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Can anyone tell me the right way to enter the elastoplasic properties of a material in Creo/WF 5.0? I have the true stress/strain curve entered. With the "Use best fit coefficients checkmarked the curves look good. However the Tensile Yield stress is at 0. If I try to hit ok it doesn't let me. It says I must have a value greater than 0. If I uncheck the box and put in the correct value the curve shifts way up. Any thoughts?
Solved! Go to Solution.
I never used this capability of Pro/E, but I see that the graph is a plot of plastic strain vs stress.
Thus it seems obvious that the curve starts after the yield stress point...
I never used this capability of Pro/E, but I see that the graph is a plot of plastic strain vs stress.
Thus it seems obvious that the curve starts after the yield stress point...
Hi,
Yes, only the part of the curve after yield should be used and should be true stress vs true strain.
This is to likely to change with Creo3.0
http://communities.ptc.com/message/195487#195487
Regards
Ok thanks. It is true stress and strue strain. Should I also use the equation you mentioned to convert true strain to plastic strain?
Paul,
The equation simply subtracts the linear part of the curve leaving only the plastic strain.
Regards
Thanks Charles. I have gotten all the correct numbers in, manipulating the engineering stress/ strain curve to get true stress/true strain. Here is what I did:
I calculated the Ramberg Osgood Coefficient: n = (LN(eus/.2))/((LN(Ftu/Fty))
eus uniform strain
Ftu ultimate strength
Fty yield strength
Uniform strain can be calculated by: eus = 100(er-(Ftu/E))
er strain at rupture
E youngs modulus
I obtained an engineering stress strain curve using:
eeng = sigmaeng/E+.002*(sigmaeng/Fty)^n
I calculate true stress and strain
sigmatrue = sigmaeng*(1+eeng)
etrue = LN(1+eeng)
Then calculated true plastic strain
etrueplastic = etrue-(sigmatrue/E)
Does this seem correct? By the way all of this info can be found in MMPDS-01
Paul,
I too have used the Ramberg Osgood relation, it seems to be generally accepted.
Could TAD D confirm or correct the following please?
the material curve input is interpretted one of 2 ways depending on whether the LDA check box is ticked.
(SDA = small deflection analysis
LDA = Large deflection analysis)
INPUT material curves:
The material curve input for SDA is interpretted as ENGINEERING STRESS vs ENGINEERING STRAIN
The material curve input for LDA is interpretted as TRUE STRESS vs LOGARITHMIC STRAIN
The axis labels on the input data graph do not vary and in CREO2 they are True plastic strain, True Stress (MPa).
OUTPUT Analysis results for the above are:
SDA results are in ENGINEERING STRESS and STRAIN
LDA results are in TRUE STRESS and LOGARITHMIC STRAIN
With SDA there is a generic assumption that the ENG and LOG strains (and other strain models) are about the same if the strain is less than 5%; therefore checking the LDA box 'doesn't matter'.
Thanks
Hi Charles,
Yes, your statements in your July 17th post are correct. Concerning your last paragraph, it might be more accurate to say that as long as the strains, displacements and rotations are small, then an SDA and LDA analysis should give nearly the same results.
Tad Doxsee
PTC
Fair point, my inverted comma's were too subtle.
Thanks
Hello,
It would be interesting to find a tutorial on how to use this function in the material, with an explanation of functions and a concrete example.
Cordially.
Denis
Hello,
See attached with some explanations on the subject link.
Cordially.
Denis.
http://www.qucosa.de/fileadmin/data/qucosa/documents/8714/SAXSIM_2012_Plasticity_Jakel.pdf
Thanks Denis, I'd forgotten about the info available from here.
PTC, This information should be available via the knowledge base.
Why do users have to discover this? Why can't technical support point to these?
More advanced users need a different kind of support than that generically offered.
Thanks
I agree with Charles !