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When assuming constant mass flow (no Spillage) this slowing down to ambient means that at the entry of the diffuser the air needs to move faster than at the Exit. When air Speed at the Exit is ambient this means that at the mouth the air flow is faster than ambient and thus Bernoulli tells us that there will be lower static pressure than above the car and thus Downforce exerted.mrluke wrote:The diffuser does not make a low pressure area. Just before the mouth of the diffuser is the lowest pressure area, the diffuser then slows the air down, increasing air pressure back to ambient as it exits the diffuser.
I disagree with that. A F1 floor, in spite of all the regulation forcing flat sections and steps and so on, still behaves like an inverted aerofoil. The front of the sidepod is the leading edge (hence the rules on the 50mm radius at the edge and the importance of undercut), then it has to be flat up to the diffuser kink line (aka kick).tok-tokkie wrote:That 'inverted' aerofoil is not behaving the same as a F1 diffuser. Look at the streamlines ahead of the aerofoil - it is drawing air from way above the leading edge into the venturi gap that the aerofoil makes with the ground. In a F1 diffuser that air is not available so it does not behave as shown by this diagram.timbo wrote: You're talking a different thing. Diffuser have clear definition. Diffuser without the floor would itself be floor.
If you look at pressure distribution on this picture, you see that the lowest pressures are at the zone which is closest to the ground:
http://www.mh-aerotools.de/airfoils/images/wig_5.jpg
Now, I am not saying diffuser does not provide downforce. However, most of its effect is in enhancing the flow upstream of it.
PS, which is why it is possible to have to big a diffuser -- if the feeding flow is inadequate.
Thanks for that. So the leading edge is way forwards and we have a much extended low pressure area but still the drawing in of streamlines - even though the leading edge is sharp rather than radiused as on an aerofoil.shelly wrote:I disagree with that. A F1 floor, in spite of all the regulation forcing flat sections and steps and so on, still behaves like an inverted aerofoil. The front of the sidepod is the leading edge (hence the rules on the 50mm radius at the edge and the importance of undercut), then it has to be flat up to the diffuser kink line (aka kick).tok-tokkie wrote:That 'inverted' aerofoil is not behaving the same as a F1 diffuser. Look at the streamlines ahead of the aerofoil - it is drawing air from way above the leading edge into the venturi gap that the aerofoil makes with the ground. In a F1 diffuser that air is not available so it does not behave as shown by this diagram.timbo wrote: You're talking a different thing. Diffuser have clear definition. Diffuser without the floor would itself be floor
If you look at pressure distribution on this picture, you see that the lowest pressures are at the zone which is closest to the ground:
http://www.mh-aerotools.de/airfoils/images/wig_5.jpg
Now, I am not saying diffuser does not provide downforce. However, most of its effect is in enhancing the flow upstream of it.
PS, which is why it is possible to have to big a diffuser -- if the feeding flow is inadequate.
If we had a flow viz of the stream line before the sidepod we would see something similar to timbo's image, with squeezed streamlines
There are 2 strong low proessure peaks under a floor -diffuser: one at the leading edge, the other at the diffuser kink line. Then thera are 3d effects (side sealing, vortex acceleration) and trapped vortices (i.e. vortex tubes running beneath the floor giving downforce.
I didn't realise the front of the floor generate that much downforce as well. Or at least, that much extraction.chuckdanny wrote:Here is an example from sauber
http://oi61.tinypic.com/34o4n46.jpg
It seems that it is a double diffuser year model with those throat in front of the extractor
Yes!SiLo wrote:I didn't realise the front of the floor generate that much downforce as well. Or at least, that much extraction.chuckdanny wrote:Here is an example from sauber
http://oi61.tinypic.com/34o4n46.jpg
It seems that it is a double diffuser year model with those throat in front of the extractor
You might find that the double diffuser cars generate a much lower pressure area a the front of the floor simply because they were extracting more air from underneath the car. I would imagine that area would be of a higher pressure now, but most likely the same across the board. In fact, the front floor should theoretically work along the same level as the diffuser. The more air the diffuser can extract the less air underneath the entire body of the car.chuckdanny wrote:Yes!SiLo wrote:I didn't realise the front of the floor generate that much downforce as well. Or at least, that much extraction.chuckdanny wrote:Here is an example from sauber
http://oi61.tinypic.com/34o4n46.jpg
It seems that it is a double diffuser year model with those throat in front of the extractor
And as i tried to express, the pattern seen suggest the structure of the flow :
http://oi59.tinypic.com/sq5h8n.jpg
That is, it is slightly divergent at the inlet due to the sidewash to shield this inlet from the turbulent wake of front tire but at the back it seems that it act as a big convergent thanks to the presence of the rear tires.
But the front wing accelerate the flow also because it is shaped (section reduction between road and wing) and the front of the floor is shaped also plus the skid plank, it's not flat. And of course front tire create a convergent structure.
The document posted by tok-tokkie on mulsanncorner say that regardless, a simple plate with rake would create the same pattern. Now in which quantity we don't know.
leading edge suction peak clearly visible, along with vortex low pressure strake at the front (the blue narrow zone protruding from the front).techF1LES wrote:Actual screens from Williams' design office
At least according to Bernoulli. But then it’s at essentially zero velocity before the car comes along.mandark wrote:One interesting thought..the air under the floor is propelled backwards relative to the road despite a 200mph car shooting forwards over it?
Hey Moose check out this direction of rotation.Moose wrote:For me, it "obviously" can't seal the under floor. It's rotating the wrong way to do that. This would actually draw air out from under the floor, not force it to stay under there.chuckdanny wrote:Well, first it's not new, the also called bat wing was there with the W05 while not at every grand prix.
They are many theories about the use of vortices. Some claim it seal the underfloor, it improves the speed carried through the bottom of the sidepod by the stream under the nose and maybe burst right in the coke bottle shape area behind the sidepod at the very top speed where maybe the flow is detaching creating drag.
That is not fully correct - as I said in an earlier post in this discussion, the calculation is done with the car stationary, and the air moving under the floor, while the reality is that the air is actually being pulled in the direction of the car's movement, with boundry layers on both the ground and on the floor. This change in POV is done to simplify the calculation - it is much easier to calculate air movement over the floor as a closed system than to try and calculate what happens to a volume of air when a car passes through it. The risk is that the simplification causes the engineers to miss important details, and the simulated data does not depict reality (anyone remember the Ferrari aero discussions with the poor coorelation?)olefud wrote:At least according to Bernoulli. But then it’s at essentially zero velocity before the car comes along.mandark wrote:One interesting thought..the air under the floor is propelled backwards relative to the road despite a 200mph car shooting forwards over it?
Also, Bernoulli address a free, incompressible, inviscid fluid which is hardy the case in the throat of the diffuser. With the static ground boundary layer and the dynamic diffuser throat boundary layer, there is probably a spectrum of velocity realities.
Yes you really see how powerful the management of the flow upstream of the floor is. Very impressive! All down to the front wing?shelly wrote:From the CFD thread of this forum, some months ago:leading edge suction peak clearly visible, along with vortex low pressure strake at the front (the blue narrow zone protruding from the front).
Also noticeable double diffuser effct and diffuser kink line suction peak