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27
Water
jacket optimization using CFD & FEM
Authors:
Stefano Fontanesi, Vincenzo Gagliardi, Matteo Giacopini, Simone
Malaguti and Reggio Emilia – University of Modena, Italy
A
detailed understanding of the flow and thermal behavior in the water
jacket of a turbocharged diesel engine can result in significant
design improvements. If the velocities of the coolant flow drop
too low then heat is not convected away from the metal engine block.
Over time, the resulting high temperatures produce cracks in the
structure, ultimately causing its catastrophic failure. The analysis
reported here enabled the coolant flow path to be optimized, reducing
the peak temperatures in key locations and resulting in a 20 % reduction
in the peak thermal stresses.
An optimization study involving both fluid-dynamic
and
thermo-structural aspects was carried out.
Using a crossdisciplinary approach,
the structural
and thermodynamic problems were decoupled
using an ad hoc
methodology to trade-off
computational effort with accuracy. This procedure
allows a sensitivity study to be carried out, varying
geometric parameters of
the engine to obtain an
optimized component.
Methodology
The adopted
methodology (shown in Figure 1) decoupled the structural and thermodynamic
simulations. In order to evaluate the temperature distribution of the metal
cast, a CFD analysis of both the water circuit and the surrounding metal was
performed. Boundary conditions from a 1-D simulation of the whole engine were
imposed, while coolant/metal heat transfer was calculated using STAR-CD.
The temperature field was then passed to the FEM code, and
structural analyses were carried out in order to assess the fatigue strength of
the component. Finally, this methodology was applied to a comparison of the
current circuit configuration and an improved design (where the water jacket
flow has been optimized) in order to estimate the effectiveness of the design
optimization on the fatigue strength of the component.
Fluid-dynamic
preliminary analysis
CFD analyses
were carried out to focus the flow distribution in the critical
regions, i.e. the valve bridges and the pre-chamber areas. Initially
an isothermal analysis was performed on the whole engine water jacket.
In order to evaluate the effect of simple geometric modifications
to the circuit layout on the cooling effectiveness, the original
configuration (BASE) was compared to a modified one (EVO). The flow
in the EVO configuration is forced to cross the whole engine block
before entering the head jacket and only reaches the jacket exit
after crossing the whole engine head (cross-flow).
A critical velocity Vcrit was defined, below which the local heat transfer is considered to be ineffective. The percentage of the coolant volume in which the velocity fell below Vcrit was compared for the two solutions.
Thermo-mechanical
analyses
On completion of the
CFD analysis of the water circuit and the surrounding metal cast,
the temperature distribution in the iron cast was evaluated. Since
the choice of boundary condition is responsible for the accuracy
of the metal cast temperature calculation, the heat flux distribution
was derived both from experimental measurements and numerical predictions.
Experimental measurements were used to set the coolant temperature
at both the gasket and the circuit outlet. For the heat flux, data
from a 1-D GT-Power simulation of the whole engine at a given operating
condition was imposed, while the coolant/metal heat transfer was
directly calculated in STAR-CD. Although the 1D model is unable
to accurately account for three-dimensional effects and non-uniform
cylinder-to-cylinder distributions, the decision to derive the boundary
data from the 1D model was considered to be a good trade-off between
accuracy and computational effort.
Please select a thumbnail to view the images on the left.
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Results |
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Conclusion
An
optimization study involving both fluid-dynamic and thermostructural
aspects of a turbocharged diesel engine head was carried out. A
cost-effective methodology was evaluated to correctly represent
the fatigue-failure critical regions without excessive computational
costs. Since the aim of the work was to trade-off solution accuracy
and computational, the following conclusions were drawn:
*
a proper choice of both fluid-dynamic and mechanical boundary conditions
is required in order to deliver the required accuracy;
* comparisons
with experimental data confirmed that the methodology adopted was
able to accurately predict locations prone
to
cracking;
* the modeling procedure allowed a sensitivity study
to be carried out of the engine head to variations of the gasket
plate
design;
* the modifications of the
gasket passages, although very simple, allowed the cooling performance
of the circuit to dramatically
improve (Figure
6), almost liminating critical stress concentrations at the cylinder
3 pre-chamber, which was experimentally detected
to crack when operating a full engine load.
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