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{{UnfinishedDocu{{#translation:}}}}
{{Docnav
{{Docnav/de
|[[FEM_MeshNetgenFromShape|FEM mesh from shape by Netgen]]
|[[FEM_MeshNetgenFromShape/de|Netz aus Form durch Netgen]]
|[[FEM_MeshBoundaryLayer|FEM mesh boundary layer]]
|[[FEM_MeshBoundaryLayer/de|NetzGrenzschicht]]
|[[FEM_Module|FEM]]
|[[FEM_Workbench/de|FEM]]
|IconL=FEM_MeshNetgenFromShape.png
|IconL=FEM_MeshNetgenFromShape.svg
|IconC=Workbench_FEM.svg
|IconR=Fem-femmesh-boundary-layer.svg
|IconR=Fem-femmesh-boundary-layer.svg
|IconC=Workbench_FEM.svg
}}
}}


{{GuiCommand
{{GuiCommand/de
|Name=FEM MeshGmshFromShape
|Name=FEM MeshGmshFromShape
|Name/de=FEM NetzGmshAusForm
|MenuLocation=Mesh → FEM mesh from shape by Gmsh
|MenuLocation=Netz → FEM-Netz aus Form - Gmsh
|Workbenches=[[Fem Workbench|FEM]]
|Workbenches=[[FEM_Workbench/de|FEM]]
|Shortcut=None
|SeeAlso=[[FEM_tutorial|FEM tutorial]]
|SeeAlso=[[FEM_tutorial/de|FEM Tutorium]]
}}
}}


<span id="Description"></span>
==Beschreibung==
==Beschreibung==


Für eine Finite-Elemente-Analyse muss die Geometrie in ein [[FEM_Mesh/de|FEM-Netz]] diskretisiert werden. Dieser Befehl verwendet die Software [https://en.wikipedia.org/wiki/Gmsh Gmsh] (die auf dem System installiert sein muss) zum Erstellen des Netzes.
For a finite elements analysis the geometry needs to be discretized into a [[FEM_Mesh]]. This command uses gmsh (which needs to be installed on the system) for calculating the mesh.


Abhängig vom Betriebssystem und dem Installationspaket kann Gmsh in FreeCAD enthalten sein oder auch nicht. Für weitere Informationen siehe [[FEM_Install/de|FEM Installation]].

<span id="Usage"></span>
==Anwendung==
==Anwendung==


# Die Form auswählen, die analysiert werden soll. Bei der Volumen-FEM muss es sich um einen Festkörper oder Compsolid (zusammengesetzten Festkörper) handeln. Ein Compsolid ist erforderlich, wenn dein Teil aus mehreren Materialien besteht. (Ein Compsolid kann mit dem Befehl [[Part_BooleanFragments/de|BoolescheFragmente]] erstellt werden).
# Select the shape you want to analyze. For volume FEM this needs to be a solid or compsolid. A compsolid is necessary if your part is made from multiple materials. (A compsolid can be created with the [[Part_BooleanFragments|BooleanFragments]] command.) -- For shell and beam FEM somebody needs to fill in the details here.
# Press the {{KEY|[[Image:FEM_MeshGmshFromShape.png|32px]] [[FEM_MeshGmshFromShape|FEM mesh from shape by GMSH]]}} button
#* Die Schaltfläche {{Button|[[Image:FEM_MeshGmshFromShape.svg|16px]] [[FEM_MeshGmshFromShape/de|FEM-Netz aus Form - Gmsh]]}} drücken.
#* Den Menüeintrag {{MenuCommand|Netz → [[Image:FEM_MeshGmshFromShape.svg|16px]] FEM-Netz aus Form - Gmsh}} auswählen.
# Optionally edit the minimal and maximal element size. (Autodetection works fine unless you apply complicated boundary conditions.)
# Bei Bedarf minimale und maximale Elementgröße anpassen. (Automatische Erkennung erstellt oft Netze, die zu grob sind).
# Click the {{KEY|Apply}} button and wait for the computation of the mesh to complete
# Die Schaltfläche {{Button|Anwenden}} anklicken und warten, bis die Erstellung des Netzes abgeschlossen ist.
# Close the task. You now should see a new FEMMeshGMSH object in your active analysis container.
# Die Aufgabe abschließen. Jetzt sollte sich ein neues FEMMeshGMSH-Objekt im aktiven Analysebehälter befinden.


