超疏水表面气膜的可视化和测量

D. Jašíková, M. Gašić, M. Kotek, V. Kopecký
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引用次数: 0

摘要

超疏水表面在工业上具有非常重要的前景,无论是在要求易于清洁的应用中,还是在处理液压机的活动部件时,它们被认为可以减少损失。流体与超疏水表面的相互作用伴随着一层空气的产生,即所谓的空气膜,这取决于表面的质量。表面质量受基体粗糙度、物理或化学覆盖物特性的影响。这种特性导致整体空气层表现为气膜,或导致多个不同大小的气泡坐落在表面上。在足够的放大倍数下,可以直观地观察到气膜,并且可以使用全局成像方法,特别是粒子图像测速(PIV)来研究流体流动与气膜之间的动态相互作用。气膜附近的速度分布是研究的重点。本文提出了空气膜随流动液体雷诺数的可视化。
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Visualization and measurement of the air film close ultra-hydrophobic surfaces
The ultra-hydrophobic surfaces have the prospect of great importance in industry, both in applications demanding easy cleaning, and they are presumed to reduce loss when the active parts of hydraulic machines are treated. Interaction of fluids with ultra-hydrophobic surface is accompanied by creation of layer of air, so called air film, which depends on the quality of the surface. The quality of the surface is influenced by the matrix roughness, the character of physical or chemical cover. This properties lead to monolithic air layer presented as air film, or lead to plurality of bubbles of various sizes seated upon the surface. The air film can be observed visually at sufficient magnification and the dynamic interaction between fluid flow and air film can be studied with Global Imaging methods, particularly Particle Image Velocimetry (PIV). There is the velocity profile in the vicinity of the air film in the main interest of the research. Here we present the visualization of air film depending on Reynolds number of flowing liquid.
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