What Forces Act on a Ball in Vertical Circular Motion?

AI Thread Summary
In vertical circular motion, a ball's net force at the top is the sum of tension and weight, with tension being twice the ball's weight. The centripetal force required for circular motion is provided by this tension, leading to the equation Mv^2/L = 3Mg, which helps determine the ball's speed at the top. When the string is cut, the ball becomes a projectile, and its time to reach the ground can be calculated using the equations of motion, considering the vertical drop. The horizontal distance traveled before hitting the ground can be derived from the initial tangential velocity and the time calculated. Understanding these forces and equations is crucial for solving problems related to vertical circular motion.
Mthees08
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Homework Statement


A ball if mass M attached to a string of length L moves in a circle in a vertical plane as shown above. At the the top of the circular path, the tension in the string is twice the weight of the ball. At the bottom, the ball just clears the ground. Air resistance is negligible. Express all answers in terms of M, L, and g
a) Determine the magnitude and direction of the net force on the ball at the top of the path
b) Determine the speed V(i) of the ball at the top
the string is now cut
c) Determine the time it takes the ball to reach the ground.
d) Determine the horizontal distance the ball travels before hitting the ground


Homework Equations


F=ma
W=mg
centripetal A=V(tangental)^2/r
d=rt
Vfinal=Vinitial+at




The Attempt at a Solution


a) i tried to set up an equilibrium of forces equation using tension and weight but got 0 points
b) i got 2 points i used the centripetal acceleration equation and get Vt=sqrt(MgL)
c)0 points... i really messed this up... I should have gotten this...
d) i used the d=rt but had the incorrect time so if i fix c (or someone explains it) then this is easy

PLEASE PLEASE PLEASE HELP
 
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Mthees08 said:
a) Determine the magnitude and direction of the net force on the ball at the top of the path

The net force is equal to the tension in the string.

Mthees08 said:
b) Determine the speed V(i) of the ball at the top

The tension in the string is the centripetal force. Since you know it, you can get the tangential velocity.

Mthees08 said:
c) Determine the time it takes the ball to reach the ground.

If the string is cut when the ball is at the top, then it's just a horizontal shot. You know that g=9.81 ms^{-2} and the distance that ball has to travel until it reaches the ground so you can get the time.

Mthees08 said:
d) Determine the horizontal distance the ball travels before hitting the ground

One more element of the horizontal shot. The starting velocity is the tangential velocity.
 
Last edited:
Dr. Jekyll said:
The net force is equal to the tension in the string.



The tension in the string is the centripetal force. Since you know it, you can get the tangential velocity.

Actually, at the top of the circle, the forces acting are the Tension,T, and the weight,W. The resultant of those 2 forces provides the centripetal force required to keep the object in a circle.

So that \frac{Mv^2}{L}=T+Mg and since T=2Mg,\frac{Mv^2}{L}= 3Mg
 
rock.freak667 said:
Actually, at the top of the circle, the forces acting are the Tension,T, and the weight,W. The resultant of those 2 forces provides the centripetal force required to keep the object in a circle.

Yes, that's right.
 

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