Comparison of Time-Resolved Experimental and Numerical Data in the Wake of a Full-Scale Passenger Car

Jonas Sebald; Jan Reiß; Marco Kiewat; Thomas Indinger

doi:10.20485/JSAEIJAE.11.4_185

Comparison of Time-Resolved Experimental and Numerical Data in the Wake of a Full-Scale Passenger Car

Jonas Sebald, Jan Reiß, Marco Kiewat, Thomas Indinger

Chair of Aerodynamics and Fluid mechanics

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

To further reduce the aerodynamic drag of passenger vehicles, a deeper understanding of the flow field is required. Analysis methods like the dynamic mode decomposition (DMD) are useful to investigate unsteady flow phenomena around the vehicle. DMD results are only relevant for the aerodynamic development, if the used numerical data is able to predict the unsteady physical flow field. Therefore, in this study unsteady hot-wire data in the wake of a passenger vehicle is compared to a numerical dataset of an unsteady Spalart-Allmaras Delayed Detached Eddy simulation. Differences and wind tunnel effects are found and explained.

Original language	English
Pages (from-to)	185-192
Number of pages	8
Journal	International Journal of Automotive Engineering
Volume	11
Issue number	4
DOIs	https://doi.org/10.20485/JSAEIJAE.11.4_185
State	Published - 2020

Keywords

Unsteady Aerodynamics [D1]
aerodynamic performance
computational fluid dynamics
heat · fluid

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10.20485/JSAEIJAE.11.4_185

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abstract = "To further reduce the aerodynamic drag of passenger vehicles, a deeper understanding of the flow field is required. Analysis methods like the dynamic mode decomposition (DMD) are useful to investigate unsteady flow phenomena around the vehicle. DMD results are only relevant for the aerodynamic development, if the used numerical data is able to predict the unsteady physical flow field. Therefore, in this study unsteady hot-wire data in the wake of a passenger vehicle is compared to a numerical dataset of an unsteady Spalart-Allmaras Delayed Detached Eddy simulation. Differences and wind tunnel effects are found and explained.",

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AU - Kiewat, Marco

AU - Indinger, Thomas

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AB - To further reduce the aerodynamic drag of passenger vehicles, a deeper understanding of the flow field is required. Analysis methods like the dynamic mode decomposition (DMD) are useful to investigate unsteady flow phenomena around the vehicle. DMD results are only relevant for the aerodynamic development, if the used numerical data is able to predict the unsteady physical flow field. Therefore, in this study unsteady hot-wire data in the wake of a passenger vehicle is compared to a numerical dataset of an unsteady Spalart-Allmaras Delayed Detached Eddy simulation. Differences and wind tunnel effects are found and explained.

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Comparison of Time-Resolved Experimental and Numerical Data in the Wake of a Full-Scale Passenger Car

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