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Why Motorcycle Aerodynamics Is So Hard
Motorcycle aerodynamics looks simple — until you actually try to model it.
At racing speeds, the airflow around a motorcycle is highly unsteady, asymmetric, and dominated by the rider, not the bike. Small changes in posture can completely restructure the wake, creating a problem that is closer to controlled chaos than clean textbook aerodynamics.
In this episode, we break down why motorcycle aerodynamics is so hard, using insights from CFD, turbulence modeling, and published research. We’ll look at:
Why the rider creates so much of the drag
How flow separates around the helmet and shoulders
What the wake actually looks like at high speed
How models like DES, SAS, and k-ω SST are used to capture unsteady flow
Whether you’re an engineer, racer, or just curious about why motorcycles behave the way they do at speed, this episode will give you a deeper intuition for the problem.
Motorcycle vs rider drag contribution
Flow separation and wake structure
Turbulence, vortices, and unsteady aerodynamics
Scale-Adaptive Simulation (SAS) vs Detached Eddy Simulation (DES)
Why motorcycles don’t behave like cars in the wind tunnel
COURSES:
Automotive Aerodynamics Course: https://premieraerodynamics.com/Automotive-Aerodynamics/
UAV Design And Build Course: https://premieraerodynamics.com/RC-Airplane-Course/Want to simulate your VERY OWN car? Check out our service here: https://premieraerodynamics.com/simulate-your-own-carLearn OpenFOAM here: https://premieraerodynamics.com/Courses/Want an easy way to make your experiments 2-4% more accurate? Check out The Atmosphere Hawk to make your aerodynamic experiments better: https://premieraerodynamics.com/Atmosphere-hawkPaper: https://www.mdpi.com/1996-1073/15/16/5920, licensed under: http://creativecommons.org/licenses/by/4.0/, Comprehensive CFD Aerodynamic Simulation of a Sport Motorcycle
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By Premier AerodynamicsMotorcycle aerodynamics looks simple — until you actually try to model it.
At racing speeds, the airflow around a motorcycle is highly unsteady, asymmetric, and dominated by the rider, not the bike. Small changes in posture can completely restructure the wake, creating a problem that is closer to controlled chaos than clean textbook aerodynamics.
In this episode, we break down why motorcycle aerodynamics is so hard, using insights from CFD, turbulence modeling, and published research. We’ll look at:
Why the rider creates so much of the drag
How flow separates around the helmet and shoulders
What the wake actually looks like at high speed
How models like DES, SAS, and k-ω SST are used to capture unsteady flow
Whether you’re an engineer, racer, or just curious about why motorcycles behave the way they do at speed, this episode will give you a deeper intuition for the problem.
Motorcycle vs rider drag contribution
Flow separation and wake structure
Turbulence, vortices, and unsteady aerodynamics
Scale-Adaptive Simulation (SAS) vs Detached Eddy Simulation (DES)
Why motorcycles don’t behave like cars in the wind tunnel
COURSES:
Automotive Aerodynamics Course: https://premieraerodynamics.com/Automotive-Aerodynamics/
UAV Design And Build Course: https://premieraerodynamics.com/RC-Airplane-Course/Want to simulate your VERY OWN car? Check out our service here: https://premieraerodynamics.com/simulate-your-own-carLearn OpenFOAM here: https://premieraerodynamics.com/Courses/Want an easy way to make your experiments 2-4% more accurate? Check out The Atmosphere Hawk to make your aerodynamic experiments better: https://premieraerodynamics.com/Atmosphere-hawkPaper: https://www.mdpi.com/1996-1073/15/16/5920, licensed under: http://creativecommons.org/licenses/by/4.0/, Comprehensive CFD Aerodynamic Simulation of a Sport Motorcycle