Reaction at 4 Points in Rectangle with Force in x-Direction

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Determining the reaction forces at four fixed points arranged in a rectangle under an applied force in the x direction is a statically indeterminate problem. Since there are more unknowns than equations, additional information, such as the material's modulus of elasticity, is necessary to solve for the forces at each corner. The concept of "bendy-ness" relates to the material's flexibility and can be quantified through the modulus of elasticity. Tensors may be applicable in analyzing the problem, depending on the complexity of the material properties involved. Understanding these principles is crucial for accurately calculating the forces in such a setup.
larocket83
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I'm pretty rusty on my statics. I'm wondering how I could determine the reaction at four points arranged in a rectangle, with a force acting in the x direction at a distance away from the plate I have shown in this graphic. I seem to remember the term statically indeterminate, I think this applies, but is there any way to figure out the forces that each of these corners see? (Assume the points are fixed to the floor.)

Thanks in advance.

x.png
 
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Hi larocket83! Welcome to PF! :smile:
larocket83 said:
… I seem to remember the term statically indeterminate, I think this applies, but is there any way to figure out the forces that each of these corners see? (Assume the points are fixed to the floor.)

You're right, it is statically indeterminate … you can calculate the forces for a table on three legs, but not on four legs (basically because if you take one leg away, the table will still stand up … or, mathematically, because you have more unknowns than equations).

Of course, you can solve it, but you need one more equation …

in this case, you need to know how bendy the table is. :wink:
 
wow, this is incredibly awesome. if the bendy-ness were given, what kind of quantity would that come as?

also, are tensors used to solve this problem?
 
frustr8photon said:
wow, this is incredibly awesome. if the bendy-ness were given, what kind of quantity would that come as?

A modulus … see http://en.wikipedia.org/wiki/Modulus_of_elasticity" :smile:
also, are tensors used to solve this problem?

Maybe … bendy-ness depends on lots of things (it's flexible :wink:).
 
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