Numerical study on the effect of pore shapes on the thermal behaviors of cellular concrete

•A 2D model was used to investigate the effect of pore shapes on the ETC of cellular concrete.•Representative volume elements of porous microstructures were reconstructed using a random algorithm.•The results provide information on the microstructure-thermal property relationship for the cellular co...

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Bibliographic Details
Published inConstruction & building materials Vol. 163; pp. 113 - 121
Main Authors She, Wei, Zhao, Guotang, Cai, Degou, Jiang, Jinyang, Cao, Xiaoyu
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 28.02.2018
Elsevier B.V
Subjects
Analysis
Cellular concrete
Concretes
Finite element method
Finite element method (FEM)
Heat transfer
Mechanical properties
Pore shapes
Thermal behavior
Thermal conductivity
Thermal properties
Tortuosity
China
Finite element method (FEM)
Pore shapes
Tortuosity
Cellular concrete
Thermal behavior
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Summary:•A 2D model was used to investigate the effect of pore shapes on the ETC of cellular concrete.•Representative volume elements of porous microstructures were reconstructed using a random algorithm.•The results provide information on the microstructure-thermal property relationship for the cellular concrete. This paper proposes a numerical method to study the effect of pore shapes on the effective thermal conductivity (ETC) of cellular concrete by a two-dimensional model. Cellular concrete can be seen as a composite of two phases with pore and cement paste. The model is established by two steps. Firstly, a generation of two-dimensional representative volume element of cellular concrete microstructure is necessary. Secondly, a finite element method is adopted to simulate heat transfer through the pixelated microstructure. Simulations are validated against analytical approximations, as well as experimental data from the literature. The model can also be used to evaluate the pore size distribution and orientation effects that are hard to measure only in laboratory experiments. It is concluded that ETC decreases when triangle pores substitute for circular pores on account that the tortuosity increases continuously. The other shapes of non-circular pores (square, pentagon and hexagon) have negligible effects on ETC. For ellipse cases, ETC decreases with increase in aspect ratio and volume fraction of pore. In the case of aligned pores, the ETC is larger along the principal axis. However, the size distribution of pores seems to have an insignificant influence. The numerical results suggest that the finite element method (FEM) considering quantitative data of thermal transfer behavior of cellular concrete can be obtained by the pore shapes, and it may be of great help to the optimization of materials.
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2017.12.108