Find the angular acceleration of the system if a torque of 1958 meter Newtons is applied to a system consisting of three concentric hoops constrained to rotate together about an axis through their common center and perpendicular to their common plane. Each hoop has a mass density of 2.228164 kilograms/meter, and the hoop radii are 3.5 meters, 7 meters and 10.5 meters.
The first circle or hoop has circumference 2 `pi ( 3.5 meters) = 21.98 meters.
The second circle or hoop has circumference 2 `pi ( 7 meters) = 43.96 meters.
The third circle or hoop has circumference 2 `pi ( 10.5 meters) = 65.94 meters.
The three moments of inertia will therefore be
These add up to the total moment of inertia
The 1958 meter Newton torque will result in an angular acceleration of `alpha = `tau / I = 1958 meter Newtons / ( 11998.89 kilogram meter ^ 2) = .1631818 radians/second.
A hoop of radius r and mass density `lambda, measured in kg / meter, will have circumference 2 `pi r and therefore total mass hoop mass = 2 `pi r * `lambda.
I = m r^2 = 2 `pi r * `lambda * r^2 = 2 `pi r^3 * `lambda.
A series of hoops with radii r1, r2, ..., rn, each with the same density `lambda, will have circumferences
masses
and will therefore have moments of inertia
The total moment of inertia will be
The acceleration resulting from applying a torque `tau will therefore be
If mass m is distributed over a circle or a hoop of radius r centered at the axis of rotation then the entire mass m lies at distance r from the axis and the moment of inertia of that hoop is m r^2.
- `alpha = `tau / I = `tau / (m1 r1^2 + m2 r2^2 + ... + mn rn^2).
The figure below depicts three concentric hoops.
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