Developing a Computational Fluid Dynamics Model for Characterizing
the Heat Transfer for a Cross-Flow Plate Heat Exchanger in a Boosted Diesel
Engine 2023-01-5020
In addition to the low cost and weight, the advantage of aluminum alloy heat
exchangers over their counterparts is thanks to their anticorrosion,
nonmagnetic, non-sparking, resilience, ductility at low temperature, high
strength-to-weight ratio, high heat transfer coefficient, and easy fabrication.
The advantages explain the currently popular utilization of aluminum alloy
intercoolers in turbocharged engines. This study develops a finite volume
simulation model using the computational fluid dynamics (CFD) available in the
Fluent package to investigate the cooling efficiency for a cross-flow plate-fin
intercooler system fabricated in this research. This is a cost-effective
air-water heat exchanger made of thin aluminum alloy plates. The cross-flow
plate-fin intercooler system was set up in this study using a perpendicular
air-water configuration to cool down the hot air outlet from a turbocharger
compressor equipped in a diesel engine. The engine with an intercooled
turbocharger was tested in an AVL dynamometer testbed. The experiment results
were used to validate the CFD model. An analysis was done for the heat transfer
characteristic length, and 270 × 270 × 10 mm plates were selected to fit with
the engine construction. The experiment was carried out for an eight-channel
intercooler (four pairs of air and water channels) while the simulation model
was developed only for two channels to reduce the computational cost. Numerical
conversions were conducted to establish a model equivalent to the experimental
one. The distributions of the inlet and outlet temperature, pressure, and
velocity of intake air and coolant under various inlet water velocities and
engine operating conditions were examined. This aims to optimize the heat
transfer rate from water to air under engine-relevant operating conditions. The
results show that the optimal cooling water velocity is 1.0 m/s corresponding
with a flow rate of 1780 liter/hr. This approach could be useful to develop
and/or optimize multichannel cross-flow plate heat exchangers for different
applications including heat engines.
Citation: Duong, C., Luong, T., Nguyen, Q., Phung, D. et al., "Developing a Computational Fluid Dynamics Model for Characterizing the Heat Transfer for a Cross-Flow Plate Heat Exchanger in a Boosted Diesel Engine," SAE Technical Paper 2023-01-5020, 2023, https://doi.org/10.4271/2023-01-5020. Download Citation
Author(s):
C. Q. Duong, T. D. Luong, Quan Q. Nguyen, D. V. Phung, P. X. Pham
Affiliated:
Le Quy Don Technical University, Dong Nai Technology
Pages: 10
Event:
Automotive Technical Papers
ISSN:
0148-7191
e-ISSN:
2688-3627
Related Topics:
Computational fluid dynamics
Diesel / compression ignition engines
Heat transfer
Aluminum alloys
Heat exchangers
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