After the mesh has been created, you can change its properties using the [[Property_editor|property editor]]. After you change a property, you must reopen the Gmsh dialog again and click the {{Button|Apply}} button (you can leave the dialog open while changing properties).
{{Docnav

|[[FEM_MeshNetgenFromShape|FEM mesh from shape by Netgen]]
<span id="Properties"></span>
|[[FEM_MeshBoundaryLayer|FEM mesh boundary layer]]
==Eigenschaften==
|[[FEM_Module|FEM]]

|IconL=FEM_MeshNetgenFromShape.png
* {{PropertyData|Algorithm2D}}: The algorithm to create 2D meshes. The different algorithms are [https://gmsh.info/doc/texinfo/gmsh.html#Choosing-the-right-unstructured-algorithm explained here]. For Delaunay, see [https://en.wikipedia.org/wiki/Delaunay_triangulation Delaunay triangulation].
|IconC=Workbench_FEM.svg
* {{PropertyData|Algorithm3D}}: The algorithm to create 3D meshes. The different algorithms are [https://gmsh.info/doc/texinfo/gmsh.html#Choosing-the-right-unstructured-algorithm explained here].
* {{PropertyData|Characteristic Length Max}}: The maximal size of the mesh elements. If set to ''0.0'', the size will be set automatically. This property can also be changed in the Gmsh dialog in the field '''Max element size'''.
* {{PropertyData|Characteristic Length Min}}: The minimal size of the mesh elements. If set to ''0.0'', the size will be set automatically. This property can also be changed in the Gmsh dialog in the field '''Min element size'''.
* {{PropertyData|Coherence Mesh}}:
** true (default); duplicate mesh nodes will be removed
** false
* {{PropertyData|Element Dimension}}: The dimension of the mesh elements. This property can also be changed in the Gmsh dialog in the field '''Mesh element dimension'''.
** From Shape (default); the dimension will be determined from the dimension of the object that is meshed
** 1D
** 2D
** 3D
* {{PropertyData|Element Order}}: The [https://www.comsol.de/support/knowledgebase/1270 mesh element order]. This property can also be changed in the Gmsh dialog in the field '''Mesh order'''. {{Version|0.20}}
** 1st
** 2nd (default)</br>'''Note:''' If you use the solver [[FEM_SolverElmer|Elmer]] you may get this error: ''ERROR:: GetEdgeBasis: Can't handle but linear elements, sorry.'' This means the solver equation cannot handle 2nd order meshes. Use either 1st order meshes then, or check the FreeCAD Wiki page for the solver equation for possible options to handle 2nd order meshes.
* {{PropertyData|Geometrical Tolerance}}: The geometrical tolerance for the mesh to match the object edges. The default ''0.0'' means that Gmsh's default of 1e-8 is used.
* {{PropertyData|Groups Of Nodes}}: All nodes and not only the elements will be saved for each physical mesh group. Physical groups are collections of mesh entities (points, curves, surfaces and volumes). They and are identified by their dimension and by a tag. For example a mesh of the same object region is internally tagged the same. So all surfaces of this region will form one physical group.
* {{PropertyData|High Order Optimize}}: If and how meshes with {{PropertyData|Element Order}} = ''2nd'' are optimized. The optimization is done by a deformation of the element borders.</br>{{Version|0.20}} Gmsh supports different optimization algorithms. '''Elastic''' is an algorithm in which the mesh elements are treated as a collection of deformable viscoelastic solids. 1st order meshes cannot be optimized because their element borders are linear an cannot be deformed.
* {{PropertyData|Mesh Size From Curvature}} {{Version|0.20}}: The number of mesh elements per <math>2\pi</math> times the radius of the curvature. To get a finer mesh at small corners or holes, this value can be increased for better results
[[Image:FEM_Gmsh-MeshSizeFromCurvature.png|450px]]
{{Caption|Effect of ''Mesh Size From Curvature'''; left: set to 12, right: deactivated}}
* {{PropertyData|Optimize Netgen}}: Whether the mesh will be optimized using the 3D mesh generator [https://github.com/NGSolve/netgen Netgen] to improve the quality of tetrahedral elements. '''Note:''' since Netgen can only create tetrahedral elements, this option is ignored for meshes whose {{PropertyData|Element Dimension}} is not ''3D''.
* {{PropertyData|Recombination Algorithm}} {{Version|0.20}}: The algorithm used for {{PropertyData|Recombine 3D All}} and also for {{PropertyData|Recombine All}}. For more info, see section [[#Element_Recombination|Element Recombination]] and for technical details see the [https://www.gmsh.info/doc/texinfo/gmsh.html#t11 Gmsh documentation].
* {{PropertyData|Recombine 3D All}} {{Version|0.20}}: Applies a recombination 3D-algorithm to all volumes. Tetrahedra will be recombined into prisms, hexahedra or pyramids if possible.
* {{PropertyData|Recombine All}}: Applies a recombination algorithm to all surfaces. Triangles will be recombined into quadrangles when possible.
* {{PropertyData|Optimize Std}} Optimizes the mesh to improve the quality of tetrahedral elements.
* {{PropertyData|Second Order Linear}}: Option if second order nodes (if {{PropertyData|Element Order}} set to ''2nd'') and/or mesh refinement points are created by linear interpolation.
** true; linear interpolation is used
** false (default); curvilinear interpolation is used
* {{PropertyData|Subdivision Algorithm}} {{Version|0.22}}: allows the creation of quadrilateral and hexahedral elements by subdivision
** None; doesn't use any subdivision algorithm
** All Quadrangles; creates quadrilateral elements by subdivision
** All Hexahedra; creates hexahedral elements by subdivision
** Barycentric; creates triangular elements by barycentric subdivision

