Determining Tension in Uniform Steel Cable

In summary, the problem involves a uniform steel cable suspended between two points at equal elevation. The tension in the cable is different at its lowest point and at the points of attachment, with the tension at the points of attachment being greater. This is due to the fact that the vertical component of tension must support the weight of the cable below that point, and the points of attachment have more cable to support. The shape of the cable is a form of the cosh function, and at any point, the tension must support both horizontal and vertical forces. The tension is not constant throughout the rope, as it varies along its length. The "massless rope" approximation is often used in simpler problems, but in this case, the cable's weight
  • #1
e(ho0n3
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A uniform steel cable of weight mg is suspended between two equal elevation points. Determine the tension in the cable (a) at its lowest point, and (b) the points of attachment.

Judging from the problem, it seems that the tension in (a) and (b) is different. Is this necessarily so? If it is, why? Do I have to calculate the tensions to determine this?
 
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  • #2
e(ho0n3 said:
Judging from the problem, it seems that the tension in (a) and (b) is different. Is this necessarily so? If it is, why? Do I have to calculate the tensions to determine this?
Think about it. At any point, the vertical component of tension must support the weight of the cable below that point. So, which point has more cable to support?
 
  • #3
Catenary

luckilly they did not ask to prove it's shape. This is not difficult if you remember that for the system as a whole the horizontal forces will equal zero and the same for vertical, start with the fact that the weight ( downward force) must be matched by the suspension. Then think of the fact that at the lowest point there can be no vertical forces.
Ray.
 
  • #4
Doc Al said:
Think about it. At any point, the vertical component of tension must support the weight of the cable below that point. So, which point has more cable to support?
Are you saying then that the tension at the points of attachment is greater than the tension at the lowest point of the cable? I just find it difficult to digest that a rope in equilibrium can have varying tensions at different points.
 
  • #5
rayjohn01 said:
This is not difficult if you remember that for the system as a whole the horizontal forces will equal zero and the same for vertical, start with the fact that the weight ( downward force) must be matched by the suspension. Then think of the fact that at the lowest point there can be no vertical forces.
I figured this already. However, if there are no vertical forces on the lowest point of the rope, then the tension is purely horizontal. So at this point, there is a tension vector pointing to the left, and another to the right. These two cancel. I don't know how to proceed. The shape of the rope looks like a graph of cosh by the way.
 
  • #6
not sure

to e -- yes they cancel but they are also equal to two OTHER horizontal forces if you can find them.
The shape is a ( form of ) cosh function ( can't remember precisely ) it took a long time ( centuaries ago) to distinguish it from eliptical.
Don't listen to much to me I also get confused by mechanical problems , but ( and I'm thinking allowed) if all points are at equilibrium and there is no motion it seems that at any slice through the cable the vertical forces and the horizontal forces must each cancel. The rope or chain tension is the vector sum of these and of course the angle changes throughout the rope.
Another point you did not state any dimensions but if I attempt to pull the rope through one of the suspension points so as to reduce it's sag ( especially close to zero) the tension must head towards infinity , which suggests you must account for rope length compared to suspension separation -- that sounds like a nice calculus problem to me.
 
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  • #7
tension varies along that rope!

e(ho0n3 said:
Are you saying then that the tension at the points of attachment is greater than the tension at the lowest point of the cable?
Absolutely!
I just find it difficult to digest that a rope in equilibrium can have varying tensions at different points.
That's because you are probably used to problems that allow the "massless rope" approximation. A section of massless rope will have the same tension throughout.

Imagine a heavy chain hanging from the ceiling. It's certainly in equilibrium. Take the chain as a whole: the tension at the top must equal the weight of the entire chain. Now just look at the bottom half of the chain: the tension at the half-way point is the only upward force on that bottom section of chain--that tension must therefore equal the weight of half the chain.

Meditate on this long enough and it will become obvious.
 
