UFR 3-32 Description: Difference between revisions
| Line 22: | Line 22: | ||
if high-speed flows are considered, in which case the unsteadiness is | if high-speed flows are considered, in which case the unsteadiness is | ||
also dependent on Mach number. | also dependent on Mach number. | ||
A first point is the understanding of the origin of these low | |||
frequencies: how is it possible to produce, from the turbulent | |||
fluctuations of the boundary layer, very low frequencies, involving | |||
scales differing from the turbulent layer itself generally by two orders | |||
of magnitude? Several possibilities have been examined in recent years. A | |||
first one assumes that the superstructures of the incoming layer (hairpin | |||
packets of length about 20 /?/ or more) make the shock wave and the | |||
separated zone move (Ganapathisubramani et al, 2007, 2009). A second one | |||
(Piponniau et al. 2009) considers that the low frequencies are produced | |||
by a process of emptying/filling of the separation bubble. Because of | |||
fluid entrainment, the air of the separation zone is drained by the large | |||
structures, Kelvin-Helmholtz-like, formed at the edge of the | |||
recirculating zone, and is progressively emptied, until it is filled | |||
again by air incoming in the reverse direction. The second scenario seems | |||
more appropriate, since it is able to reproduce the dominant frequencies | |||
in shock reflections, while the first one fails for this flow case. A | |||
point which can be underlined is that the scales involved in the | |||
unsteadiness are not directly related to the incoming boundary layer, and | |||
therefore cannot be reduced by some simple similarity to the | |||
characteristics of the boundary layer. This latter point is reinforced by | |||
a third approach (Touber & Sandham, 2011), based on a simplified momentum | |||
integral analysis, which shows how the low frequency can develop from | |||
uncorrelated broadband stochastic forcing of a separating boundary layer. | |||
From the CFD point of view, such flows remain challenging. Many attempts | |||
have been made to compute SWBLI, to determine the mean and turbulent | |||
fields or the unsteadiness. The few attempts of applying compressibility | |||
flow corrections in turbulence modelling have demonstrated an | |||
insufficient predictive capability of unsteady flows with strong | |||
compressibility effects and attempts to 'extrapolate' turbulence | |||
modelling from incompressible flows have also proven insufficient for | |||
the accurate prediction of the buffeting phenomenon and of transonic-dip | |||
flutter (examples: research program ETMA, Vieweg, Vol. 65 and European | |||
research program UNSI, final report edited by Springer, Vol. 81), | |||
concerning the simulation of buffeting phenomenon and of shock unsteady | |||
motion. A difficulty for RANS methods comes probably from their tuning to | |||
simple, self-similar equilibrium situations, and hence cannot cope with | |||
the new scales which are typically out of equilibrium, having a | |||
particular dynamics. More recently the hybrid approach DES (Detached Eddy | |||
Simulation), that is an inherently 3D approach, has been applied to the | |||
transonic flows around airfoils, indicating the crucial need for | |||
improvement of flow-physics knowledge concerning the modification of the | |||
turbulence scales due to the unsteadiness and compressibility. | |||
It seems that methods like LES do not suffer from the same limitations as | |||
RANS; a consequence is that hybrid methods like the different versions of | |||
DES may represent an interesting compromise by combining the flexibility | |||
of LES and the economy in computational resources of RANS. On the | |||
numerical side, such flows represent some challenging aspects: there are | |||
the usual requirements on meshes, since in LES computations the mesh size | |||
acts as a filter and therefore is part of the modelling, and there are | |||
other difficulties since unsteady shocks should be adequately represented | |||
by the computations, without being confused with turbulence. | |||
For the present application to shock-wave/boundary-layer interaction, | |||
experiments provide detailed descriptions of the flow, for the mean and | |||
turbulent fields, and for the characterization of the unsteadiness. The | |||
data are compared to the results of computations, using LES, several | |||
types of DES, and URANS and RANS methods based on Spalart-Allmaras | |||
modelling. The discussions will also lead to the assessment of the | |||
importance of taking in account the 3D effects for predicting correctly | |||
the separated zone and in turn, the interaction unsteadiness. | |||
== Review of UFR studies and choice of test case == | == Review of UFR studies and choice of test case == | ||
{{Demo_UFR_Desc_Review}} | {{Demo_UFR_Desc_Review}} | ||
Revision as of 08:25, 12 August 2013
Planar shock-wave boundary-layer interaction
Semi-confined Flows
Underlying Flow Regime 3-32
Description
Introduction
The problem of the unsteadiness in shock wave/boundary layer interactions (SWBLI) is challenging in many respects. A more general question is related to the unsteadiness or "breathing" of separated flows, whatever the regime, subsonic or supersonic. This is a problem that is important for both applications and basic research. In many aeronautical applications, such as aircraft profiles, air intakes, turbines or compressors, shock waves are formed and generally lead to separation. The resulting separation bubbles are unsteady, in the sense that they produce frequencies much lower (by at least two orders of magnitude) than the identified frequencies of the turbulent flow. Another difficulty arises if high-speed flows are considered, in which case the unsteadiness is also dependent on Mach number.
