A massless disk holds two objects, one of mass 9.900001 kilograms and the other of mass 9 kilograms. The system is constrained to rotate about an axis of rotation. The first object is 5.12 meters and the second 16 meters from the axis of rotation. A torque of 8.25 meter Newtons is applied to the system.
Each mass rotates at a constant distance from the center of rotation.
The acceleration resulting from a torque of 8.25 meter Newtons will therefore be `alpha = `tau /( `Sigma mr ^ 2) = ( 8.25 meter Newtons) / ( 2563.522 kg m^2) = 3.218228E-03 rad/s ^ 2.
If we have point masses m1, m2, ..., mn along a rod at distances r1, r2, ..., rn from the center of rotation, then we have individual moments of inertia m1 r1^2, m2 r2^2, ..., mn rn^2.
- angular acceleration = `tau / I = `tau / [ `sigma (m r^2)] = `tau / [ m1 r1^2 `m2 r2^2 0... `mn rn^2 ].
The figure below shows two masses m1 and m2 along a massless rod which constrains them to rotate about a central axis at respective distances r1 and r2 from the axis.
- Angular acceleration = `alpha = `tau / I = `tau / (m1 r1^2 `m2 r2^2).
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