How Is the Deflection Formula for a Simply Supported Beam Derived?

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SUMMARY

The deflection formula for a simply supported beam under a uniformly distributed load is derived through integration of the bending moment. The correct formula is Actual Deflection = (5 x WL^4) / (384EI), where L is the length of the beam, W is the load, E is the modulus of elasticity, and I is the moment of inertia. The derivation involves calculating the moment using M = (w*L*x)/2 - (w*x^2)/2, integrating the moment to find the rotation, and then integrating again to determine the deflection. Boundary conditions are crucial for solving integration constants.

PREREQUISITES
  • Understanding of beam mechanics and deflection principles
  • Familiarity with integration techniques in calculus
  • Knowledge of bending moment and shear force diagrams
  • Basic concepts of material properties such as modulus of elasticity (E) and moment of inertia (I)
NEXT STEPS
  • Study the derivation of the bending moment for various loading conditions
  • Learn about boundary conditions in beam theory and their impact on deflection calculations
  • Explore advanced integration techniques relevant to structural analysis
  • Investigate software tools for beam analysis, such as SAP2000 or ANSYS
USEFUL FOR

Structural engineers, civil engineering students, and professionals involved in beam design and analysis will benefit from this discussion.

clairepearl
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Hi,:smile:
I am only new to this forum so any feedback would be greatly appreciated.
I am wondering if anyone could help me derive the formula for a simply supported beam with a uniformly distributed load. I understand that it is done using integration but I fail to understand the steps involved. The end formula required is that of

Actual Deflection = 5 x WL3(where the L is cubed)
.........(384)EI


Thanks for your time

Claire:smile:
 
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Hi Claire,

sure you have the correct formula for deflection? My notes asy L^4 not L^3...
Anyways, the expression of moment at any part of the beam is

M = (w*L*x)/2 - (w*x^2)/2 as moment is the integration of the shear force (look at the bending moment diagram compared to the shear force diagram) and x is the variable distance from one of the supports

Now, integrate the rotation of the beam as R = integration(M/EI) dx
and integrate this once more to find the deflection, as you would know from definition.To work out the integration constants that you get from each integration, consider the boundary conditions for the beam, ie where both the deflection v and variable distance x is 0, but also where x=L (L= full length of the beam)

This will give you the full expression for the deflection at any point on the beam.

Now to find the maximum deflection just set x=L/2 , ie half-way along the beam.

Hope this helps!

You really just have to go through the integration following the steps I've provided in order to fully understand what is going on.

A
 

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