Instabilities in supersonic compression ramp flow

A. J P Fletcher; A. I. Ruban; J. D A Walker

doi:10.1017/S0022112004000916

Instabilities in supersonic compression ramp flow

A. J P Fletcher, A. I. Ruban, J. D A Walker

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Abstract

Separation of a supersonic boundary layer near a compression ramp is considered in the limit of large Reynolds numbers and for Mach numbers O(1). When the ramp angle is small, the motion may be described by the well-known triple-deck theory describing viscous-inviscid interactions. For small values of the scaled ramp angle, steady stable solutions can be obtained. However, it is shown that when a recirculation zone is present and the ramp angle is sufficiently large, the flow in the recirculation zone is susceptible to convective instabilities when perturbations are introduced there. At still larger values of the scaled ramp angle, an absolute instability is shown to occur that leads to a violent local breakdown of the boundary layer. The calculated results are shown to be consistent with a theoretical criterion that is the necessary and sufficient condition for the onset of instability. © 2004 Cambridge University Press.

Original language	English
Pages (from-to)	309-330
Number of pages	21
Journal	Journal of Fluid Mechanics
Volume	517
DOIs	https://doi.org/10.1017/S0022112004000916
Publication status	Published - 25 Oct 2004

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title = "Instabilities in supersonic compression ramp flow",

abstract = "Separation of a supersonic boundary layer near a compression ramp is considered in the limit of large Reynolds numbers and for Mach numbers O(1). When the ramp angle is small, the motion may be described by the well-known triple-deck theory describing viscous-inviscid interactions. For small values of the scaled ramp angle, steady stable solutions can be obtained. However, it is shown that when a recirculation zone is present and the ramp angle is sufficiently large, the flow in the recirculation zone is susceptible to convective instabilities when perturbations are introduced there. At still larger values of the scaled ramp angle, an absolute instability is shown to occur that leads to a violent local breakdown of the boundary layer. The calculated results are shown to be consistent with a theoretical criterion that is the necessary and sufficient condition for the onset of instability. {\textcopyright} 2004 Cambridge University Press.",

author = "Fletcher, {A. J P} and Ruban, {A. I.} and Walker, {J. D A}",

year = "2004",

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T1 - Instabilities in supersonic compression ramp flow

AU - Fletcher, A. J P

AU - Ruban, A. I.

AU - Walker, J. D A

PY - 2004/10/25

Y1 - 2004/10/25

N2 - Separation of a supersonic boundary layer near a compression ramp is considered in the limit of large Reynolds numbers and for Mach numbers O(1). When the ramp angle is small, the motion may be described by the well-known triple-deck theory describing viscous-inviscid interactions. For small values of the scaled ramp angle, steady stable solutions can be obtained. However, it is shown that when a recirculation zone is present and the ramp angle is sufficiently large, the flow in the recirculation zone is susceptible to convective instabilities when perturbations are introduced there. At still larger values of the scaled ramp angle, an absolute instability is shown to occur that leads to a violent local breakdown of the boundary layer. The calculated results are shown to be consistent with a theoretical criterion that is the necessary and sufficient condition for the onset of instability. © 2004 Cambridge University Press.

AB - Separation of a supersonic boundary layer near a compression ramp is considered in the limit of large Reynolds numbers and for Mach numbers O(1). When the ramp angle is small, the motion may be described by the well-known triple-deck theory describing viscous-inviscid interactions. For small values of the scaled ramp angle, steady stable solutions can be obtained. However, it is shown that when a recirculation zone is present and the ramp angle is sufficiently large, the flow in the recirculation zone is susceptible to convective instabilities when perturbations are introduced there. At still larger values of the scaled ramp angle, an absolute instability is shown to occur that leads to a violent local breakdown of the boundary layer. The calculated results are shown to be consistent with a theoretical criterion that is the necessary and sufficient condition for the onset of instability. © 2004 Cambridge University Press.

U2 - 10.1017/S0022112004000916

DO - 10.1017/S0022112004000916

M3 - Article

SN - 1469-7645

VL - 517

SP - 309

EP - 330

JO - Journal of Fluid Mechanics

JF - Journal of Fluid Mechanics

ER -

Instabilities in supersonic compression ramp flow

Abstract

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