高各向异性建筑材料在冻结和融化过程中的湿热和力学耦合模拟

IF 1.8 4区 工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY
Kazuma Fukui, C. Iba, D. Ogura
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引用次数: 1

摘要

多孔建筑材料,如板材、木材、石材、烧制粘土材料和生物基材料,往往具有各向异性。本文研究了强各向异性建筑材料在冻融过程中的热湿力学耦合行为的数值模型。首先,对两种烧制粘土材料进行了应变测量,以确定其冻融变形的各向异性。在计算中,基于各向异性孔隙弹性考虑材料Biot系数的各向异性。测量结果与计算结果的对比表明,如果不考虑比奥系数的各向异性和力学性能的各向异性,就不能再现测量过程中的各向异性变形。此外,对变形原因的分析表明,由于冻结过程中水压的发展,在材料厚度垂直方向上的膨胀被较小的Biot系数所抑制。结果表明,Biot系数的各向异性显著影响了冻害变形;因此,在数值模拟中应充分考虑各向异性Biot系数。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Coupled hygrothermal and mechanical simulations of highly anisotropic building material during freezing and thawing
Porous building materials, such as board materials, wood, stones, fired clay materials, and bio-based materials, often have anisotropic properties. This study investigates adequate numerical models for the coupled hygrothermal and mechanical behaviors of strongly anisotropic building materials during freezing and thawing. First, strain measurements are reported for two types of fired clay materials to confirm the anisotropy of deformation during freezing and thawing. In calculations, the anisotropy of the Biot coefficient of a material is considered based on anisotropic poroelasticity. The comparison between the measurements and calculations revealed that the anisotropic deformation during the measurement cannot be reproduced without considering the anisotropies of the Biot coefficient as well as those of the mechanical properties. In addition, analysis of the causes of the deformation reveals that the expansion in the direction normal to the material thickness due to the water pressure development during the freezing is suppressed by the small Biot coefficient. These results indicate that the anisotropy of the Biot coefficient significantly influence the deformation due to frost actions; consequently, the anisotropic Biot coefficient should be adequately considered in numerical simulations.
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来源期刊
Journal of Building Physics
Journal of Building Physics 工程技术-结构与建筑技术
CiteScore
5.10
自引率
15.00%
发文量
10
审稿时长
5.3 months
期刊介绍: Journal of Building Physics (J. Bldg. Phys) is an international, peer-reviewed journal that publishes a high quality research and state of the art “integrated” papers to promote scientifically thorough advancement of all the areas of non-structural performance of a building and particularly in heat, air, moisture transfer.
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