the7joker7
Feb25-08, 11:53 PM
1. The problem statement, all variables and given/known data
A tire 2.00 feet in diameter is placed on a balancing machine, where it is spun so that its tread is moving at a constant speed of 60.0 mi/h. A small stone is stuck in the tread of the tire. What is the acceleration of the stone as the tire is being balanced?
2. Relevant equations
\omega = \frac{change in theta}{change in time}
r = diameter/2
\alpha = \frac{\omega - \omega_{0}} {time}
a_{t} = r*\alpha
3. The attempt at a solution
\omega = 840.3 rev/min = 88 radians/sec.
radius = .305m.
\alpha = \frac{88 radians}{1 second} = 88 radians/second^{2}.
a_{t} = .305 *88 = 26.84 m/s^{2}
1. The problem statement, all variables and given/known data
2. Relevant equations
3. The attempt at a solution
A tire 2.00 feet in diameter is placed on a balancing machine, where it is spun so that its tread is moving at a constant speed of 60.0 mi/h. A small stone is stuck in the tread of the tire. What is the acceleration of the stone as the tire is being balanced?
2. Relevant equations
\omega = \frac{change in theta}{change in time}
r = diameter/2
\alpha = \frac{\omega - \omega_{0}} {time}
a_{t} = r*\alpha
3. The attempt at a solution
\omega = 840.3 rev/min = 88 radians/sec.
radius = .305m.
\alpha = \frac{88 radians}{1 second} = 88 radians/second^{2}.
a_{t} = .305 *88 = 26.84 m/s^{2}
1. The problem statement, all variables and given/known data
2. Relevant equations
3. The attempt at a solution