Page Menu
Home
c4science
Search
Configure Global Search
Log In
Files
F92173153
manual-structuralmechanicsmodel.tex
No One
Temporary
Actions
Download File
Edit File
Delete File
View Transforms
Subscribe
Mute Notifications
Award Token
Subscribers
None
File Metadata
Details
File Info
Storage
Attached
Created
Mon, Nov 18, 00:24
Size
9 KB
Mime Type
text/x-tex
Expires
Wed, Nov 20, 00:24 (2 d)
Engine
blob
Format
Raw Data
Handle
13196182
Attached To
rAKA akantu
manual-structuralmechanicsmodel.tex
View Options
\chapter{Structural Mechanics Model}
Static structural mechanics problems can be handled using the
class \code{StructuralMechanicsModel}. So far, \akantu provides 2D and 3D
Bernoulli beam elements \cite{frey2009}. This model is instantiated for a given
\code{Mesh}, as for the \code{SolidMechanicsModel}. The model will create its own \code{FEEngine} object to
compute the interpolation, gradient, integration and assembly
operations. The \code{StructuralMechanicsModel} constructor is called
in the following way:
\begin{cpp}
StructuralMechanicsModel model(mesh, spatial_dimension);
\end{cpp}
where \code{mesh} is a \code{Mesh} object defining the structure for
which the equations of statics are to be solved, and
\code{spatial\_dimension} is the dimensionality of the problem. If
\code{spatial\_dimension} is omitted, the problem is assumed to have
the same dimensionality as the one specified by the mesh.
\note[\ 1]{Dynamic computations are not supported to date.}
\note[\ 2]{Structural meshes are created and loaded as described in
Section~\ref{sect:common:mesh} with \code{MeshIOMSHStruct} instead of \code{MeshIOMSH}:}
\begin{cpp}
akantu::MeshIOMSHStruct mesh_io;
mesh_io.read("structural_mesh.msh", beams);
\end{cpp}
\vspace{1cm}
This model contains at least the following \code{Arrays}:
\begin{description}
\item[blocked\_dofs] contains a Boolean value for each degree of
freedom specifying whether that degree is blocked or not. A
Dirichlet boundary condition can be prescribed by setting the
\textbf{blocked\_dofs} value of a degree of freedom to
\code{true}. The \textbf{displacement} is computed for all degrees
of freedom for which the \textbf{blocked\_dofs} value is set to
\code{false}. For the remaining degrees of freedom, the imposed
values (zero by default after initialization) are kept.
\item[displacement\_rotation] contains the generalized displacements
(\textit{i.e.} displacements and rotations) of all degrees of freedom. It can be
either a computed displacement for free degrees of freedom or an
imposed displacement in case of blocked ones ($\vec{u}$ in the
following).
\item[force\_moment] contains the generalized external forces (forces
and moments) applied to the nodes ($\vec{f_{\st{ext}}}$ in the
following).
\item[residual] contains the difference between the generalized external and internal
forces and moments. On the blocked degrees of freedom,
\textbf{residual} contains the support reactions ($\vec{r}$ in the
following). It should be mentioned that, at equilibrium,
\textbf{residual} should be zero on the free degrees of freedom.
\end{description}
An example to help understand how to use this model will be presented in the
next section.
\section{Model Setup}
\label{sec:structMechMod:setup}
\subsection{Initialization}
The easiest way to initialize the structural mechanics model is:
\begin{cpp}
model.initFull();
\end{cpp}
The method \code{initFull} computes the shape functions, initializes
the internal vectors mentioned above and allocates the memory for the
stiffness matrix, unlike the solid mechanics model, its default argument is \code{\_static}.
Material properties are defined using the \code{StructuralMaterial}
structure described in
Table~\ref{tab:structMechMod:strucMaterial}. Such a definition could,
for instance, look like
\begin{cpp}
StructuralMaterial mat1;
mat.E=3e10;
mat.I=0.0025;
mat.A=0.01;
\end{cpp}
\begin{table}[htb] \centering
\begin{tabular}{cl}
\toprule
Field & Description \\
\midrule
\code{E} & Young's modulus \\
\code{A} & Cross section area \\
\code{I} & Second cross sectional moment of inertia (for 2D elements)\\
\code{Iy} & \code{I} around beam $y$--axis (for 3D elements)\\
\code{Iz} & \code{I} around beam $z$--axis (for 3D elements)\\
\code{GJ} & Polar moment of inertia of beam cross section (for 3D elements)\\
\bottomrule
\end{tabular}
\caption{Material properties for structural elements defined in
the class \code{StructuralMaterial}.}
\label{tab:structMechMod:strucMaterial}
\end{table}
Materials can be added to the model's \code{element\_material} vector using
\begin{cpp}
model.addMaterial(mat1);
\end{cpp}
They are successively numbered and then assigned to specific elements.
\begin{cpp}
for (UInt i = 0; i < nb_element_mat_1; ++i) {
model.getElementMaterial(_bernoulli_beam_2)(i,0) = 1;
}
\end{cpp}
\subsection{Setting Boundary Conditions}\label{sect:structMechMod:boundary}
As explained before, the Dirichlet boundary conditions are applied through the
array \textbf{blocked\_dofs}. Two options exist to define Neumann conditions.
