A 1.0- kg mass is attached to a string wrapped around a shaft of negligible mass and having a 4.0- cm radius. A dumbbell-shaped "flywheel" made from two 0.500- kg masses is attached to one end of the shaft and perpendicular to its axis (see the figure). The mass is released from rest and allowed to fall 1.3 m to the floor. It reaches a speed of 1.4852 m/s just before striking the floor. How far apart are the masses of the dumbbell?

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### Figure 9.48: Simple Machine System In this diagram, we have a physical setup involving a rotational system with attached masses. The system consists of the following components: 1. **Rod System:** - Two small masses, each with a weight of \( m = 0.500 \, \text{kg} \), are attached to either end of a rod. - The length from the center of the rod to each mass is indicated as \( R \). 2. **Cylindrical Pulley:** - The rod is connected to a cylindrical pulley. - A string is wrapped around the pulley and extends vertically, with a second mass attached to its free end. 3. **Hanging Mass:** - At the loose end of the string, a larger mass \( m = 1.00 \, \text{kg} \) is suspended. This setup typically presents a rotational dynamics problem, where one might calculate the angular acceleration, tensions in the string, or forces acting on the masses. This figure would be part of a problem to demonstrate the principles of mechanics and dynamics, particularly focusing on rotational motion and the conservation of energy.