Aerodynamic Analysis and Cab Geometry Optimization of an Electric Heavy-Duty Truck
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Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Modellbyggare
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This thesis investigates the influence of cab geometry and aerodynamic add-ons on
the aerodynamic performance of a heavy-duty electric truck using computational
fluid dynamics. A parameterized 3D-CAD tractor-trailer model was developed in
STAR-CCM+ and evaluated using steady Reynolds-Averaged Navier–Stokes sim
ulations with the SST k-ω turbulence model. Two cab geometries were studied:
a baseline flat-front cab and a more streamlined electric-truck cab. For each cab
geometry, configurations with a large side skirt and a side extender were simulated
to assess the effect of add-ons on the tractor-trailer gap and underbody flow. A
two-stage cab optimization was then performed using the SHERPA algorithm, first
on a simplified model and then on the complete Model 1 configuration.
The results show that cab geometry has a strong influence on both the front pres
sure distribution and the effectiveness of the add-ons. For Model 1, the combined
large side skirt and side extender reduced the drag coefficient from 0.407 to 0.391,
corresponding to a reduction of approximately 3.9%. For the more streamlined
Model 2, the same add-on configuration reduced the drag coefficient from 0.411 to
0.364, corresponding to a reduction of approximately 11.4%. The complete Model 1
optimization reduced the drag coefficient from 0.391 to 0.373, giving an additional
reduction of approximately 4.6% relative to Model 1 configuration 3. The accumu
lated drag and pressure-coefficient results indicate that this improvement mainly
originates from the optimized cab-front shape, while the downstream flow remains
strongly affected by the side skirt, side extender, and trailer arrangement.
The work provides a foundation for continued research on aerodynamic analysis
and optimization of zero-emission heavy-duty vehicles. The parameterized model
and CFD workflow can be further refined to include additional design concepts,
experimental validation, and more realistic operating conditions such as crosswind.
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Ämne/nyckelord
electric heavy-duty truck, truck aerodynamics, CFD, aerodynamic add-ons, cab geometry optimization