A first point is the understanding of the origin of these low
frequencies: how is it possible to produce, from the turbulent
fluctuations of the boundary layer, very low frequencies, involving
scales differing from the turbulent layer itself generally by two orders
of magnitude? Several possibilities have been examined in recent years. A
first one assumes that the superstructures of the incoming layer (hairpin
packets of length about 20 /?/ or more) make the shock wave and the
separated zone move (Ganapathisubramani et al, 2007, 2009). A second one
(Piponniau et al. 2009) considers that the low frequencies are produced
by a process of emptying/filling of the separation bubble. Because of
fluid entrainment, the air of the separation zone is drained by the large
structures, Kelvin-Helmholtz-like, formed at the edge of the
recirculating zone, and is progressively emptied, until it is filled
again by air incoming in the reverse direction. The second scenario seems
more appropriate, since it is able to reproduce the dominant frequencies
in shock reflections, while the first one fails for this flow case. A
point which can be underlined is that the scales involved in the
unsteadiness are not directly related to the incoming boundary layer, and
therefore cannot be reduced by some simple similarity to the
characteristics of the boundary layer. This latter point is reinforced by
a third approach (Touber & Sandham, 2011), based on a simplified momentum
integral analysis, which shows how the low frequency can develop from
uncorrelated broadband stochastic forcing of a separating boundary layer.
From the CFD point of view, such flows remain challenging. Many attempts
have been made to compute SWBLI, to determine the mean and turbulent
fields or the unsteadiness. The few attempts of applying compressibility
flow corrections in turbulence modelling have demonstrated an
insufficient predictive capability of unsteady flows with strong
compressibility effects and attempts to 'extrapolate' turbulence
modelling from incompressible flows have also proven insufficient for
the accurate prediction of the buffeting phenomenon and of transonic-dip
flutter (examples: research program ETMA, Vieweg, Vol. 65 and European
research program UNSI, final report edited by Springer, Vol. 81),
concerning the simulation of buffeting phenomenon and of shock unsteady
motion. A difficulty for RANS methods comes probably from their tuning to
simple, self-similar equilibrium situations, and hence cannot cope with
the new scales which are typically out of equilibrium, having a
particular dynamics. More recently the hybrid approach DES (Detached Eddy
Simulation), that is an inherently 3D approach, has been applied to the
transonic flows around airfoils, indicating the crucial need for
improvement of flow-physics knowledge concerning the modification of the
turbulence scales due to the unsteadiness and compressibility.
It seems that methods like LES do not suffer from the same limitations as
RANS; a consequence is that hybrid methods like the different versions of
DES may represent an interesting compromise by combining the flexibility
of LES and the economy in computational resources of RANS. On the
numerical side, such flows represent some challenging aspects: there are
the usual requirements on meshes, since in LES computations the mesh size
acts as a filter and therefore is part of the modelling, and there are
other difficulties since unsteady shocks should be adequately represented
by the computations, without being confused with turbulence.
For the present application to shock-wave/boundary-layer interaction,
experiments provide detailed descriptions of the flow, for the mean and
turbulent fields, and for the characterization of the unsteadiness. The
data are compared to the results of computations, using LES, several
types of DES, and URANS and RANS methods based on Spalart-Allmaras
modelling. The discussions will also lead to the assessment of the
importance of taking in account the 3D effects for predicting correctly
the separated zone and in turn, the interaction unsteadiness.
Review of UFR studies and choice of test case
Provide a brief review of past studies of this UFR which have included
test case comparisons of experimental measurements with CFD results.
Identify your chosen study (or studies) on which the document will
focus. State the test-case underlying the study and briefly explain how
well this represents the UFR? Give reasons for this choice (e.g a well
constructed test case, a recognised international comparison exercise,
accurate measurements, good quality control, a rich variety of
turbulence or physical models assessed etc.) . If possible, the study
should be taken from established data bases. Indicate whether of not
the experiments have been designed for the purpose of CFD validation
(desirable but not mandatory)?
Contributed by: Jean-Paul Dussauge — Orange
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