Moment of Inertia/Torque - Calculating the Angular Velocity of a Catapult Arm

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The discussion focuses on calculating the angular velocity of a catapult arm by determining torque and moment of inertia. The user seeks clarification on whether the mass (M) in the moment of inertia formula should include only the arm's mass or all components, and whether L and D represent the arm's length and the distance to the center of mass, respectively. It is confirmed that M refers only to the arm's mass, and the user must add the contributions from the projectile, basket, and counterweight for the total moment of inertia. Additionally, the center of mass of the arm can be found by balancing it, and if the arm has a uniform cross-section, the center of mass will be at its midpoint. Accurate calculations for both torque and moment of inertia are essential for the catapult's performance.
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Hi all, I'm working on a catapult for a project and I'm having some problems with some of the calculations, I'm trying to get the angular velocity of my catapult's arm by first obtaining the torque and moment of inertia.

Homework Statement


http://img46.imageshack.us/img46/2687/physproblem.th.png
A diagram I made with all the information and the sum of torques solved.

Homework Equations


Torque = Force * Distance to axis of rotation
I=(1/12)ML^2 + MD^2
F = mg

3.Attempt at solution
I've solved Torque, but I have some doubts for Moment of Inertia:
1) Is M the mass of the arm by itself or the addition of all the masses involved (arm+counterweight+basket+projectile)
2) Is L the distance of the whole Arm and D the distance of the axis of rotation to the center of mass?

I=(1/12)ML^2 + MD^2
I=(1/12)(0.9)(.3650)^2 + (0.9)(.1)^2
I=.0189 kg*m^2
Is this right?
 
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Can anyone at least confirm that my solution is right?
 
First, welcome to Physics Forums :smile:
JJX said:
A diagram I made with all the information and the sum of torques solved.
Since the axis of rotation is not at the arm's center of mass, you need to add a torque term for the arm.

Homework Equations


Torque = Force * Distance to axis of rotation
I=(1/12)ML^2 + MD^2
F = mg

3.Attempt at solution
I've solved Torque, but I have some doubts for Moment of Inertia:
1) Is M the mass of the arm by itself or the addition of all the masses involved (arm+counterweight+basket+projectile)
2) Is L the distance of the whole Arm and D the distance of the axis of rotation to the center of mass?

I=(1/12)ML^2 + MD^2
I=(1/12)(0.9)(.3650)^2 + (0.9)(.1)^2
I=.0189 kg*m^2
Is this right?
1) M is just the arm mass
2) Yes to both
HOWEVER ... this I is the M.O.I. for the arm only. You need to add the contributions of the projectile+basket and counterweight, to get I for the entire catapult. These would be m·d2 for each mass, using the distance from the axis of rotation.
 
Thank You Red Belly, that was extremely helpful. I have now come across another problem, I need to find the centre of mass of this very same arm. Is it always the centre? I placed it there by the way, seemed right. Does it have anything to do with the Masses*r aswell? I wonder if the counterweight and the basket affect it.
 
You can find the center of mass for yourself by seeing where the arm balances.

Is the arm thicker or heavier at one end? If not, and it is a uniform cross-section size along it's whole length, then the center of mass should be in the middle of the arm. If you can verify this by checking where the balance point is (with no other masses attached), all the better.

Don't worry about the other masses when calculating the arm's center of mass. You are accounting separately for those masses' contribution to torque and moment of inertia.
 
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