A bicycle wheel has a mass of 1.0 kg, a radius of 0.35 m, and a rotational inertia of 0.1225 kg-m². The wheel is spun up to a rotational velocity of 6 radians per second and then placed on the ground and released, allowing it to roll away. Assuming no energy is lost to internal energy in this process, draw an energy bar chart for this process and use it to determine the linear and rotational velocity of the wheel once it is released.
A bicycle wheel has a mass of 1.0 kg, a radius of 0.35 m, and a rotational inertia of 0.1225 kg-m². The wheel is spun up to a rotational velocity of 6 radians per second and then placed on the ground and released, allowing it to roll away. Assuming no energy is lost to internal energy in this process, draw an energy bar chart for this process and use it to determine the linear and rotational velocity of the wheel once it is released.
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Transcribed Image Text:3) A bicycle wheel has a mass of 1.0 kg, a radius of 0.35 m, and a rotational inertia of
0.1225 kg-m². The wheel is spun up to a rotational velocity of 6 radians per second
and then placed on the ground and released, allowing it to roll away. Assuming no
energy is lost to internal energy in this process, draw an energy bar chart for this
process and use it to determine the linear and rotational velocity of the wheel once it
is released.
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