Conservation of energy/momentum in a pendulum?

AI Thread Summary
The discussion centers on a physics problem involving a pendulum and a block at rest. The bob's mass is 200g, and it swings from a height calculated to give it a speed of 2.4 m/s just before impact. Momentum conservation equations were used to find the velocities of both the bob and the block after the impact, yielding values of -1.6 m/s for the bob and 0.8 m/s for the block. The rebound angle of the bob can be determined by calculating how high it will rise after the impact, using its velocity at the bottom of the swing. The participants confirm the calculations and express satisfaction with the problem-solving process.
mattpd1
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Homework Statement


http://www.phy-astr.gsu.edu/Hsiao-Ling/quiz2211-F10.ppt"

You have a pendulum:
The bob's mass is 200g.
The string length is 1m.
The angle the bob is raised to is 45 degrees.

You also have a block that is at rest at the bottom of the pendulum's swing:
The block's mass is 1kg.
The block is at rest.
No friction.

What is the speed of the bob right before it makes impact with the block?
What is the velocity of the bob and block right after impact?
What is the maximum rebound angle of the bob after impact?



Homework Equations


Total energy of system = U + K
Initial momentum of the system = Final momentum of the system
Total initial energy = total final energy


The Attempt at a Solution


I think I have solved the first question:
By calculating the change in height of the bob, to be .293m, I found the potential energy to be .574 joules. The kinetic energy right before impact should also equal .574, therefore velocity = 2.4 m/s. So right before impact the bob's speed is 2.4 m/s, is this right?

For the second questions:
Initial momentum = final momentum
.48 = .2Vf(bob) + Vf(block)

This is as far as I can get. How can I solve these velocities individually, and how to I go about finding the rebound angle?
 
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I think I may have answered the second part too.

Vf(block)=.8 m/s
Vf(bob)= -1.6 m/s

Does this look right?
 
Welcome to Physics Forums :smile:
mattpd1 said:

The Attempt at a Solution


I think I have solved the first question:
By calculating the change in height of the bob, to be .293m, I found the potential energy to be .574 joules. The kinetic energy right before impact should also equal .574, therefore velocity = 2.4 m/s. So right before impact the bob's speed is 2.4 m/s, is this right?
Yes.
For the second questions:
Initial momentum = final momentum
.48 = .2Vf(bob) + Vf(block)

This is as far as I can get. How can I solve these velocities individually, and how to I go about finding the rebound angle?
Looks like you got the correct velocities below.

For rebound angle, you now have the "reverse" problem from before: when you knew the initial height of the bob, you were able to calculate it's velocity at the bottom of the swing. Now you know it's velocity at the bottom, so how high will it go in its upward swing?
mattpd1 said:
I think I may have answered the second part too.

Vf(block)=.8 m/s
Vf(bob)= -1.6 m/s

Does this look right?
Yes.
 
Got it, thank you much.
 

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