Feather aerodynamics suggest importance of lift and flow predictability over drag minimization

Frida Alenius, Johan Revstedt, Christoffer Johansson
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Abstract

Partly overlapping feathers form a large part of birds wing surfaces, but in many species the outermost feathers split, making each feather function as an independent wing. These feathers are complex structures that evolved to fulfil both aerodynamic and structural functions. Yet, relatively little is known about how the profile shape and microstructures of feathers impact aerodynamic performance. Here we determine, using fluid dynamic modelling, the aerodynamic capabilities of a section of the primary flight feather forming the leading edge of the split wing tip of a Jackdaw (Corvus monedula). Our findings demonstrate that the feather section exhibits a relatively high performance, with lift comparable to manmade aerofoils and plates with larger camber at higher Reynolds number. However, there is a drag penalty associated with the feather shaft. The models vortex shedding behaviour results in stable lift, with small fluctuations, compared to manmade aerofoils. Notably, the aerodynamic pitch torque around the shaft varies with angle of attack. This, when combined with the built-in pitch-up twist of the feather implies a passive pitch control mechanism for the feather. Taken together, our findings suggest evolutionary adaptations of the flow around the feather, which could be of interest when designing micro-air vehicles and wind turbines.
羽毛空气动力学表明,升力和流动可预测性比阻力最小化更重要
部分重叠的羽毛构成了鸟类翅膀的大部分表面,但在许多物种中,最外层的羽毛会裂开,使每根羽毛都具有独立翅膀的功能。这些羽毛结构复杂,在进化过程中兼具空气动力学和结构功能。然而,人们对羽毛的轮廓形状和微观结构如何影响空气动力性能知之甚少。在这里,我们利用流体动力学建模确定了形成鸦雀(Corvus monedula)分裂翼尖前缘的一段主飞行羽毛的空气动力性能。我们的研究结果表明,羽毛部分具有相对较高的性能,在较高的雷诺数下,其升力可与人造气垫和具有较大凸度的板相媲美。然而,羽轴存在阻力损失。与人造气膜相比,模型的涡流脱落行为导致升力稳定,波动较小。值得注意的是,轴周围的气动俯仰力矩随攻角变化。这与羽毛内置的俯仰扭转相结合,意味着羽毛具有被动俯仰控制机制。综上所述,我们的研究结果表明,羽毛周围的气流在进化过程中发生了适应性变化,这在设计微型飞行器和风力涡轮机时可能会引起人们的兴趣。
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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