A string over a pulley, same tension?

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Homework Help Overview

The discussion revolves around understanding why the tension in a string remains the same on both sides of a pulley, given that the pulley has zero moment of inertia and negligible friction. The original poster is tasked with explaining this concept without specific numerical data.

Discussion Character

  • Conceptual clarification, Assumption checking

Approaches and Questions Raised

  • Participants suggest using Newton's Laws to analyze the forces acting on the string and the body attached to it. There is a focus on writing equations for different sections of the string to explore the tension. Some participants question the implications of friction and torque in relation to the pulley system.

Discussion Status

Participants are actively engaging with the problem, offering various perspectives on how to approach the explanation of tension in the string. Some have provided guidance on applying Newton's Laws, while others are exploring the implications of assumptions about friction and the pulley’s characteristics. No consensus has been reached yet, but the discussion is ongoing and productive.

Contextual Notes

There is a hint referencing a specific equation related to torque and angular acceleration, which participants are encouraged to consider in their reasoning. The original poster has expressed difficulty in articulating the explanation for the tension being the same, indicating a need for further clarification and exploration of the concepts involved.

Kate16
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Hi, I am new here!


1. There is no actually data given, I am just supposed to explain why a string that crosses a pulley have the same tension both sides. The pulleys moment of inertia is zero and friction is negligible.
There is a little hint in this problem that says; study equation 9-15, which is:"Στ=lα"

trissa snöre.jpg


The only thing I know here is that a pulley doesn't change the tension just the direction.

Need help, Thanks in advance.

Kate
 
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Hi! Try to imagine the situation when you attach one body (mass m) to both ends of a string hung up by a pulley. Describe this system from the point of view of dynamics (Newton's II. Law). Important thing to note: you can also write Newton's Laws for different cross-sections of the string. This will probably lead you to the answer. I hope I could help a little :)
 
Robin04 said:
Hi! Try to imagine the situation when you attach one body (mass m) to both ends of a string hung up by a pulley. Describe this system from the point of view of dynamics (Newton's II. Law). Important thing to note: you can also write Newton's Laws for different cross-sections of the string. This will probably lead you to the answer. I hope I could help a little :)

I still don't understand how I should explain why the tension must be the same?
thanks for the reply
 
Maybe my help was a bit complicated. Let's try a simpler problem. No pulleys yet. You attach one end of a rope to the ceiling and the other end to a body of let's say 5 kg. The force that is required to hold this (balance the gravitational force/weight) body will be the tension in the rope, because the rope is exerting this force. You can write Newton's II. Law for the body. Two forces: weight and tension. Their vectorial sum is the net force, and because the body is not moving that must be zero. To be able to prove that the tension is equal everywhere in the rope you have the consider a part of the rope as a different 'body" for which you can also write Newton's II. Law. Note: two forces again, net force zero. If you got this, try to apply this method for a system with a pulley.
 
Robin04 said:
Maybe my help was a bit complicated. Let's try a simpler problem. No pulleys yet. You attach one end of a rope to the ceiling and the other end to a body of let's say 5 kg. The force that is required to hold this (balance the gravitational force/weight) body will be the tension in the rope, because the rope is exerting this force. You can write Newton's II. Law for the body. Two forces: weight and tension. Their vectorial sum is the net force, and because the body is not moving that must be zero. To be able to prove that the tension is equal everywhere in the rope you have the consider a part of the rope as a different 'body" for which you can also write Newton's II. Law. Note: two forces again, net force zero. If you got this, try to apply this method for a system with a pulley.
So the tension in the string must be the same because? I've done the example you described it but I can't figure out a good way to explain it.
 
What did you get for the forces on a part of the rope?
 
Robin04 said:
What did you get for the forces on a part of the rope?
what do you mean by: "for the forces"?
 
Kate16 said:
what do you mean by: "for the forces"?
In order to prove that the tension in the rope is equal everywhere, you have to describe the forces acting on a cross section of the rope.
I think the best way I could help would be if you told be how did you attack this problem. How would you start?
 
Kate16 said:
1. There is no actually data given, I am just supposed to explain why a string that crosses a pulley have the same tension both sides. The pulleys moment of inertia is zero and friction is negligible.
There is a little hint in this problem that says; study equation 9-15, which is:"Στ=lα"

The only thing I know here is that a pulley doesn't change the tension just the direction.
Welcome to PF.
First, let me clarify one thing. When a problem regarding pulleys says ignore friction it generally means friction at the axle, not friction between pulley and rope. If there's no friction between pulley and rope you don't need it to be a pulley at all.
Answering this question in detail is a bit tricky. In principle, the tension could vary along the part of the rope in contact with the pulley. If we consider that made up of many short sections, each section could create a net torque, namely, the difference in the tensions at the ends of the section multiplied by the radius. The torque from the tension at one end of such a section cancels the torque from the tension at the adjoining end of the next section. So when these are all added up you are left with the two torques at the points where the straight rope sections meet the pulley.
Suppose thesewo tensions are different. What can you say about the net torque? What does the equation in your hint then tell you?
 

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