Thanks to Khan_F1 on twitter
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WilliamsF1 wrote:No wonder Mclaren were trying to get their wing to flex.
Thanks to Khan_F1 on twitter
I'm sure that the wing pillars are part of the magic here. They really allow the wing to pivot while being able to carry all of the load. I'm convinced this is one way RB get around the deflection tests where the wing is loaded symmetrically (I think).Raptor22 wrote:thats just roll due to load transfer.
Yeah, sorry, my bad, the deflection test is asymmetric, so allowing the wing to pivot would not help. I still think it does pivot some though (about the centre line) and perhaps this aids the non-linear behaviour of the flex?Raptor22 wrote:I don't folow. If it pivots how does it pass the load test?
A pivot is a frictionless device that allows articulation.
If there is a pivot there is no way of controlling the deflection without a bulky restraining device which is absent (else would have been questioned by FIA)horse wrote: I still think it does pivot
I take it back that the pivot would aid passing the deflection test, I had the wrong idea of how it was carried out. I still think some pivot is beneficial (and apparent in the above photo) and must be initiated/constrained by the action of the pillars.WilliamsF1 wrote:If there is a pivot there is no way of controlling the deflection without a bulky restraining device which is absent (else would have been questioned by FIA)
horse wrote:Yeah, sorry, my bad, the deflection test is asymmetric, so allowing the wing to pivot would not help. I still think it does pivot some though (about the centre line) and perhaps this aids the non-linear behaviour of the flex?Raptor22 wrote:I don't folow. If it pivots how does it pass the load test?
A pivot is a frictionless device that allows articulation.
Some example pivot:
Yeah, I take on what you're saying about the picture, it could be a fluke, it's hard to disprove it, although you do see a lot of pictures of the RB with the wing "cocking" so to speak.Raptor22 wrote:The wing certainly won't flex more on one side due to the cornering force since the wing span feels the centripetal force parallel to the road.
What you are suggesting is an increase in wing flexure as the ground effect increases?horse wrote:Yeah, I take on what you're saying about the picture, it could be a fluke, it's hard to disprove it, although you do see a lot of pictures of the RB with the wing "cocking" so to speak.Raptor22 wrote:The wing certainly won't flex more on one side due to the cornering force since the wing span feels the centripetal force parallel to the road.
Regarding the centripetal force, yes, I see that that could push the wing away from the centre line. However, I think the wing can still flex more on one side because, as you pointed out, the car's set will tip the chassis + nose onto the loaded side which initiates an asymmetry on the wing as one side is now closer to the road. Now if the wing can flex and pivot further then that asymmetry will get more pronounced as the wing on the loaded side gets closer and closer to the road surface.
The caveat to this idea is what happens when the car straightens out? If my premise is true, how does the wing snap out of the asymmetry and return to level?
during last years race at SPA, the BBC showed a comparison between the mclaren and the red bull as they took right handed of the final chicane. the mclaren wing flexed only slightly as the car bounced over the curbing, where as the red bull wing flexed a huge amount in 2 ways. the pillars "flexed" laterally (mainly from the point where they join the nose cone), and either side of the main plane of the wing flexed vertically from the point where they 'connect' to the FIA restricted centre section. i cant currently find a video of it, so if someone has a recording of that race from the BBC that would be useful to see what im saying.horse wrote:WilliamsF1 wrote:No wonder Mclaren were trying to get their wing to flex.
Thanks to Khan_F1 on twitterI'm sure that the wing pillars are part of the magic here. They really allow the wing to pivot while being able to carry all of the load. I'm convinced this is one way RB get around the deflection tests where the wing is loaded symmetrically (I think).Raptor22 wrote:thats just roll due to load transfer.
You want the most force on the loaded wheel so let the wing pivot to generate the more downforce on the loaded side while sacrificing some DF on the unloaded side.
Hard to tell about ground effect, but in corner (yaw) air speed (and downforce) is bigger on the outside part of the wind - exactly the same effect as pushing a ruder on airplane - one wing drops, the other goes up.Raptor22 wrote:What you are suggesting is an increase in wing flexure as the ground effect increases?horse wrote:Yeah, I take on what you're saying about the picture, it could be a fluke, it's hard to disprove it, although you do see a lot of pictures of the RB with the wing "cocking" so to speak.Raptor22 wrote:The wing certainly won't flex more on one side due to the cornering force since the wing span feels the centripetal force parallel to the road.
Regarding the centripetal force, yes, I see that that could push the wing away from the centre line. However, I think the wing can still flex more on one side because, as you pointed out, the car's set will tip the chassis + nose onto the loaded side which initiates an asymmetry on the wing as one side is now closer to the road. Now if the wing can flex and pivot further then that asymmetry will get more pronounced as the wing on the loaded side gets closer and closer to the road surface.
The caveat to this idea is what happens when the car straightens out? If my premise is true, how does the wing snap out of the asymmetry and return to level?
You could be right but I can't answer that without data on the wing.
And then throw in a bit of flexy-wing and that's the full story!Raptor22 wrote:We're seeing the effect of a car not running rear springs. The rear suspension is much more supple than the fronts so the cars tend to roll on their rear axles, cocking the inside front wheel and the inside front wing span.
