Length of a massive elastic string hung by it's end

AI Thread Summary
The discussion focuses on determining the new length L' of a homogeneous elastic string hung by one end in a gravitational field, utilizing Hooke's law. Participants explore the equilibrium condition where total potential energy is minimized, addressing the non-uniform stretching of the string. They discuss the tension distribution along the string and how to incorporate the string's mass into the calculations. The conclusion reached is that the new length can be expressed as L' = L + Mg/2k, reflecting the balance between gravitational and elastic forces. Overall, the thread emphasizes the application of Hooke's law in a context where the string's mass affects its stretching.
Heirot
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Homework Statement



Given a homogenous string of mass M, length L and elasticity k, find the length L' when it's hung by one end in a constant gravity field.

Homework Equations



Hooke's law.

The Attempt at a Solution



I don't know how to apply Hooke's law in this situation. Please help.
Thanks
 
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Hi Heirot! :smile:

It will be in equilibrium when its total potential energy (gravitational plus spring) is a minimum. :wink:

(can you see why?)
 
Yes, I can see that :) I just don't know what to minimize mathematically because the streching won't be uniform.
 
Heirot said:
… the streching won't be uniform.

Yes it will …

consider a small section of spring from rest-length x to x + dx …

the external forces on it are T(x + dx) and -T(x) and Mgdx/L, so … ? :smile:
 
So dT = - Mg/L dx -> T(x) = Mg/L (L-x) if x is measured form the top. But this we already knew. How does this help in calculating the streaching?
 
Now use Hooke's law
 
But spring constant k is a global property of the string, not local. Recall that if we cut the string in half, the new constant is 2k, not k. So, what would be the string constant for an infinitesimal part of the string?
 
Do it for the (L-x) part of the spring
 
Well, all below x, we can replace by an external force Mg (L-x)/L. If the upper part of the string were massless, we would have Mg(L-x)/L= k L/x s, where s is the displacement. I can't figure out how to include the mass of the string.
 
  • #10
I'm confused … where does Hooke's law (which is only concerned with internal tension) come into that? …

and what does the mass have to do with it? :confused:
 
  • #11
Can you please show me your solution so that I can precisely tell you where I think the problem lies?
 
  • #12
After having thought about it for a week, still not being able to solve it, I was thinking about your approach. Would you say that L' = L + Mg/k?
 
Last edited:
  • #13
Yup! … gravitational force = elastic force (so net force = 0) … Mg = (L' - L)k. :smile:
 
  • #14
It just occurred to me now, if we divide the unstreched length L into equal parts of length dx then the spring constant for that part is k'=kL/dx. On the other hand, a change in the length dl(x) of dx at some point x is dl(x) = F(x)/k'. Integration gives L' = L + Mg/2k as is pretty much expected.

Thanks for your help, tiny-tim :)
 

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