Frictional Force: Contact Area & Motorsports Tires

In summary: This is why wider tires are necessary to use a softer compound. Ok. So in summary, the frictional force between an object and a surface is independant of the surface area in contact. However, if you want to increase friction, you need to make the tire wider and use a softer compound.
  • #1
paul11273
156
0
I have a question regarding frictional force, and how it is related to a contact area.
Last week our professor mentioned that the frictional force between an object and a surface is independant of the surface area in contact.

If this is true, then why do vehicles in motorsports want to have wide tires to keep as much rubber on the ground as possible? According to the prof's statement, it shouldn't matter.

Can anyone explain the prof's statement? Or prove it wrong? Or introduce something that perhaps he left out?

Thanks.
 
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  • #3
Thanks for that link. But...I still don't quite get it. The link does state that there are exceptions to the general rule. However, how do you actually figure out those exceptions?

In an engineering application, how would you decide if it was worth it to add extra material to increase contact area in order to increase friction? Maybe the added material wouldn't matter. How would we know?

Any ideas?
 
  • #4
Friction is a very complicated phenomenon, so I don't have all the answers, but here's a little of what I know:

When you're considering something like Coulomb friction, the apparent macroscopic contact area is irrelevant. This is because the effective contact area is only a fraction of that. The effective contact area is determined by the roughness of the two surfaces on a microscopic level, where asperities are evident. Under a load, these asperities will deform (by Hooke's law), thus changing the effective contact area and, consequently changing the magnitude of the friction. So we see (more explicitly if you look at the equations, but nonetheless) that friction is independent of the apparent (macroscopic) contact area.

With tires, the model for friction changes, since the stretch of the tire tread affects things. Here is a site that talks about that a bit.
 
  • #5
paul11273 said:
... In an engineering application, how would you decide if it was worth it to add extra material to increase contact area in order to increase friction? Maybe the added material wouldn't matter. How would we know?

Any ideas?

We would know by trying. That's what experimentation is all about. If a theoretical understanding of a certain concept is lacking, you do experiments to see what different situations lead to. From those results, it may be possible to generate a theory.

However, the area of tribology (the study of friction, wear, etc.) is not new and has been extensively covered in the last three or four hundred years. In general, and to a fairly high degree of accuracy, the area independence (Amontons 2nd Law) is found to be true. So you need not spend time experimenting on that.

Now to answer your question about wider tires : The reason for wider tires is not that the increased contact area automatically leads to more friction (though there may be some effects that depend on the area indirectly). The design parameter that determines the coefficient of friction between the tires and the track is the something related to the molecular compressibility of the rubber. In other words, "the softer the rubber, the better the friction." However, when you use a softer rubber, you need to make the tires wide enough to give them strength. So, "the softer the tire, the wider it needs to be", to withstand design forces and moments.

Compare the two statements in quotes and you'll see why it looks like increasing the width (or contact area) gives you better friction.
 
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  • #6
paul11273 said:
... there are exceptions to the general rule.
This may be the problem. I suggest to think of it as the most simplified approximation rather than a "general rule." The rule is certainly not general. Another example of this kind of misinterpretation that may help you put things into perspective is Hooke's Law for springs. Hooke's Law is not the "general rule," but it can serve you with an outstandingly accurate approximation for small perturbations. The general rule goes into reversible deformations (nonlinearity) and then eventually irreversible deformations (plasticity/hysteresis).
 
  • #7
Gokul43201 -
I understand that a softer compound increases the friction coeffecient. So the primary reason for a fatter tire is to maintain structural integrity for a softer compound? The tire getting fatter is simply a necessity to allow the use of a softer compound. That makes sense.

Then it would follow that going to a wider tire of the same compound would not increase friction, right?

JamesRC,
So what you have said is that the contact patch we see is only a small part of the story. That what really counts is the contact at a microscopic level. That is why increased force causes more friction, slight deformations cause greater contact between "tiny grooves". That also ties into the softer compound tires. The softer it is, the more easily it can "fill in" the tiny grooves of the surface it rides on.
This microscopic contact area is what really matters? But then, wouldn't increasing the macroscopic area also cause the microscopic area to increase, probably my orders of magnitude higher, thus causing overall friction to increase?
 
