Linear Elastic Orthotropic Model
In contrast to an isotropic material, an orthotropic material has preferred
directions of strength which are mutually perpendicular. The properties
along these directions (also known as principal directions) are the extreme
values of elastic coefficients. The [D]
matrix for an orthotropic material has nine independent elastic properties.
In addition, there are three properties for the thermal expansion.
2-D Orthotropic Stress-Strain Relations
In two dimensions, the orthotropic stress-strain relations can be written
as follows, including temperature effects:
Note that in order to satisfy symmetry in the matrix of elastic moduli,
nxyEy = nyx Ex.
You need to satisfy the foregoing symmetry
condition when you input the numerical values of either the elastic modulus
or Poisson's ratio.
Further, if you do not input the numerical value of the shear modulus,
the program will compute it as shown below:
In three dimensions, the orthotropic symmetry conditions dictate:
When you input the orthotropic material properties in three dimensions,
you must therefore make sure that the above symmetry conditions are not
violated. Note that if you do not input the numerical values of shear
moduli, the program will compute them using the relations shown below:
If Ex
= Ey = Ez, the
program calculates the shear moduli internally even if explicitly defined.
The program assumes 0.0 for Poisson's ratios that are not explicitly defined.
Isotropic
vs. orthotropic materials