Does Mass Affect Friction in a Pulley System?

AI Thread Summary
In a pulley system, the force of friction is influenced by the mass of the puck and the block. As the mass of the puck increases, the frictional force adjusts to match the weight of the puck until reaching the limiting friction point, at which equilibrium is maintained. If the mass of the block on the table increases while the mass of the hanging object remains constant, the friction force remains constant as long as the puck's mass is less than the block's mass. Conversely, if the mass of the hanging object increases while the block's mass stays constant, the friction will increase until limiting friction is reached, after which the block will accelerate. Understanding these dynamics is crucial for analyzing the behavior of friction in pulley systems.
tnutty
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Imagine a pulley system, where a puck is connected by a massless string to a massless pulley that joins a mass m that's hanging at the end of the table.

Would the force of friction change as you increase mass m , the object that's hanging? why so?
 
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tnutty said:
Imagine a pulley system, where a puck is connected by a massless string to a massless pulley that joins a mass m that's hanging at the end of the table.

Would the force of friction change as you increase mass m , the object that's hanging? why so?

Didn't quite understand what you meant by mass m 'hanging' at the end of the table.
Is it something like this?

th_untitled4.jpg


The mass m on the table and the puck hanging?
 
Or is it just the other way, the puck on the table and the mass hanging?
 
exactly. So I have a question. Would the force of friction increase as the block that's on the table, mass increases?
 
tnutty said:
exactly. So I have a question. Would the force of friction increase as the block that's on the table, mass increases?
That depends on the mass of the puck. We're talking about static friction here, which is a self-adjusting force. The frictional force acting on the block depends on mass of the puck.
 
If the mass of the puck was gradually increasing, then what would happen to the friction.
 
Its like this. You go on increasing the mass of the puck. the weight of the puck increases accordingly. The friction between the block adjusts itself to a value that equals the weight of the puck UNTIL the point of limiting friction (max. value of static friction). The mass of the puck at this point is the greatest mass it can have for the system to be in equilibrium. If you increase the mass of the puck slightly, there is a net acceleration.
Let the mass of block and puck be M and m
Writing equations, mg - T = 0 and T - f =0 (If you consider the acceleration of both the bodies to be zero)
We get, mg = f.
Mass of the puck is proportional to the frictional force on the block. Hope this makes things clear..
 
So what if the mass of the hanger was constant and the mass of the block was constantly increasing, what would happen to friction?

would it stay constant because the tension that the rope is providing is constant.
 
tnutty said:
So what if the mass of the hanger was constant and the mass of the block was constantly increasing, what would happen to friction?

would it stay constant because the tension that the rope is providing is constant.

Yea, exactly. You can go on increasing the mass of the block but the friction force remains constant.
 
  • #10
All this, provided..the mass of the puck < mass of the block. Unless, this condition is satisfied there will be a net acceleration and friction will be different.
 
  • #11
and if the block had a constant mass and the hanger had a gradually increasing mass the force of friction would increase up until a point?
 
  • #12
tnutty said:
and if the block had a constant mass and the hanger had a gradually increasing mass the force of friction would increase up until a point?

Yes, it would increase till limiting friction is experienced by the block. Further increase would lead to the block accelerating to the right.
 
  • #13
thanks for making it clear
 

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