Affiliation:
1. Department of Mechanical Engineering, SUNY Polytechnic Institute , 100 Seymour Road, Donovan Hall 1185, Utica, NY 13502
Abstract
Abstract
Cavity flows studied over the past few decades have led to an increased understanding of the flow physics and instability modes in a range of configurations. While a large number of these studies focus on two-dimensional and three-dimensional rectangular/cuboidal cavities, significant variations are seen with three-dimensional cylindrical cavities with a top bounding wall. The present work details the flow physics of such cavities with a compressible (air) flow past the cavity at two pressure drops of 3850 Pa and 2000 Pa. Results from detached eddy simulations (DES) reveal the presence of the wake mode and shear layer instabilities, respectively, with modified dynamics and oscillatory modes owing to the top wall. In the interest of preventing mode switching with changes in operating conditions, which could lead to large-scale flow disruptions, a passive flow control technique is tested. The modified cavity (with a downstream ramp scaled by the size of shed structures) is seen to maintain the same mode throughout the range of operation offering valuable insights into design modifications for such cavities in practical settings.
Reference20 articles.
1. Review of Numerical Simulations for High-Speed, Turbulent Cavity Flows;Prog. Aerosp. Sci.,2011
2. Measurements of Fluctuating Pressures in and Behind the Bomb Bay of a Canberra Aircraft,1968
3. Characteristics of Cylindrical Cavities in a Compressible Turbulent Flow;Aerosp. Sci. Technol.,2017
4. Drag of a Rectangular Planform Cavity in a Flat Plate With a Turbulent Boundary Layer for Mach Numbers Up to 3. Part I: Closed Flow;ESDU,2000
5. Drag of a Rectangular Planform Cavity in a Flat Plate With a Turbulent Boundary Layer for Mach Numbers Up to 3. Part II: Open and Transitional Flows;ESDU,2000