Direct numerical simulation of turbulent flows through concentric annulus with circumferential oscillation of inner wall

doi:10.1007/s10483-018-2364-7

Applied Mathematics and Mechanics (English Edition) ›› 2018, Vol. 39 ›› Issue (9): 1267-1276.doi: https://doi.org/10.1007/s10483-018-2364-7

Direct numerical simulation of turbulent flows through concentric annulus with circumferential oscillation of inner wall

Yichen YAO, Chunxiao XU, Weixi HUANG

Department of Engineering Mechanics, Tsinghua University, Beijing 100084, China

收稿日期:2017-12-24 修回日期:2018-03-11 出版日期:2018-09-01 发布日期:2018-09-01
通讯作者: Chunxiao XU E-mail:xucx@tsinghua.edu.cn
基金资助:
Project supported by the National Natural Science Foundation of China (No. 11490551)

Direct numerical simulation of turbulent flows through concentric annulus with circumferential oscillation of inner wall

Yichen YAO, Chunxiao XU, Weixi HUANG

Department of Engineering Mechanics, Tsinghua University, Beijing 100084, China

Received:2017-12-24 Revised:2018-03-11 Online:2018-09-01 Published:2018-09-01
Contact: Chunxiao XU E-mail:xucx@tsinghua.edu.cn
Supported by:
Project supported by the National Natural Science Foundation of China (No. 11490551)

摘要/Abstract

摘要： Periodic wall oscillations in the spanwise or circumferential direction can greatly reduce the friction drag in turbulent channel and pipe flows. In a concentric annulus, the constant rotation of the inner cylinder can intensify turbulence fluctuations and enhance skin friction due to centrifugal instabilities. In the present study, the effects of the periodic oscillation of the inner wall on turbulent flows through concentric annulus are investigated by the direct numerical simulation (DNS). The radius ratio of the inner to the outer cylinders is 0.1, and the Reynolds number is 2 225 based on the bulk mean velocity U_m and the half annulus gap H. The influence of oscillation period is considered. It is found that for short-period oscillations, the Stokes layer formed by the circumferential wall movement can effectively inhibit the near-wall coherent motions and lead to skin friction reduction, while for long-period oscillations, the centrifugal instability has enough time to develop and generate new vortices, resulting in the enhancement of turbulence intensity and skin friction.

关键词: finite element, quadrilateral element, h-convergence, errorestimate, Taylor vortex, drag reduction, circumferential oscillation, turbulence

Abstract: Periodic wall oscillations in the spanwise or circumferential direction can greatly reduce the friction drag in turbulent channel and pipe flows. In a concentric annulus, the constant rotation of the inner cylinder can intensify turbulence fluctuations and enhance skin friction due to centrifugal instabilities. In the present study, the effects of the periodic oscillation of the inner wall on turbulent flows through concentric annulus are investigated by the direct numerical simulation (DNS). The radius ratio of the inner to the outer cylinders is 0.1, and the Reynolds number is 2 225 based on the bulk mean velocity U_m and the half annulus gap H. The influence of oscillation period is considered. It is found that for short-period oscillations, the Stokes layer formed by the circumferential wall movement can effectively inhibit the near-wall coherent motions and lead to skin friction reduction, while for long-period oscillations, the centrifugal instability has enough time to develop and generate new vortices, resulting in the enhancement of turbulence intensity and skin friction.

Key words: finite element, quadrilateral element, h-convergence, errorestimate, drag reduction, Taylor vortex, circumferential oscillation, turbulence

中图分类号:

Yichen YAO, Chunxiao XU, Weixi HUANG. Direct numerical simulation of turbulent flows through concentric annulus with circumferential oscillation of inner wall[J]. Applied Mathematics and Mechanics (English Edition), 2018, 39(9): 1267-1276.

参考文献

[1] BRADSHAW, P. and PONTIKOS, N. S. Measurements in the turbulent boundary layer on an "infinite" swept wing. Journal of Fluid Mechanics, 159, 105-130(1985)
[2] JUNG, W. J., MANGIAVACCHI, N., and AKHAVAN, R. Suppression of turbulence in wallbounded flows by high-frequency spanwise oscillations. Physics of Fluids A:Fluid Dynamics, 4(8), 1605-1607(1992)
[3] AKHAVAN, R., JUNG, W. J., and MANGIAVACCHI, N. Turbulence control in wall-bounded flows by spanwise oscillations. Advances in Turbulence IV, Springer, Netherlands, 299-303(1993)
[4] LAADHARI, F., SKANDAJI, L., and MOREL, R. Turbulence reduction in a boundary layer by a local spanwise oscillating surface. Physics of Fluids, 6(10), 3218-3220(1994)
[5] QUADRIO, M. and RICCO, P. Critical assessment of turbulent drag reduction through spanwise wall oscillations. Journal of Fluid Mechanics, 521, 251-271(2004)
[6] CHOI, J. I., XU, C. X., and SUNG, H. J. Drag reduction by spanwise wall oscillation in wallbounded turbulent flows. AIAA Journal, 40(5), 842-850(2002)
[7] QUADRIO, M., RICCO, P., and VIOTTI, C. Streamwise-travelling waves of spanwise wall velocity for turbulent drag reduction. Journal of Fluid Mechanics, 627, 161-178(2009)
[8] QUADRIO, M. and RICCO, P. The laminar generalized Stokes layer and turbulent drag reduction. Journal of Fluid Mechanics, 667, 135-157(2011)
[9] CHOI, K. S., DEBISSCHOP, J. R., and CLAYTON, B. R. Turbulent boundary-layer control by means of spanwise-wall oscillation. AIAA Journal, 36(7), 1157-1163(1998)
[10] CHOI, K. S. Near-wall structure of turbulent boundary layer with spanwise-wall oscillation. Physics of Fluids, 14(7), 2530-2542(2002)
[11] CHUNG, S. Y., RHEE, G. H., and SUNG, H. J. Direct numerical simulation of turbulent concentric annular pipe flow:part 1, flow field. International Journal of Heat and Fluid Flow, 23(4), 426-440(2002)
[12] CHUNG, S. Y. and SUNG, H. J. Large-eddy simulation of turbulent flow in a concentric annulus with rotation of an inner cylinder. International Journal of Heat and Fluid Flow, 26(2), 191-203(2005)
[13] JUNG, S. Y. and SUNG, H. J. Characterization of the three-dimensional turbulent boundary layer in a concentric annulus with a rotating inner cylinder. Physics of Fluids, 18(11), 115102(2006)
[14] KARNIADAKIS, G. E., ISRAELI, M., and ORSZAG, S. A. High-order splitting methods for the incompressible Navier-Stokes equations. Journal of Computational Physics, 97(2), 414-443(1991)
[15] TOUBER, E. and LESCHZINER, M. A. Near-wall streak modification by spanwise oscillatory wall motion and drag-reduction mechanisms. Journal of Fluid Mechanics, 693, 150-200(2012)

Direct numerical simulation of turbulent flows through concentric annulus with circumferential oscillation of inner wall

Direct numerical simulation of turbulent flows through concentric annulus with circumferential oscillation of inner wall

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