You can create a multi-sections surface by sweeping one or more
section curves along an automatically computed or user-defined spine. The surface
can be made to respect one or more guide curves.
You can create a multisections surface by sweeping one or more section curves along the
spine.
From the Surface
section of the action bar, click
Multi-sections Surface.
Select one or more planar section curves.
Important:
The curves must be continuous in point.
You need to have GS1 installed to create a multisections surface with more than two
sections.
Tip:
A closing point can be selected for the closed section
curves.
Optional:
Select a support surface for each of the extremity section curve.
Note:
The boundary must fully lie on the support. The support surfaces must
not be parallel to the sections.
Optional:
In the
Continuity list, select the continuity type
for each support surface.
By default, the continuity is set to Tangent.
Note:
You can modify the continuity type either from:
the dialog box: select the input in the list and modify the type
from the Continuity list, or
the work area: click the widget to switch
from one type to another or right-click it and select the type.
Widgets are useful to visualize whether and which continuity is
set on a section curve.
indicates tangent
continuity.
indicates curvature
continuity.
Click
Preview.
Important:
The sections can be 3D curves provided that the intersection between
one 3D profile and all guides is coplanar (if three guides or more are
defined.)
Optional: Select one or more guide curves.
Important:
The guide curves must intersect each section curve
and must be continuous in point.
The first guide curve is a
boundary of the multisections surface if it intersects the first extremity
of each section curve.
Similarly, the last guide curve is a boundary of
the multisections surface if it intersects the last extremity of each
section curve.
You can make a multisections surface tangent to an adjacent surface by
selecting an end section that lies on the adjacent surface. In this
case, the guides must also be tangent to the surface.
You can also impose tangency conditions by specifying a direction for the
tangent vector (selecting a plane to take its normal, for example). This
is useful for creating 3D shape representations that are symmetrical
with respect to a plane. Tangency conditions can be imposed on the two
symmetrical halves.
Similarly, you can impose a tangency onto each guide, by selection of a
surface or a plane (the direction is tangent to the plane's normal.) In
this case, the sections must also be tangent to the surface.
Note:
You can create a multisections surface by sweeping a section curve
along two guide curves intersecting each other at one extremity.
Optional:
Select the support for extremity guide curves and select the continuity
type for each support surface.
By default, the continuity is set to
Tangent.
Click OK.
The surface (identified as Multi-sections
Surface.xxx) is added to the tree.
In case a section is defined by a
closed curve, the extremum points are aggregated under the parent
command that created them and put in no show in the tree.
Define Smooth Parameters
You can define the smoothing parameters on the multisection surfaces.
In the Smooth parameters area, you can select the following options:
Option
Description
Angular Correction
Smoothes the lofting motion along the reference guide curves. This may be required
when small discontinuities are detected for the spine tangency or the reference guide
curves' normal. The smoothing is done for any discontinuity, for
which angular deviation is smaller than the input value, and
therefore helps generating better quality for the resulting
multisections surface. Over 0.01deg, the smoothing is canceled. By
default, the angular correction is set to 0.5deg.
Angular Correction
Smoothes the lofting motion by deviating from the guide curves. A smoothing is
performed using correction default parameters in tangency and
curvature. By default, the deviation is set to 0.001mm, as defined
in the preferences.
Select a Spine
You can select a spine to guide the multisections surfaces.
In the Spine
box, select Computed Spine to use a spine that is automatically computed or select a curve to impose that curve as the spine.
The spine curve should be normal to each section plane and must be continuous in
tangency. Otherwise, it may lead to an unpredictable shape.
If the plane normal to the spine intersects one of the guiding curves at different points, it is advised to use the closest point to the spine point for coupling.
You can create multisections surfaces between closed section curves. These curves have
point continuity at their closing point. This closing point is
either a vertex or an extremum points automatically detected and
highlighted by the system. By default, the closing points of each
section are linked to each other. The red arrows in the figures
below represent the closing points of the closed section curves. You
can change the closing point by selecting any point on the curve.
Relimit the Multisections Surface
You can specify the relimitation type.
Select either to limit the multisections surface on the start section
(Relimited on start section), only on the end
section (Relimited on end section), on both, or on
none.
When none of the options are selected: the swept surface is
extrapolated up to the spine limits.
When both options are selected: the multisectionssections surface is
limited to corresponding .
When one or both options are cleared: the multisections surface is
swept along the spine:
If the spine is a user spine, the multisections surface is
limited by the spine extremities or by the first guide
extremity met along the spine.
If the spine is an automatically computed spine, and no
guide is selected: the multisections surface is limited by
the start and end sections.
If the spine is an automatically computed spine, and one or
two guides are selected: the multisections surface is
limited by the guides extremities.
if the spine is an automatically computed spine, and more
than two guides are selected: the spine stops at a point
corresponding to the barycenter of the guide extremities. In
any case, the tangent to the spine extremity is the mean
tangent to the guide extremities.
Important:
After the multisections surface is relimited, the following constraint needs to be fulfilled:
the plane normal to the guides spine defined at the points relimitation
point must intersect the
the resulting from this intersection must belong to the section.
Use a Canonical Element
You can detect planar surfaces to be used as planes for features needing one in
their definition.
Select the Canonical portion detection to automatically detect planar surfaces to be used as planes for features needing one in their definition.