  • #8
tension cancels? What does that mean?

e(ho0n3 said:
I figured this already. However, if there are no vertical forces on the lowest point of the rope, then the tension is purely horizontal.
Right. At the lowest point, the force produced by the rope's tension is horizontal.
So at this point, there is a tension vector pointing to the left, and another to the right. These two cancel.
I don't know what you mean by "cancel". At any point the tension in the rope pulls on on both sides of the rope at that point. These forces don't "cancel", since they act on different sections of rope.
I don't know how to proceed. The shape of the rope looks like a graph of cosh by the way.
If you can figure out the angle that the rope makes at the attachment points, then you can figure out the horizontal and and vertical components of the force on the rope at that point. Apply equilibrium constraints.
 
  • #9
Doc Al said:
That's because you are probably used to problems that allow the "massless rope" approximation. A section of massless rope will have the same tension throughout.
Yes indeed.

Imagine a heavy chain hanging from the ceiling. It's certainly in equilibrium. Take the chain as a whole: the tension at the top must equal the weight of the entire chain. Now just look at the bottom half of the chain: the tension at the half-way point is the only upward force on that bottom section of chain--that tension must therefore equal the weight of half the chain.
OK, I'm convinced.

I don't know what you mean by "cancel". At any point the tension in the rope pulls on on both sides of the rope at that point. These forces don't "cancel", since they act on different sections of rope.
Let T be the tension. What is the sum of the forces in the horizontal direction at the lowest point on the rope? Wouldn't that be T - T = 0 (this is what I mean by "cancel")?

If you can figure out the angle that the rope makes at the attachment points, then you can figure out the horizontal and and vertical components of the force on the rope at that point. Apply equilibrium constraints.
I'm given the angle already, but I can only figure out the tension at the points of attachment (since they don't "cancel" each other).
 
  • #10
e(ho0n3 said:
Let T be the tension. What is the sum of the forces in the horizontal direction at the lowest point on the rope? Wouldn't that be T - T = 0 (this is what I mean by "cancel")?
The sum of the forces on what? The 0-length piece of rope exactly in the middle? :smile: By your logic, tension always cancels out--since the same logic applies anywhere on the rope.
I'm given the angle already, but I can only figure out the tension at the points of attachment (since they don't "cancel" each other).
It's easy to show that the horizontal component of the tension force is the same throughout the rope. For example, analyze the right half of the rope: the tension at the bottom pulling left must balance the tension at the attachment pulling right (which is the horizontal component of the tension at the attachment).

If you're given the angle, it's a breeze.
 
  • #11
Doc Al said:
It's easy to show that the horizontal component of the tension force is the same throughout the rope.
Excellent point. This never came to mind. I guess that does it for this problem. Thanks.
 

FAQ: Determining Tension in Uniform Steel Cable

What is tension and why is it important to determine in a uniform steel cable?

Tension is the amount of force or stress applied to an object, in this case a uniform steel cable. It is important to determine tension in a cable because it affects the cable's strength, durability, and ability to withstand external forces.

How is tension measured in a uniform steel cable?

Tension can be measured through a variety of methods, such as using a dynamometer or a strain gauge. These devices measure the amount of force or stress applied to the cable and provide a numerical value for tension.

What factors affect the tension in a uniform steel cable?

The tension in a uniform steel cable can be affected by several factors, including the weight of the cable itself, the weight of any objects or loads attached to the cable, the angle at which the cable is suspended, and any external forces or impacts on the cable.

How does the material and diameter of a steel cable impact its tension?

The material and diameter of a steel cable play a crucial role in determining its tension. A thicker cable or a cable made of stronger materials will be able to handle more tension before breaking or deforming. Additionally, a cable with a larger diameter will have a higher weight capacity and can withstand more external forces.

What are some common techniques for determining tension in a uniform steel cable?

Some common techniques for determining tension in a uniform steel cable include using a tension meter, applying mathematical equations such as Hooke's Law, and conducting physical tests such as a pull test or a break test. It is important to choose the appropriate method based on the specific circumstances and requirements of the cable in question.

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