...per square inch (PSI). What unit of pressure do you use? I've never known anyone use anything other than PSI for tire pressures.
...per square inch (PSI). What unit of pressure do you use? I've never known anyone use anything other than PSI for tire pressures.
bar ... like everyone else in germany and probably the entire rest of europe does
or technically i think its actually bar - 1
That depends whether you're talking about absolute pressure or gauge pressure
Atmospheric pressure is 1 bar absolute, 0 bar gauge. Your tyre pressures will almost certainly be gauge pressures, which is the pressure above atmospheric.
Speaking of strange units, I work in the automotive emissions sector and we measure catalyst metal loading in g/ft^3 !
Indeed. I forget the exact figures, but I'm talking pretty small changes in yaw. It doesn't seem logical to me, since less surface area is exposed to the direction of flow but nonetheless it's true.
Per anything, it's a flexible unit unlike a bar
...Really bad habit typing lbs instead of PSI :hide:
:hihi:
1 Bar is pressure that is in your personal intake (nose) during breathing in as you probably are naturally aspired as most of us, naturally 2 bars is pressure doubled, very practical unit as 1 bar is ~1 atmosphere at sea level so put 2 bars absolute pressure (1bar of boost) and you get double power, right?
(for those that don't know of my perversions, I'm joking a bit again :razzOh, and sorry that my quote is all f*ckd up, that was about BBT's bar thing that I meant to quote, but I'm newbie
i know i know but we were talking about tyre pressures which round here are usually measured in bar - 1 ... or actually bar - atmospheric not that the changes of atmosheric pressure matter but anyway
are you sure this is a general effect and not just something with that particular wing profile in the test youre refering to which might improve its perfomance if you look at the profile cut slightly diagonally ?
how much of an increase is it anyway ?
no i breathe turbo air fueled from my farts
That would make sense for the tire pressures to be in gauge pressure, since they would be way too low otherwise.
Here's two of Todd's posts from RSC (http://forum.rscnet.org/showthread.php?t=269177&page=5), they're great reading - so I have no problem posting them here:
At Shotglass: looks like he was mainly talking about spoilers, not wings per se - shame on me!
At Shotglass: looks like he was mainly talking about spoilers, not wings per se - shame on me!
That was an awesome reading, now I want to know more about this subjet.
well i guess for a spoiler is might make sense if you consider the spoiler at 0° yaw is usually in the low pressure area behind the driver compartment and as you increase yaw it will stick out more and more from it
a simple test for this theory would be to see if the downforce is different on both rear tyres
a simple test for this theory would be to see if the downforce is different on both rear tyres
Omg, CH4 boosted beast, I never try to beat you in running, that is really a badass setup you got
I tend to believe what Todd says as it really has shown dramatic improvement to that known game mod handling, even it is surprising that many books show wrong graphs, but that could really be so.
Luckily I don't have time to test everything thoroughly, so I can just believe what I'm told
Get "Race Car Vehicle Dynamics"
It's a great book. A little tough to read, but it's good.
The only "concrete" info (in quotes because I don't recall the numbers) I can recall on wings and how downforce is effected by yaw angle was from an SAE conference I went to last October. One of the presentations I sat in on was a CFD (computational fluid dynamics) deal where they were showing the latest aerodynamic modelling on a formula car. Very impressive stuff to be sure!
Anyway, you know those little vertical fins that you see somewhat outside of the center on the front wing of a lot of formula cars? The thing I remember most was a CFD comparison before and after adding a pair of those little fins. What tended to happen when yaw angle was increased to 4 degrees, which is right at the peak of the lateral force curve (tire slip angles would be about 4 degrees then too, pretty much), was that a set of low pressure "bubbles" would come off the outside half of the wing and stream into/around the outside pod. It was neat seeing it in CFD. When he showed the fins the bubbles coalesced and more or less disappeared, restoring pressure in that area.
The result was a slight increase in downforce. However, I don't know if there was an increase from 0 degrees yaw or if the fins just increased downforce at 4 degrees when compared to 4 degrees and no fins. I want to say there was indeed an increase from 0 degrees yaw, but don't really remember for sure. The impression I got was that the tiny, extra downforce (14 or 18 lb comes to mind, but I could be remembering wrong) wasn't generated at the wing, per se, but as a result of how the airstream went around the side pod afterwards, slightly forward of the car's center of gravity and thereby increased front downforce. A slight change in pressure on any top or bottom surface anywhere on the car changes downforce, so changing the front wing can actually effect more than just that part. It changes the airflow at the rear too. I don't know how much though. I've got quite a lot of aero data on one formula car and they don't specify a change in rear downforce when the front wing flaps are adjusted, so perhaps it's not much or enough to worry about.
