It has long been said that the FIA are restricting freedoms in the design of F1 cars with ever more restrictive regulations; but how restrictive are the rules, and by what means do the FIA force particular shapes?
I don't think that is correct. The rear of the car and those counter-rotating vortices indeed throw air upwards at the car's centerline. But that doesn't mean that you get a partial vacuum ("low pressure") behind the leading car at ground level. It just means that new air has to come in from the sides to fill that space. And that air will, partially because it has to fill the otherwise vacant space, be moving forwards (and a bit sideways).Except no, the wake behind the car is pure low pressure, so driving directly behind the car will lower downforce because of the nature of the wake. The two counter rotating vortecies are pumping air upwards creating a pressure reduction.
I get what you're saying, as the car moves forward it gives the air some forward momentum as that air fills the partial vacuum the car leaves in its wake. It's the macro movement of the car and the air rushing to fill the low pressure created as the car moves across the road.hollus wrote: ↑19 Feb 2021, 20:53I don't think that is correct. The rear of the car and those counter-rotating vortices indeed throw air upwards at the car's centerline. But that doesn't mean that you get a partial vacuum ("low pressure") behind the leading car at ground level. It just means that new air has to come in from the sides to fill that space. And that air will, partially because it has to fill the otherwise vacant space, be moving forwards (and a bit sideways).Except no, the wake behind the car is pure low pressure, so driving directly behind the car will lower downforce because of the nature of the wake. The two counter rotating vortecies are pumping air upwards creating a pressure reduction.
So one could say that there is low pressure behind the leading car, but only in the "dynamic" meaning of low pressure. Static pressure is pretty close to 1 atmosphere everywhere.
In a car's wake, at ground level, you do encounter air with the same density, there is no vacuum, but the speed of that air relative to your car is slower, hence less downforce.
But I might be getting it wrong, of course; either the physics or the terminology.
That's a nice picture, but it doesn't mean anything on its own.
The part on the car and the falcon alula are both creating a tip vortex that helps keep airflow attached to the wing/top side of the floor.hUirEYExbN wrote: ↑01 Apr 2021, 17:33That's a nice picture, but it doesn't mean anything on its own.
How does the alula of a falcon relate to that part of the floor? What's your thesis?
The stooping falcon is a lifting body and the alula is a roll control device. There is no correlation between what a stooping falcon is doing and what an F1 car is doing with the air flow along the edge of the floor.godlameroso wrote: ↑01 Apr 2021, 18:22The part on the car and the falcon alula are both creating a tip vortex that helps keep airflow attached to the wing/top side of the floor.hUirEYExbN wrote: ↑01 Apr 2021, 17:33That's a nice picture, but it doesn't mean anything on its own.
How does the alula of a falcon relate to that part of the floor? What's your thesis?
Both the bird and car have a similar profile from the alula to the tip of the wing, and the device on the car to the tapered section of the floor. My thesis is that the bird design can help guide the development of the car.
Of course the bird is trying to generate lift(the inverse of an F1 car), and the bird doesn't come with spinning tires, but the design principles are the same. The bird is trying to guide airflow in a similar manner to an F1 car only inverted.
If you notice, the alula curves inward, while the device on the F1 car curves outward, IE inverted.
Wouldn't this be beneficial if you're interested in increasing the pressure of the upper side of the floor near the rear tire?Just_a_fan wrote: ↑01 Apr 2021, 19:10The stooping falcon is a lifting body and the alula is a roll control device. There is no correlation between what a stooping falcon is doing and what an F1 car is doing with the air flow along the edge of the floor.godlameroso wrote: ↑01 Apr 2021, 18:22The part on the car and the falcon alula are both creating a tip vortex that helps keep airflow attached to the wing/top side of the floor.hUirEYExbN wrote: ↑01 Apr 2021, 17:33
That's a nice picture, but it doesn't mean anything on its own.
How does the alula of a falcon relate to that part of the floor? What's your thesis?
Both the bird and car have a similar profile from the alula to the tip of the wing, and the device on the car to the tapered section of the floor. My thesis is that the bird design can help guide the development of the car.
Of course the bird is trying to generate lift(the inverse of an F1 car), and the bird doesn't come with spinning tires, but the design principles are the same. The bird is trying to guide airflow in a similar manner to an F1 car only inverted.
If you notice, the alula curves inward, while the device on the F1 car curves outward, IE inverted.
The alula curves the way it does because it's normally held against the surface of the wing and the feathers are shaped accordingly.
The F1 floor edge VGs are designed to roll up a vortex that spins in a specific direction in order to interact with other similar vortices generated up stream.
Where the alula does mimic human designs (or rather vice versa) is in high angles of attack. Then the alula performs a similar role to the leading edge slats on a human-built aircraft wing.
OK, I understand the connection you are making.godlameroso wrote: ↑01 Apr 2021, 18:22The part on the car and the falcon alula are both creating a tip vortex that helps keep airflow attached to the wing/top side of the floor.hUirEYExbN wrote: ↑01 Apr 2021, 17:33That's a nice picture, but it doesn't mean anything on its own.
How does the alula of a falcon relate to that part of the floor? What's your thesis?
Both the bird and car have a similar profile from the alula to the tip of the wing, and the device on the car to the tapered section of the floor. My thesis is that the bird design can help guide the development of the car.
Of course the bird is trying to generate lift(the inverse of an F1 car), and the bird doesn't come with spinning tires, but the design principles are the same. The bird is trying to guide airflow in a similar manner to an F1 car only inverted.
If you notice, the alula curves inward, while the device on the F1 car curves outward, IE inverted.
In nature, form tends to be strongly correlated with function. From chemistry to physics. Unless the birds are using a different type of air than F1 cars, then they're subject to the same physical laws.Just_a_fan wrote: ↑01 Apr 2021, 23:20Resembling in appearance does not mean they are similar in action.