<span id="Notes"></span>
==Hinweise==

=== Nonpositive Jacobians ===

When you get a meshing error about nonpositive Jacobians, you can try out the following strategies:

* Set {{PropertyData|Second Order Linear}} to ''true'' but keep {{PropertyData|Element Order}} at ''2nd''.
* Set {{PropertyData|Element Order}} to ''1st''.
* Use a smaller element size by reducing the {{PropertyData|Characteristic Length Max}}.
* If solver ccxtools is used and the run button is used (not the task panel) the nodes of nonpositive jacobian elements will be green.

===Mesh Growth===

At edges and small geometric entities, the mesh has to be smaller than in areas without edges. So the mesh element size grows away from the edges. The growing strategy of Gmsh is to grow between edges of different sizes. So the growing fails when an area has the same sized edges like for example this tube:

[[Image:FEM_Gmsh-MeshGrowth-failing.png|400px]]
{{Caption|Failing mesh growing because the cylindrical area is surrounded by the same edges}}

To enable a sensible mesh growing, you must in this case add an edge to the area. In the example, this would be a circle in the middle of the cylinder. The circle is added as part of a [[Part_BooleanFragments|BooleanFragments]] compound (to form a CompSolid), see [https://forum.freecadweb.org/download/file.php?id=146255 the project file] of the example.

[[Image:FEM_Gmsh-MeshGrowth-success.png|400px]]
{{Caption|Sensible mesh growing due to the additional edge in the middle of the cylindrical area}}

===Element Recombination===

Elements can be recombined in two ways, on the surface of objects so that triangles will be recombined into quadrangles if possible and in the volume of objects so that tetrahedra will be recombined into prisms, hexahedra or pyramids if possible. Thinking about the geometry, it becomes clear that the recombination result depends strongly on the geometry of the body and that recombining a 3D body only at the surface will mostly lead to strange results.