In conclusion, I don't know how much yaw angle effects downforce on wings. Without end plates I'd tend to think the downforce would decrease with any yaw angle at all, but don't really know for sure. Remember that the airflow around the rest of the car is also influencing downforce, and that is changing with yaw too. With end plates I wouldn't be surprised to see it go either way over a small yaw angle range. Indycars on super speedways tend to spin in a real hurry when you get the slip angle much past the peak, so it looks to me like downforce plummets pretty quickly after a point. That's at the rear though where the airflow has gone all crazy over the body compared to the front wing which still has clean air. So it's a body/wing interaction. There could very well be a small region from 0-5 degrees or so where there's a slight increase, but I don't know for sure. If there is, I doubt it's much though (1-2% or less if I had to take a wild guess). Measured data has gone contrary to my intuition before, so take that with a grain of salt
BTW., the CFD simulation covered probably just a couple of seconds of simulated time. IIRC, the computation took 120,000 CPU hours, which would take over 13.5 years on one PC!
They ran it on a massive CPU cluster and it took a week straight, 24 hours a day. All for a few seconds of simulated time. The result was sure pretty to look at, although I don't know how practical that really is. 
EDIT: If each CPU did 1.3 billion calculations per second (my P4 3.6Ghz does that), 120,000 CPU hours would be 561,600,000,000,000,000 calculations (561.6 quadrillion!)
Here's a copy of the graph charting yaw angle against coefficient of lift for various rear spoiler configurations that Todd and BBT are talking about.
http://i9.tinypic.com/4pvajhg.jpg
In the third config, the lift coeff rises very slightly at small yaw angles.
As Todd mentioned, this graph is taken from 'Race Car Vehicle Dynamics' by Milliken and Milliken, pp 494.
http://i9.tinypic.com/4pvajhg.jpg
In the third config, the lift coeff rises very slightly at small yaw angles.
As Todd mentioned, this graph is taken from 'Race Car Vehicle Dynamics' by Milliken and Milliken, pp 494.
It's amazing how threads can change subjects so fast. This has got to be one of the most informative online forum threads ever. LFS, tire physics, FOV, tire pressure, units of measurement, and now aero stuff...
What's next I wonder?
What's next I wonder?Don't forget humans running on F/I methane! (although incidentally not all humans produce methane apparantly)
Yes, some produce only bad smelling gases that actually decrease performance and may cause even dizzy feeling, but few quality persons do have proper F/I methane setup and we mere normals are no match for them
You find it hard to believe? Well, how did you think some can do those incredible WR times, by practising? LOL, no way you could get that fast with practise
The experts? You mean the people who write books on racing tyres?
Have they actually done REAL research, or are they just talking from experience and what they've read? I suspect that your average 'tyre expert' has never seen any actual data themselves. Todd has. Todd is going to events that even F1 teams find enlightening. You'll probably find several senior tyre company people in the audience too, learning about the things they make.
Have they actually done REAL research, or are they just talking from experience and what they've read? I suspect that your average 'tyre expert' has never seen any actual data themselves. Todd has. Todd is going to events that even F1 teams find enlightening. You'll probably find several senior tyre company people in the audience too, learning about the things they make.
Todd was also specifically addressing these books, and the general consensus is that the first authors maybe took own driving experiences or reports from race drivers of the "cars letting go" once you go "over the limit". That way those funky curves with huge dropoffs after the peak were created. However, feeling a change in force, like when the car starts sliding and lateral force is replaced by rotational one, has nothing to do with what happens at the tyres and how much traction they provide - these curves describe more what the driver feels, rather than what the tyres actually do. Newer racing books then, instead of doing own research, more or less just copied this author's fantasy curves which in the end created the myth of tyres that lose huge amounts of grip when they slide.
I have nothing to add what Tristan and AndroiXP replied, but tell me have you seen how much of real measured data from tires? Have you raced IRL?
Specificaly?
i doubt it because if those guys had actually spent a second thinking about what those curves would mean for car handling (especially countersteering) they would never have put them into their books
which goes to show how much or rather little they must know about physics
But you can t disagree that there is always a moment with a dropoff in the curves,i can t imagine a car who would be catchable in all situations(angle).
I m pretty sure that is the point they try to explain with the sudden dropoff.
You are going sideways at 30deg,then 40..........and more and more and poufff,you lost the ass(that is what i mean with violent griploose).Can you really say it doesn t happend to you one time.
You are talking from illusion that led to this misbelief of dropoff.
Does rubber know what is it's slip angle and does it turn ice after certain angle is exceeded? No, it does not, what happens is that sideways movement velocity becomes greater than amount of grip can handle and car is sliding and this can lead even to loss of control when velocity is great enough.
Also when tire slides it starts to heat up and when tire overheats this reduces grip, but you don't put this to tire curves, it is own modifier that modifies grip and tire curve according to tire temp. Also there are few other modifiers that cause that there really is less grip when sliding, but those are not to be included to tire curve itself.
Todd told once that reason books have such curves is that books are for racing drivers and intention is to illustrate to drive how there is less grip when sliding. Correct me if my memory is inaccurate, but that is how I remember it was.
Also I don't know all fancy words and such, I know just basic principle and that is enough for me, I don't have time to study it deeply enough to know all words and proof things with numbers etc.
Realistic roadholding? Not for me . . .
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