Finding the Mass of a Hanging Rope (Wave Problem)

AI Thread Summary
The discussion focuses on solving a physics problem involving a wave pulse traveling up a hanging rope with a mass at the end. The key points include the need to establish the relationship between tension, mass, and wave velocity, considering the changing restoring force as the wave travels. The tension at any point on the rope is influenced by both the weight of the box and the weight of the rope itself. Participants emphasize the importance of correctly formulating equations to relate the wave's speed to the mass per unit length of the rope. Ultimately, understanding the tension dynamics is crucial for finding the mass of the rope.
Chansudesu
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Homework Statement


"...you were presented with a geologist at the bottom of a mineshaft next to a box suspended from a vertical rope. The geologist sent signals to his colleague at the top by initiating a wave pulse at the bottom of the rope that would travel to the top of the rope. The mass of the box is 20.0 kg and the length of the rope is 80.0 m. If a wave pulse initiated by the geologist takes 1.26 s to travel up the rope to his colleague at the top, find the mass of the rope."

mBox = 20.0kg

L = 80.0m

T = 1.26

Homework Equations


v = √(F/μ)

∑F = ma

v = λƒ

The Attempt at a Solution


I'm still trying to figure out how to approach the problem (set up my equations)...

I know that because the rope hangs vertical, the restoring force (weight UNDER a given point) is changing as the wave travels upwards, thus, the velocity is changing as well. So

dv = √(dFRestoring/μ)

and then we need to find the restoring force:

∑F = T - mBoxg - mRopeg = 0 (because it's in equilibrium in the y-direction)

T = mBoxg + mRopeg

At the beginning, the restoring force is only the weight of the box; and at the end, the restoring force is the weight of the box AND the weight of the rope. So

dFRestoring = dT = wBox + (dmRope)g

And then I tried turning μ = m/L into:

μ = dm/dL -> dm = μdL

but this doesn't get me anywhere.. I do not know what μ is equal to since we don't know the weight and when I put the equations together I get

dv = √[(wBox + μdL)/μ] -> dv = √[L(wBox + μdL)/ m]

I'm kinda stuck here and I don't think it's in the right direction because I haven't figured out why I was given the period...

Any help would be appreciated ^^
 
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You have one equation that relates ##\dot y## to ##F##. You can easily write one relating ##y## to ##F##, and you have almost done so, but this equation is incorrect:
Chansudesu said:
dFRestoring = dT = wBox + (dmRope)g
Pick a point ##y## on the rope. What is the tension on the rope at that point?
When you get that figured out, you can eliminate the restoring force from the two equations and solve the resulting differential equation for the time the wave takes to travel up the rope.
 
tnich said:
You have one equation that relates ##\dot y## to ##F##. You can easily write one relating ##y## to ##F##, and you have almost done so, but this equation is incorrect:

Pick a point ##y## on the rope. What is the tension on the rope at that point?
When you get that figured out, you can eliminate the restoring force from the two equations and solve the resulting differential equation for the time the wave takes to travel up the rope.

Hmm... I can't see the tension in a rope at point y being other than Ty = mBoxg + μyg because the the mass at a point y in the rope would be the mass linear density times y...
 
Chansudesu said:
Hmm... I can't see the tension in a rope at point y being other than Ty = mBoxg + μyg because the the mass at a point y in the rope would be the mass linear density times y...
Sounds right to me.
 
Ahhhh! I see now. Thank you!
 

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