A PARAMETRIC STUDY ON DRAG REDUCTION USING ENGINEERED MICROTEXTURES IN VISCOUS LAMINAR FLOW

Pooyan Tirandazi, J. Healy, C. Hidrovo
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Abstract

The topic of friction reduction has been studied through the decades for numerous engineering applications that involve internal and external flows. Inspired by the natural surface structure of different plants and animals, engineered microtexturing of surfaces is one of the effective ways of reducing the drag. By introducing different texture geometries, the flow behavior close to the solid boundary can be altered and thus manipulated towards achieving a reduced net drag force on the surface. Despite considerable research on the subject, most works have concentrated on optimization of the surface texturing for maximizing the friction reduction and minimizing the pumping power requirements, and less attention has been paid to characterization of the flow and boundary layer in the vicinity of the wall, especially in laminar regime. In this work we investigate the role that microtexturing has on friction reduction under low to moderate Reynolds numbers (Re). We perform a parametric study on the shape and dimensions of the surface textures and investigate the boundary layer and streamline behavior as well as the local shear stress and pressure distribution along the solid-fluid interface under different flow conditions. The outcomes of this work will provide a guideline for optimal design of artificial textures with major implications for many engineering applications such as microfluidic systems used in thermal management and biochemical diagnostics.
粘性层流中工程微结构减阻的参数化研究
几十年来,许多涉及内部和外部流动的工程应用已经研究了减少摩擦的主题。受不同植物和动物的自然表面结构的启发,工程表面微纹理是减少阻力的有效方法之一。通过引入不同的纹理几何形状,可以改变靠近固体边界的流动行为,从而实现减少表面上的净阻力。尽管对该问题的研究相当多,但大多数工作都集中在优化表面纹理以最大限度地减少摩擦和最小化泵送功率要求,而很少关注壁面附近流动和边界层的表征,特别是在层流状态下。在这项工作中,我们研究了微织构在低至中等雷诺数(Re)下减少摩擦的作用。我们对表面结构的形状和尺寸进行了参数化研究,并研究了不同流动条件下的边界层和流线行为以及沿固液界面的局部剪切应力和压力分布。这项工作的结果将为人工纹理的优化设计提供指导,并对许多工程应用具有重大意义,例如用于热管理和生化诊断的微流体系统。
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