A random-jet-stirred turbulence tank

We report measurements of the flow above a planar array of synthetic jets, firing upwards in a spatiotemporally random pattern to create turbulence at an air–water interface. The flow generated by this randomly actuated synthetic jet array (RASJA) is turbulent, with a large Reynolds number and a weak secondary (mean) flow. The turbulence is homogeneous over a large region and has similar isotropy characteristics to those of grid turbulence. These properties make the RASJA an ideal facility for studying the behaviour of turbulence at boundaries, which we do by measuring one-point statistics approaching the air–water interface (via particle image velocimetry). We explore the effects of different spatiotemporally random driving patterns, highlighting design conditions relevant to all randomly forced facilities. We find that the number of jets firing at a given instant, and the distribution of the duration for which each jet fires, greatly affect the resulting flow. We identify and study the driving pattern that is optimal given our tank geometry. In this optimal configuration, the flow is statistically highly repeatable and rapidly reaches steady state. With increasing distance from the jets, there is a jet merging region followed by a planar homogeneous region with a power-law decay of turbulent kinetic energy. In this homogeneous region, we find a Reynolds number of 314 based on the Taylor microscale. We measure all components of mean flow velocity to be less than 10% of the turbulent velocity fluctuation magnitude. The tank width includes roughly 10 integral length scales, and because wall effects persist for one to two integral length scales, there is sizable core region in which turbulent flow is unaffected by the walls. We determine the dissipation rate of turbulent kinetic energy via three methods, the most robust using the velocity structure function. Having a precise value of dissipation and low mean flow allows us to measure the empirical constant in an existing model of the Eulerian velocity power spectrum. This model provides a method for determining the dissipation rate from velocity time series recorded at a single point, even when Taylor's frozen turbulence hypothesis does not hold. Because the jet array offers a high degree of flow control, we can quantify the effects of the mean flow in stirred tanks by intentionally forcing a mean flow and varying its strength. We demonstrate this technique with measurements of gas transfer across the free surface, and find a threshold below which mean flow no longer contributes significantly to the gas transfer velocity.

[1]  Gerhard H. Jirka,et al.  Near-surface turbulence in a grid-stirred tank , 1987, Journal of Fluid Mechanics.

[2]  C. Meneveau,et al.  Evolution and modelling of subgrid scales during rapid straining of turbulence , 1999, Journal of Fluid Mechanics.

[3]  B. Pearson,et al.  Measurements of the turbulent energy dissipation rate , 2002 .

[4]  S. Pope Turbulent Flows: FUNDAMENTALS , 2000 .

[5]  Harindra J. S. Fernando,et al.  Oscillating grids as a source of nearly isotropic turbulence , 1994 .

[6]  Z. Warhaft,et al.  On the onset of high-Reynolds-number grid-generated wind tunnel turbulence , 1996, Journal of Fluid Mechanics.

[7]  G. Pedersen,et al.  PIV and Water Waves , 2004 .

[8]  Eberhard Bodenschatz,et al.  Lagrangian acceleration measurements at large Reynolds numbers , 1998 .

[9]  L. Montenegro,et al.  Generation of nearly isotropic turbulence using two oscillating grids , 1996 .

[10]  M. Birouk,et al.  An Attempt to Realize Experimental Isotropic Turbulence at Low Reynolds Number , 2003 .

[11]  Shraiman,et al.  Persistent small scale anisotropy in homogeneous shear flows. , 1995, Physical review letters.

[12]  Makita Hideharu Realization of a large-scale turbulence field in a small wind tunnel , 1991 .

[13]  J. Turner,et al.  Mixing across an interface due to turbulence generated by an oscillating grid , 1975, Journal of Fluid Mechanics.

[14]  J. C. R. Hunt,et al.  Free-stream turbulence near plane boundaries , 1978, Journal of Fluid Mechanics.

[15]  Emmanuel Villermaux,et al.  Intense vortical structures in grid‐generated turbulence , 1995 .

[16]  S. Monismith,et al.  A hybrid digital particle tracking velocimetry technique , 1997 .

[17]  E. Cowen,et al.  QUANTITATIVE IMAGING TECHNIQUES AND THEIR APPLICATION TO WAVY FLOWS , 2004 .

[18]  A. Kolmogorov,et al.  The local structure of turbulence in incompressible viscous fluid for very large Reynolds numbers , 1991, Proceedings of the Royal Society of London. Series A: Mathematical and Physical Sciences.

[19]  Isabelle Calmet,et al.  Statistical structure of high-Reynolds-number turbulence close to the free surface of an open-channel flow , 2003, Journal of Fluid Mechanics.

[20]  J. Eaton,et al.  Creating homogeneous and isotropic turbulence without a mean flow , 2004 .

[21]  J. Yen,et al.  A novel laboratory apparatus for simulating isotropic oceanic turbulence at low Reynolds number , 2004 .

[22]  T. McDougall Measurements of turbulence in a zero-mean-shear mixed layer , 1979, Journal of Fluid Mechanics.

[23]  Bernd Jähne,et al.  Air‐sea gas transfer: Its dependence on wind stress, small‐scale roughness, and surface films , 2004 .

[24]  E. J. Hopfinger,et al.  Spatially decaying turbulence and its relation to mixing across density interfaces , 1976, Journal of Fluid Mechanics.

[25]  M. Kenward,et al.  An Introduction to the Bootstrap , 2007 .

[26]  G. Triantafyllou,et al.  Effect of surfactants on free-surface turbulent flows , 2004, Journal of Fluid Mechanics.

[27]  Sean P. McKenna,et al.  The role of free-surface turbulence and surfactants in air–water gas transfer , 2004 .

[28]  N. Malik,et al.  Kinematic simulation of homogeneous turbulence by unsteady random Fourier modes , 1992, Journal of Fluid Mechanics.

[29]  A. N. Kolmogorov Equations of turbulent motion in an incompressible fluid , 1941 .

[30]  Y. Couder,et al.  Direct observation of the intermittency of intense vorticity filaments in turbulence. , 1991, Physical review letters.

[31]  E. Cowen,et al.  A random synthetic jet array driven turbulence tank , 2004 .

[32]  G. Voth,et al.  Measurement of particle accelerations in fully developed turbulence , 2001, Journal of Fluid Mechanics.

[33]  The velocity skewness measured in grid turbulence , 1987 .

[34]  S. S. Shy,et al.  A nearly isotropic turbulence generated by a pair of vibrating grids , 1997 .

[35]  W. Snyder,et al.  Acoustic doppler velocimeter evaluation in stratified towing tank , 1999 .

[36]  Harindra J. S. Fernando,et al.  Note on secondary flows in oscillating‐grid, mixing‐box experiments , 1993 .

[37]  H. Fernando,et al.  Experimental examination of Eulerian frequency spectra in zero‐mean‐shear turbulence , 1995 .

[38]  Qian Liao,et al.  An efficient anti-aliasing spectral continuous window shifting technique for PIV , 2005 .

[39]  H. Tennekes,et al.  Eulerian and Lagrangian time microscales in isotropic turbulence , 1975, Journal of Fluid Mechanics.

[40]  Haitao Xu,et al.  Small-scale anisotropy in Lagrangian turbulence , 2006 .