Calculating Moment of Inertia for a Rectangle

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SUMMARY

The discussion centers on calculating the second moment of area (moment of inertia) for a rectangle with height \( h \) and width \( b \). The user initially attempted to derive the moment of inertia using a simplified approach, yielding \( I = \frac{bh^3}{16} \). However, the correct calculation through integration, \( I = \frac{bh^3}{12} \), was confirmed by another participant. The distinction between using a mean distance and the radius of gyration was clarified, emphasizing the importance of integration in accurate calculations.

PREREQUISITES
  • Understanding of the second moment of area (moment of inertia)
  • Familiarity with integration techniques in calculus
  • Knowledge of geometric properties of rectangles
  • Concept of radius of gyration
NEXT STEPS
  • Study the derivation of the second moment of area for various shapes
  • Learn about the radius of gyration and its applications in structural engineering
  • Explore integration techniques for calculating moments of inertia
  • Review the differences between discrete and continuous methods in moment calculations
USEFUL FOR

Students and professionals in engineering, particularly those focusing on structural analysis and mechanics, will benefit from this discussion on calculating the moment of inertia for rectangular sections.

imstat
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If I have a Rectangle h high, b wide, I thought I could calculate 2nd Moment of Area, I , about its neutral axis this way: taking the top half of the rectangle, the area is bh/2, and then multiplying this by the distance from the centroid of the top half to the neutral axis, squared ie (h/4)**2. Then because there are two halves of the rectangle, doubling the answer. This all gives I=(bh**3)/16.

My problem is reconciling this with the answer obtained by integrating
(y**2) b dy from -h/2 to h/2, which gives I=bh**3)/12.

I generally thought the concept of second moment of area was an area times the distance of the centroid of the area to an axis it is rotated about, squared. Now I'm not so sure.

Any assistance appreciated.
 
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I=\int _{S} r^2 dS

This is the definition, so your second calculation is correct.

I generally thought the concept of second moment of area was an area times the distance of the centroid of the area to an axis it is rotated about, squared

Although this looks much like the definition, and yields the correct units, it differs from it because you multiply instead of integrate. If you insist using multiplication of some sort of 'mean distance' (it's called the radius of gyration) with an area, you should not use h/4. Because the definition involves r^2 instead of r you should use the 'root mean square' instead of the mean distance for your radius of gyration. But calculating the root mean square involves another integration, so I'd just stick to the above integral...
 
Thank you da Willem. My concepts were not translating to accurate definition. So thanks for clarifying this for me.
Imstat
 

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