Large-Scale Vehicle-Wake Characterization Using a Novel, Single-Camera Particle Tracking Technique
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- Format
- Price
- Non-members (tax incl.):¥6,600 Members (tax incl.):¥5,280
- Paper/Info type
- SAE Paper
No.2021-01-0940
- Pages
- 1-10(Total 10 p)
- Date of publication
- Apr 2021
- Publisher
- SAE International
- Language
- English
- Event
- SAE WCX Digital Summit 2021
Detailed Information
Author(E) | 1) Jianfeng Hou, 2) Frieder Kaiser, 3) Brian McAuliffe, 4) David Rival |
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Affiliation(E) | 1) Queen's University Kingston, 2) Queen's University Kingston, 3) National Research Council Canada, 4) Queen's University Kingston |
Abstract(E) | The aerodynamic forces experienced by vehicles depend on a variety of factors including wind direction, traffic, and roadside vegetation. Such complex boundary conditions often result in unsteady flow separation and the formation of large-scale coherent structures, which, in turn, significantly influence the aerodynamics of following vehicles. To gain a deeper understanding of the unsteady behaviour of such vehicle wakes under large-scale conditions, a time-resolved field measurement technique is required. Existing methods, such as tomographic particle image velocimetry and three-dimensional particle tracking velocimetry are unfortunately quite limited at these scales. Furthermore, such techniques require complex multi-camera calibrations, hazardous lasers, and optical access from many vantage points. To date, the high costs, long set-up times, and prohibitive safety measures for lasers limit the application of classical field-measurement techniques in industrial automotive wind tunnels. To overcome the aforementioned issues, a simple and efficient single-camera approach to perform large-scale time-resolved three-dimensional flow-field measurements is proposed. The flow is seeded with centimeter-sized soap bubbles, which are illuminated via pulsed LED arrays. The feasibility of the novel measurement approach was tested in an industrial wind tunnel (cross-section 9.1 m × 9.1 m) at the National Research Council Canada. The test successfully captured the vortical structure in the wake of a 30%-scale tractor-trailer model at a 9° yaw angle with a measurement volume of approximately 4.0 m × 1.5 m × 1.5 m. Long tracks of up to 90 time steps were captured, along which the twisting motions help identify the vortex wake near the trailer. These sparse tracks not only allow for time-resolved analysis of the wake but also provide insights into Lagrangian transport. Time-averaged results are derived from the Lagrangian data and showed good agreement with a comparative experiment measuring the wake flow behind a 9° yawed 1/15-scale tractor-trailer model using pressure probes. |