If a nodal force is applied, it has to be directly set in the array
\textbf{force\_momentum}. For loads distributed along the beam length, the
method \code{computeForcesFromFunction} integrates them into nodal forces. The
method takes as input a function describing the distribution of loads along the
beam and a functor \code{BoundaryFunctionType} specifing if the function is
expressed in the local coordinates (\code{\_bft\_traction\_local}) or in the
global system of coordinates (\code{\_bft\_traction}).
\begin{cpp}
static void lin_load(double * position, double * load,
Real * normal, UInt surface_id){
memset(load,0,sizeof(Real)*3);
load[1] = position[0]*position[0]-250;
}
int main(int argc, char *argv[]){
...
model.computeForcesFromFunction<_bernoulli_beam_2>(lin_load,
_bft_traction_local);
...}
\end{cpp}
\section{Static Analysis\label{sect:structMechMod:static}}
The \code{StructuralMechanicsModel} class can perform static analyses
of structures. In this case, the equation to solve is the same as for
the \code{SolidMechanicsModel} used for static analyses
\begin{equation}\label{eqn:structMechMod:static}
\mat{K} \vec{u} = \vec{f_{\st{ext}}}~,
\end{equation}
where $\mat{K}$ is the global stiffness matrix, $\vec{u}$ the
generalized displacement vector and $\vec{f_{\st{ext}}}$ the vector of
generalized external forces applied to the system.
To solve such a problem, the static solver of the
\code{StructuralMechanicsModel}\index{StructuralMechanicsModel} object
is used. First a model has to be created and initialized.
\begin{cpp}
StructuralMechanicsModel model(mesh);
model.initFull();
\end{cpp}
\begin{itemize}
\item \code{model.initFull} initializes all internal vectors to zero.
\end{itemize}
Once the model is created and initialized, the boundary conditions can
be set as explained in Section~\ref{sect:structMechMod:boundary}.
Boundary conditions will prescribe the external forces or moments for
the free degrees of freedom $\vec{f_{\st{ext}}}$ and displacements or
rotations for the others. To completely define the system represented
by equation (\ref{eqn:structMechMod:static}), the global stiffness
matrix $\mat{K}$ must be assembled.
\index{StructuralMechanicsModel!assembleStiffnessMatrix}
\begin{cpp}
model.assembleStiffnessMatrix();
\end{cpp}
The computation of the static equilibrium is performed using the same
Newton-Raphson algorithm as described in
Section~\ref{sect:smm:static}.
\note{To date,
\code{StructuralMechanicsModel} handles only constitutively and
geometrically linear problems, the algorithm is therefore guaranteed
to converge in two iterations.}
\begin{cpp}
model.updateResidual();
model.solve();
\end{cpp}
\index{StructuralMechanicsModel!updateResidual}
\index{StructuralMechanicsModel!solve}
\begin{itemize}
\item \code{model.updateResidual} assembles the internal forces and
removes them from the external forces.
\item \code{model.solve} solves the Equation (\ref{eqn:structMechMod:static}).
The \textbf{increment} vector of the model will contain the new
increment of displacements, and the \textbf{displacement\_rotation}
vector is also updated to the new displacements.
\end{itemize}
%At the end of the analysis, the final solution is stored in the
%\textbf{displacement} vector. A full example of how to solve a
%structural mechanics problem is presented in the code
%\shellcode{\examplesdir/structural\_mechanics/test\_structural\_mechanics\_model\_bernoulli\_beam\_2\_exemple\_1\_1.cc}.
%This example is composed of a 2D beam, clamped at the left end and
%supported by two rollers as shown in Figure
%\ref{fig:structMechMod:exem1_1}. The problem is defined by the
%applied load $q=\SI{6}{\kilo\newton\per\metre}$, moment $\bar{M} =
%\SI{3.6}{\kilo\newton\metre}$, moments of inertia $I_1 =
%\SI{250\,000}{\power{\centi\metre}{4}}$ and $I_2 =
%\SI{128\,000}{\power{\centi\metre}{4}}$ and lengths $L_1 =
%\SI{10}{\metre}$ and $L_2 = \SI{8}{\metre}$. The resulting
%rotations at node two and three are $ \varphi_2 = 0.001\,167\
%\mbox{and}\ \varphi_3 = -0.000\,771.$
At the end of the analysis, the final solution is stored in the
\textbf{displacement\_rotation} vector. A full example of how to
solve a structural mechanics problem is presented in the code
\shellcode{\examplesdir/structural\_mechanics/bernoulli\_beam\_2\_example.cc}.
This example is composed of a 2D beam, clamped at the left end and
supported by two rollers as shown in Figure
\ref{fig:structMechMod:exem1_1}. The problem is defined by the
applied load $q=\SI{6}{\kilo\newton\per\metre}$, moment $\bar{M} =
\SI{3.6}{\kilo\newton\metre}$, moments of inertia $I_1 =
\SI{250\,000}{\centi\metre\tothe{4}}$ and $I_2 =
\SI{128\,000}{\centi\metre\tothe{4}}$ and lengths $L_1 =
\SI{10}{\metre}$ and $L_2 = \SI{8}{\metre}$. The resulting
rotations at node two and three are $ \varphi_2 = 0.001\,167\
\mbox{and}\ \varphi_3 = -0.000\,771.$
\begin{figure}[htb]
\centering
\includegraphics[scale=1.1]{figures/beam_example}
\caption{2D beam example}
\label{fig:structMechMod:exem1_1}
\end{figure}
%%% Local Variables:
%%% mode: latex
%%% TeX-master: "manual"
%%% End:
Event Timeline
Log In to Comment