Circular Motion and Centripetal Force of a Swinging Bucket

AI Thread Summary
To determine the speed required for a 6.5 kg bucket of water to complete a vertical circle with a radius of 3.6 m without spilling, centripetal acceleration must be calculated. At the top of the swing, the normal force exerted by the bucket on the water is zero, meaning the gravitational force must equal the centripetal force needed to keep the water in the bucket. This leads to the equation mg = (mv²/r), where solving for v gives a speed of 5.94 m/s. The relationship between gravitational force and centripetal force is crucial for maintaining the water's position in the bucket. Understanding these forces is essential for solving problems related to circular motion.
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Homework Statement


You swing a 6.5 kg bucket of water in a vertical circle of radius 3.6 m.
What speed must the bucket have if it is to complete the circle without spilling any water?
mass=6.5 kg
r= 3.6

Homework Equations


ay=(v^(2)/(r))
may= A-N-Mg

The Attempt at a Solution


I know that the force of gravity on the water and the normal force of the bucket on the water both point down. I assume you need to get the centripetal acceleration first. But I do not know what the applied force is and have no way of knowing. What do I do?
 
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What would need to happen for the water to stay in the bucket? (something needs to equal something else)
 
the normal force and gravity must equal the applied force. But if that is the case, then ay is 0 and the problem is unsolvable.
 
You need to use centripetal acceleration (or a reaction against it), and acceleration of gravity for this one.
 
at the top of the path, the normal force the bucket exerts on the water is 0. therefore, applied force, which is equal to normal force, is 0. Thus mg=(m)(v2/r) solving for v gets 5.94 m/s.
 

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