Satya Prakash Singh scite author profile

Flow past a circular cylinder for Re = 100 to 10 7 is studied numerically by solving the unsteady incompressible two-dimensional Navier-Stokes equations via a stabilized finite element formulation. It is well known that beyond Re ∼ 200 the flow develops significant three dimensional features. Therefore, two dimensional computations are expected to fall well short of predicting the flow accurately at high Re. It is fairly well accepted that the shear layer instability is primarily a two dimensional phenomenon. The frequency of the shear layer vortices, from the present computations, agree quite well with the Re 0.67 variation observed by other researchers from experimental measurements. The main objective of this paper is to investigate a possible relationship between the drag crisis (sudden loss of drag at Re ∼ 2 × 10 5 ) and the instability of the separated shear layer. As Re is increased the transition point of shear layer, beyond which it is unstable, moves upstream. At the critical Reynolds number the transition point is located very close to the point of flow separation. As a result, the shear layer eddies cause mixing of the flow in the boundary layer. This energizes the boundary layer and leads to its reattachment. The delay in flow separation is associated with narrowing of wake, increase in Reynolds shear stress near the shoulder of the cylinder and a significant reduction in the drag and base suction coefficients. The spatial and temporal power spectra for the kinetic energy of the Re = 10 6 flow are computed. As in two dimensional isotropic turbulence, E(k) varies as k −5/3 for wavenumbers higher than energy injection scale and as k −3 for lower wavenumbers. The present computations suggest that the shear layer vortices play a major role in the transition of boundary layer from laminar to turbulent state.1

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Vortex-induced vibrations at subcritical Re

Mittal

Singh

2005

J. Fluid Mech.

108

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Flow past a stationary cylinder becomes unstable at Re$\,{\sim}\,47$. Flow-induced vibrations of an elastically mounted cylinder, of low non-dimensional mass, is investigated at subcritical Reynolds numbers. A stabilized finite-element formulation is used to solve the incompressible flow equations and the cylinder motion in two dimensions. The cylinder is free to vibrate in both the transverse and in-line directions. It is found that, for certain natural frequencies of the spring–mass system, vortex shedding and self-excited vibrations of the cylinder are possible for Re as low as 20. Lock-in is observed in all cases. However, the mass of the oscillator plays a major role in determining the proximity of the vortex-shedding frequency to the natural frequency of the oscillator. A global linear stability analysis (LSA) for the combined flow and oscillator is carried out. The results from the LSA are in good agreement with the two-dimensional direct numerical simulations.

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Effect of blockage on vortex-induced vibrations at low Reynolds numbers

Prasanth

Behara

Singh

et al. 2006

Journal of Fluids and Structures

120

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Perovskite photocatalysis: realizing long-lived charge-separated states at the interface of CsPbBr₃nanocrystals and functionalized ferrocene molecules

et al. 2022

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