  • #8
paul11273 said:
Gokul43201 -
I understand that a softer compound increases the friction coeffecient. So the primary reason for a fatter tire is to maintain structural integrity for a softer compound? The tire getting fatter is simply a necessity to allow the use of a softer compound. That makes sense.

Then it would follow that going to a wider tire of the same compound would not increase friction, right?

I'm certain that this is at least "mostly" correct.

But I've also come across arguments where your initial condition is a spinning tire, and the model that best works to describe the subsequent dynamics uses a probability factor. This probability factor has some weak dependence on the area of contact. But I think this only determines how long you are "likely" to keep spinning before you find traction.
 
  • #9
paul11273 said:
Thanks for that link. But...I still don't quite get it. The link does state that there are exceptions to the general rule. However, how do you actually figure out those exceptions?

In an engineering application, how would you decide if it was worth it to add extra material to increase contact area in order to increase friction? Maybe the added material wouldn't matter. How would we know?

Any ideas?

One factor to take into consideration is the relative smoothness of the surfaces involved. If one surface is flexible (like tire rubber), increased contact area increases the probability that a certain point of potential contact will make actual contact at any given time.
 
  • #10
paul11273 said:
Then it would follow that going to a wider tire of the same compound would not increase friction, right?
It's even worse than that. Going to wider tires without lowering tire pressure does not increase amount of rubber on road. Contact area is just weight divided by tire pressure.

Money spent on wider tires without going to softer, is wasted. In fact it has a negative impact in that it increases unsprung weight and rolling resistance. It can only help if the original tire is pushed so hard it frequently exceeds recommended temperature. Larger tires will run lower temp, other factors remaining constant.
 
  • #11
What about going to a thinner tire in order to reduce rolling friction? Say on a bicycle. Is there any advantage, other than a weight savings, for a bike to use thinner tires?
 
  • #12
paul11273 said:
What about going to a thinner tire in order to reduce rolling friction? Say on a bicycle. Is there any advantage, other than a weight savings, for a bike to use thinner tires?
Oh yes. The very most specialized racing bikes have the thinnest tires. The tradeoff is that the thinner the tire, the higher pressure is needed to keep it from bottoming on road irregularities. And of course the rider is subject to a lot of vibration.
 
  • #13
I have my own interpration of this effect, that relies on statistics. Since the coefficient of static friction is higher than kinetic friction, then the portion of the tire that remains in static contact with the surface dominates. A wider tire has a greater probably that a significant portion of the tire has not broken loose from the surface.

Heat kills tire traction. In general, you want your tires to run cool. At least that is my opinion on the matter.
 
  • #14
JohnDubYa said:
Heat kills tire traction. In general, you want your tires to run cool. At least that is my opinion on the matter.

Oops ! There's better traction on a hot track. Pit crews prep new tires (keep them hot) before putting them on. The higher the temperature of the tire, the softer the rubber gets, and the better is the traction.
 
  • #15
I definitely agree that hot tires have better traction. I know this from my own experience with riding motorcycles.

However, I still am wrestling with the contact area/traction relationship.
Despite everyone's input on this question and my own googling, I have not come across anything that quantitatively explains this relationship. So far about the only thing I have to go on is [tex]F_{s}={\mu}_{s}N[/tex] which does not account for the surface area contact.

I thought this would have a fairly simple answer.
 
  • #16
The problem with hot tires is that its construction breaks down as the tire heats up. I once saw some data on this issue and the results were pretty convincing.

Heating up a tire before putting it on does little, as the tire cools down to its surroundings very quickly. For example, in water burnouts the tires get hot, but by the time the dragster gets the green the tires will have cooled down. Tires have huge surface area and lose heat to their surroundings very quickly.

But if you have any data that shows the relationship between tire temperature and traction, I would be willing to reconsider.
 
  • #17
I definitely agree that a tire will have a threshold where the rubber will begin to breakdown, resulting in adverse effects.
However, when people talk of the tire being "hot", they are reffering to the temperature it attains from running. A cold tire, at ambient air temperature, has noticeably less traction than once it has been running for a few minutes and has warmed up.
I do not have actual data for you, but I have experienced this difference myself. It is more noticeable on a spring or fall day when the air temp is 50-60 degress F vs. a summer day with 90-95 degree F temps.
I will search the web to see what I can come up with. I think that anyone who has ridden a motorcycle will agree with my own experience of "hot" vs. "cold" tires.
 
