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4. How did Louis Vuitton enter into the Japanese market originally? What were the other entry strategies it adopted later to strengthen its presence?
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Cross-checking of numerical-experimental procedures for interface characterization in quasi 2-D transitional flow in the context of MultiSECtioning strategy.
1. Cross-checking of numerical-experimental procedures for interface characterization in
quasi 2-D transitional flow in the context of MultiSECtioning strategy.
G. Sorrentino! ,1,2
, D. Scarpa2
, R. Ragucci1
, A. Cavaliere2
1
Istituto di Ricerche sulla Combustione - CNR, P. Tecchio, 80, 80125 Napoli, Italy
2
DICMAPI- Università Federico II Napoli, P. Tecchio, 80, 80125 Italy
Abstract
MultiSECtioning strategy is a sequential approach aimed to the evaluation and verification of non-premixed
diffusion controlled combustion processes. The first step of this strategy, namely the characterization of the interface
kinematics, is the sinews of this approach. Laser light scattering and PIV techniques with digital image processing
procedures are used on a proper 3D test-rig in order to obtain a complete characterization of the interface. On the
other hand, a 2D DNS has been performed to cross-check the experimental results. The cross-checking opens new
issues to find directions for model updating, limits of computer simulation quality, and to perform uncertainty
quantification.
!
Corresponding author: g.sorrentino@unina.it
Proceedings of the European Combustion Meeting 2013
Introduction
Turbulent combustion has a particular relevance
since typical flows in practical devices are inevitably
turbulent, because of both their large flow rates and the
request of intense heat and mass exchanges. The
persistence of research on turbulent combustion over
many decades reflects the formidable challenges of the
subject, which yield slowly to our increasing
understanding and technological capabilities in terms of
computer power and instrumentation. The modeling
paradigms of turbulent combustion are also relevant to
an even broader range of physical phenomena, which
exhibit multiscale and multiphysics natures. The
advances needed in such computational modeling for
practical combustion systems will require considerable
investment in modeling research in this area, including
the new paradigms of multi-scale modeling. It will also
need an increased emphasis on research directed at
improving experimental databases for model validation
that are of a hierarchical nature and start with relatively
simple problems that encapsulate the most important
physics. For such reasons, strategies which select
particular sub-models and which exploit them in such a
way that split effects can be separately introduced in
more and more complex processes, should be preferred
to other ones. In fact, this rational approach allows more
sensible evaluation of their effects as well as of their
interaction with more complex processes. In this
context, the paper reports some results of a new
framework aimed to analyze non-premixed turbulent
flames. The step-by-step systematic procedure, called
MultiSECtioning, allows for analyzing different
phenomena and their interaction in non-premixed
combustion processes. The first step (and the “sinews”
of the approach) considers the stirring of material
surfaces in transitional/turbulent flows. An experimental
setup has been developed to study this. The optical
diagnostics and the digital image processing procedures
are here described and results for a 2D transitional flow
are reported.
Moreover, for this reference case the experimental
results have been compared with the corresponding
numerical patterns obtained through a 2D Direct
Numerical Simulation with a lagrangian particle
tracking.
To allow a correct evaluation of the results, a cross-
checking between experimental and numerical results
has been outlined. Qualitative and quantitative
comparisons indicate quite good agreement between
experimental and numerical patterns.
The knowledge of some specific quantities appears to be
necessary for the full control of the investigated
phenomenon. Improvement in the accuracy of
theoretical and numerical models and their experimental
validation is an indispensable procedure in such cases.
This issue seems to be especially pertinent when
modelling multi-scale phenomena.
MultiSECtioning Strategy and relevant quantities
Complex reactive flow systems need proper
strategies for their modeling. A possible procedure
consists in sectioning the whole process in parts, by
means of geometrical sectioning of the control volumes
or selection of a subset of one or more physical effects,
which are suitable to be separately modelled and are,
hence, separately validated in a sequential cascade of
increasingly complex models. For these sequential
processes cascade it is possible to check the accuracy of
the numerical predictions through the comparison with
the experimental data “side by side” at each one of the
“stages” in which the whole combustion process has
been sectioned. On the ground of these considerations a
strategy, named MultiSECtioning [1, 2], allowing for a
correct analysis of the influence of single subprocesses
has been conceived. The name refers to the multiple
repetition of the three letters acronym SEC in its
2. schematic description: “Sequential Enlargement
Combination” (SEC) of the “Separated Effect
Contribution” (SEC) for “Side-by-side
Experimental/Numerical Checking” (SEC).
