Calculating Stress in Beam Under Point Load: Best Methods

AI Thread Summary
To calculate stress in a beam under a point load using deflection, three key equations are necessary: one for deflection based on load, length, modulus of elasticity, and moment of inertia; one for bending stress related to moment; and one for shear stress related to shear force. Bending stress varies with height, being maximum at the top and bottom fibers, while shear stress is parabolic and zero at the mid-plane. The bending stress can be calculated using the formula sigma_B = M_max * Z/I, where I is the moment of inertia. Shear stress is linear and also needs to be considered, particularly at the extreme fibers. Understanding these principles is essential for accurate stress calculations in beam mechanics.
ladil123
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Hello!

If I know the deflection (w) of a beam subjected to a point load in the middle, can I calculate the stress in that beam by calculating the shear force or moment ?
or use a 2d plane strain state ?

What is the best way to do it ?

Thanks
 
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Yes. You need three equations:

deflection of beam as a function of (P,L,E,I)
bending stress of beam as a function of moment.
shear stress of beam as a function of shear.

Then you need to add the two stresses together, but they almost always don't add linearly. Bending stress is varies with the height, y, within the section; ie: high at both top and bottom fibers, and zero at the mid section. Shear stress is parabolic, with its maximum at the mid section. A bit of reading will reveal what shear stress engineers usually use at the extreme fibers (it is not zero).

This is all in most books on "Mechanics of Materials".
 
Last edited:
Shear stress is linear and is zero at the mid plane. Bending stress is parabolic.

You had them backwards
 
Ok.
So the bending stress sigma_B = M_max *Z/I , right? I=moment of inertia.

What about the stress due to shear then? With the equation for deflection I could integrate and get the shear force, but how do I get the shear stress ?
 
CFDFEAGURU said:
Shear stress is linear and is zero at the mid plane. Bending stress is parabolic.

You had them backwards

I guess I wasn't clear. I was referring to the transverse stress level within a SECTION of the beam, and not referring along its length.

What you said is true but for longitudinal stress along the length.
 
I think I didn't get the question.

Yeah if you know the deflection, you can apply hooks law and figure out the stress.

But for that you also need to know 'sigma'; the constant.
 

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