Aero is not my field of engineering but… the car is moving so the fact that air would decelerate for Bernoulli doesn’t mean much at the speed the car is going, what matters is that it creates an area of extreme low pressure.hsg wrote:1. How such a small intake can feed all floor with air?
2. Air move from small volume(intake) to huge floor volume, so air must decelerate by Bernulli, so how this works, how this accelerate flow if we increase volume?
3. Are these fences here because of rules or because they are optimal solution for this floor, why F1 flat floor didnt use this outwash fences?
Can someone explain this?
Does race cars with flat floor use outwash fences?
I could dig through examples and spend time explaining, but based on how you’ve handled previous replies, it would be a complete waste of effort...
If you put a canard guiding the air towards the outside the floor would not be flat anymore and would be illegal.
Density is changing. The air is compressible and expandable. Bernoulli in simple terms assumes no density changes for basic fluid flow, and no changes in internal energy. So simple Bernoulli cannot apply to the analysis.hsg wrote: ↑27 Apr 2025, 15:091. How such a small intake can feed all floor with air?
2. Air move from small volume(intake) to huge floor volume, so air must decelerate by Bernulli, so how this works, how this accelerate flow if we increase volume?
3. Are these fences here because of rules or because they are optimal solution for this floor, why F1 flat floor didnt use this outwash fences?
Can someone explain this?
https://i.ibb.co/Xxd6S1Pm/FQ9-9-Rl-WUAYLMNA.jpg
You want to say if they are allowed to use outwash fences on flat floor, they will use it?Sevach wrote: ↑27 Apr 2025, 18:56If you put a canard guiding the air towards the outside the floor would not be flat anymore and would be illegal.
Even then teams still ran vestigial fences at the floor leading edge trying to smooth the air flow
https://storage.googleapis.com/the-race ... -floor.jpg
Yup.hsg wrote: ↑27 Apr 2025, 20:26You want to say if they are allowed to use outwash fences on flat floor, they will use it?Sevach wrote: ↑27 Apr 2025, 18:56If you put a canard guiding the air towards the outside the floor would not be flat anymore and would be illegal.
Even then teams still ran vestigial fences at the floor leading edge trying to smooth the air flow
https://storage.googleapis.com/the-race ... -floor.jpg
What is optimal volume ratio intake/throat/diffuser and floor/diffuser?Sevach wrote: ↑28 Apr 2025, 01:35Yup.hsg wrote: ↑27 Apr 2025, 20:26You want to say if they are allowed to use outwash fences on flat floor, they will use it?Sevach wrote: ↑27 Apr 2025, 18:56
If you put a canard guiding the air towards the outside the floor would not be flat anymore and would be illegal.
Even then teams still ran vestigial fences at the floor leading edge trying to smooth the air flow
https://storage.googleapis.com/the-race ... -floor.jpg
Ferrari for example use outwashing vanes on the floor of their (road)cars.
Whoah there. Please inform yourself. The air can be treated as incompressible up to around 0.3 Ma (speed of sound varies with temperature, but for standard atmosphere calculations (15*C) 0.3 Ma is around 360 kph).ringo wrote: ↑27 Apr 2025, 22:09No it is not minimal.
A lot his happening under the car outside of basic flow equations, with energy of the flow, density, pressure etc.
A density change happens very easily. Remember with the F-1 car the body of the car is working the air.
The car is squashing the air head on underneath it. You will have density changes quite easily far away from anything supersonic.
When the air expands it slows down, but the molecules don't have more space to move around. What they have is more freedom of movement. When they are crammed in a tight space, they are being pushed from behind and so their movement is restricted to a narrower band of vectors (if they try to move backwards they quickly bounce off of the molecules behind. In a forward direction they have a more unobstructed travel (they're less likely to bounce off of other molecules), so that their average velocity increases in that direction).
There are optimal slope angles of the intake/diffuser, but the volume ratio depends on desired drop in pressure.
I'm going to disregard vortices, which greatly influence the flow, as I have no idea about them.
What is your background and experience with CFD?SharkY wrote: ↑28 Apr 2025, 14:37Whoah there. Please inform yourself. The air can be treated as incompressible up to around 0.3 Ma (speed of sound varies with temperature, but for standard atmosphere calculations (15*C) 0.3 Ma is around 360 kph).ringo wrote: ↑27 Apr 2025, 22:09No it is not minimal.
A lot his happening under the car outside of basic flow equations, with energy of the flow, density, pressure etc.
A density change happens very easily. Remember with the F-1 car the body of the car is working the air.
The car is squashing the air head on underneath it. You will have density changes quite easily far away from anything supersonic.
However, given that's an upper limit of F1 car and to have the most presice results, I'd assume teams include the energy equations in their simulations, but from our perspective it's not necessary.
https://www.cradle-cfd.com/media/column/a149
When the air expands it slows down, but the molecules don't have more space to move around. What they have is more freedom of movement. When they are crammed in a tight space, they are being pushed from behind and so their movement is restricted to a narrower band of vectors (if they try to move backwards they quickly bounce off of the molecules behind. In a forward direction they have a more unobstructed travel (they're less likely to bounce off of other molecules), so that their average velocity increases in that direction).
When the walls expand, the molecules are more likely to travel in different directions (up, down, back), as they aren't being pushed from behind so much, and so their average velocity decreases.
There are optimal slope angles of the intake/diffuser, but the volume ratio depends on desired drop in pressure.
I'm going to disregard vortices, which greatly influence the flow, as I have no idea about them.
But is the cross sectional area at inlet actually smaller than behind? Note, that the roof at the inlet is much higher than dowstream.
