Post on 13-Feb-2018
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7/23/2019 Pope Pecs 85
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The princrpal influence of inhom ogeneity is to cau se
convective transport in physical space. This effect
appears in closed form in the joint pdf equation
through the term Vjaf/axj. In contrast, in second-
order closures, this term gives rise to the correlations
( u , u , u ~ ) . ( u , u , ~ ~ )nd (u,4:4;) which are generally
modelled by gradient diffusion. It is emphasized tha t,
in the joint pdf equa tion, the conv ective term is in
closed form and therefore no gradient diffusion
models are needed.
The first term on the right-h and side ofEq (5.196)
represents translport in physical space due to
molecular diffusion, and (at high Reynolds nu mb er) is
usually negligible. Nevertheless, the term appears in
closed form and can be retained without additional
modelling being required.
The next three terms represent the effects of
dissipation and pressure fluctuations that have been
modelled in Sections 5.3-6. Since dissipation and (to a
lesser exten t) the slow pressure a re associated with th e
smaller turbulent scales, it is reasonable to assume
that these processes are unaffected by inhomo-
geneities.
Fo r flows remote from walls, it is assumed that the
rapid-pressure models still apply. An analysis of the
rapid pressure ra te of s traing 9 shows tha t, to first
order, departures from homogeneity have no effect.
Near walls, however, the velocity gradients and
Reynolds stresses vary rapidly. Fur the r, the analysis of
Section 5.4.1. has to be modified to include surface
rnteprals at the wall. Consequently, the models (Eqs
5.1 19 an d 5.148) (or a t least the tenso rs C and G ave
to be mod ified: this is a su bject for future work.
The final term in Eq. (5.196) represents tra nsp ort
due to the fluctuating pressure. Pope7' suggested the
model
which is consistent with Lumley's mode l for (pluj).
But this mode l has not been tested.
5.7.2. Intermittency
Nea r to the edge of bou nda ry layers and free shear
layers the flow is intermittent-sometimes turbu lent,
Fig 5 8 Pdf of indicator
4
showing a delta function of
magnitude 1 - y at
, =
0
sometimes non-turbulent.loO Consider a high
Reynolds number jet which transports a conserved
passive scalar (b,(%t), where
y
=
a
1. At th e jet exit
4,
is positive, while in the non-turbulent, irrotational
fluid remote from the jet
4,
is zero. As the Reynolds
number tends to infinity, the condition ,&, t) >
0
can be used a s an indicato r of turbu lent fluid. Th at is,
if &&t)
> 0,
the fluid is in turbulent motion, if
,& t)
=
0, the fluid is in irrotational, non-turbulent
motion. The intermittency factor y
t
is defined as
the prob ability of the fluid at ) being turbule nt. In
terms of the indicato r ,, th e intermittency facto r is
Th e pdf of 4,,
f4? ( ,
;&
t),
is zero for
II
0, see Fig. 5 8
Integration over th e delta function an d over the con-
tinuous distribution yields
I $, w ; & t) dl17 = 1 -?(is t). (5.199)
and
The joint pdf
y,
k;z t) can be decomposed into
two parts: the first f T ( K & ; g ) is the joint pdf of jJ
and conditional upo n the fluid being turbulent, the
second fN(V-&; 5 t s conditional o n th e fluid being
non-turbulent :
In terms of fw,(V,&,$,; 5 [)-the joint pdf of U
and 4,-these two conditional pdf's are
and
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