Transcript Document

Ene-39.4053 Postgraduate Seminar on Energy Technology
Turbulence Models Validation in a
Ventilated Room by a Wall Jet
Guangyu Cao
[email protected]
02-04-2007
Laboratory of Heating, Ventilating and Air-Conditioning,
Faculty of Mechanical Engineering, Helsinki University of Technology
Content
1 Introduction
2 Description of the
experiment
3 Air jet distribution in the
space
4 Airflow modeling
4.1 Turbulence modelling
4.2 Near-wall treatment
4.3 Boundary conditions
5 Results and discussions
6 Conclusion
1 Introduction
Why?
1
2
3
Predicting indoor comfortable level
Evaluate the ventilation effectiveness
Indoor gaseous pollutants and associated air
quality control
The draught rate model
(ISO 7730:2005 standard)
DR  (34  ta,l )(va,l  0,05)
0,62
(0,37 va,l  Tu  3,14)
where DR is the draught rate,
ta,l is the local air temperature,
va is the local mean air velocity,
Tu is the local turbulence intensity
The ventilation effectiveness
CR  CS
V 
CP  CS
•
•
•
CR pollutant concentration in exhaust air;
CS pollutant concentration in supply air;
CP pollutant concentration in the inhalation zone.
2 Description of the experiment
Air jet outlet and inlet
Investigation of 4 plans
The median plan x = 1.55 m
Three vertical plans located at y = 0.60m,
y =1.10 m and at y = 1.60m
The median plan is scanned with 1892 positions of
the mobile arm; each vertical plan is scanned with
440 positions.
3 Air jet distribution in the space
Only the values superior to 0.05 m/s were retained
Figs. 4–6 present the velocity isovalue lines obtained
with the experimental set-up. The hot case is
reaching the ceiling faster than the isothermal case.
The jet in the cold case does not attach but collapse
from the ceiling.
4 Airflow modeling
What kind of problems will be confronted by CFD modelling ?
Inside heat plumes will disturb the normal air jet
performance.
Low air inlet velocity will result in incompletely
mixing of indoor air with large temperature
gradient from ceiling to floor.
The ineffective simulation of air outlet will
underestimate
the
percentages
of
the
uncomfortable people due to draught.
4.1 Turbulence modelling
(1) What kind of model can be used to
predict the turbulence of indoor air
distribution?
(2) What kind of CFD models can predict
indoor air distributions accurately?
Reynolds-averaged Navier-Stokes (RANS)
• The equations represent transport equations for the mean flow
quantities only, with all the scales of the turbulence being
modeled.
• The approach of permitting a solution for the mean flow
variables greatly reduces the computational effort. If the mean
flow is steady, the governing equations will not contain time
derivatives.
• A computational advantage is seen even in transient situations,
since the time step will be determined by the global
unsteadiness rather than by the turbulence.
The k–ε realizable model
• This model uses the transport equations of k and ε to
compute the turbulent viscosity by Shih,
• Compared with the other k–ε models, the realizable
one satisfies certain mathematical and consistent
with the physics of turbulent flows (for example the
normal Reynolds stress terms must always be
positive).
• A new model for the dissipation rate
RNG k–ε Model
• The RNG k–ε Model is derived from the
instantaneous Navier- Stokes equations, using a
mathematical technique called renormalization
group methods.
• The RNG theory provides an analytical formula
for Prt.
• It provides an analytically derived differential
formula for effective viscosity.
The standard k– ω model
• The two equation k– ω models are based on model
transport equations for the turbulent kinetic energy
and the specific dissipation rate which can also be
thought of as the ratio of ω to k.
The Shear-stress transport (SST) k–ω model
• The standard k- ω model and the transformed k- ω
model are both multiplied by a blending function and
both models are added together. The blending
function is designed to be one in the near-wall region,
which activates the standard k- ω model, and zero
away from the surface, which activates the
transformed k- ε model.
4.2 Near-wall treatment
Correct calculation of a wall-bounded
flow and its associated transport
phenomena is not possible without the
adequate description of the flow in the
near wall region.
Near wall treatment for the k– ε models
In FLUENT, the near-wall treatment combines a two
layer model with enhanced wall functions. In other
words, the first cell values of temperature and
velocity are given by enhanced wall functions
applicable in the entire near-wall region, and the
viscosity affected region is resolved by the two-layer
model.
Near-wall treatment for the k– ω models
The near-wall treatment for the k– ω and k– ω SST
models is computed following the same logic as for
the k– ε realizable model. However, there is no need
for a special treatment for the viscosity affected
region because of the low-Reynolds correction in the
k– ω and k– ω SST models.
4.3 Boundary conditions
In our case, there are three kinds of boundary
conditions: air inlet conditions, air outlet conditions
and wall boundary conditions.
5 Results and discussions
The axisymmetric wall jet
Fig. 10 presents the
maximum velocity decay
for the experimental data
and the numerical models
for the isothermal case.
Fig. 11 presents the
maximum velocity
decay for the
experimental data and
the numerical models
for the hot case.
• Concerning the
maximum
temperature
presented Fig. 12, the
k– ω model is in good
agreement with the
experiment.
Fig. 13 is the
maximum
velocity curve for
the cold case.
Fig. 14 shows that
none of the models
can give the good
maximum position
value.
Fig. 14. Velocity profile—hot case—median plan y= 1.60 m.
The velocity profile of
Fig. 15 illustrate the
incapacity of the
numerical models to
predict the jet behavior.
Fig. 15. Velocity profile—cold case—median plan y= 1.60 m.
Jet
expansion
rates
The experimental data show that the
axisymmetric wall jet is highly anisotropic.
6. Conclusion
1
2
3
4
None of the four numerical models can predict correctly the
expansion rates for the cold case.
None of the turbulence models is reliable for predicting either
the global values for temperature and velocity or the maximum
velocity decay.
The k–ω model seems to give better results for the expansion
rates. The three other models give expansion rates lower than
the experimental results.
For the hot case, the k–ω and k– ε realizable models are closer
to the experiment.
Thank you!