Resolvent Analysis of Turbulent Friction Drag Reduction by Manipulation of Mean Velocity Profile

Volume 1: Fluid Mechanics Pub Date : 1900-01-01 DOI:10.1115/ajkfluids2019-5125

Riko Uekusa, Aika Kawagoe, Yusuke Nabae, K. Fukagata

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Abstract

In the present study, we numerically manipulate the mean velocity profile of a turbulent channel flow and assess the friction drag reduction performance by using resolvent analysis. Building on the implication obtained from Kühnen et al. (Nat. Phys., Vol. 14, 2017, pp. 386–390) that modifying mean velocity profile flat leads to significant drag reduction, we first introduce two functions for turbulent mean velocity, which can express ‘flattened’ profiles: one is derived based on the turbulent viscosity model proposed by Reynolds & Tiederman (J. Fluid Mech., Vol. 658, 2010, pp. 336–382), and the other is based on the mean velocity profile of laminar flow. These functions are used as the mean velocity profile for the resolvent analysis, and the flatness of the resulting profiles is characterized by two different measures. As a result, we confirm that, friction drag reduction is achieved if the turbulent mean velocity profile is ‘flattened’. However, we also find that the flatness of the mean velocity profile in the center of the channel alone is not enough to evaluate the drag reduction performance.

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操纵平均速度剖面的湍流摩擦减阻的解析分析

在本研究中，我们对湍流通道流动的平均速度分布进行了数值处理，并使用解析分析来评估摩擦减阻性能。基于从k hnen等人(Nat. Phys.)获得的含义。， Vol. 14, 2017, pp. 386-390)，修改平均速度曲线平坦导致显着的阻力减少，我们首先引入两个湍流平均速度函数，可以表达“平坦”的轮廓:一个是基于Reynolds & Tiederman (J. Fluid Mech.)提出的湍流粘度模型推导出来的。另一种是基于层流的平均速度分布。这些函数被用作解析分析的平均速度剖面，并通过两种不同的测量来表征所得剖面的平坦度。因此，我们确认，如果湍流平均速度剖面“变平”，摩擦阻力减少是可以实现的。然而，我们也发现，仅通道中心平均速度分布的平整度不足以评估减阻性能。

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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Volume 1: Fluid Mechanics

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