  • #18
RE: "I definitely agree that a tire will have a threshold where the rubber will begin to breakdown, resulting in adverse effects."

The data I saw, however, showed an almost linear drop in traction with temperature, not a threshold.

I admit I was taken by surprise.

RE: "However, when people talk of the tire being "hot", they are reffering to the temperature it attains from running. A cold tire, at ambient air temperature, has noticeably less traction than once it has been running for a few minutes and has warmed up."

But this warming up may be just a relaxation of the rubber, similar to stretching exercises athletes perform before competition.

Maybe Goodyear or Hoosier has some data on the matter.
 
  • #19
JohnDubYa said:
Tires have huge surface area and lose heat to their surroundings very quickly.
But new heat is produced while driving. The tyre is constantly deformed when it is rolling on the road (->inner friction), and there is of course a bit friction between tyre and road, depending on how you drive.

By the site below, formula one tyres run at 90-110 °C. I would say the connection between friction coeff. and temperature is not linear over far distances, each tyre compound has its optimal temperature. If you drive a winter tyre in summer you have less traction than with a summer tyre, although the first is then probably softer.

http://www.formula1.com/insight/technicalinfo/11/476.html [Broken]
 
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  • #20
RE: "But new heat is produced while driving."

But that wasn't the issue I was describing.

RE: "I would say the connection between friction coeff. and temperature is not linear over far distances, each tyre compound has its optimal temperature."

Yes, I agree.
 
  • #21
But that wasn't the issue I was describing.
At least you wrote: "Heating up a tire before putting it on does little, as the tire cools down to its surroundings very quickly."
And I say it doesn't.
 
  • #22
"Heating up a tire before putting it on does little, as the tire cools down to its surroundings very quickly."

Before the race begins, the tire will cool down. It has to, because its surroundings are at a lower temperature.

You say it doesn't. Okay, we disagree.
 
  • #23
Here is a site which states that better traction is attained with high temps on NASCAR tires.

http://www.bodydynamicsracing.com/tires.htm

Of course it also states there is an optimal temperature, which implies too much heat is not good.
 
  • #24
"Heating up a tire before putting it on does little, as the tire cools down to its surroundings very quickly."

What exactly do you mean by "...putting it on..." in this statement?
Do you mean before running the tire on the track or road?
Another site I found stated that race teams use tire warmers to heat the tires to 80 degree C. Their optimal running temps were stated as 110-120 degree C. That is hot.
 
  • #25
I race motorcycles and can assure you that you need 'hot' tyres for best grip. I've had two first lap crashes this year due to the tyres not warming up enough (Classic racers are't allowed tyre warmers), or rather I should say due to me pushing it too hard before they had warmed up.

Tyre warmers are essential for modern v high power machines, and it is true that they start to cool down when these are removed, but that is why racers have a warm up lap before every race... it is to warm up and keep the heat in the tyres, not to warm up the engine which can be done in the pits.

Production racing classes using road tyres generally have a two lap warm up in order to get the tyres suitably warm, as they cool far quicker, and normally run at a lower temp, than race tyres.
 
  • #26
Motorcycles - temperature vs traction

I just discovered this site and it seems like a good one on which to post my question.

On Friday, 18 January, 2008, I crashed my motorcycle while negotiating a round-about. The temperature was right around freezing. I knew that traction is reduced at low temperatures, but I did not expect it to be reduced by that much. Basically, the tires skidded, and I went down. Fortunately, there was only light damage to my Honda VFR, my protective gear wasn't even scuffed, and I didn't even feel an impact.

There is general consensus that motorcycle tires lose more traction in cold weather than car tires do. That would seem to be the case because I have never really noticed a cold-induced traction reduction when driving a car, but I sure did with my motorcycle.

Can anyone explain why motorcycles should lose more traction in cold weather than car tires do? Probably there are thousands of bikers who would like to know.
 
  • #27
Sorry to interrupt, but I know there are two distinct areas that needs addressing. The first is (1) friction and the second is (2) stability.
 
  • #28
True, but in this case, the important factor is friction / traction. Above a certain minimum speed, a 2-wheel vehicle is stable as long as adequate traction is available. This can easily be demonstrated. If you stand beside a bicycle and walk it slowly ahead while leaning it to one side, the handle bars will automatically turn in the direction of the lean. That effect alone is sufficient to provide stability above a certain minimum speed, provided that adequate traction is available. Gyroscopic effects add to the stability. These forces work whether the 2-wheel vehicle is going straight ahead or turning. Of course, when turning, the tires have to have sufficient traction to resist the radial forces, else the 2-wheel vehicle will not remain upright.