The first part of the procedure is a fluid-dynamic
characterization of the patterns of interest when not
reacting flows are introduced in fixed control volume,
for fixed boundary-initial conditions, for fixed external
parameters.
The fluid dynamic database, generated in this first step,
has to be suitable for the characterization of the effects
generated by considering the injection of not-diffusing
tracers in the control volume. This is the step of the
strategy, which is reported in fig 1 in the block quoted
as “stirring”. It is anticipated here that it can be obtained
from experimental point as smoke streak-lines, which in
turn yield interface between the two reactants and that
the prediction of the location of such surface is the
object of the numerical codes which are “enlarged” in
order to include also the convective transport of an inert,
passive not-diffusing material. Then a new database is
generated which can be analyzed in terms of local or
integral stirring quantities (interface location) either for
mutual checking between experimental and numerical
determinations or for evaluating the efficiency of
stirring in relation to the whole combustion process.
The most basic structure of this methodology is the
material surface. By definition, a material surface
moves with the fluid: every point of the surface is a
fluid particle.
Various measures of the surface geometry, such as
surface-to-volume ratio or volume-fill fraction, and their
relation to the distribution of spatial scales, are, as a
consequence, important to our understanding and
modeling of mixing, chemical reactions, and
combustion in turbulent flows.
If we consider mixing segregated fluids in the absence
of diffusion, the mixing process is described by the
location of the interface between the fluids [3]. For a
fast mixing flow such as a chaotic or turbulent flow, this
interface stretches at an exponential rate [4].
This paper aims at the characterization of the stirring
sub-process, which in turn yield interface between the
two reactants. In particular, the identification of these
surfaces can be seen as the “sinew” of the proposed
approach.
This expression summarizes a twofold concept:
• Characterization of advected-surfaces is the
“skeleton” of this strategy and it is connected to
the other step;
• Interface identification is the mainstay of the
approach. The strength of MultiSECtioning is
derived from this stage. In this sense, the
subsequent steps are a consequence of the first
one. In fact, without a good prediction of the
stirring phenomena, the whole combustion
process cannot be analyzed in a correct way.
!"#$%&'(
#')*+%#,-.
(/.0*-/'!,!
(1+",2(2.3%4,&!(
&/%#%&-'#,5%-,*3
!"# ! "
!
" #
#
!
#$% #
#
! #
#
$
&# &%
'
(' &%#)'
'*'
(
!"#!$!%#
&!'!#"
($!))!#"
+ #,-#
.
Fig.1 Main sequential blocks of the
“MultiSECtioning” strategy
The main difficulties in the experimental/numerical
evaluation of the stirring part will be discussed in the
following and the main limits of the presented
procedures will be pointed out for a reference case.
It is worthwhile to note that some quantities, reported in
Fig. 1 in the fluid-dynamics characterization stage
(stirring-block), such as mean velocity ( ˆv ) and the
stretch rate ( ˆK!A ), conditioned on the interface location
have to be evaluated in order to characterize the
interface evolution.
The surface stretch rate is linked to the velocity pattern
of the flow, in which it evolves, by the following
kinematic relationship:
1) K!A = "#v $ "v :nn
where n and v are the normal unit vector and the
velocity vector of the surface !A , respectively.
It is also possible to demonstrate that [5] :
2) K!A = "t #vt + vnC
3. Where vt and vn are the projection of the velocity
vector on the surface !A and the modulus of the
projection vn along the normal to the surface,
respectively, !t the divergence operator on the surface
and C is its curvature. This last expression shows that
the stretch rate consists both of a contribution related to
the “planar divergence” of velocities on the surface and
of a contribution related to the mean surface curvature.
Another important quantity that has to be evaluated or
modelled is the interface density ( ! ) defined as the
expected value of the local surface-to-volume ratio, at
fixed Eulerian position:
3) ! =
A "V
"V
A physical interpretation of ! is that its inverse is a
striation thickness. The striation thickness is related to
the amount of area between the fluids [6]. This quantity
can be interpreted as a structured continuum property;
thus, if the surface is multiply folded so that locally it
appears like parallel planes (i.e. the structure is lamellar
and uniform), then the mean distance between the
planes is !"1
. This quantity is useful in describing
mixing with diffusion and reaction [7]. In the following
paragraphs results for the quantity previously mentioned
are reported for a reference test case. Mean velocity
fields, strain rate and interface density have been
obtained both with digital image processing procedure
and with Direct Numerical Simulation.
Main results and cross-checking
Some results relative to a reference condition,
corresponding to a mean Reynolds number of 2800 are
reported in the following. The Reynolds number is
based on the mean velocity pattern in the chamber.
