A machinist turns the power on to a grinding wheel, at rest, at time t = 0 s. The wheel accelerates uniformly for 10 s and reaches the operating angular velocity of 96 rad/s. The wheel is run at that angular velocity for 40 s and then power is shut off. The wheel slows down uniformly at 1.5 rad/s2 until the wheel stops. In this situation, the angular displacement in Revolutions during the slowdown is:

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nuuk nuuk · Answer 1 · 2019-08-05T10:46:44+02:00

Answer:489 Revolutions

Explanation:

Given

Angular deceleration[tex](\alpha ) =1.5rad/s^2[/tex]

Given wheel angular velocity =96 rad/s when machine is turned off

time taken by machine to reach zero angular velocity

[tex]0=\omega _0+(\alpha)t[/tex]

0=96+(-1.5)t

t=64 sec

angular displacement is given by

[tex]\theta =\omega_0t+\frac{1}{2}\alpha t^2[/tex]

[tex]\theta =96(64)-\frac{1}{2}(-1.5)(64^2)=3072 degree[/tex]

For revolutions =[tex]\frac{3072}{2\cdot \pi}=488.86 \approx 489 revolution during Slowdown[/tex]