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manual-cohesive_elements_insertion.tex
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manual-cohesive_elements_insertion.tex
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\subsection
{
Insertion of Cohesive Elements
}
\subsubsection
{
Dynamics
}
As far as dynamic simulations are concerned, cohesive elements are
currently compatible only with the explicit time integration scheme
(see section~
\ref
{
ssect:smm:expl-time-integr
}
). They do not have to be
inserted when the mesh is generated but during the
simulation. Intrinsic cohesive elements can be introduced at the
beginning of the simulation as follows:
\begin
{
cpp
}
SolidMechanicsModelCohesive model(mesh);
model.initFull();
model.limitInsertion(
_
x, -1, 1);
model.insertIntrinsicElements();
\end
{
cpp
}
where the insertion is limited to the facets whose barycenter's
$
x
$
coordinate is in the range
$
[-
1
,
1
]
$
. Additional restrictions with
respect to
$
y
$
and
$
z
$
directions can be added as well. Similarly the
dynamic insertion of extrinsic cohesive elements can be utilized in
the following way:
\begin
{
cpp
}
SolidMechanicsModelCohesive model(mesh);
model.initFull(SolidMechanicsModelCohesiveOptions(
_
explicit
_
lumped
_
mass, true));
model.limitInsertion(
_
x, -1, 1);
model.updateAutomaticInsertion();
\end
{
cpp
}
in which this time the method
\code
{
limitInsertion
}
prevents the
cohesive elements to be inserted out of the range
$
[-
1
,
1
]
$
in the
$
x
$
direction. In order to check stress and automatically insert elements,
it is necessary to call the function
\code
{
checkCohesiveStress
}
in the
main loop where
\code
{
solveStep
}
is:
\begin
{
cpp
}
model.checkCohesiveStress();
model.solveStep();
\end
{
cpp
}
At any time during the simulation, it is possible to access the
following energies with the relative function:
\begin
{
cpp
}
Real Ed = model.getEnergy("dissipated");
Real Er = model.getEnergy("reversible");
Real Ec = model.getEnergy("contact");
\end
{
cpp
}
\subsubsection
{
Statics
}
The only cohesive law that is applicable in this case is the
exponential one (see
section~
\ref
{
ssect:smm:cl:coh-exponential
}
). However
unloading-reloading cycles are not supported yet. In this case
cohesive elements have to be inserted before creating the
\code
{
SolidMechanicsModelCohesive
}
model:
\begin
{
cpp
}
Mesh mesh(spatial
_
dimension);
mesh.read("implicit
_
mesh.msh");
CohesiveElementInserter inserter(mesh);
inserter.setLimit(
_
y, 0.9, 1.1);
inserter.insertIntrinsicElements();
SolidMechanicsModelCohesive model(mesh);
model.initFull(SolidMechanicsModelCohesiveOptions(
_
static));
\end
{
cpp
}
Also in this case the element insertion can be limited to a given
range thanks to the method
\code
{
setLimit
}
. The first input parameter
of this method indicates the direction while the other two indicate
the extreme values of the range
$
[
0
.
9
,
1
.
1
]
$
. In order to compute the
energies, the same functions illustrated for dynamics in the last
section can be used.
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