8. F modeling#
8.1. Characteristics of modeling#
Shell element DST (modeling a quarter of a plate).
The plate model associated with the E model is rotated 20 degrees according to the alpha nautical angle and 30 degrees according to beta. Compared to C modeling, the model is characterized here by a different orientation of the cells.
Boundary conditions: |
LIAISON_OBLIQUE |
(GROUP_NO =”AB”, ANGL_NAUT =( 20.,30.,0.), DZ=0., DRY =0.) |
|
(GROUP_NO =”BC”, ANGL_NAUT =( 20.,30.,0.), DX=0., DRY =0.) |
|
(GROUP_NO =”CD”, ANGL_NAUT =( 20.,30.,0.), DY=0., DRX =0.) |
|
(GROUP_NO =”DA”, ANGL_NAUT =( 20.,30.,0.), DZ=0., DRX =0.) |
|
Point \(C\) |
mesh: 72 |
8.2. Characteristics of the mesh#
Number of knots: 56
Number of meshes and types: 72 TRIA3
8.3. Tested values#
Point C |
Identification |
Reference |
Aster |
% Difference |
|
\({\sigma }_{x}\) on lower layer 3 |
4.7100E+01 |
5.2430E+01 |
11.317 |
||
\({\sigma }_{x}\) on top layer 3 |
5.8800E+01 |
6.5537E+01 |
11.459 |
||
Constraints |
\({\sigma }_{x}\) on lower layer 2 |
—4.7100E+01 |
—5.2430E+01 |
11.317 |
|
\({\sigma }_{x}\) on top layer 2 |
4.7100E+01 |
5.2430E+01 |
11.317 |
||
\({\sigma }_{x}\) on layer 1 below |
—5.8800E+01 |
—6.5537E+01 |
11.459 |
||
\({\sigma }_{x}\) on top layer 1 |
—4.7100E+01 |
—5.2430E+01 |
11.317 |
||
\(\mathrm{DX}\) |
1.9696E+01 |
1.9744E+01 |
1.9696E+01 |
0.248 |
|
Displacement |
\(\mathrm{DY}\) |
7.1687E+00 |
7.1865E+00 |
0.249 |
|
\(\mathrm{DZ}\) |
3.6304E+01 |
3.6393E+01 |
3.6304E+01 |
0.248 |
8.4. notes#
The reference values of the displacement at point \(C\) are obtained by projecting the theoretical displacement established for an unrotated plate into the new user frame of reference (the displacement for an unrotated plate being vertical, the new displacement is a function of the projection of the \(Z\) axis). In the local coordinate system, the projection of the \(Z\) axis is as follows:
, with
and
8.5. Contents of the results file#
Values at the displacement observation point and constraints \({\sigma }_{x}\).