Kinematic Car Race: Which Car Will Win with and without Friction?

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Homework Help Overview

The discussion revolves around a kinematics problem involving two cars racing down a hill, with considerations for both friction and mass. The original poster presents a scenario where Car A and Car B start from the same height but have different masses, prompting questions about the effects of mass and friction on their race outcomes.

Discussion Character

  • Exploratory, Conceptual clarification, Assumption checking

Approaches and Questions Raised

  • Participants explore the implications of mass on the race outcomes, questioning whether mass affects the time taken to finish the race when friction is ignored. They discuss the equations of motion and the role of friction in determining the final velocities of the cars.

Discussion Status

Participants are actively engaging with the problem, examining the equations and their implications. There is a focus on whether mass can be canceled out in the equations and how friction impacts the energy dynamics of the cars. Multiple interpretations of the effects of mass and friction are being explored without a clear consensus.

Contextual Notes

Participants are considering the assumptions made in the problem, such as the effects of friction on different masses and the conditions under which the cars race. There is an ongoing examination of the equations provided and their relevance to the scenario described.

keemosabi
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Homework Statement


Two cars start 10 meters up a hill. Car A has a mass of 9 grams and Car B has a mass of 2 grams. Additionally, both cars must travel the same distance to the finish line.
a) If friction is ignored which car will win the race?
b) If friction is not ignored, which car will win the race.


Homework Equations


u + k = u + k


The Attempt at a Solution


a) Both cars will finish at the same time because at any point on the track, both cars will have equal velocities.
b) Car B will finish first because it is lighter, so it will have less of a friction force that will slow it down less. As a result, Car B will move faster and thus reach the finish line first.

Is this right?
 
Last edited:
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What do the equations say?

With friction or without what is the dependence on mass?
 
LowlyPion said:
What do the equations say?

With friction or without what is the dependence on mass?

With mgh = 1/2mv^2 the mass would cancel out, so is there so dependence on mass? This means the cars finish at the same time, right?

Would friction play any role, or no?
 
keemosabi said:
With mgh = 1/2mv^2 the mass would cancel out, so is there so dependence on mass? This means the cars finish at the same time, right?

Would friction play any role, or no?

Write out the equation for the case with friction.
 
LowlyPion said:
Write out the equation for the case with friction.
Is the first part correct?

Fnet = ma
uN = ma
n(mg)=ma
ng=a

So the mass is canceled out when friction is and is not ignored?
 
keemosabi said:
Is the first part correct?

Fnet = ma
uN = ma
n(mg)=ma
ng=a

So the mass is canceled out when friction is and is not ignored?

The mass canceled out in the first one, so yes it would have to be correct wouldn't it?

What happens in the case where you have

Potential at the top = kinetic at the bottom + work lost to friction ?
 
LowlyPion said:
The mass canceled out in the first one, so yes it would have to be correct wouldn't it?

What happens in the case where you have

Potential at the top = kinetic at the bottom + work lost to friction ?
Friction will do more work on the heavier car, so more energy will be lost. As a result, there will be less kinetic energy to contribute to the velocity of the heavier car than the lighter car.
 
keemosabi said:
Friction will do more work on the heavier car, so more energy will be lost. As a result, there will be less kinetic energy to contribute to the velocity of the heavier car than the lighter car.

What does the equation say?

m*g*h = 1/2*m*v2 - μ*m*g*cosθ*d
 
LowlyPion said:
What does the equation say?

m*g*h = 1/2*m*v2 - μ*m*g*cosθ*d
Can you cancel the mass out of each term?
 
  • #10
keemosabi said:
Can you cancel the mass out of each term?

That would be what it looks like to me.

And d must be the same according to the problem.
 

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