Why Does Tcos(20) Equal umg in a Sledge Problem?

In summary, the conversation is about a problem involving a sledge loaded with bricks being pulled at a constant speed by a rope on a horizontal surface. The coefficient of kinetic friction is known, and the question is to find the tension of the rope. The person asking for help initially thought the forces in the x-direction were Tcos0 - f, but then realized that the forces in the y-direction also needed to be taken into account. They were able to set up the equations for both the x-direction and y-direction forces, but were unsure of how to solve them simultaneously. After receiving some help, they were able to solve for T = 79.46, but the given solution was incorrect.
  • #1
unnamedplayer
6
0
Hi all, I was hoping for a little help with this problem. I already have the solution but I don't understand how they got the answer. The question is:

A sledge loaded with bricks has a total mass of 18.0 kg and is pulled at constant speed by a rope. The rope is inclined at 20.0° above the horizontal, and the sledge moves a distance of 20.0 m on a horizontal surface. The coefficient of kinetic friction between the sledge and the surface is 0.500. (a) What is the tension of the rope?

Now I originally thought that the forces in the x direction were: Tcos0 - f (where f = kinetic friction) Therefore, I thought I need to find f by first finding the normal force and then multiplying by the coeff. of kinetic friction. To do this I thought the forces in the y direction were: n + Tsin0 - mg = 0.

This made it a problem solving for n - the normal force. So I looked at the solution and it show they found the tension by saying:

Tcos(20) = umg (where u = coeff of kinetic friction)

That is what I don't understand. How can Tcos(20) = umg? That would mean the normal force is equal to mg which I don't understand how because shouldn't it be less because the rope is kinda of pulling it in that direction too (ie the Tsin(20) portion of the y-direction forces).

Any way I'm sorry for the long post but any help is greatly appreciated!
 
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  • #2
normal reaction plus the compoment of the tension in the virtical should equal mg
i think this may involve a simultaneous equation
 
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  • #3
normal reaction plus the compoment of the tension in the virtical should equal mg

Yes that is what I got. In the vertical direction I came up with n + Tsin20 - mg = 0 so n + Tsin20 = mg or n = mg - Tsin20. But then I can't find the normal force because I don't know T.

But the solution just shows Tcos20 = umg (again u = coeff of kinetic friction)
Which I can't seem to be able to understand why.
 
  • #4
unnamedplayer said:
Yes that is what I got. In the vertical direction I came up with n + Tsin20 - mg = 0 so n + Tsin20 = mg or n = mg - Tsin20. But then I can't find the normal force because I don't know T.
Your equation for vertical forces is correct, but what about horizontal forces? Write the equation for horizontal forces (expressing the friction in terms of normal force) and combine it with this one. You'll have two equations and two unknowns. Solve them simultaneously.
But the solution just shows Tcos20 = umg (again u = coeff of kinetic friction)
Which I can't seem to be able to understand why.
The solution given is wrong; your equations are correct.
 
  • #5
unnamedplayer said:
...How can Tcos(20) = umg? ...
It doesn't. Thar's wrong!
unnamedplayer said:
...
Now I originally thought that the forces in the x direction were: Tcos0 - f (where f = kinetic friction) ...
That's right.
But they are the only forces and since the sled is moving with constant velocity, then the net force is zero. i.e. Tcos20 - f = 0.
unnamedplayer said:
...I thought the forces in the y direction were: n + Tsin0 - mg = 0...
That's right too.
I assume that where you have Tcos0 and Tsin0, they should be Tcos20 and Tsin20.
 
  • #6
Hi again all. Thank you for all the help! I'll have to have a talking with my TA. I thought I was going crazy for a little bit there :-p

Now forgive me but as you've probably notice I'm not really good at this stuff but this is how I proceeded. I made n = mg - Tsin20. My equation for the x-direction was Tcos20 - un so I plugged in n and got Tcos20 - u(mg-Tsin20) and went farther making it Tcos20 - 0.5mg + 0.5Tsin20 = 0 and solved for T getting T = 79.46. That doesn't match what's given in the solution I have but since the procedure was wrong in that I'm assuming the tension they came up with is also wrong. So I'm wondering if that sounds right or do I have to combine some equations (I'm not really sure which ones I'd have to combine that's why I tried doing it like this first). Any way thanks again for all the help!
 
  • #7
Is that the problem statement? i suspect there's more to it than that.
 
  • #8
unnamedplayer said:
I made n = mg - Tsin20. My equation for the x-direction was Tcos20 - un so I plugged in n and got Tcos20 - u(mg-Tsin20) and went farther making it Tcos20 - 0.5mg + 0.5Tsin20 = 0 and solved for T getting T = 79.46. That doesn't match what's given in the solution I have but since the procedure was wrong in that I'm assuming the tension they came up with is also wrong. So I'm wondering if that sounds right or do I have to combine some equations (I'm not really sure which ones I'd have to combine that's why I tried doing it like this first). Any way thanks again for all the help!
Looks good to me. (Of course it won't match the incorrect solution given.)
 

FAQ: Why Does Tcos(20) Equal umg in a Sledge Problem?

What is tension in a rope?

Tension in a rope is the force that is applied to the rope when it is stretched or pulled. It is the opposite force to the force that is pulling on the rope, and is what keeps the rope taut.

How is tension measured in a rope?

Tension in a rope is typically measured in units of force, such as newtons or pounds. This can be done using a tension gauge or a load cell, which measures the amount of force being applied to the rope.

What factors affect tension in a rope?

The tension in a rope can be affected by several factors, including the weight of the object being pulled, the angle at which the rope is being pulled, and the strength and elasticity of the rope itself.

How does tension affect the strength of a rope?

Excessive tension can cause a rope to break or weaken over time, especially if the rope is not designed to handle high levels of tension. It is important to use the right type of rope for the amount of tension it will be subjected to, and to regularly check and replace worn or damaged ropes.

What are some practical applications of understanding tension in a rope?

Understanding tension in a rope is important for a variety of practical applications. For example, it is crucial in rock climbing and sailing to ensure that ropes are properly tensioned to support the weight of a climber or sail. It also plays a role in engineering and construction, where ropes may be used to support structures or lift heavy objects.

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