A. You have an Atwood's Pulley with the two hanging masses being m1=22 kg, m2=49 kg,...

A. You have an Atwood's Pulley with the two hanging masses being m₁=22 kg, m₂=49 kg, and the pulley having moment of inertia I=69 kg.m² and radius R=3.4 m. Use g=9.78 m/s/s.

When the system is in its free motion, calculate the magnitude of the torque , in units of N.m, on the pulley.

You have an Atwood's Pulley with the two hanging masses being m₁=32 kg, m₂=52 kg, and the pulley having moment of inertia I=58.4 kg.m² and radius R=2 m. Use g=9.8 m/s/s.

When the system is in its free motion, calculate the magnitude of the acceleration of the masses, in units of m/s/s, of the hanging masses.

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genius_generous answered 1 year ago

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