Flow Separation Control and Drag Reduction for a Two-Dimensional Boat-Tailed Bluff Body Through Transverse Grooves

Volume 1: Flow Manipulation and Active Control; Bio-Inspired Fluid Mechanics; Boundary Layer and High-Speed Flows; Fluids Engineering Education; Transport Phenomena in Energy Conversion and Mixing; Turbulent Flows; Vortex Dynamics; DNS/LES and Hybrid RANS/LES Methods; Fluid Structure Interaction; Fl Pub Date : 2018-07-15 DOI:10.1115/FEDSM2018-83458

A. Mariotti, G. Buresti, M. Salvetti

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引用次数: 1

Abstract

The present work focuses on a passive strategy consisting in the introduction of properly contoured transverse grooves to delay the flow separation occurring on a boat-tailed bluff body before its sharp-edged base. We consider a two-dimensional body having a cross-section with a 3:1 elliptical forebody and a rectangular main part followed by a circular-arc boat tail. We carry out Variational Multiscale Large Eddy Simulations at Re = Du∞/v = 9.6 × 104. A boat-tail drag reduction of the order of 9.7% is produced by the significant delay of the flow separation caused by the groove and by the consequent increase of the base pressure. This effect is mainly due to the relaxation of the no-slip condition over the small and steady recirculation region inside the groove, which reduces the momentum losses near the wall and thus delays boundary layer separation. The flow control device is also robust to small variations of the groove location and depth.

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二维船尾钝体通过横槽的流动分离控制与减阻

目前的工作重点是一个被动的策略，包括在引入适当轮廓的横向凹槽，以延迟流动分离发生在船尾钝体在其锋利边缘的基础。我们考虑一个二维物体，其横截面为3:1的椭圆前体和矩形主体，后面是圆弧船尾。在Re = Du∞/v = 9.6 × 104条件下进行了变分多尺度大涡模拟。由于沟槽引起的流动分离的显著延迟以及由此引起的基压的增加，船尾阻力减少了9.7%左右。这种影响主要是由于槽内小而稳定的再循环区域的无滑移条件松弛，减少了壁面附近的动量损失，从而延迟了边界层分离。流量控制装置对凹槽位置和深度的小变化也很稳定。

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: Flow Manipulation and Active Control; Bio-Inspired Fluid Mechanics; Boundary Layer and High-Speed Flows; Fluids Engineering Education; Transport Phenomena in Energy Conversion and Mixing; Turbulent Flows; Vortex Dynamics; DNS/LES and Hybrid RANS/LES Methods; Fluid Structure Interaction; Fl

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