Authors :
Neev Menon
Volume/Issue :
Volume 10 - 2025, Issue 7 - July
Google Scholar :
https://tinyurl.com/mvpk98w6
Scribd :
https://tinyurl.com/yfe58v9r
DOI :
https://doi.org/10.38124/ijisrt/25jul932
Note : A published paper may take 4-5 working days from the publication date to appear in PlumX Metrics, Semantic Scholar, and ResearchGate.
Note : Google Scholar may take 30 to 40 days to display the article.
Abstract :
The aerodynamic wake effect in Formula 1 continues to be a critical barrier to close racing and overtaking,
particularly through corners. Despite years of regulatory developments, the aerodynamic turbulence generated by a leading
car still severely compromises the downforce and performance of a following car. While this phenomenon is widely
acknowledged in the motorsport community, experimental data that quantifies the loss of aerodynamic performance under
wake conditions remains limited, especially at small scale. This study aims to analyze and quantify the downforce loss
experienced by a Formula 1 car due to wake turbulence using a cost-efficient, scaled wind tunnel setup. An official 1:18 scale
diecast model of a 2021 F1 car was mounted on a load cell within a custom-built wind tunnel, and raw downforce values
were measured under clean air conditions and various wake conditions simulated using upstream obstructions. The
experimental setup focused on within-subject comparisons, varying the distance and lateral offset between the test model
and the simulated wake source. Findings revealed a maximum downforce loss of approximately 53% at 5 cm behind the
obstruction with no lateral offset, with recovery observed at increased distances and small offsets. These results affirm the
hypothesis that wake turbulence significantly affects aerodynamic performance and provide a tangible demonstration of
how proximity and alignment influence downforce retention. By offering a simplified, replicable approach to studying wake
effects, this research contributes valuable experimental insight into a widely discussed yet under-tested aerodynamic
challenge in Formula 1 racing.
Keywords :
Wake Turbulence, Formula 1 Aerodynamics, Downforce Loss.
References :
- Guerrero, Alex, and Robert Castilla. 2020. "Aerodynamic Study of the Wake Effects on a Formula 1 Car" Energies 13, no. 19: 5183. https://doi.org/10.3390/en13195183
- Newbon, J., Sims-Williams, D., and Dominy, R., "Aerodynamic Analysis of Grand Prix Cars Operating in Wake Flows," SAE Int. J. Passeng. Cars - Mech. Syst. 10(1):318-329, 2017, https://doi.org/10.4271/2017-01-1546.
- Mcauliffe, Brian & Sowmianarayanan, Bhargav & Barber, Hali. (2021). Near-to-Far Wake Characteristics of Road Vehicles Part 1: Influence of Ground Motion and Vehicle Shape. SAE International Journal of Advances and Current Practices in Mobility. 3. 10.4271/2021-01-0957.
- Senft V, Gillan M. Recent advances and test processes in automotive and motorsports aerodynamic development. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science. 2019;233(23-24):7573-7589. doi:10.1177/0954406219875770
- Katz, Joseph. (2006). Aerodynamics of race cars. Annu. Rev. Fluid Mech. 38. 27-63. 10.1146/annurev.fluid.38.050304.092016.
- Martins, Daniel & Correia, João & Silva, André. (2021). The Influence of Front Wing Pressure Distribution on Wheel Wake Aerodynamics of a F1 Car. Energies. 14. 4421. 10.3390/en14154421.
- Lienhart, Hermann & Stoots, C & Becker, S.. (2002). Flow and Turbulence Structures in the Wake of a Simplified Car Model (Ahmed Model). Notes on Numerical Fluid Mechanics. 77. 10.1007/978-3-540-45466-3_39.
The aerodynamic wake effect in Formula 1 continues to be a critical barrier to close racing and overtaking,
particularly through corners. Despite years of regulatory developments, the aerodynamic turbulence generated by a leading
car still severely compromises the downforce and performance of a following car. While this phenomenon is widely
acknowledged in the motorsport community, experimental data that quantifies the loss of aerodynamic performance under
wake conditions remains limited, especially at small scale. This study aims to analyze and quantify the downforce loss
experienced by a Formula 1 car due to wake turbulence using a cost-efficient, scaled wind tunnel setup. An official 1:18 scale
diecast model of a 2021 F1 car was mounted on a load cell within a custom-built wind tunnel, and raw downforce values
were measured under clean air conditions and various wake conditions simulated using upstream obstructions. The
experimental setup focused on within-subject comparisons, varying the distance and lateral offset between the test model
and the simulated wake source. Findings revealed a maximum downforce loss of approximately 53% at 5 cm behind the
obstruction with no lateral offset, with recovery observed at increased distances and small offsets. These results affirm the
hypothesis that wake turbulence significantly affects aerodynamic performance and provide a tangible demonstration of
how proximity and alignment influence downforce retention. By offering a simplified, replicable approach to studying wake
effects, this research contributes valuable experimental insight into a widely discussed yet under-tested aerodynamic
challenge in Formula 1 racing.
Keywords :
Wake Turbulence, Formula 1 Aerodynamics, Downforce Loss.