For this case, profiles of interface density have been
obtained and they will be shown in the following with
results of main velocity fields and strain rate
conditioned on the interface location. The flow
visualizations have been performed for seeding-flow
velocity of 3.3 m/s while the velocity in the outer
channels has been fixed to 0.5 m/s. These values have
been chosen to reproduce transitional flow conditions
into the test section. The pattern on the left of Figure 2
shows instantaneous representative image of the flow
inside the test-section, taken in the mid-plane for the
reference case.
Fig.2 Image of flow inside the chamber with the
respective binary and contour images.
The image reported in the figure is only an example and
is useful to give an impression of the great variety of
structures, which can be established in 3D flows.
The visualizations have been obtained by means of a 2D
laser sheet technique for detecting the interface. The
sequence of consecutive visualizations is taken at a 1
kHz frequency.
It is here useful to underline that behind this
representation there is an important hypothesis, namely
that for low Reynolds number the flow field remains
almost two-dimensional [8] and then it can be
characterized by means of a 2D diagnostic system.
In this sense, the cross-check that will be show below is
very useful in assessing the validity of two-
dimensionality assumption.
An image processing procedure has been carried out in
order to obtain the interface contour, showed in the right
of Fig. 2, which is located where the concentration of
the tracer is discontinuous, that is where it passes from
zero to a finite value on an infinitely thin surface, and to
compute some numerical indicator of the ongoing of the
stirring process. The instantaneous interface position is
determined from the sharp gradient in the seeding
concentration.
In order to obtain an assessment of the experimental
results, a comparison with some numerical results is
here reported.
A Direct Numerical Simulation has been performed in
FLUENT 6.3 on a simple flat configuration with an
adaptive mesh. The geometry consists of a main channel
with a ratio 1:3 of height to length, in which 35 square
channels of 2 mm in width compose the inflow
boundary. In order to create a relatively unstable flow
near the exit of the channels, the seeding-flow is fed in
the central one with a velocity approximately 6 times
higher than the others (3.3 m/s). The Reynolds number
in this channel is, however, such as to ensure a laminar
initial motion (Re = 470). Starting from a fixed time,
which is conventionally assumed to be equal to the
value zero, the flow is seeded with massless particles at
the tip of the rim which separates the central duct with
the lateral ducts in correspondence of the first contact
point. The trajectory of the particles is simulated using
an Eulerian-Lagrangian approach. In practice the
trajectory calculations are performed using the local
continuous phase conditions as the particle moves
through the flow. The interpolating curve determines the
intermaterial line at different times. From this point of
view, the interface is defined as a set of particles that
have same border of the jet confinements. The
isosurfaces are instead related to the solution of the
transport equation on a fixed volume control. In this
case, a unitary mass fraction is distributed along the
points of the input section of the small central channel.
For the flow configuration abovementioned an ensemble
of patterns obtained from flow visualizations and
numerical computations are reported in Fig. 3.
4. Blue particles indicate the right interface contour and
red indicates the left one.
The upper row is relative to numerical predictions while
the lower one is relative to pattern of laser light
scattered by a sub-micron seeding. The field of view is
4 cm x 10 cm. Both numerical and experimental results
are reported in Fig. 3 for five selected times.
Fig.3 Exp/Num comparison of interfaces for a 2D
transitional flow.
It is of great interest to underline that the comparison is
quite satisfactory. Among the numerical predictions, the
agreements are not so good in the high-convolution
zones. Interfaces are quite convoluted, as it is possible
to observe in Fig. 3. They undergo a relatively intense
stretch rate. The stretch rate is sufficient for high level
of convolution. Moreover, the interface contour at the
downstream region in the numerical results is not well
identified due to the high stretch rate. In general the
agreement are quite satisfactory and they depict an
important assessment of the experimental results.
A quantitative exp/num comparison for the patterns
reported in Fig. 3 has been obtained by comparing the
mean velocity magnitude profiles conditioned on the
interface along the dimensionless axial direction (X/D)
for three selected streamwise positions (Y). They are
reported in Fig.4.
The mean velocity magnitude has been obtained by
means of ensemble average of the instantaneous
velocity fields.
The experimental results in Fig. 4 have been obtained
by means of PIV measurements.
The computed mean velocities along the interface are
also shown in Fig. 4. The agreement between
experimental and numerical results is quite good. For
each streamwise position, there are two local maximum
in the mean velocity relative to the interface position
and an increase in velocity through the interface zone
due to the local stretch.
Fig.4 Cross-Checking of Exp/Num velocity fields
conditioned on interface location.
