Hi ESPcomposites,
Following are responses to your questions:
Why are you using Neuber's rule? That has been developed for fatigue analysis. I suppose I could see some correlation to a static analysis, but I have never seen that used.
---> I apply this rule to a static analysis to avoid nonlinear analysis. Please check the attached picture. For the same mesh and load, Linear Solver found the peak Von Mises Stress a 119 ksi and Nonlinear solver results to 70 ksi. By using Neuber's elastic stress correction, I found 73.9 ksi. I prefer the Linear FEA + Neuber's rule versus Nonlinear FEA, because linear model with 848,664 DOFs runs in 29 minutes, but the same model with nonlinear material runs in 1444 minutes. So, nonlinear analysis is computationally 50 times more expensive.
---> I know that four other companies are using Neuber's rule to correct the linear FEA stresses. But, you are right this rule is coming from fatigue analysis. Specially, strain-life method (low cycle & high magnitude of stress).
- If it is "brittle", then you might directly use the Kt. Do you have a reference to using Neuber's rule for a static analysis? I suppose it could be done, but it seems like you are mixing concepts?
---> I think that there is a misunderstanding, when we use FEA the stress concentration is implicitly included (if we mesh all tiny features).
- If it is ductile, how large of a region is in the high Kt area? If it is relatively small, you might generally neglect the Kt completely. For example, the ultimate tension strength of plate with a hole is close to that of Ftu*(net section).
- If it is ductile, but the elongation limit will be reached within then ultimate load, then you could apply something like a plastic factor (i.e. plastic bending).
What SW mentions about landing gear is true as well, at least for typical aerostructure landing gear that we are used to. But those are generally high strength steels, which have very different static and fatigue behavior than would a "typical" aluminum.
---> We are dealing with landing gears for VLJs, so we manufacture some parts from steel and some others from aluminum.
Could you better define the material, failure model, fatigue approach? By asking whether or not use max principal or von mises, indicates to me that you are not sure about which failure model to use (and how to apply it properly).
---> For Static purpose, we know that for brittle material, failure occurs in a multiaxial system when either a principal tensile stress reaches the uniaxial tensile strength or a principal compressive reaches the uniaxial compressive strength. On the other hand, yield test of ductile materials have shown that the Von Mises criterion interprets well the results of a variety of biaxial conditions.
---> For Fatigue purpose (Ref. MSC.Fatigue Manual), the results of fatigue tests conducted under proportional loading at various biaxiality ratios suggest that the best parameter to use for loadings with 0>ae>-1 (i.e., between uniaxial and pure shear) is the absolute maximum principal strain. For 0<ae<1 (i.e., between uniaxial and equibiaxial) it is better, and more conservative, to use the signed Tresca parameter.
Before you start your FEM or get anything useful out of it, I would think you should better understand that.
---> Your last paragraph is not appropriate, I am always open to learn from more experienced engineers like SWComposites & rb1957.
For aluminum alloy, since it is a ductile material Von Mises stress is better. This is not the case for a brittle material. Based on my personal experiences, I did not see more than 2-3 percent difference between peak of Von Mises stress versus Max. Principal stress.
I believe that there is a mis-understanding, maybe you are not aware of the benefit of using Neuber's rule + Linear FEA versus Nonlinear FEA.
Thank you for your reply,
A.A.Y.