With adequate traction, my motorcycle would not have fallen. Although the physics of stability is interesting and has design implications, the question here is why the traction of a motorcycle seems to be more sensitive to cold than a car.

Since making my previous post, I did think of a possible answer. A car tire is straight across so the rubber has to flex in only one plane to maintain contact with the road. A motorcycle tire is not straight across; to provide for leaning, the tread is curved from one side to the other. Thus, the rubber has to flex in 2 planes to maintain contact with the road; possibly that makes traction more sensitive to the flexibility of the rubber and, since rubber loses flexibility as the temperature drops, the traction might be more sensitive to temperature. This is just a guess.

I would be interested in ideas that others may have regarding this.
 
  • #29
FRE said:
True, but in this case, the important factor is friction / traction. Above a certain minimum speed, a 2-wheel vehicle is stable as long as adequate traction is available. This can easily be demonstrated. If you stand beside a bicycle and walk it slowly ahead while leaning it to one side, the handle bars will automatically turn in the direction of the lean. That effect alone is sufficient to provide stability above a certain minimum speed, provided that adequate traction is available. Gyroscopic effects add to the stability. These forces work whether the 2-wheel vehicle is going straight ahead or turning. Of course, when turning, the tires have to have sufficient traction to resist the radial forces, else the 2-wheel vehicle will not remain upright.

With adequate traction, my motorcycle would not have fallen. Although the physics of stability is interesting and has design implications, the question here is why the traction of a motorcycle seems to be more sensitive to cold than a car.

Since making my previous post, I did think of a possible answer. A car tire is straight across so the rubber has to flex in only one plane to maintain contact with the road. A motorcycle tire is not straight across; to provide for leaning, the tread is curved from one side to the other. Thus, the rubber has to flex in 2 planes to maintain contact with the road; possibly that makes traction more sensitive to the flexibility of the rubber and, since rubber loses flexibility as the temperature drops, the traction might be more sensitive to temperature. This is just a guess.

I would be interested in ideas that others may have regarding this.

Hi,

I know this is a pretty old post but as it involves motorcycle safety I'm going to take a shot at your question. First, a motorcycle tire (MT) is indeed much more unforgiving in the cold than a car tire (CT). A MT has a rounded tread area to better support consistant traction at high lean angles. This rounded shape results in a very small area of contact with the road at any lean angle. The small contact area results in much higher pressure on small MT contact area than on the much larger contact area of a CT.

The small contact area and high pressure result in a higher normal operating temperature due to the higher hysteresis loads on the small contact area. MTs are made with harder rubber than CTs to in order to allow reasonable wear on that small contact patch, and this harder rubber is formulated to provide the best traction at a much higher ideal operating temperature than a CT.

A MT must reach and maintain a higher operating temperature than a CT for the best traction. As the hard rubber on a MT has pretty horrible traction when cold compared to the softer rubber on a CT, the MT is much more sensitive to the cold and will slide out from under you and put you on your butt if you're not careful.
 

What is frictional force?

Frictional force is the force that resists the motion of an object when it is in contact with another surface. It is caused by the microscopic irregularities and adhesion between the two surfaces.

How does contact area affect frictional force?

The larger the contact area between two surfaces, the greater the frictional force. This is because there is more surface area for the microscopic irregularities and adhesion to act upon, resulting in a stronger resistance to motion.

Why is frictional force important in motorsports tires?

Frictional force plays a crucial role in motorsports tires as it determines the traction and grip of the tires on the track. A higher frictional force allows for better control of the vehicle and can result in faster speeds.

What factors can affect the frictional force of tires?

The type of surface, the material of the tires, and the weight of the vehicle are some of the factors that can affect the frictional force of tires. Additionally, the temperature and pressure of the tires can also impact the amount of frictional force.

How can frictional force be maximized for optimal performance in motorsports?

To maximize the frictional force of motorsports tires, it is important to ensure that the tires have the appropriate amount of pressure and that they are made of a material that provides a good grip on the track surface. Additionally, maintaining the tires at the recommended temperature can also help to optimize the frictional force.

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