hecti wrote: ↑12 Apr 2021, 17:20
This seems like far fetched but don't we have to look at not only the air underneath and above the floor, but the air coming over the sidepod as well? There are 3-4 distinct flows that all converge in roughly the same area, if the more "Z" shaped cut out is really acting like an Alula (which seems very possible, as falcons can reach the same speeds F1 cars can) then maybe we can draw some conclusions as to what is going on. When looked at individually we don't see the clear picture. If we assume that the y250 vortex, strengthened by the barge boards and then merged with the underbody flows that exit from the sides of the floor after the barge boards all converge, then it leaves a gap that needs to be filled, mostly by the air coming over the side pods which most have a slope element towards the cutout and maybe flow over the flow that comes around the under cut of the sidepod. this flow interacts with the cutout and the small floor edge VGs to create a vortex that may seem like a leaky edge but actually seals the diffuser from the inward tire squirt further back. The harder the air floor is worked underneath (ie: high rake) at the beginning of the floor the more effective the cutout vortex is.
When thinking of air, you have to consider the air around the object. Some air is attached to the car due to viscous forces, and that air gets dragged along with the car, but the air around the object is not. The dragged air along the vehicle skin and the boundary where the dragged air stops interacting with the surrounding air is called the boundary layer.
The air being dragged by the car IE the boundary layer is moving faster than the air above and around it, this faster air lowers its pressure.
Imagine a Jenga tower, and the blocks are the air, and the floor is the skin on the car, if you skillfully pull the bottom layer of blocks, all the blocks above will collapse their mass on the space below. The air that surrounds the boundary layer does the same thing because air is at 14.7psi at sea level, so when the car drags air behind it, the static high pressure air above it is at atmospheric pressure and collapses on the low pressure caused by the faster moving air below the boundary layer.
When you create a high pressure circulation, entrained low pressure like a vortex, will go around this high pressure zone. You can see this in the path of hurricanes across the ocean, high pressure troughs push the storm, and low pressure systems pull the storm. If we translate this to F1, we see the diffuser, being a low pressure system pulls the low pressure tire squirt into itself. The low pressure side being the rear of the tire, and the high pressure side being the front of the tire, the squirt itself is the high pressure in the front rushing to fill the low pressure in the back of the tire. That turbulent low pressure vortex gets steered by the low pressure created by the diffuser.
Now with lower rake, that tire squirt is more powerful, because the diffuser is closer to the ground, there are no slots to lower the pressure on the face of the tire, which reduces the pressure difference and weakens the tire squirt.
The challenge of the teams is to use the new floor to either increase the pressure at the rear of the tire, or lower the pressure at the front of the tire, or both.
