A review of recent developments in flow control

Ashill, P. R.; Fulker, J. L.; Hackett, K.

doi:10.1017/s0001924000005200

Cited by 119 publications

(74 citation statements)

References 54 publications

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“…In Lin's review [3] on the low-profile vortex generator, it was mentioned that MVG could alleviate the flow distortion in compact ducts to some extent and control boundary layer separation due to the adverse pressure gradients. Similar comments were made in the review by Ashill et al [4].…”

Section: Introductionsupporting

confidence: 72%

LES Study on Mechanism of Reduction of Shock Induced Flow Separation by MVG

Yang

Yan

Liu

2015

53rd AIAA Aerospace Sciences Meeting

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Shock-boundary layer interaction (SBLI) is a kind of problem which is frequently met in supersonic engine inlet flow and external flow. A detail study on mechanism of reduction of shock induced flow separation by MVG is carried out by high order implicit large eddy simulation (LES). To generate the fully developed turbulent flow, a series of turbulent profiles are given by previous DNS simulation results. The mechanism of reduction of shock induced flow separation was originally considered as a result of plump velocity profile caused by turbulent kinetic energy. It was acclaimed that turbulent flow has so stronger kinetic energy that the velocity profile is changed to be plump, which lead to reduction of shock induced flow separation. However, according to our detail study in this paper, the shock wave breaks down when ring-like vortices generated by MVG are passing through it, while the vortex structure never breaks down and is even little influenced. Therefore, the flow separation induced by shock is reduced by break-down of shock wave, not plump velocity profile. More details of the investigation on the mechanism are reported in this paper.

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Section: Introductionsupporting

confidence: 72%

LES Study on Mechanism of Reduction of Shock Induced Flow Separation by MVG

Yang

Yan

Liu

2015

53rd AIAA Aerospace Sciences Meeting

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“…In recent years, as our knowledge of the (vortical) flow structures associated with 3-D SCBs has matured, researchers have begun to compare these devices with vortex generators. In one such study, Colliss et al [9] found that the strength of the vortices produced by a 3-D SCB is of the same order of magnitude as those of vortex generators (as reported by Ashill et al [1]), when expressed in terms of the non-dimensional circulation parameter /(u τ h) (where u τ is the local uncontrolled friction velocity and h is the SCB or vortex generator height). However, Colliss et al [9] also explain that quantifying the 'strength' of the vortices is not always trivial: as the existence of strong shear flows, in which the vortices are embedded, can make it difficult to extract the contribution to of the vortex itself.…”

Section: Comparisons With Other Supersonic Flow Control Strategiesmentioning

confidence: 67%

“…Broadly speaking, a glance through the relevant literature from the past two decades reveals that studies of SCBs fall into one of the two categories: (1) Investigations that consist of parametric studies and/or optimisation; and (2) Investigations that probe the detailed flow physics produced by SCBs in controlled environments. In this review article, we will draw together the results from studies of both types.…”

Section: Scopementioning

confidence: 99%

“…Numerous review papers and research projects have made comparisons between SCBs and other (supersonic and transonic) flow control strategies [1,3,33]. A common conclusion amongst these studies and reviews is that 3-D SCBs offer a unique combination of promising performance potential (in terms of drag and/or buffet) and practicality (in terms of ease of installation, cost, weight, etc.)…”

Section: Comparisons With Other Supersonic Flow Control Strategiesmentioning

confidence: 99%

“…The basic principle of shock control is well summarised by Ogawa and Babinsky [23], who explain that any flow control device that causes a flow deflection has the potential to reduce wave drag. However, although other (passive) shock-control techniques have been considered (such as the perforated surface cavity), it has been found that such techniques invariably incur prohibitively high levels of viscous drag which outweigh any wave drag benefit [1,33]. In recent years, as our knowledge of the (vortical) flow structures associated with 3-D SCBs has matured, researchers have begun to compare these devices with vortex generators.…”

Section: Comparisons With Other Supersonic Flow Control Strategiesmentioning

confidence: 99%

See 2 more Smart Citations

Review of research into shock control bumps

Bruce

Colliss

2014

Shock Waves

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This paper presents a review of research on shock control bumps (SCBs), a class of flow control device with potential for application to transonic wings. Beginning with a brief review of the origins of the SCB concept, the primary focus is on the more recent studies from the last decade. Results from both experimental and numerical work are considered and the synergy between these two approaches to SCB research is critically explored. It is shown that the aerodynamic performance enhancement potential of SCBs, namely their capacity for drag reduction and delaying the onset of buffet for transonic wings, has been widely demonstrated in the literature, as has the high sensitivity of SCB performance to flow conditions including shock strength and position, and post-shock adverse pressure gradient. These characteristic features of SCBs are relatively well explained in terms of the flow physics that have been observed for different bump geometries. This stems from a number of studies that have focused on the balance of viscous and inviscid flow features and also the mechanism by which finite span SCBs generate streamwise vorticity. It is concluded that our understanding of SCBs is reaching an advanced level of maturity for SCBs in simple configurations and steady flow fields. However, SCB performance in unsteady flow and on swept wings requires further investigation before the concept can be considered a viable candidate for transonic wings. These investigations should adopt a multi-disciplinary approach combining carefully designed experiments and targeted computations. Finally, two concepts for future SCB research are suggested: the adaptive SCB and SCBs in engine intakes.Communicated by A. Hadjadj.

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Aerodynamics of horizontal axis wind turbines

2021

Wind Energy Handbook 3e

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A review of recent developments in flow control

Cited by 119 publications

References 54 publications

LES Study on Mechanism of Reduction of Shock Induced Flow Separation by MVG

LES Study on Mechanism of Reduction of Shock Induced Flow Separation by MVG

Review of research into shock control bumps

Aerodynamics of horizontal axis wind turbines

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