A bully is chasing little Billy through the playground. In an attempt to escape,
ID: 1369225 • Letter: A
Question
A bully is chasing little Billy through the playground. In an attempt to escape, Billy runs toward a stationary merry-go-round. He leaps onto it tangentially with a horizontal velocity of 4 m/s and lands on the edge. The bully decides to spin the merry-go-round with a constant torque of 30 Nm so that Billy flies off. Billy has nothing to hang onto and only friction is keeping him on the merry-go-round, how long does it take for poor young Billy to fly off of the merry-go-round? Billy is 35 kg and the merry-goround is 100 kg. The radius of the merry-go-round is 1 m and the coefficient of static friction between the rubber on the soles of Billy's shoes and the steel merry-go-round is 0.7. Gather: (0.5 point) Draw a diagram showing the the distribution of mass when Billy is on the merry-go-round and another showing the forces acting on Billy when he is being spun up. Organize: (0.5 point) Which principle can be used to determine the initial angular velocity of the merry-go-round? What condition determines when Billy will fly off the merry-go-round? Analyze (3 points) Use the ideas which you have organized in order to solve the problem. Learn (1 point) Would Billy have stayed on the merry-go-round longer if he was heavier? What could Billy do to make it harder to spin him off the merry-go-round
Explanation / Answer
The initial angular momentum of the system is Billy's angular momentum,
L = r mBilly v = 140 kg *m^2/s
Now, we treat the merry go round as a disk, with
Imerry = 1/2 M R^2 = 50 kg*m^2
The I due to Billy is
Ibilly = mBilly R^2 = 35 kg*m^2
Thus,
Itot = 85 kg*m^2
Thus, the initial angular velocity after Billy jumped, by conservation of angular momentum, is
w0 = 1.647 rad/s
Now, the bully is putting in a torque of 30 Nm, which is
Torque = I(alpha) ---> alpha = Torque/I
Thus,
alpha = 0.3529 rad/s^2
Now, Billy flies off if
centripetal force = us m g = m w^2 r
Solving for the critical w,
w = 2.6192 rad/s
Thus as
w = w0 + alpha t
Solving for t,
t = 2.755 s [ANSWER]
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