Combined linear and rotational motion question

AI Thread Summary
A small solid disk rolls on a circular track, and the problem involves calculating the force it exerts on the track when it reaches the top. To find the velocity at the top, conservation of energy is suggested, with the equation mg(h-2r) = 1/2mv^2 being a key point of discussion. The centripetal force at the top is considered, with some confusion about whether it approaches zero. The importance of including both translational and rotational kinetic energy in the calculations is emphasized. Overall, the discussion revolves around applying conservation laws to solve the problem effectively.
Dtbennett
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Homework Statement



A small solid disk (r<<R), mass m = 9.3 g, rolls on its edge without skidding on the track shown, which has a circular section with radius R = 9.7 cm. The initial height of the disk above the bottom of the track is h = 30.8 cm. When the ball reaches the top of the circular region, what is the magnitude of the force it exerts on the track? (Hint: how fast is it going then?)

Homework Equations



I = 1/2MR^2

F(centripetal) = (mv^2)/r

The Attempt at a Solution



So I'm pretty sure you have to first calculate the velocity of the disk as it enters the circular part. However, I'm confused as to how as we are not provided with a time. Can you assume it is 1 second?

Then the net force must equal the centripetal force at the top of the loop, which will probably be close to zero.
And the speed of the object must match the centripetal force provided by gravity.

so making the centripital force equal to mg gives you

v= sqrt(rg)

I've gotten this far, but I have no idea where to go from here. Please help!
 

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Dtbennett said:
So I'm pretty sure you have to first calculate the velocity of the disk as it enters the circular part.

You can, but why do you need to? You need the velocity at the top of the circular track, not at its bottom.

Then the net force must equal the centripetal force at the top of the loop, which will probably be close to zero.

This assumption is not based anything substantial, and so best avoided.

And the speed of the object must match the centripetal force provided by gravity.

Then you can already answer the question in the problem: zero. Does that look right to you?
 
Use a conservation law.
 
this problem is really tricky, I am having many problems trying to solve it
 
Last edited:
Hi,
what I did was saying that mg(h-2r)=1/2mv^2 at the top of the circle. would this be correct?
 
Gianf said:
Hi,
what I did was saying that mg(h-2r)=1/2mv^2 at the top of the circle. would this be correct?
Yes.
 
Since ##r## is taken into account for potential energy, perhaps the kinetic energy due to rotation should also be taken into account?
 

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