Work done on accelerating car is zero?

In summary, the conversation discusses the concept of work in relation to a car's kinetic energy. The static friction force provides acceleration but does not move through a distance, and it is only external forces that can change an object's translational kinetic energy. This does not violate energy conservation as the chemical potential energy in the car's engine is converted to kinetic energy. The conversation also mentions that the kinetic energy of a system can change without net work being done. The contact points of the car are virtual and change over time, but the wheel is always rotating around the contact point. The effect of multiple contact points is mathematically equivalent to one continuous force acting over a distance, and switching frames of reference shows that the force is always applied at the same
  • #36
BrainSalad said:
The fact remains that no work is actually done on the car.
IMO, there is work performed on the car, equal to the force at the contact patch times the distance that the force is applied. However, the source of the energy is the car's engine (after losses), not the road or the tires.
 
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  • #37
rcgldr said:
IMO, there is work performed on the car, equal to the force at the contact patch times the distance that the force is applied. However, the source of the energy is the car's engine (after losses), not the road or the tires.

The force is not applied through any distance though. The COM moves through a distance, and that's useful for calculation. But, work (the transfer of energy from one object to another) is not done by the road.
 
  • #38
The correct answer is that the road performs 0 work on the car. Any method that disagrees with that is simply wrong. If the road does work on the car then the road must lose energy and the car must gain it. You cannot have the road doing work on the car but the car's energy not increase and the road's energy not decrease.
 
  • #39
DaleSpam said:
If the road does work on the car then the road must lose energy and the car must gain it.
Is the reverse also true? If the road does negative work on the car then the road must gain energy and the car must lose it?
 
  • #40
A.T. said:
Is the reverse also true? If the road does negative work on the car then the road must gain energy and the car must lose it?

That happens in a skid - the road gets a bit warmer from the work done 'on' the surface material.

But why is there this preoccupation about who does what? It's just another of these daft 'what really happens?' questions that are only there for entertainment. There is always some answer available; it just needs to be very convoluted, sometimes.

Is this question any different from the question about whether or not the Fulcrum of a lever does any work on the Load? If it doesn't move at all then it cannot - but how does knowing that improve the sum total of human knowledge? A real fulcrum will deflect a bit so there is work done on it and then by it (if you really feel those concepts are of any consequence) as the forces are first applied and later removed.
 
  • #41
A.T. said:
If the road does negative work on the car then the road must gain energy and the car must lose it?
sophiecentaur said:
That happens in a skid - the road gets a bit warmer from the work done 'on' the surface material.
Let me pose the question quantitatively: Is the energy transferred from the car to the road, always equal to the negative work done on the car by the road?
 
  • #42
A.T. said:
Is the reverse also true? If the road does negative work on the car then the road must gain energy and the car must lose it?
Yes.
 
  • #43
sophiecentaur said:
But why is there this preoccupation about who does what? It's just another of these daft 'what really happens?' questions that are only there for entertainment.
You know that I despise such questions. This isn't a philosophical question, it is a question about the correct use of the model.

In our model energy is transferred through work and heat. That is a rule of the model. Any approach which violates the rules is not using the model correctly.
 
  • #44
DaleSpam said:
Yes.
What about the quantitative version: Is the energy transferred from the car to the road, always equal to the negative work done on the car by the road?
 
  • #45
DaleSpam said:
You know that I despise such questions. This isn't a philosophical question, it is a question about the correct use of the model.

In our model energy is transferred through work and heat. That is a rule of the model. Any approach which violates the rules is not using the model correctly.

I think that is too literal an interpretation of the question and you are getting inveigled into treating it as such. I see it precisely as a philosophical question (in as far as it assumes that it actually has meaning and can have an answer, within the gamut of the model). Imo, such questions are aimed at finding 'flaws' and loopholes in these basic models, rather than spotting where the model is being mis - applied. You can't apply the modhich is what you say here.
The only causal arrow that can be drawn is from engine to car motion. No energy comes from any other source and the 'by and to' ideas don't have to apply everywhere in the system. You may as well ask the same question about the bearings and chassis. Force is 'transmitted' through them but what has that to do with work?
 
