Mechanical Behaviour Modelling of an Mg-Stabilized Zirconia Reinforced TRIP-Matrix-Composite under Cold Working Conditions
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Author(s)
In the present work, a new method to predict the
stress-strain curves for three-phase materials has been developed. It
was applied using the example of an Mg-stabilized zirconia reinforced
TRIP-matrix-composite. The content of the ceramic phase was varied
between 5% and 20%, whereas the particle size of the ceramic was
selected to be 30 to 50 μm. The method is a further development of
mixture rule for multiphase materials with more than two microstructure
components. The prediction results were compared with the original
method of mixture rule and with the IsoE-method. It is shown that the
new method significantly improves the convergence compared to the
standard method for mixture rule, even though it does not reach the
accuracy of IsoE-method. Furthermore, there is an improvement of
predicted convergence for large values of the total stress. Finally, a
working map was designed for a quick graphical definition of the
objective functions.
KEYWORDS
Cite this paper
Guk, S. , Müller, W. , Pranke, K. and Kawalla, R.
(2014) Mechanical Behaviour Modelling of an Mg-Stabilized Zirconia
Reinforced TRIP-Matrix-Composite under Cold Working Conditions. Materials Sciences and Applications, 5, 812-822. doi: 10.4236/msa.2014.511081.
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