In
the Visualization module,
examine the deformation of the blank.
Deformed model shape and contour
plots
The basic result of this simulation is the deformation of the blank and the
plastic strain caused by the forming process. We can plot the deformed model
shape and the plastic strain, as described below.
To plot the deformed model shape:
Plot the deformed model shape. You can remove the die and the punch from the
display and visualize just the blank.
In the
Results Tree,
expand the Instances container underneath the output
database file named Channel.odb.
From the list of available part instances, select
BLANK-1. Click mouse button 3, and select
Replace from the menu that appears to replace the current
display group with the selected elements. Click
, if necessary, to fit the model in the viewport.
To plot the contours of equivalent
plastic strain:
From the main menu bar, select
PlotContoursOn
Deformed Shape; or click the
tool from the toolbox to display contours of Mises stress.
Open the Contour Plot Options dialog box.
Drag the Contour Intervals slider to change the number
of contour intervals to 7.
Click OK to apply these settings.
Select Primary from the list of variable types on the
left side of the Field Output toolbar, and select
PEEQ from the list of output variables.
PEEQ is an integrated measure of plastic
strain. A nonintegrated measure of plastic strain is
PEMAG. PEEQ
and PEMAG are equal for proportional loading.
Use the
tool to zoom into any region of interest in the blank, as shown in
Figure 2.
The maximum plastic strain is approximately 21%. Compare this with the
failure strain of the material to determine if the material will tear during
the forming process.
History plots of
the reaction forces on the blank and punch
The solid line in
Figure 3
shows the variation of the reaction force RF2 at the punch's rigid body reference node.
To create a history plot of the reaction force:
In the
Results Tree,
expand the History Output container. Double-click
Reaction force: RF1 PI: PUNCH–1 Node
xxx in NSET REFPUNCH.
A history plot of the reaction force in the 1-direction appears.
Open the Axis Options dialog box to label the axes.
Switch to the Title tabbed page.
Specify Reaction Force - RF2 as the
Y-axis label, and Total
Time as the X-axis label.
Click Dismiss to close the dialog box.
The punch force, shown in
Figure 3,
rapidly increases to about 160 kN during Step 2, which runs from a total time
of 1.0 to 2.0.
History plot of
the stabilization and internal energies
It is important to verify that the presence of contact stabilization does
not significantly alter the physics of the problem. One way to assess this
requirement is to compare the energy dissipation due to stabilization (ALLSD) against the internal energy of the structure (ALLIE). Ideally the amount of stabilization energy should be a small
fraction of the internal energy.
Figure 4
shows the variation of the stabilization and internal energies. It is clear
that the dissipated stabilization energy is indeed small.
Plotting
contours on surfaces
Abaqus/CAE
includes a number of features designed specifically for postprocessing contact
analyses. Within
the Visualization module,
the Display Group feature can be used to collect surfaces
into display groups, similar to element and node sets.
To display contact surface normal vectors:
Plot the undeformed model shape.
In the
Results Tree,
expand the Surface Sets container. Select the surfaces
named BLANKTOP and
PUNCH-1.PUNCHSURF. Click mouse button 3, and
select Replace from the menu that appears.
Using the Common Plot Options dialog box, turn on the
display of the normal vectors (On surfaces) and set the
length of the vector arrows to Short.
Use the
tool, if necessary, to zoom into any region of interest, as shown in
Figure 5.
To contour the contact
pressure:
Plot the contours of plastic strain again.
From the list of variable types on the left side of the Field
Output toolbar, select Primary, if it is not
already selected.
From the list of output variables in the center of the toolbar, select
CPRESS.
Remove the PUNCH-1.PUNCHSURF surface from
your display group.
To visualize contours of surface-based variables better in two-dimensional
models, you can extrude the plane strain elements to construct the equivalent
three-dimensional view. You can sweep axisymmetric elements in a similar
fashion.
From the main menu bar, select
ViewODB Display
Options.
The ODB Display Options dialog box appears.
Select the Sweep/Extrude tab to access the
Sweep/Extrude options.
In the Extrude region of the dialog box, toggle on
Extrude elements; and set the Depth
to 0.05 to extrude the model for the purpose of
displaying contours.
Click OK to apply these settings.
Rotate the model using the
tool to display the model from a suitable view, such as the one
shown in
Figure 6.