 |
Body Forces
are intensive loads representing volume body force fields of uniform magnitude applied to
parts.
Body Force objects belong to the Loads objects
set.You need to specify three
components for the direction of the field, along with a magnitude information. Upon modification of any of these four
values, the volume body force vector components and magnitude are updated
based on the last data entry. The volume body force vector remains
constant independently of the geometry selection.
Units are volume body force units (typically N/m3
in SI).
|
 |
Body Forces can be applied to the following types of
Supports:
|
 |
This task shows you how to
create a Body Force applied to a part.
|
 |
You can use the sample00.CATAnalysis
document from the samples directory
for this task:
Finite Element Model containing a Static Analysis Case and computed corresponding Static
Solution.
Before You Begin:
Go to View -> Render Style -> Customize View and make
sure the Shading, Outlines and Materials options are active in the Custom View Modes
dialog box.
|
|
1. Click the Body Force icon 
.
The Body Force dialog box is displayed.
2. You can change the identifier of the
Body Force by editing
the Name field.
3. Set the Axis System.
In this example, select Global.
The Axis System Type combo box allows you to
choose between Global and User Axis systems for entering
components of the volume body force field.
 | Global: if you select the Global Axis system, the components of the
volume body force field will be interpreted as relative to the fixed
global rectangular coordinate system. |
| User: if you select a User-defined Axis system, the
components of the volume body force field will be
interpreted as relative to the specified rectangular coordinate system. |
To select a User-defined Axis system, you must activate an existing
Axis by clicking it in the specification tree. Its name will then be
automatically displayed in the Current Axis field.
If you choose the User axis system, the Local
orientation combo box further allows you to choose between Cartesian,
Cylindrical and Spherical local axis
orientations.
| Cartesian: the components of the surface traction field are
interpreted as relative to a fixed rectangular coordinate system aligned with
the Cartesian coordinate directions of the User-defined Axis. |
| Cylindrical: the components of the surface traction field are
interpreted as relative to a local variable rectangular coordinate system
aligned with the cylindrical coordinate directions of each point
relative to the User-defined Axis. |
| Spherical: the components of the surface traction field are
interpreted as relative to a a local variable rectangular coordinate system aligned
with the spherical coordinate directions of each point relative to
the User-defined Axis. |
|
|
You can re-use data (Data Mapping)
that are external from this version (experimental
data or data coming from in-house codes or procedures). For more
details, see Creating Pressures.
This capability is only available if you installed the ELFINI Structural Analysis product.
|
|
|
| You can define the
volume body force direction by using the compass. |
| You can modify the compass
orientation either with the mouse or by editing the compass. |
| By applying the compass to any
part geometry, you can align the compass directions with the implicit axis
directions of that geometry: drag the compass by handling the red square
and drop it on the appropriate surface. The normal direction to this
surface defines the new direction. Then, click on the Compass Direction
button to take this new direction into account. You can now invert the
direction if desired, editing the values of the three components. |
|
| |
4. Select the geometry
support (a part) on which the volume body force is to be applied. Any selectable geometry is
highlighted when you pass the cursor over it.
You can select several supports in
sequence, to apply the Body Force
to all supports
simultaneously. Symbols representing the Body Force are displayed on the
support geometry to visualize the volume body force field.
5. If needed, enter a new value for any one of the four fields. For
example, enter values for the X, Y, Z
components of the volume body force field as shown below
| The corresponding Norm
value is automatically computed and displayed. |
| The remaining three
fields are automatically computed and displayed. |
| The visualized symbols orientation is also updated to reflect the
modification. |
6. Click OK in the Body Force
dialog box to
create the Volume Force Density.
A Body Force object appears in the specification tree under the
active Loads objects set.
|
|
|
| You can either select the
part and then set the Body Force specifications, or set the Body Force specifications and then select the part. |
| If you select other
parts,
you can create as many Body Force loads as desired with the
same dialog box. A series of Body Force objects can therefore be
created quickly. |
| Loads are required for Stress
Analysis computations. |
|
If several Analysis Cases have been defined in
the Finite Element Model, you must activate a Loads objects set in the features
tree before creating a Body Force object (only available if you installed the ELFINI Structural Analysis
product). |
| Body Force objects can be edited by a double click on the
corresponding object or icon in the specification tree. |
|
|
Make sure the computation is finished before
starting any of the below operations.
|
|
|
Products
Available in
Analysis Workbench
The ELFINI Structural Analysis
product offers the following additional features with a right mouse click
(key 3):
|
on a Body Force object:
Volume load visualization on mesh: the translation of
your Body Force object specifications into solver
specifications can be visualized symbolically at the impacted mesh
elements, provided the mesh has been previously generated via a
Compute action.
|
|
on a Loads objects set:
1) Generate Image: generates an image of the computed Load objects
(along with translating all user-defined Loads specs into explicit solver commands
on mesh entities), by
generating symbols for the elementary loads imposed by the Loads
objects set. The image can be edited to include part or all of the
options available.
2) Report: the partial status and results of intermediate
pre-processor computations are reported in HTML format. It represents
a subset of the global Report capability and generates a partial
report of the Loads objects set Computation.
See Creating Pressures for more details.
|
|
|
3) Double-clicking on the Loads set, you will display the
Loads dialog box that lets you choose whether you wish to apply
self-balancing to the load. Example of use: if this option is used with
iso-static specifications, it will allow you to simulate free-body
loading. If you make the option active, the center of inertia results
null.
|
|
|
 |
