivity when heating porous bodies using fractal-like structures

V. Gorbynov, G. A. Perevezentsev, S.S. Teplyakova, M. Mechtaeva
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Abstract

Thermal insulation, porous composite, ceramic, charge materials are frequently used in the energy industry. The materials are heat treated to improve the structure and give them the desired properties required for specific production conditions. The important task is to assess the influence of geometric parameters of the fractal-like structure and radiation heat transfer on the thermophysical properties of porous bodies. For numerical description of porous bodies, the technique of replacing geometry of porous body with the bodies with a fractal-like structure having self-similarity properties is significant. The object under study is an array of blanks arranged chaotically, the structures that are called bulk cages. The porous body is replaced by a fractal cube structure of the 2nd rank of partitioning. The simulation has been performed in the COMSOL Multiphysics software based on a three-dimensional model of the Sierpinski carpet. Since the distribution of heat can be non-uniformed over the structure of the object, three variants of the fractal-like cubic structure cross section are considered. A method to determine the effective thermal conductivity coefficients based on the use of fractal-like structures has been developed. Depending on the cross sections, one-dimensional computational models with sufficient accuracy for engineering analysis are obtained. The effective thermal conductivity coefficients are determined. The results of data analysis have shown that the geometric parameters of the structure and radiation heat transfer significantly affect the effective coefficient of thermal conductivity at high temperatures. In comparison to the currently available approaches, the developed method allows solving the problem of determining thermophysical properties without physical experiments. The technique used in the study may be used for mathematical modeling of heat exchange processes of heat-power facilities when calculating temperature fields and determining heating modes.
用分形结构加热多孔体时确定有效导热系数的方法
保温材料、多孔复合材料、陶瓷材料、充电材料是能源工业中经常使用的材料。这些材料经过热处理,以改善结构,并使其在特定生产条件下具有所需的性能。重要的任务是评估分形结构的几何参数和辐射传热对多孔体热物性的影响。对于多孔体的数值描述,用具有自相似性质的类分形结构体代替多孔体的几何形状具有重要意义。所研究的对象是一组杂乱排列的空白,这种结构被称为散装笼子。多孔体被二级分形立方体结构所取代。基于Sierpinski地毯的三维模型,在COMSOL Multiphysics软件中进行了模拟。由于热量在物体结构上的分布可能是不均匀的,因此考虑了分形立方结构截面的三种变体。提出了一种基于分形结构确定有效导热系数的方法。根据截面,得到了具有足够工程分析精度的一维计算模型。确定了有效导热系数。数据分析结果表明,结构的几何参数和辐射传热对高温下的有效导热系数有显著影响。与目前可用的方法相比,所开发的方法可以解决无需物理实验即可确定热物理性质的问题。本研究所采用的技术可用于热电设施换热过程的数学建模,用于计算温度场和确定加热方式。
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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