Active Control for Wall Drag Reduction: Methods, Mechanisms and Performance

Zhang, Lu; Shan, Xiaobiao; Xie, Tao

doi:10.1109/access.2020.2963843

Cited by 30 publications

(5 citation statements)

References 171 publications

(146 reference statements)

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“…The discussion of spanwise wall motion is brief, covering some major observations derived from DNS studies on the optimum choice of actuation parameters, and power-saving issues. More recent reviews on flow control that discuss spanwise wall oscillations are by Asidin et al [2019] and Zhang et al [2020]. In addition, a few books on turbulence and flow control contain chapters devoted to the oscillating-wall technique, e.g., Fan and Dong [2016], Soldati and Monti [2014], Tardu [2017].…”

Section: Introductionmentioning

confidence: 99%

A review of turbulent skin-friction drag reduction by near-wall transverse forcing

Riccó

Skote

Leschziner

2021

Progress in Aerospace Sciences

106

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Section: Introductionmentioning

confidence: 99%

A review of turbulent skin-friction drag reduction by near-wall transverse forcing

Riccó

Skote

Leschziner

2021

Progress in Aerospace Sciences

106

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“…They considered both active (synthetic jets, dynamic pins) and passive (static pins/vortex generators) devices individually as well as a combination, thus generating a hybrid actuator that has potential to be a more efficient controller than the baseline devices for certain flow fields. In their review, Zhang et al 21 focused their attention on active wall drag reduction. They summarized previous works on actively disturbing the turbulent boundary layer in order to reduce the skin-friction drag of vehicles by one of the following: wall motion, wall deformation, wall micro oscillation, or effects of volume force.…”

Section: Background and Introductionmentioning

confidence: 99%

Current state and future trends in boundary layer control on lifting surfaces

Svorcan

Wang

Griffin

2022

Advances in Mechanical Engineering

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Successful flow control may bring numerous benefits, such as flow stabilization, flow reattachment, separation delay, drag reduction, lift increase, aerodynamic performance improvement, energy efficiency increase, shock delay or weakening, noise reduction, etc. For these purposes, many different flow control devices, which can be classified as passive, semi-active and active, have been designed and tested. This review paper aims to highlight the most promising and commonly employed boundary layer control methods as well as outline their potential in specific applications in aerospace and energy engineering. Referenced studies, performed on various geometries (flat plates, channels, airfoils, wings, blades, cylinders), are primarily numerical or experimental. Although enhanced aerodynamic performance is achieved in many cases, further research is required to draw general conclusions. This paper aims to demonstrate that, in the future, we may expect further developments of flow control actuators, as well as their increased application.

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“…Wall turbulence drag reduction technologies have represented a dramatic topic in aerospace and other engineering applications over the past few decades as a result of the oil crisis in the early 1970s [1]. So far, various control schemes [2] have been put forward with remarkable success and are of great significance in improving the performance of vehicles and saving energy [3].…”

Section: Introductionmentioning

confidence: 99%

Influence of Synthetic Jets on Multiscale Features in Wall-Bounded Turbulence

Zhang

Jiang

2022

Actuators

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This experimental research focuses on the impacts of submerged synthetic jets on a fully-developed turbulent boundary layer (TBL) under a drag reduction working case. Two-dimensional velocity vectors in the flow field are captured with the aid of a particle image velocimetry (PIV) system. Proper orthogonal decomposition (POD) analyses provide evidence that synthetic jets notably attenuate the induction effect of prograde vortex on the low-speed fluid in large-scale fluctuation velocity field, thereby weakening the bursting process of near-wall turbulent events. Furthermore, the introduced perturbance redistributes the turbulent kinetic energy (TKE) and concentrates the TKE onto small-scale coherent structures. Modal time coefficients in various orders of POD are divided into components of multiple frequency bands by virtue of complementary ensemble empirical mode decomposition (CEEMD). It is found that the turbulence signals are shifted from low-frequency to high-frequency bands thanks to synthetic jets, thus revealing the relationship between scales and frequency bands. One further method of scale decomposition is proposed, that is, the large-scale fluctuating flow field will be obtained after removing the high-frequency noise data with the help of continuous mean square error (CMSE) criterion.

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Active Control for Wall Drag Reduction: Methods, Mechanisms and Performance

Cited by 30 publications

References 171 publications

A review of turbulent skin-friction drag reduction by near-wall transverse forcing

A review of turbulent skin-friction drag reduction by near-wall transverse forcing

Current state and future trends in boundary layer control on lifting surfaces

Influence of Synthetic Jets on Multiscale Features in Wall-Bounded Turbulence

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