Use an Area Law
You can define and control the shape of a multisectionssections surface between its .
Important:
The Area law option is available only if you have the Generative Shape Morphing (GSO) and Cast & Forged Part Design (CFO) licenses.
To create a multisections surface allowing an area law, the following inputs can be used:
planar sections (with no tangency conditions)
a spine (optional)
a guide curve (either no guide curve, one or two guide curves)
Lets you define the law that is used to create the multisections surface.
In our example, three sketches with closed contours have been created and filled. A spine
between these sections has been created:
Click Measure
to compute
the geodesic length of the spine:
Click Split
to split
the spine by the section plane.
Click Measure
again to
compute the geodesic length of the resulting curve:
Using the Sketcher, create a line and a curve
corresponding to the previous computed lengths.
Important:
Radius values (16.2, 9.5 and 14.142) are similar to
the radius values of the corresponding sections (that is R=√(A/π) where
A is the section area).
Click Extract
to create
separate elements of the line and curve.
Click Law
to create the law from the previously extracted elements.
Select the Reference line and the
Definition curve.
Click OK to create the law.
Click Multi-sections Surface
.
The Multi-sections Surface Definition dialog
box appears.
Select the sketches as the planar section curves.
Select the Area lawtab.
In the Law box, specify the length law to be used to
control the section area.
Here, select the law we have newly created.
The Intermediate sections deviation option only applies to
intermediate sections (unlike the Deviation
option that applies to the sections extremities) and is homogeneous with
the selected law. It specifies the deviation of the length law to be
applied to the intermediate sections in smooth the resulting shape.
Click OK to create the multisections surface.
Important:
You can select the Display computed area
law check box to display in the 3D geometry:
You need to first start the computation of law before displaying
its computed area in the 3D geometry. Double-click the law in
the tree and then click
Preview to display the computed area.
Red indicates the area law.
Blue indicates the sections areas and a flag on each section
that displays the deviation between the area law and the
sections areas as well as the equivalent radius of each section.
Creating a Coupling
There are three kinds of coupling during the creation of the multisections surface.
These couplings compute the distribution of isoparameters on the surface.
Coupling between two consecutive sections
This coupling is based on the curvilinear abscissa.
Click Multi-sections Surface
.
Select the two consecutive sections.
Click OK.
If you want to create a coupling between particular potots, you can add guides or define
the coupling type.
Coupling between guides
The coupling of the sections is performed by the spine.
If a guide is the concatenation of several curves, the resulting multisections surface
contains as many surfaces as curves within the guide.
Before you begin: Several coupling types are available, depending on the section configuration:
Ratio: the curves are coupled according to the curvilinear abscissa ratio.
Tangency: the curves are coupled according to their tangency discontinuity points. If they do not have the same number of points, they cannot be coupled using this option.
Tangency then curvature: the curves are coupled according to their tangency continuity first then curvature discontinuity points. If they do not have the same number of points, they cannot be coupled using this option.
Vertices: the curves are coupled according to their vertices. If they do not have the same number of vertices, they cannot be coupled using this option.
Manual Coupling
If the number of vertices differ from one section to another, you need to
perform a manual coupling.
Select the sections for the multisectionssections surface, and confirm
their orientations.
In the Couplingtab, select
Tangency and click
Preview.
An error message is displayed as the number of discontinuity points on the first
section is greater than on the other two .
The points that could not
be coupled, are displayed in the geometry with the specific symbol
depending on the selected mode, along with coupling lines:
In Tangency mode: uncoupled tangency
discontinuity points are represented by a square.
In Tangency then curvature mode:
Uncoupled tangency discontinuity points are represented
by a square.
Uncoupled curvatures discontinuity points are
represented by an empty circle.
In Vertices mode: uncoupled vertices are
represented by a full circle
Double-click in the coupling list, or select Add
in the context menu, or using the Add
option, and manually select a point on the first section.
The Coupling dialog box appears.
Select a corresponding coupling point on each section of the
multisections surface.
The Coupling dialog box is updated
consequently, and the coupling curve is previewed, provided
Display coupling curves check box is
selected.
When a coupling point has been defined on each section,
this dialog box automatically disappears.
Click OK.
The multisections surface is created as defined with the coupling specifications.
The same multisections- surface without coupling and with
Ratio option would have looked like this:
Note the increased number of generated surfaces.
Tips:
You can create a coupling point on the fly, using the Create coupling
pointcontext menu item (click in the work area to display the context menu) instead of selecting an
existing point.
To edit the coupling, double-click the coupling name in the list
(Couplingtab) to display the
Coupling dialog box. Then you select the
point to be edited from the list and create/select a replacing
coupling point, then click OK.
Use the context menu on the coupling list to edit
defined couplings.
Edit a Multisections Surface
You can edit the multiselection surfaces.
Double-click the multisections surface either in the work area or in the tree. More possibilities are available with
the context menu:
right-click the surface to access the following options:
Add Section
Computed Spine
Add Spine
Add Guide
Add Guide
Add Coupling
Ratio Coupling
Tangency Coupling
Tangency then Curvature Coupling
Vertices Coupling
No relimitation
right-click the multisections surface reference elements, either
a curve in the dialog box list or the red text on the figure to
access the following options: