A numerical study of vortex shedding from flat plates with square leading and trailing edges-Reference-Cited by-同舟云学术

A numerical study of vortex shedding from flat plates with square leading and trailing edges

Published:1992-03 Issue: Volume:236 Page:445-460
ISSN:0022-1120
Container-title:Journal of Fluid Mechanics
language:en
Short-container-title:J. Fluid Mech.

Author:

Ohya Yuji,Nakamura Yasuharu,Ozono Shigehira,Tsuruta Hideki,Nakayama Ryuzo

Abstract

This paper describes a numerical study of the flow around flat plates with square leading and trailing edges on the basis of a finite-difference analysis of the two-dimensional Navier—Stokes equations. The chord-to-thickness ratio of a plate, d/h, ranges from 3 to 9 and the value of the Reynolds number based on the plate's thickness is constant and equal to 103. The numerical computation confirms the finding obtained in our previous experiments that vortex shedding from flat plates with square leading and trailing edges is caused by the impinging-shear-layer instability. In particular, the Strouhal number based on the plate's chord increases stepwise with increasing d/h in agreement with the experiment. Numerical analyses also provide some crucial information on the complicated vortical flow occurring near the trailing edge in conjunction with the vortex shedding mechanism. Finally, the mechanism of the impinging-shear-layer instability is discussed in the light of the experimental and numerical findings.

Publisher

Cambridge University Press (CUP)

Subject

Mechanical Engineering,Mechanics of Materials,Condensed Matter Physics

Reference14 articles.

1. Harlow, F. H. & Welch, J. E. 1965 Numerical calculation of time-dependent viscous incompressible flow of fluid with free surface.Phys. Fluids 8,2182–2189.

2. Nakamura, Y. , Ohya, Y. & Tsuruta, H. 1991 Experiments on vortex shedding from flat plates with square leading and trailing edges.J. Fluid Mech. 222,437–447.

3. Troutt, T. R. , Scheelke, B. & Norman, T. R. 1984 Organized structures in a reattaching separated flow field.J. Fluid Mech. 143,413–427.

4. Kawamura, T. & Kuwahara, K. 1984 Computation of high Reynolds number flow around a circular cylinder with surface roughness.AIAA Paper 84–0340.

5. Stokes, A. N. & Welsh, M. C. 1986 Flow-resonant sound interaction in a duct containing a plate, II: Square leading edge.J. Sound Vib. 104,55–73.

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