Tension Problem: Maximum Forces for Two Ropes Connected to a Body

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The discussion centers on the tension problem involving two ropes connected to a body, where rope A can resist a maximum force of 60 N and rope B can resist 50 N. It is established that if a downward force exceeding 50 N is applied to rope B, it will break first, regardless of the application speed. The mass of the body significantly influences the outcome; for instance, with a mass of 7 kg, rope A will break without any additional force. The analysis emphasizes the importance of understanding force transmission and the role of mass in determining which rope fails first.

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Homework Statement


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A body is connected at the middle with two different ropes as in the figure. The maximum force that rope A can resist is 60 N, and for rope B its 50 N. What will happen if someone apply a downward force at the loose end of rope B, a) gradually b) very fast

Homework Equations

The Attempt at a Solution


My opinion is: if the force is greater than 50N, rope B will tear for both cases. Nothing will happen to rope A.
 
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Assuming the diagram represents a vertical configuration, the mass of the body is relevant.
 
When the applied force is is gradual the tensions in both the strings have to be identical and equal to the applied force, if we neglect the mass of the body, as the body remains at rest in a permanent fashion. So as F increase it will reach 50 N first and then become 60 N so lower rope will break first. I am not able to think about the sudden application of force.
 
Last edited:
I think in second case also the lower rope will break first. if weight of the body cannot be neglected, then when you apply force even if suddenly the two tensions have to be equal but the lower rope may have less tension at any instant as in the beginning lower rope has zero tension and the tension is upper rope is equal to the weight of the body. So it is possible that at some instance above is 60 N and the lower one is below 50 N, in that case the upper rope will break.
 
PeroK said:
Assuming the diagram represents a vertical configuration, the mass of the body is relevant.
The mass was not given in the problem.
 
If the mass is 7kg, say, then the upper rope will break without any additional force being applied.

If it's 5kg, then the upper rope will break when the applied force reaches about 12N.
 
PeroK said:
If the mass is 7kg, say, then the upper rope will break without any additional force being applied.

If it's 5kg, then the upper rope will break when the applied force reaches about 12N.
Then I guess the mass is negligible.
 
arpon said:
Then I guess the mass is negligible.

Then you essentially have two ropes joined together and the lesser rope will always break first.

What about the case where the mass is 5kg and you apply a force of,say, 100N instantaneously?

How is the force transmitted to the upper rope?
 
PeroK said:
Then you essentially have two ropes joined together and the lesser rope will always break first.

What about the case where the mass is 5kg and you apply a force of,say, 100N instantaneously?

How is the force transmitted to the upper rope?
Won't rope B break?
 
  • #10
arpon said:
Won't rope B break?

That's what you have to work out. You need a free body diagram.
 
  • #11
PeroK said:
That's what you have to work out. You need a free body diagram.
I am confused about how the force will be transmitted.
 
  • #12
Hi arpon ,

In part b) , when the downward force is applied very fast , will the acceleration of the mass/body be large or small ?
 
  • #13
Vibhor said:
Hi arpon ,

In part b) , when the downward force is applied very fast , will the acceleration of the mass/body be large or small ?
Will the mass be accelarated? Won't the rope break if the force exceeds the limit of 50N?
 
  • #14
arpon said:
Will the mass be accelarated?

Won't a large sudden force try to accelerate the bottom rope ? Isn't rope connected to the mass ? Won't the string and rope have same acceleration till the time they are connected ?

arpon said:
Won't the rope break if the force exceeds the limit of 50N?

This is what we are trying to find .
 
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  • #15
arpon said:
I am confused about how the force will be transmitted.
It's perhaps not a good question. My thinking is:

1) the maximum tension in A is the tension in B plus ##mg##. If ##mg## is less than 10N then B must break first.

2) If ##mg## is greater than 10N then under a gradual increase in force, A must break first. But, under an instantaneous force it's not so clear what happens. If you assume that the system is rigid and the tension travels almost infinitely fast, then A will break.

Edit: Corrected A and B.
 
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  • #16
PeroK said:
It's perhaps not a good question. My thinking is:

1) the maximum tension in B is the tension in A plus ##mg##. If ##mg## is less than 10N then A must break first.

2) If ##mg## is greater than 10N then under a gradual increase in force, B must break first. But, under an instantaneous force it's not so clear what happens. If you assume that the system is rigid and the tension travels almost infinitely fast, then B will break.
12.png

I think the maximum tension in B is the tension in A minus ##mg##.
 
  • #17
arpon said:
View attachment 101953
I think the maximum tension in B is the tension in A minus ##mg##.
Yes, I got A and B mixed up!
 

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