5. Fig.5 Cross-Checking of Exp/Num strain rate
conditioned on interface location.
Another quantitative cross-check has been obtained by
comparing the ensemble average strain rate profiles
conditioned on the interface along the dimensionless
axial direction (X/D) for three selected streamwise
positions (Y). They are reported in Fig.5.
The comparison between experimental and numerical
results is quite good only for the central plot at Y=0.03
m. In this case, the results are qualitatively the same.
Moreover, for Y=0.01 and 0.05 m the numerical profiles
show a not good quantitative agreement with
experiments.
Fig.6 Comparison of Exp/Num interface density
profiles along the streamwise direction.
Finally, the interface density, previously defined in
equation 3), has been obtained from both experimental
and numerical procedures.
The development of interface density is shown in Fig. 6
for the reference case. Both experimental and numerical
profiles are plotted versus the streamwise direction Y.
It appears that the generation of surface area is
dominated by the length scale variations with the
distance, and it depends on the increase of the
turbulence intensity.
The evolution of surface is a reversible process where
fluid elements are transported across the domain,
rotated, stretched and folded. Even for very simple
velocity fields, the combined action of stretching and
folding of fluid elements generates complex patterns,
hence the name ‘chaotic advection’ or ‘stirring’ [9].
In the absence of diffusivity, the advection homogenizes
the distribution of the tracer at an exponential rate and
blurs the structures present in the initial distribution as
well as the patterns created by chaotic stirring.
These considerations partially justify the ! profiles
along Y which show the main effect of stretching and
folding, i.e. a more than linear increase of interface
density in both experimental and numerical profiles.
On the other hand, the results in Fig. 6 show quite good
agreement between experimental and numerical profiles
only in the near field region of the jet (Y < 30 mm).
In fact, in the far field region the computed interface
density values are totally not correlated with the
experimental results. As a matter of fact the not good
agreement shown in Fig. 6 depends on the inaccuracy in
both experimental and numerical procedures. These
6. considerations show the potentiality of the cross-
validation.
Discussion and Conclusions
Complex reactive flow systems need proper strategies
for their modeling. The MultiSECtioning strategy has
been proposed as a procedure to the evaluation and
verification of non-premixed combustion processes. In
the paper, the first step of this procedure, namely the
characterization of the interface kinematics, was
analyzed in detail, taking into account the most relevant
quantities that characterize the stirring process.
Experimental and numerical evaluations of interface
density were discussed in relation of an experimental
apparatus, which has been purposely designed in order
to be suitable for the experimental/numerical
comparison.
Patterns of the flow field have been experimentally
obtained for different selected times and they showed
quite good agreement with DNS computations.
Ensemble average velocity and strain rate profiles have
been cross-checked for both experimental and numerical
procedures.
The results are quite similar only for the mean velocity
profiles.
The final comment, devoted to the diagnostic aspects,
concerns the difficulty of performing Lagrangian
measurements in a wide control volume.
The experimental method for generating material
surfaces seems to be a unique choice in the case of
gaseous systems. In fact it is formed by a tracer which,
by definition, is a non-diffusing, fully-convected
material. However, the diffusion of particles dispersed
in a gaseous medium can be considered negligible with
respect to gaseous diffusion. In this case particles have
to be dragged in such a way that they are representative
of the gas displacement.
For the TiO2 particles, used for the interface
characterization, the Stokes number at the injection
point is smaller than 10-3
taking into account that the
largest particle size is 2 "m and the apparent density is
0.95 kg dm-3
. In this respect diffusion effects have to be
taken into account in some flow local conditions.
There are a number of considerations, however, that
must be taken into account in order to show the
inaccuracy of the experimental results. They include the
image processing procedures, differential diffusion
effects, and imaging resolution.
Therefore, it is expected that there can be some sub-
pixel stirring, but it is not expected to strongly bias the
results. Some numerical computation inaccuracy has
been also demonstrated in the cross-checking of the
interface density profiles. In fact, the Fig. 6 shows that
surface area in the far field region is underestimated
from the experimental measurements.
On the other hand DNS results show an overestimation
of the interface density probably due to some inaccuracy
in the lagrangian-tracking algorithm that has been used.
The analysis has allowed the identification of the merits
and the limits of the exp/num methods.
The main limits of these methods are related to
technological and numerical constraints rather than to
its principles.
Therefore, it seems difficult that these techniques can be
used directly in multidimensional flow like turbulent
ones, but it will be very useful in the characterization of
prototypical flows, which can be considered as
elementary spatial-temporal structures of more complex
flows.
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