Physics and control of wall turbulence for drag reduction

Turbulence physics responsible for high skin-friction drag in turbulent boundary layers is first reviewed. A self-sustaining process of near-wall turbulence structures is then discussed from the perspective of controlling this process for the purpose of skin-friction drag reduction. After recognizing that key parts of this self-sustaining process are linear, a linear systems approach to boundary-layer control is discussed. It is shown that singular-value decomposition analysis of the linear system allows us to examine different approaches to boundary-layer control without carrying out the expensive nonlinear simulations. Results from the linear analysis are consistent with those observed in full nonlinear simulations, thus demonstrating the validity of the linear analysis. Finally, fundamental performance limit expected of optimal control input is discussed.

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Drag Reduction of a Cube-Type Truck Configuration Through Boundary-Layer Control: Experiments and Prototype Road Tests

10.4271/931893 ◽

1993 ◽

Author(s):

V. J. Modi ◽

S. St. Hill ◽

T. Yokomizo

Keyword(s):

Boundary Layer ◽

Drag Reduction ◽

Boundary Layer Control ◽

Layer Control

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Boundary Layer Combustion for Skin Friction Drag Reduction in Scramjet Combustors

50th AIAA/ASME/SAE/ASEE Joint Propulsion Conference ◽

10.2514/6.2014-3667 ◽

2014 ◽

Cited By ~ 2

Author(s):

Ryan J. Clark ◽

Shiva Om Bade Shrestha

Keyword(s):

Boundary Layer ◽

Drag Reduction ◽

Skin Friction ◽

Friction Drag ◽

Scramjet Combustors ◽

Friction Drag Reduction

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Direct numerical simulation of spatially developing turbulent boundary layers with uniform blowing or suction

Journal of Fluid Mechanics ◽

10.1017/jfm.2011.219 ◽

2011 ◽

Vol 681 ◽

pp. 154-172 ◽

Cited By ~ 46

Author(s):

YUKINORI KAMETANI ◽

KOJI FUKAGATA

Keyword(s):

Numerical Simulation ◽

Boundary Layer ◽

Direct Numerical Simulation ◽

Drag Reduction ◽

Skin Friction ◽

Reduction Factor ◽

Stream Velocity ◽

Normal Velocity ◽

Friction Drag ◽

Local Skin

Direct numerical simulation (DNS) of spatially developing turbulent boundary layer with uniform blowing (UB) or uniform suction (US) is performed aiming at skin friction drag reduction. The Reynolds number based on the free stream velocity and the 99% boundary layer thickness at the inlet is set to be 3000. A constant wall-normal velocity is applied on the wall in the range, −0.01U∞ ≤ Vctr ≤ 0.01U∞. The DNS results show that UB reduces the skin friction drag, while US increases it. The turbulent fluctuations exhibit the opposite trend: UB enhances the turbulence, while US suppresses it. Dynamical decomposition of the local skin friction coefficient cf using the identity equation (FIK identity) (Fukagata, Iwamoto & Kasagi, Phys. Fluids, vol. 14, 2002, pp. L73–L76) reveals that the mean convection term in UB case works as a strong drag reduction factor, while that in US case works as a strong drag augmentation factor: in both cases, the contribution of mean convection on the friction drag overwhelms the turbulent contribution. It is also found that the control efficiency of UB is much higher than that of the advanced active control methods proposed for channel flows.

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Energy efficiency and performance limitations of linear adaptive control for transition delay

Journal of Fluid Mechanics ◽

10.1017/jfm.2016.707 ◽

2016 ◽

Vol 810 ◽

pp. 60-81 ◽

Cited By ~ 6

Author(s):

Nicolò Fabbiane ◽

Shervin Bagheri ◽

Dan S. Henningson

Keyword(s):

Boundary Layer ◽

Drag Reduction ◽

Skin Friction ◽

Linear Control ◽

Transition To Turbulence ◽

Control Technique ◽

Net Energy ◽

Nonlinear Behaviour ◽

Friction Drag ◽

Budget Analysis

A reactive control technique with localised actuators and sensors is used to delay the transition to turbulence in a flat-plate boundary-layer flow. Through extensive direct numerical simulations, it is shown that an adaptive technique, which computes the control law on-line, is able to significantly reduce skin-friction drag in the presence of random three-dimensional perturbation fields with linear and weakly nonlinear behaviour. An energy budget analysis is performed in order to assess the net energy saving capabilities of the linear control approach. When considering a model of the dielectric-barrier-discharge (DBD) plasma actuator, the energy spent to create appropriate actuation force inside the boundary layer is of the same order as the energy gained from reducing skin-friction drag. With a model of an ideal actuator a net energy gain of three orders of magnitude can be achieved by efficiently damping small-amplitude disturbances upstream. The energy analysis in this study thus provides an upper limit for what we can expect in terms of drag-reduction efficiency for linear control of transition as a means for drag reduction.

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