Conservation of Angular Momentum bicycle problem

AI Thread Summary
The discussion revolves around a bicycle wheel problem involving the conservation of angular momentum. A student on a rotatable stool holds a spinning wheel and flips it, prompting questions about how this affects the system's angular velocity. The key insight is that the total angular momentum must remain constant, leading to a calculation that combines the initial and final angular momentum of both the wheel and the student-stool system. Ultimately, the student successfully determines the final angular velocity of the stool and student after flipping the wheel, confirming the solution through calculations. The discussion highlights the importance of understanding angular momentum conservation in rotational dynamics.
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Homework Statement


In a demonstration, a bicycle wheel with moment of inertia = .37 kg*m^2 is spun up to 14 rad/s, rotating about a vertical axis. A student hold the wheel while sitting on a rotatable stool. The student and the stool are initially stationary and have a moment of inertia equal to 3.6 kg*m^2. If the student turns the bicycle wheel over so its axis point in the opposite direction, with what angular velocity will the student and stool rotate? Assume the wheel, student, and stool all have the same axis of rotation.


Homework Equations


Im not entirely sure if you need the equation for angular momentum, or just to know that it is conserved. Ill give the equation anyways.
Angular Momentum Equation: L=I*ω

Moment of Inertia Equation: I = m*r^2


The Attempt at a Solution



I figured that this question is all about the conservation of angular momentum. If I add the moment of inertia of the stool and student to the negative of the inertia for the bicycle wheel (because its now upside-down, right? ) I would get the total moment of inertia for the system. I have no idea how to proceed from here, becase the equation for moment of inertia is I = m*r^2, and I don't have an r to use. Maybe I need to look into the angular momentum equation some more (derivative of that equation to find the change of ω perhaps?)

I feel like this should be an easy problem (this is a reading review problem supposedly) but its just not clicking for me. Any help is greatly appreciated.
 
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Treat the system as having two parts: (1) The wheel, and (2) The student and stool.

Initially, only the wheel is rotating. So what's the total angular momentum of the system?

What happens to the angular momentum of the wheel when it is inverted?
 
If I treat this system as two parts, then the angular momentum is just that of the wheel in the beginning, .37 kg*m^2. So does the angular momentum become negative if we flip the wheel on its z axis, becoming -.37kg*m^2?

this would mean that the angular velocity of the system would flip, becoming -14 rad/s right?

Does the angular momentum of the student and the stool have any use in this case?
 
pogo2065 said:
If I treat this system as two parts, then the angular momentum is just that of the wheel in the beginning, .37 kg*m^2. So does the angular momentum become negative if we flip the wheel on its z axis, becoming -.37kg*m^2?

this would mean that the angular velocity of the system would flip, becoming -14 rad/s right?
The moment of inertia of the wheel doesn't change, but its angular momentum does.

Does the angular momentum of the student and the stool have any use in this case?
Consider the total angular momentum of the system. Can that change?
 
Sorry, I was a bit confused while writing my previous post. I mean does the moment of inertia for the student and the stool matter?

So if I flip over the bicycle wheel, its angular velocity should become negative, right? (relative to the system, its now spinning in the other direction). Should I then use this new angular velocity and the sum of the moments of inertia (which don't change) to calculate the new angular momentum?

I feel like this is going in circles, since once I calculate that new angular momentum I would have to use all the same values again to calculate the angular velocity.
 
pogo2065 said:
Sorry, I was a bit confused while writing my previous post. I mean does the moment of inertia for the student and the stool matter?
Of course it matters.

So if I flip over the bicycle wheel, its angular velocity should become negative, right? (relative to the system, its now spinning in the other direction).
Right.
Should I then use this new angular velocity and the sum of the moments of inertia (which don't change) to calculate the new angular momentum?
Treat the two parts of the system as separate (but loosely connected) entities.

I feel like this is going in circles, since once I calculate that new angular momentum I would have to use all the same values again to calculate the angular velocity.
Try this:

Ang Mom (of stool & student) + Ang Mom (of wheel) = constant.

If Ang Mom (of wheel) changes, how must Ang Mom (of stool & student) change?
 
Doc Al said:
If Ang Mom (of wheel) changes, how must Ang Mom (of stool & student) change?

The Angular Momentum of the stool and student must change to make the equation still valid, since Angular Momentum is conserved.

So to calculate the Angular Momentum of the wheel:

AM(wheel) = .37*(-14) = -5.18

so then:

AM(wheel) + AM(Student) = constant.

-5.18 + 3.6*ω(student) = constant.

How should I proceed from here? I am not sure how to calculate the constant before the switching of direction of the wheel...

Im off to class for a bit but I will check back after.
 
pogo2065 said:
The Angular Momentum of the stool and student must change to make the equation still valid, since Angular Momentum is conserved.

So to calculate the Angular Momentum of the wheel:

AM(wheel) = .37*(-14) = -5.18

so then:

AM(wheel) + AM(Student) = constant.

-5.18 + 3.6*ω(student) = constant.
Good. That's for after the wheel was flipped.

How should I proceed from here? I am not sure how to calculate the constant before the switching of direction of the wheel...
Do the same calculation for before the wheel is flipped.

(You're almost there.)
 
So should i do something like:

AM(student-initial) + AM(wheel-initial)=AM(student-final)+AM(wheel-final)

and then solve it for the AM of the student-final.

so it would be:

3.6*0 +.37*14 = 3.6*x+.37*-14

and solve for the final angular velocity.

x = 2.89 rad/s

Is this correct?

EDIT: I just checked my work over and typed the answer into the online homework system for my class - i got it right. This was such a simple problem in hindsight!
Thank you Doc Al for all your help and patience as i struggled to grasp this concept. Your assistance has been invaluable!
 
  • #10
Excellent! :approve:
 
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