Vehicle platooning of DrivAer model at different flow regimes: Effect on aerodynamic forces

Moath N. Zaareer; Abdel Hamid I. Mourad

doi:10.1016/j.ijft.2025.101181

Vehicle platooning of DrivAer model at different flow regimes: Effect on aerodynamic forces

Moath N. Zaareer, Abdel Hamid I. Mourad

Department of Mechanical and Aerospace Engineering

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

Abstract

Vehicle platooning, where vehicles travel in close proximity to reduce aerodynamic drag and improve efficiency, is increasingly feasible with advances in autonomous driving technologies. This study examines the aerodynamic forces acting on two and three vehicles in series at different spacings, corresponding to the extended-body, reattachment, and co-shedding regimes. Results reveal a 50.6 % reduction in drag coefficient for the front vehicle and a 65 % increase in downforce for the rear vehicle in the extended-body regime. These findings highlight significant potential for decreasing drag effect and stability in platooning scenarios. A similar trend is observed for three vehicles, with the first and second vehicles having the lowest drag coefficients and the third vehicle experiencing the highest downforce.

Original language	English
Article number	101181
Journal	International Journal of Thermofluids
Volume	27
DOIs	https://doi.org/10.1016/j.ijft.2025.101181
Publication status	Published - May 2025

Keywords

Aerodynamics
Autonomous vehicles
Drag reduction
Flow regimes
Lift coefficient
Turbulence
Vehicle platooning

ASJC Scopus subject areas

Condensed Matter Physics
Mechanical Engineering
Fluid Flow and Transfer Processes

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10.1016/j.ijft.2025.101181

Cite this

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title = "Vehicle platooning of DrivAer model at different flow regimes: Effect on aerodynamic forces",

abstract = "Vehicle platooning, where vehicles travel in close proximity to reduce aerodynamic drag and improve efficiency, is increasingly feasible with advances in autonomous driving technologies. This study examines the aerodynamic forces acting on two and three vehicles in series at different spacings, corresponding to the extended-body, reattachment, and co-shedding regimes. Results reveal a 50.6 % reduction in drag coefficient for the front vehicle and a 65 % increase in downforce for the rear vehicle in the extended-body regime. These findings highlight significant potential for decreasing drag effect and stability in platooning scenarios. A similar trend is observed for three vehicles, with the first and second vehicles having the lowest drag coefficients and the third vehicle experiencing the highest downforce.",

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AB - Vehicle platooning, where vehicles travel in close proximity to reduce aerodynamic drag and improve efficiency, is increasingly feasible with advances in autonomous driving technologies. This study examines the aerodynamic forces acting on two and three vehicles in series at different spacings, corresponding to the extended-body, reattachment, and co-shedding regimes. Results reveal a 50.6 % reduction in drag coefficient for the front vehicle and a 65 % increase in downforce for the rear vehicle in the extended-body regime. These findings highlight significant potential for decreasing drag effect and stability in platooning scenarios. A similar trend is observed for three vehicles, with the first and second vehicles having the lowest drag coefficients and the third vehicle experiencing the highest downforce.

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KW - Lift coefficient

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Vehicle platooning of DrivAer model at different flow regimes: Effect on aerodynamic forces

Abstract

Keywords

ASJC Scopus subject areas

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