  • #46
sophiecentaur said:
I think that is too literal an interpretation of the question and you are getting inveigled into treating it as such. I see it precisely as a philosophical question (in as far as it assumes that it actually has meaning and can have an answer, within the gamut of the model).
I am not sure what your position is. I am both too literal and too philosophical?

Work isn't a philosophical term. It is a defined term in the model. This isn't an "interpretation" question, it is simply identifying correct use of the model and its defined terms. If work is done then energy is transferred. If you make a calculation where work is done without energy transfer then the calculation is wrong. I don't know what about that you can possibly find objectionable.
 
  • #47
A.T. said:
What about the quantitative version: Is the energy transferred from the car to the road, always equal to the negative work done on the car by the road?
Yes (neglecting heat).

Heat can be important in slipping. Consider a car skidding to a stop. F.v is negative for the car so negative mechanical work is being done on the car and the mechanical energy decreases. F.v is zero for the Earth so there is no mechanical work being done on the Earth and the mechanical energy does not change. The quantitative difference in mechanical energy goes to heat.
 
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  • #48
DaleSpam said:
I am not sure what your position is. I am both too literal and too philosophical?

Work isn't a philosophical term. It is a defined term in the model. This isn't an "interpretation" question, it is simply identifying correct use of the model and its defined terms. If work is done then energy is transferred. If you make a calculation where work is done without energy transfer then the calculation is wrong. I don't know what about that you can possibly find objectionable.

They're not mutually exclusive, imo.
I am not finding anything "objectionable" - I am trying to dissuade you from getting tied up in something where your answer is bound to be in quadrature with the question, as I read it. It can only result in frustration for you.
Work is not a philosophical term, of course, because it is defined. But, insisting that every point in a machine has to have work done 'to or by ' something is philosophical.You seem to be trying to answer that philosophical (implied) question with reference to the 'model'.
We are not disagreeing about the model - or where it applies. I don't imagine you would feel it necessary to bring up the 'to or by' question, if it hadn't been slipped in under the radar.
 
  • #49
DaleSpam said:
Yes (neglecting heat).

Right. In a situation like braking, the breaks keep the wheels from turning, allowing the road to apply a force which slows down the car. The kinetic energy of the car is turned into heat in the break pads and wheels. The road still does no work though. Skidding is about the only time significant energy is lost to the road, I think. Other than normal heat losses from the tires, which we've ignored so far.
 
  • #50
Before sophiecentaur casts this discussion into the depths of argument for no reason, thanks to everyone for the replies. I learned something.
 
  • #51
A.T. said:
What about the quantitative version: Is the energy transferred from the car to the road, always equal to the negative work done on the car by the road?
No. It's a closed system, momentum is conserved, so the momentum change in the Earth is equal in magnitude but opposite in direction to the momentum change of the car. As mentioned earlier, since the Earth is so much more massive than the car, almost all of the energy from the engine goes into the car.
 
  • #52
rcgldr said:
No. It's a closed system, momentum is conserved, so the momentum change in the Earth is equal in magnitude but opposite in direction to the momentum change of the car. As mentioned earlier, since the Earth is so much more massive than the car, almost all of the energy from the engine goes into the car.

I think he was referencing the skidding scenario, in which negative work is done on the car and the road and tires are heated up.
 
  • #53
sophiecentaur said:
But, insisting that every point in a machine has to have work done 'to or by ' something is philosophical.
That is the model. In the model, energy conservation doesn't happen by energy just magically disappearing from one system and appearing at another. It is transferred from system to system via work and heat only. This isn't an optional part of the model.
 
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  • #54
BrainSalad said:
Right. In a situation like braking, the breaks keep the wheels from turning, allowing the road to apply a force which slows down the car. The kinetic energy of the car is turned into heat in the break pads and wheels. The road still does no work though.
This is a correct analysis. The road does not do work in this situation because the energy of the car is unchanged. The car loses KE and gains thermal energy at the brake pads and shoes. No energy is transferred.

BrainSalad said:
Skidding is about the only time significant energy is lost to the road, I think. Other than normal heat losses from the tires, which we've ignored so far.
I agree.
 
  • #55
DaleSpam said:
Consider a car skidding to a stop. F.v is negative for the car so negative mechanical work is being done on the car and the mechanical energy decreases. F.v is zero for the Earth so there is no mechanical work being done on the Earth and the mechanical energy does not change. The quantitative difference in mechanical energy goes to heat.

