rAKA/examples/c++/solid_mechanics_cohesive_model/cohesive_extrinsic_ig_tg571699bcd9affeatures/python-doc
rAKA/examples/c++/solid_mechanics_cohesive_model/cohesive_extrinsic_ig_tg
571699bcd9affeatures/python-doc
cohesive_extrinsic_ig_tg
cohesive_extrinsic_ig_tg
README.rst
README.rst
cohesive_extrinsic_ig_tg (2D)
'''''''''''''''''''''''''''''
:Sources:
.. collapse:: cohesive_extrinsic_ig_tg.cc (click to expand)
.. literalinclude:: examples/c++/solid_mechanics_cohesive_model/cohesive_extrinsic_ig_tg/cohesive_extrinsic_ig_tg.cc
:language: c++
:lines: 20-
.. collapse:: material.dat (click to expand)
.. _mat-cohesive-extrinsic-ig-tg:
.. literalinclude:: examples/c++/solid_mechanics_cohesive_model/cohesive_extrinsic_ig_tg/material.dat
:language: text
:caption:
:Location:
``examples/c++/solid_mechanics_cohesive_model/`` `cohesive_extrinsic_ig_tg <https://gitlab.com/akantu/akantu/-/blob/master/examples/c++/solid_mechanics_cohesive_model/cohesive_extrinsic_ig_tg/>`_
In ``cohesive_extrinsic_ig_tg``, the insertion of cohesive element is not
limited to a given location. Rather, elements at the boundaries of the block and
those on the inside have a different critical stress ``sigma_c``. This is done
by defining two different materials in the :ref:`mat-cohesive-extrinsic-ig-tg`.
In this case the cohesive materials are chosen based on the bulk element on both
side. This is achieved by defining ``MaterialCohesiveRules``
The four block sides are then moved outwards. The resulting displacement is
shown in :numref:`fig-ex-cohesive-ext-ig-tg`.
.. _fig-ex-cohesive-ext-ig-tg:
.. figure:: examples/c++/solid_mechanics_cohesive_model/cohesive_extrinsic_ig_tg/images/cohesive_extrinsic_ig_tg.gif
:align: center
:width: 60%
Displacement magnitude for the cohesive_extrinsic_ig_tg example.
'''''''''''''''''''''''''''''
:Sources:
.. collapse:: cohesive_extrinsic_ig_tg.cc (click to expand)
.. literalinclude:: examples/c++/solid_mechanics_cohesive_model/cohesive_extrinsic_ig_tg/cohesive_extrinsic_ig_tg.cc
:language: c++
:lines: 20-
.. collapse:: material.dat (click to expand)
.. _mat-cohesive-extrinsic-ig-tg:
.. literalinclude:: examples/c++/solid_mechanics_cohesive_model/cohesive_extrinsic_ig_tg/material.dat
:language: text
:caption:
:Location:
``examples/c++/solid_mechanics_cohesive_model/`` `cohesive_extrinsic_ig_tg <https://gitlab.com/akantu/akantu/-/blob/master/examples/c++/solid_mechanics_cohesive_model/cohesive_extrinsic_ig_tg/>`_
In ``cohesive_extrinsic_ig_tg``, the insertion of cohesive element is not
limited to a given location. Rather, elements at the boundaries of the block and
those on the inside have a different critical stress ``sigma_c``. This is done
by defining two different materials in the :ref:`mat-cohesive-extrinsic-ig-tg`.
In this case the cohesive materials are chosen based on the bulk element on both
side. This is achieved by defining ``MaterialCohesiveRules``
The four block sides are then moved outwards. The resulting displacement is
shown in :numref:`fig-ex-cohesive-ext-ig-tg`.
.. _fig-ex-cohesive-ext-ig-tg:
.. figure:: examples/c++/solid_mechanics_cohesive_model/cohesive_extrinsic_ig_tg/images/cohesive_extrinsic_ig_tg.gif
:align: center
:width: 60%
Displacement magnitude for the cohesive_extrinsic_ig_tg example.
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