可移动的鲨鱼鳞片作为一种被动动态微粗糙度来控制流动分离。

Movable shark scales act as a passive dynamic micro-roughness to control flow separation.

作者信息

Lang Amy W, Bradshaw Michael T, Smith Jonathon A, Wheelus Jennifer N, Motta Philip J, Habegger Maria L, Hueter Robert E

机构信息

Department of Aerospace Engineering & Mechanics, University of Alabama, 255H. M. Comer, 245 7th Avenue, Box 870280, Tuscaloosa, AL 35487, USA.

出版信息

Bioinspir Biomim. 2014 Sep;9(3):036017. doi: 10.1088/1748-3182/9/3/036017. Epub 2014 Jul 21.

DOI:10.1088/1748-3182/9/3/036017

PMID:25046552

Abstract

Shark scales on fast-swimming sharks have been shown to be movable to angles in excess of 50°, and we hypothesize that this characteristic gives this shark skin a preferred flow direction. During the onset of separation, flow reversal is initiated close to the surface. However, the movable scales would be actuated by the reversed flow thereby causing a greater resistance to any further flow reversal and this mechanism would disrupt the process leading to eventual flow separation. Here we report for the first time experimental evidence of the separation control capability of real shark skin through water tunnel testing. Using skin samples from a shortfin mako Isurus oxyrinchus, we tested a pectoral fin and flank skin attached to a NACA 4412 hydrofoil and separation control was observed in the presence of movable shark scales under certain conditions in both cases. We hypothesize that the scales provide a passive, flow-actuated mechanism acting as a dynamic micro-roughness to control flow separation.

摘要

研究表明，快速游动的鲨鱼身上的鳞片可移动至超过50°的角度，我们推测这一特性使这种鲨鱼皮具有一个优先流动方向。在分离开始时，靠近表面会引发流动逆转。然而，可移动的鳞片会被反向流动驱动，从而对进一步的流动逆转产生更大阻力，并且这种机制会扰乱导致最终流动分离的过程。在此，我们首次通过水洞试验报告了真实鲨鱼皮具有分离控制能力的实验证据。我们使用了尖吻鲭鲨的皮肤样本，测试了附着在NACA 4412水翼上的胸鳍和体侧皮肤，在这两种情况下，在特定条件下有可移动鲨鱼鳞片时均观察到了分离控制现象。我们推测，这些鳞片提供了一种被动的、由流动驱动的机制，作为一种动态微观粗糙度来控制流动分离。

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可移动的鲨鱼鳞片作为一种被动动态微粗糙度来控制流动分离。

Movable shark scales act as a passive dynamic micro-roughness to control flow separation.

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