Impact of air entrapment on capillary absorption in porous building materials

IF 1.8 4区 工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY
Kazuma Fukui, Satoru Takada
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Abstract

When the water content of a porous material is high, air entrapped in the pore space is expected to affect water transfer through the pores. To understand the effects of air entrapment on water transfer in porous building materials in the high-water-saturation region, we examined the water transfer characteristics corresponding to significantly small air entrapment effects. First, we conducted two sets of water uptake experiments. In the first experiment, using three building materials, the time evolution of the amount of water absorption was measured at a low air pressure near vacuum (several kPa). In the second experiment, the water content profile during water uptake was measured using the gamma-ray attenuation method. The experimental results showed that low air pressure accelerated the water uptake by the brick and aerated concrete specimens, whereas water uptake by the calcium silicate board specimens was not significantly affected. These differences among materials were analyzed from a pore structure viewpoint. Moreover, gamma-ray attenuation measurements confirmed that the obtained water content profile was qualitatively similar at atmospheric and low air pressures, although the low air pressure increased both the water content of the material after capillary absorption and the wetting front propagation rate. Finally, simultaneous water and air transfer calculations based on the air and liquid water balance in a material reproduced the measured water absorption rates well, confirming that air entrapment and pressure development in the pores can significantly reduce the rate of water uptake and water content after capillary absorption. The calculation results also indicated that the air pressure in a material did not significantly increase at early water uptake stages where local water content was not high, which supported the general assumption that treating the liquid-water transfer in porous building materials as a one-component flow is valid in most cases.
空气夹带对多孔建筑材料毛细吸收的影响
当多孔材料的含水量较高时,孔隙中夹带的空气会影响水分通过孔隙的传递。为了了解高水饱和度区域空气夹杂对多孔建筑材料传水的影响,我们研究了空气夹杂影响明显较小情况下的传水特性。首先,我们进行了两组吸水实验。在第一组实验中,我们使用了三种建筑材料,在接近真空的低气压(几千帕)下测量了吸水量的时间变化。在第二个实验中,使用伽马射线衰减法测量了吸水过程中的含水率曲线。实验结果表明,低气压加速了砖和加气混凝土试样的吸水率,而硅酸钙板试样的吸水率没有受到明显影响。从孔隙结构的角度分析了材料之间的这些差异。此外,伽马射线衰减测量证实,在大气压和低气压条件下,所获得的含水率曲线在质量上是相似的,尽管低气压会增加毛细管吸水后材料的含水率和湿润前沿的传播速度。最后,根据材料中的空气和液体水平衡同时进行的水和空气转移计算很好地再现了测量的吸水率,证实了孔隙中的空气夹带和压力发展会显著降低毛细管吸水后的吸水率和含水率。计算结果还表明,在局部含水率不高的早期吸水阶段,材料中的气压并没有显著增加,这支持了将多孔建筑材料中的液水传递视为单组分流动在大多数情况下是有效的这一一般假设。
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
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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