Calculating Moment of Inertia for a Cylinder with Varying Radii?

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Homework Help Overview

The discussion revolves around calculating the moment of inertia for a composite cylinder with varying radii, specifically a larger cylinder and smaller cylinders that create holes within it. The original poster seeks assistance in determining the moment of inertia given the mass and dimensions of the body.

Discussion Character

  • Exploratory, Mathematical reasoning, Assumption checking

Approaches and Questions Raised

  • Participants discuss the use of integration to calculate the moment of inertia, suggesting the application of density and volume relationships. There are considerations regarding the integration of the full cylinder and the holes created by the smaller cylinders. Some participants propose using vector representations for the integration process.

Discussion Status

Several approaches have been suggested, including integrating over the entire volume and adjusting for the holes. Participants are exploring different methods and sharing insights, but there is no explicit consensus on a single approach yet.

Contextual Notes

The original poster has not provided specific values for mass or dimensions, which may affect the clarity of the discussion. There is also a casual mention of external resources for stress relief, indicating a light-hearted tone amidst the technical discussion.

TBoy
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Please, help me to solve this problem.

I need to calculate moment of inertia, I, for this body on picture:
- mass o the body is m
- radius of the big cylinder is a
- radius of the small cylinders is a/3


Thanks for your help!
 

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Well you have that I=Integral(r^2*dm)
Then u have the density=Mass/Volume (I'm supposing it's a cylinder)
then dm=density*dV
Then you solve I=Integral(r^2*density*dx*dy*dz) where r^2=x^2+y^2.
now you have the full cylinder without the holes.
Do the same for the holes and sum (with a minus of course)

Good luck
 
Ohh if you're having trouble with the holes just integrate but using r as a vector. So you do r=x+(cos(tethta), sen(theta)) where x is the vector from the oringin to the center of the wholes. Using that r just repeat it for the 4 circles (it's simetrical). Just remember that when integrating area in polar coordiantes dA=dx*dy=r*dr*dTheta

Cheers
 
Ohh and one more thing! remember that in vectors r^2=inner product (r,r)
:)
If u get stressed check tubepolis.com for some funny videos jeje. Look for triger happy those r really fun.
 
Thanks, will try it later when i will have some time! It seams logical! :)
 

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