Solving Force in a Stretched Rope: Applying Hooke's Law

In summary, the problem is that you can't solve this problem with geometric similarity between the force and the deformation.
  • #1
Paul L
8
0
The problem:
See attachment for figure.
(1) A rope with a spring constant k is stretched by a force F.The length of the rope is l (including the deformation).
(2) A force mg is then applied at l/2 on the rope. This results in a height difference between the highest (and unchanged point) and the lowest point, h. The length between the endpoints where the force F is applied is still l.

Equations:
Hooke's law for springs: F=kx
Maybe something else? Cant see where and what though...

The question:
Set up an equation for the force F.


My attempts:
I've tried to solve this problem with geometric similarity between the force and the deformation, but obviously not correctly...


Applying in real life:
This is thought to be a model of a slack line set up. If you don't know what that is, do a search on flickr.com and you'll get the idea. Is it reasonable to expect that such thing will follow Hooke's law for springs? Is there any other theory that is better to use? Links?
 

Attachments

  • rope.GIF
    rope.GIF
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  • #2
F in the figure 1 is not equal to F in the figure 2.
F in the figure 2 can be found in terms of mg by using vector method.
New half length of the string can be found in terms of l/2 and h.
Using these values you can find F in figure 1.
 
  • #3
The F in figure 2 should be called S. If we call the new length of the rope (the hypotenuse) L, I get the following similarity: L/h = S/F
Then, with some algebra (see attachment), I get an equation I'm not sure what to do with.
 

Attachments

  • rope algebra.gif
    rope algebra.gif
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  • #4
L/h = S/F This is not correct. It should be L/(l/2) = S/F and h/L = mg/2S. Solve for F.
 
  • #5
I'm not sure if I'm following you, but I tried what you suggested (attachment once again) and ended up with this:

F=(mgl)/(4h)

I have a bit problems believing that's correct as it would mean that an inelastic rope (k -> infinity) will stretch and bend down equally much as a elastic rope when the same force is applied.
 

Attachments

  • rope algebra II.gif
    rope algebra II.gif
    1.4 KB · Views: 476
  • #6
For a perfecly elestic body k -> infinity and for a perfectly inelastic body k->0. If you replace the rope by a steel rod and apply the force mg at the mid point, the depression of the mid point is very small.
 
  • #7
rl.bhat said:
For a perfecly elestic body k -> infinity and for a perfectly inelastic body k->0. If you replace the rope by a steel rod and apply the force mg at the mid point, the depression of the mid point is very small.

For a perfectly inelastic body k -> infinity. Hooke's law gives x = F/k and F/k -> 0 when k -> infinity. For a perfectly inelastic body, x = 0 for any given force F.

If the rope is replaced with a steel rod this would be a completely different problem as a rod can absorb torque and a rope cannot. However if you replace the rope with a steel wire, the depression would indeed be very small. That's why the equation F=(mgl)/(4h) can't be correct as it doesn't take this into account.

I still haven't figured out this problem, so any help would be highly appreciated.
 
  • #8
Young's modulus of elesticity is given by Y = Stress / strain = (F/A)/(x/L) where F is the stretching force, A is the area of cross section, x is th elongation and L is the original length. So F = [(y*A)/L]*x or F = k*x So for a given deforming force F, when K...> infinity x...> zero. When you apply froce S, x increases.( since k remains constant) And hence the depression of the mid point h increases. Steel is more elestric than rubber, because for an applied force elongation in steel wire is very small compared to that in rubber.
 
  • #9
rl.bhat said:
Steel is more elestric than rubber, because for an applied force elongation in steel wire is very small compared to that in rubber.

And therefore should the material constant k be included in the equation when the depression (and hence the elongation) is given. The equation F=(mgl)/(4h) must be wrong since it doesn't include the material constant.
 
  • #10
Welcome to PF!

Hi Paul! Welcome to PF! :smile:

What a mess everyone is making! :rolleyes:

This is a perfectly simple force diagram question …

it's a rope, so the only force in it is the tension …

you can work out the tension from the length, or vice versa

and the tension is the same at each end …

and you know the angle …

so … ? :smile:
 

FAQ: Solving Force in a Stretched Rope: Applying Hooke's Law

What is Hooke's Law?

Hooke's Law is a principle in physics that states that the force required to stretch or compress a spring is directly proportional to the distance the spring is stretched or compressed. It is named after the scientist Robert Hooke, who first proposed this relationship in the 17th century.

How do you solve for force in a stretched rope using Hooke's Law?

To solve for force in a stretched rope using Hooke's Law, you need to know the spring constant (k) of the rope and the distance it has been stretched (x). The formula for force (F) is F = kx. Simply plug in the values for k and x and solve for F.

What is the spring constant and how is it determined?

The spring constant (k) is a measure of the stiffness of the rope and is determined by the material and physical properties of the rope. It is typically measured in units of force per unit distance, such as Newtons per meter (N/m). The spring constant can be determined experimentally by measuring the force required to stretch the rope a certain distance.

Can Hooke's Law be applied to other materials besides ropes?

Yes, Hooke's Law can be applied to any elastic material, such as rubber bands, springs, and even some types of metals. The key is that the material must exhibit elastic behavior, meaning it can return to its original shape after being stretched or compressed.

What are some real-world applications of Hooke's Law?

Hooke's Law has many practical applications, such as in the design of springs for various mechanical devices, measuring the elasticity of materials, and even in medical devices such as orthodontic braces. It is also used in engineering and construction to determine the force and stress on structures, such as bridges and buildings.

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