Understanding Angular Acceleration and Speed in a Human Centrifuge

AI Thread Summary
The discussion revolves around calculating angular acceleration and speed in a human centrifuge that completes 20 revolutions in one minute. The correct angular acceleration is determined to be 40 rev/min², while the final speed is 40 rev/min. Participants suggest using kinematic equations adapted for rotational motion, emphasizing the importance of correctly interpreting the given data, particularly distinguishing between displacement and final velocity. A misunderstanding regarding the interpretation of the 20 revolutions as final velocity was clarified, leading to the correct solution. The conversation highlights the significance of unit consistency and proper setup in solving physics problems.
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This problem states:

A human centrifuge takes 1.0 min to turn through 20 complete revolutions before reaching final speed.

They are asking for angular acceleration (a) and angular speed in rpm (b).

The answer to a is 40 rev/min^2
The answer to b is 40 rev/min
-I'm have the formulas for angular acceleration but most of them won't work b/c I don't have any velocity attached to this problem.

I don't know how to set the problem up to receive the right answer. I've tried converting from radians to rev/min^2 and end up with the wrong answer every time. This isn't a very difficult problem but I don't understand how to set the problem up to find the right answer.

I end up with 2.09 rad/s but that answer doesn't take me in the right direction (at least I don't think so).

Thanks in advance,
Dusty
 
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Why not try some Kinematics equations? Since angular acceleration is presumed to be constant, you can convert these equations to the relevant form for rotational motion.

For example, a=(v-u)/t will now be: angular acceleration=(final angular velocity-initial angular velocity)/time

Note: Choose units for angular displacement, angular velocity and angular acceleration wisely! Also, remember that the centrifuge starts from rest.
 
Last edited:
when i use that equation, i end up with .333.

i'm doing (20rad/s-0rad/s)/60s = 0.333 ? The answer needs to be in rev/min^2 and I don't know how to get the answer in the form that they want it. If i double the amount that I have, I'll have the right answer, but I don't understand why.
 
20 isn't the final angular velocity, it is the displacement. You don't yet know what the final velocity is, but since you know the initial velocity, the time, and the displacement, you can use a kinematics equation like displacement = vi*t + 1/2*a*t^2 to solve for the acceleration. Now you have the initial velocity, the time, and the acceleration, so you can easily solve for the final velocity. Since the answer is in rpm, you don't need to convert any of the numbers to a different form, ie leave the time in minutes and don't use radians.
 
thank you dzza...finally got the right answer.

i don't think i understood exactly what information i had. i misinterpreted the 20 rev/min as final velocity.

thank you very much!
 

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