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A bucket for collecting water from a well is suspended by a rope which is wound around a pulley. The empty bucket has a mass of 2.0 kg, and the pulley is essentially a uniform cylinder of mass 3.0 kg on a frictionless axle. Suppose a person drops the bucket (from rest) into the well.

Part A

What is the bucket's acceleration as it falls?

Solution

We will consider two different methods to obtain the solution.

Systems:

The pulley and the bucket are treated as separate objects. The bucket can be treated as a point particle, but the pulley must be treated as a rigid body.

Interactions:

The pulley and the bucket are each subject to external influences from the rope and from gravitation. The pulley is also subject to a force from the axle.

Model:

Single-Axis Rotation of a Rigid Body and Point Particle Dynamics

Approach:

Interactions:

The system is subject to external forces from the earth acting on the bucket and the pulley (gravity) and from the axle acting on the pulley (contact force). If we choose the axis of rotation to coincide with the axle of the pulley, then the axle's force and gravity acting on the pulley each produce no torque. We need only consider the effects of gravity acting on the bucket.

Model:

1-D Angular Momentum and Torque

Approach:

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Part B

What is the bucket's speed after falling 5.0 m down the well?

Solution

Again, we will use two methods.

Method 1

System:

Bucket as point particle.

Interactins:

External influences from the earth (gravity) and the rope (tension).

Model:

One-Dimensional Motion with Constant Acceleration.

Approach:

Method 2

System:

Treat the bucket, pulley and the earth as a single system.

Interactions:

Internal interactions of gravity (conservative) and tension from the rope (non-conservative) plus an external influence from the normal force on the pulley (non-conservative).

Model:

Mechanical Energy and Non-Conservative Work.

Approach:

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