Numerical Evaluation Of Effective Thermal Properties For Materials With Variable Porosity

Building Research Journal Pub Date : 2014-09-01 DOI:10.2478/brj-2014-0010

P. Staňák, J. Sládek, V. Sládek, S. Krahulec

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Abstract

Abstract In this paper a computational homogenization technique is applied to thermal analyses in porous materials. A volume fraction of pores on the microstructural level is the key factor that changes the macroscopic thermal properties. Thus, the distribution of thermal fields at the macroscopic level is analysed through the incorporation of the microstructural response on the representative volume element (RVE) assuming a uniform distribution of pores. For the numerical analysis the scaled boundary finite element method (SBFEM) is introduced to compute the thermal response of RVE. The SBFEM combines the main advantages of the finite element method (FEM) and the boundary element method (BEM). In this method, only the boundary is discretized with elements leading to the reduction of spatial dimension by one, similarly as in the BEM. It reduces computational efforts in the mesh generation and CPU time. The proposed method is used to study square RVE with a circular and elliptic pore under the thermal load. Dimensions of the pore are varied to obtain different volume fractions of matrix material. Numerical results for effective thermal conductivities obtained via SBFEM modelling show an excellent agreement with the finite element analysis using commercial software COMSOL Multiphysics.

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变孔隙率材料有效热性能的数值计算

本文将计算均质化技术应用于多孔材料的热分析。微观结构上孔隙的体积分数是改变宏观热性能的关键因素。因此，在假设孔隙均匀分布的情况下，通过纳入代表性体积元(RVE)上的微观结构响应，分析了热场在宏观水平上的分布。在数值分析中，引入了尺度边界有限元法(SBFEM)来计算RVE的热响应。边界元法结合了有限元法和边界元法的主要优点。该方法与边界元法类似，只对边界进行离散化，使空间维数降低1。它减少了网格生成的计算量和CPU时间。将该方法应用于热载荷作用下具有圆形孔和椭圆形孔的方形RVE的研究。通过改变孔隙的尺寸来获得不同的基体材料体积分数。通过SBFEM模拟得到的有效导热系数数值结果与商用软件COMSOL Multiphysics的有限元分析结果非常吻合。

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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Building Research Journal

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