Right, so in respect to Newtons 3rd Law force pairs and work we we can say:

If kinetic energy is converted into other energy forms at the interface, then the positive work done by one force can be less than the negative work done by the other force.


What about the opposite situation?

If kinetic energy is generated from other energy forms at the interface, then the positive work done by one force can be more than the negative work done by the other force.


The later would apply to an accelerating car modeled as a single rigid body, with the propulsive system seen as part of the interface to the road. The force of the ground could do positive work on the car, despite the opposite force doing no negative work on the road. Note, that if you model the car as one translating body, then the force from the ground is not static any more. The "car" in the model is a sliding block. Just that the interface is not opposing the sliding, but propelling it.

I know that this sounds like a stretch, but the point of my question is to figure out how far you can abstract things, and still have a valid model. Is it permissible at all, to model a machine with moving parts as one rigid body, if those parts are interacting with other bodies?
 
  • #56
A.T. said:
I know that this sounds like a stretch, but the point of my question is to figure out how far you can abstract things, and still have a valid model. Is it permissible at all, to model a machine with moving parts as one rigid body, if those parts are interacting with other bodies?

I think that depends on how the parts are interacting and which model you apply. Newtons 1st and 2nd, for instance, are valid for extended bodies and systems of particles as long as the velocities and accelerations considered are those of the COM. Work, however cannot be done without the exchange of energy across the interface(s). But, sometimes we can pretend it's done by modeling an object as a point particle or something like that and using the work energy theorem for the COM.
 
  • #57
What a confusing thread. Let me start from the beginning.

BrainSalad said:
... Isn't it that only external forces may change the translational kinetic energy of an object?

If that were true, then how do hamster balls get around? I suppose you could say that gravity is the external force pulling on the hamster. But I don't think gravity pushed the hamster forward.

If so, and if the only external force does no work, how does the car's kinetic energy change?
The hamster moved.

Obviously, there is no problem with energy conservation here (the chemical potential energy in the oxygen/gasoline mixture in the engine is converted to kinetic energy in the wheels and body of the car). But doesn't this mean that the kinetic energy of a system may change without net work being done?

No. The hamster added potential energy to the system, and since he's in a sphere, the torque he created caused the sphere to rotate.

jbriggs444 said:
Points do not rotate.

They do if you model them as tidally locked geohubstationary tennis shoes.

pf.2014.01.25.9am.tidally.locked.tennis.shoes.jpg

I can quite obviously see that each point/tennis shoe is going to rotate once for each full orbit around the hub.

DaleSpam said:
A.T. said:
What about the quantitative version: Is the energy transferred from the car to the road, always equal to the negative work done on the car by the road?

Yes (neglecting heat).

Heat can be important in slipping. Consider a car skidding to a stop. F.v is negative for the car so negative mechanical work is being done on the car and the mechanical energy decreases. F.v is zero for the Earth so there is no mechanical work being done on the Earth and the mechanical energy does not change. The quantitative difference in mechanical energy goes to heat.

I don't quite understand this answer.

Although... I think I got it.

Your answer is "No, as heat balances the equation.".

Yes?

Although... hmmm...

Can a car accelerating be modeled as the null velocity point in an elastic collision problem?
 
  • #58
OmCheeto said:
If that were true, then how do hamster balls get around? I suppose you could say that gravity is the external force pulling on the hamster. But I don't think gravity pushed the hamster forward.
Are you saying that a hamster ball can start moving without there being an external force acting on it? Better rethink that one.
 
  • #59
Doc Al said:
OmCheeto said:
... I suppose you could say that gravity is the external force pulling on the hamster.
...
Are you saying that a hamster ball can start moving without there being an external force acting on it? Better rethink that one.

What? Where did I say that?
 
  • #60
Doc Al said:
Are you saying that a hamster ball can start moving without there being an external force acting on it? Better rethink that one.

