Flow visualization and PIV measurements of flow around a sport utility vehicle model
Flow visualization and PIV measurements of flow around a sport utility vehicle model
The instantaneous flow structure around a 1:18 scaled model of a square-back sport utility vehicle (Hummer H2) was documented in a low-speed water tunnel. The study comprises both flows with the model fixed on a flat plate and flows with the model's wheels rolling on an endless belt that moved with the speed of the free stream, thus simulating ground effects. The flow structure was investigated using flow visualization by dye injection as well as particle image velocimetry (PIV) for several Reynolds numbers in the range of 7000 to 27700. The flow along the roof, the sidewalls, and the underbody was observed to separate at the rear edges of the body, creating a recirculation zone at the rear of the vehicle, which is associated with pressure loss and a major contribution to aerodynamic drag. In the vertical plane of symmetry, this recirculation zone appears as two counter-rotating vortices. With a fixed ground, the lower vortex was less energetic than the upper vortex because the boundary layer that developed along the ground upstream of the model reduced the momentum of the flow below the vehicle. This boundary layer was also observed to separate from the ground behind the vehicle, creating a third vortex located further downstream along the ground. This boundary layer separation forced the bottom vortex to remain attached to the base of the vehicle, whereas the upper vortex was advected in the wake. The dimensionless frequency (Strouhal number) of the vortex shedding process from the roof was found to be in the range of 0.1 to 0.9. With a moving ground, the upper vortex behaved similarly to that in the fixed ground configuration; however, in the absence of the boundary layer along the ground, the lower vortex was typically stronger and its location showed some variability. In both configurations, the Reynolds number had little influence on the wake topology, mostly increasing the turbulence intensity without modifying the main flow pattern.
2587-2593
The American Society of Mechanical Engineers
Lamy, Alban
d27b2507-7ab4-4c52-9a7f-59af6b118ed1
Hamel, Amandine
74873036-34dc-445b-8117-08dd46b9610d
Vanderwel, Christina
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Tavoularis, Stavros
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Kourta, Azeddine
e3da4513-8b58-4ba1-a524-1a558855e385
Lamy, Alban
d27b2507-7ab4-4c52-9a7f-59af6b118ed1
Hamel, Amandine
74873036-34dc-445b-8117-08dd46b9610d
Vanderwel, Christina
fbc030f0-1822-4c3f-8e90-87f3cd8372bb
Tavoularis, Stavros
9800ff44-e983-4293-a2b1-f29eec90d359
Kourta, Azeddine
e3da4513-8b58-4ba1-a524-1a558855e385
Lamy, Alban, Hamel, Amandine, Vanderwel, Christina, Tavoularis, Stavros and Kourta, Azeddine
(2011)
Flow visualization and PIV measurements of flow around a sport utility vehicle model.
In Proceedings of the ASME 2010 3rd Joint US-European Fluids Engineering Summer Meeting collocated with 8th International Conference on Nanochannels, Microchannels, and Minichannels. ASME 2010 3rd Joint US-European Fluids Engineering Summer Meeting.
vol. 1,
The American Society of Mechanical Engineers.
.
(doi:10.1115/FEDSM-ICNMM2010-30193).
Record type:
Conference or Workshop Item
(Paper)
Abstract
The instantaneous flow structure around a 1:18 scaled model of a square-back sport utility vehicle (Hummer H2) was documented in a low-speed water tunnel. The study comprises both flows with the model fixed on a flat plate and flows with the model's wheels rolling on an endless belt that moved with the speed of the free stream, thus simulating ground effects. The flow structure was investigated using flow visualization by dye injection as well as particle image velocimetry (PIV) for several Reynolds numbers in the range of 7000 to 27700. The flow along the roof, the sidewalls, and the underbody was observed to separate at the rear edges of the body, creating a recirculation zone at the rear of the vehicle, which is associated with pressure loss and a major contribution to aerodynamic drag. In the vertical plane of symmetry, this recirculation zone appears as two counter-rotating vortices. With a fixed ground, the lower vortex was less energetic than the upper vortex because the boundary layer that developed along the ground upstream of the model reduced the momentum of the flow below the vehicle. This boundary layer was also observed to separate from the ground behind the vehicle, creating a third vortex located further downstream along the ground. This boundary layer separation forced the bottom vortex to remain attached to the base of the vehicle, whereas the upper vortex was advected in the wake. The dimensionless frequency (Strouhal number) of the vortex shedding process from the roof was found to be in the range of 0.1 to 0.9. With a moving ground, the upper vortex behaved similarly to that in the fixed ground configuration; however, in the absence of the boundary layer along the ground, the lower vortex was typically stronger and its location showed some variability. In both configurations, the Reynolds number had little influence on the wake topology, mostly increasing the turbulence intensity without modifying the main flow pattern.
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e-pub ahead of print date: 1 March 2011
Venue - Dates:
ASME 2010 3rd Joint US-European Fluids Engineering Summer Meeting, FEDSM 2010 Collocated with 8th International Conference on Nanochannels, Microchannels, and Minichannels, , Montreal, QC, Canada, 2010-08-01 - 2010-08-05
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Local EPrints ID: 491937
URI: http://eprints.soton.ac.uk/id/eprint/491937
PURE UUID: 03399c1a-e97b-4560-9d3d-78a501a128ab
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Date deposited: 08 Jul 2024 17:50
Last modified: 11 Jul 2024 01:53
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Author:
Alban Lamy
Author:
Amandine Hamel
Author:
Stavros Tavoularis
Author:
Azeddine Kourta
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