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Few weeks ago there was a thread discussing exactly thatErunanethiel wrote:Against a no-downforce car, what would the bike do, in terms of cornering g. Assuming no driver/rider error, and exactly the same tire compound?
Well, in braking, the limiting factor is the high CoG of the bike, which makes the rear tire lift up from the ground. But cornering is another story, because of the lean, CoG isnt the limiting factor, the tires μ is. And since we are using the same copmound tires on both the car and the bike, the cornering g's must be the same.Andres125sx wrote:Few weeks ago there was a thread discussing exactly thatErunanethiel wrote:Against a no-downforce car, what would the bike do, in terms of cornering g. Assuming no driver/rider error, and exactly the same tire compound?
Summary, cars are faster cornering and braking, bikes are much faster on the straights. Please stop it here
Same tyre compound = same grip per mm^2 or contact patch, but a car has more contact patch! This is stacked against the force or weight of the vehicle pulling you out. In other words, heavier cars need more tyre contact patch (wider tyres) for equal cornering speed (than lighter cars). Which is whiy in high speed corners, a bike can hold its own against even very grippy cars. A nice example of this is a TopGear video where they pit a racing truck against a Ferrari 360CS on the track.Erunanethiel wrote:Well, in braking, the limiting factor is the high CoG of the bike, which makes the rear tire lift up from the ground. But cornering is another story, because of the lean, CoG isnt the limiting factor, the tires μ is. And since we are using the same copmound tires on both the car and the bike, the cornering g's must be the same.
Although I do believe contact patch area has a lot to do with it, its not quite correct to equate the compound to the grip (force) per mm^2 of contact patch area.Phil wrote:Same tyre compound = same grip per mm^2 of contact patch
How much of a difference do you reckon will there be in terms of cornering force, assuming both are set up perfectly, driven perfectly, and with the same compound.Tim.Wright wrote:I wouldn't bother about the other thread - it was a complete abortion and was rightly locked.
Even with the same compound, a car and a bike one other major difference regarding the tyres and that is the construction. This affects the contact patch size and therefore the cornering stiffness as well as the sensitivity to camber angle.
A car tyre has a larger contact patch and this (generally) allows a lot more cornering force. Tyres don't use pure coulomb friction but rather a mix of coulomb and chemical/adhesive forces so they don't have a constant coefficient of friction. Due to this, a larger contact patch will give you more grip due to the chemical/adhesive which works on contact patch area.
Regarding the construction, the motorcycle tyres are obviously rounded to deal with the large tilt angles - and from a quick glance at some examples of the tyre curves in Pacejka's book it seems that the tyres aren't so sensitive to camber angle at their limit (but they are very sensitive in the linear range). Car tyres on the other hand can usually increase their peak lateral force a reasonable amount by changing the inclination angle (camber).
One thing the bike tyres have as an advantage is a lower weight force which usually helps obtain a higher peak friction coefficient.
I haven't done a comparison of bike and car tyre directly but given the above I'd suggest that in steady state cornering a car would be quicker - mainly due to the larger contact patch area.
What's of interest is not cornering force but cornering force per kg of weight force. Basically the coefficient of friction. The force will always be higher on a road car tyre because it has a higher weight force acting on it.Erunanethiel wrote: How much of a difference do you reckon will there be in terms of cornering force, assuming both are set up perfectly, driven perfectly, and with the same compound.
Comparing what car with what bike?Erunanethiel wrote:How much of a difference do you reckon will there be in terms of cornering force, assuming both are set up perfectly, driven perfectly, and with the same compound.Tim.Wright wrote:I wouldn't bother about the other thread - it was a complete abortion and was rightly locked.
Even with the same compound, a car and a bike one other major difference regarding the tyres and that is the construction. This affects the contact patch size and therefore the cornering stiffness as well as the sensitivity to camber angle.
A car tyre has a larger contact patch and this (generally) allows a lot more cornering force. Tyres don't use pure coulomb friction but rather a mix of coulomb and chemical/adhesive forces so they don't have a constant coefficient of friction. Due to this, a larger contact patch will give you more grip due to the chemical/adhesive which works on contact patch area.
Regarding the construction, the motorcycle tyres are obviously rounded to deal with the large tilt angles - and from a quick glance at some examples of the tyre curves in Pacejka's book it seems that the tyres aren't so sensitive to camber angle at their limit (but they are very sensitive in the linear range). Car tyres on the other hand can usually increase their peak lateral force a reasonable amount by changing the inclination angle (camber).
One thing the bike tyres have as an advantage is a lower weight force which usually helps obtain a higher peak friction coefficient.
I haven't done a comparison of bike and car tyre directly but given the above I'd suggest that in steady state cornering a car would be quicker - mainly due to the larger contact patch area.