This is the way I thought about it originally. It's net momentum can't change without an outside force, but that has no bearing on the kinetic energy. An bomb for instance, converts chemical energy into kinetic and heat energy, without outside forces. The net momentum of all its exploded pieces is the same as it was initially though. Kinetic energy also can't be added from outside sources without work being done. A car can move from rest as a single unit because it has an internal energy source and an external force acting on it, but that force does no work. If the car was in space, you push the gas and all the energy goes into wheel rotation. Add the ground and gravity and the car moves forward under the influence of an external force.
 
  • #61
OmCheeto said:
What? Where did I say that?
Right here:
OmCheeto said:
BrainSalad said:
... Isn't it that only external forces may change the translational kinetic energy of an object?

If that were true, then how do hamster balls get around?
 
  • #62
Doc Al said:
Right here:

Oh...

Umm...

It never crossed my mind that west coast, internally powered hamster balls:

Girl-in-Hamster-Suit-Runs-on-Water-in-Hamster-BallHamster.jpg

might be externally powered.

We call those:

elephant-on-ball.jpg

elephant balls.

My bad.
 
  • #63
OmCheeto said:
It never crossed my mind that west coast, internally powered hamster balls:

might be externally powered.
Just because the energy source is internal does not remove the need for an external force to accelerate.
 
  • #64
Doc Al said:
Just because the energy source is internal does not remove the need for an external force to accelerate.

Hmmm... My boss and I were discussing "mathematical word problems" the other day, and I showed him that internet meme about aliens, hats, and purple. It was inspired by this thread.

If you are Hercules, positioned between Earth and BrainSalads car, and pushed really hard, in equal and opposite directions, what happens?

If you removed gravity, the car would go one way, and the Earth would move the other way.

Mathematically, the resulting momentum of the car and Earth would have the same magnitude, but the kinetic energy would go almost exclusively to the car.

If you're not willing to ignore gravity, then model this as a "Car in Spaaaaaace...", mechanically linked, but free to move, via fancy gears and such, to the midpoint of a million kilometer long, 6E24 kg, roadway. Floor the accelerator pedal for about a second.

Where now is this "external force" that you require?

--------------------------------
ps. Everything I've learned about momentum and impulse, I've learned in the last two days.
 
  • #65
OmCheeto said:
Where now is this "external force" that you require?

--------------------------------
ps. Everything I've learned about momentum and impulse, I've learned in the last two days.

Taking the car to be the system, the external force is the static friction force of the road on the tires.

If you've really only learned about momentum the past two days, add to your knowledge that "external" and "internal" are relative terms. Any force exerted by an object outside the system in question, arbitrarily defined, is external. Thus, an external force is needed to change momentum (accelerate). Of course, if you change the size of the system, car+Earth for example, a previously external force may now be internal and cause no net change of momentum at all (Earth gains as much negative momentum as the car gains positive).
 
  • #66
BrainSalad said:
Taking the car to be the system...

I learned long ago, to ignore everything past the first wrong premise.
 
  • #67
OmCheeto said:
If you're not willing to ignore gravity, then model this as a "Car in Spaaaaaace...", mechanically linked, but free to move, via fancy gears and such, to the midpoint of a million kilometer long, 6E24 kg, roadway. Floor the accelerator pedal for about a second.

Where now is this "external force" that you require?
You're kidding, right?

For the car to accelerate, the road must exert an external force on it. Same for your hamster wheel.

--------------------------------
ps. Everything I've learned about momentum and impulse, I've learned in the last two days.
So it seems.
 
  • #68
OmCheeto said:
BrainSalad said:
Taking the car to be the system...

I learned long ago, to ignore everything past the first wrong premise.
I suggest that you reread this thread from the beginning.
 
  • #69
OmCheeto said:
I learned long ago, to ignore everything past the first wrong premise.

What's wrong with the premise? We can't take the whole universe as the object in question.

You don't have any real physics education, do you? Every force is an internal force if you define the system large enough, but that isn't helpful a lot of the time.
 
  • #70
rcgldr said:
I've often read here that static friction does no work.
That is true in the rest frame of the objects in contact. But when you model the entrie car as one translating block, then there is no rest frame of both objects: ground and car.

I know, in reality there is a wheel that has a contact point at rest. But when you do calculations in physics, you do them based on your model, not on reality. And if you apply the F*d definition of work here, then the external force is doing work, because it is not static in this particular coarse model of reality.
 

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