To illustrate this, look at the image below. A cuboid body is meshed using the standard settings (tetrahedra, 2nd order mesh). This is the subimage at the upper left. The image at the upper right shows the result, when additionally the elements are recombined only at the surface of the body. The result is bad because the changed surface elements don't fit to the unchanged volume elements. So {{PropertyData|Recombine All}} alone usually only makes sense for 2D meshes. </br>When we use now also {{PropertyData|Recombine 3D All}}, the result is better, see the lower left subimage. However, the result doesn't show a great difference compared to the mesh without recombinations. Since our body is a cuboid, it is therefore sensible to use a recombination algorithm that tries to create cuboids as well. And this result is shown in the subimage at the lower right.

The ''Simple'' recombination algorithm will leave some triangles in the mesh in case the recombining leads to badly shaped quads. In such cases use a ''full-quad'' recombination algorithm, which will automatically perform a coarser mesh followed by the recombination, smoothing and subdividing. See [https://forum.freecadweb.org/viewtopic.php?f=18&t=20351#p520392 forum topic]

[[Image:FEM_Gmsh-Recombination.png|600px]]
{{Caption|Effect of mesh element recombination.<br>
Upper left: standard mesh.<br>
Upper right: recombination only at the surface using the '''Simple''' algorithm.<br>
Lower left: recombination at the surface and in the volume using the '''Simple''' algorithm.<br>
Lower right: recombination at the surface and in the volume using the '''Simple full-quad''' algorithm}}


{{Docnav/de
|[[FEM_MeshNetgenFromShape/de|Netz aus Form durch Netgen]]
|[[FEM_MeshBoundaryLayer/de|NetzGrenzschicht]]
|[[FEM_Workbench/de|FEM]]
|IconL=FEM_MeshNetgenFromShape.svg
|IconR=Fem-femmesh-boundary-layer.svg
|IconR=Fem-femmesh-boundary-layer.svg
|IconC=Workbench_FEM.svg
}}
}}


Latest revision as of 09:21, 18 March 2024

Other languages:

FEM NetzGmshAusForm

Menüeintrag
Netz → FEM-Netz aus Form - Gmsh
Arbeitsbereich
FEM
Standardtastenkürzel
Keiner
Eingeführt in Version
-
Siehe auch
FEM Tutorium

Beschreibung

Für eine Finite-Elemente-Analyse muss die Geometrie in ein FEM-Netz diskretisiert werden. Dieser Befehl verwendet die Software Gmsh (die auf dem System installiert sein muss) zum Erstellen des Netzes.

Abhängig vom Betriebssystem und dem Installationspaket kann Gmsh in FreeCAD enthalten sein oder auch nicht. Für weitere Informationen siehe FEM Installation.

Anwendung

  1. Die Form auswählen, die analysiert werden soll. Bei der Volumen-FEM muss es sich um einen Festkörper oder Compsolid (zusammengesetzten Festkörper) handeln. Ein Compsolid ist erforderlich, wenn dein Teil aus mehreren Materialien besteht. (Ein Compsolid kann mit dem Befehl BoolescheFragmente erstellt werden).
  2. Bei Bedarf minimale und maximale Elementgröße anpassen. (Automatische Erkennung erstellt oft Netze, die zu grob sind).
  3. Die Schaltfläche Anwenden anklicken und warten, bis die Erstellung des Netzes abgeschlossen ist.
  4. Die Aufgabe abschließen. Jetzt sollte sich ein neues FEMMeshGMSH-Objekt im aktiven Analysebehälter befinden.

After the mesh has been created, you can change its properties using the property editor. After you change a property, you must reopen the Gmsh dialog again and click the Apply button (you can leave the dialog open while changing properties).

Eigenschaften

  • DatenAlgorithm2D: The algorithm to create 2D meshes. The different algorithms are explained here. For Delaunay, see Delaunay triangulation.
  • DatenAlgorithm3D: The algorithm to create 3D meshes. The different algorithms are explained here.
  • DatenCharacteristic Length Max: The maximal size of the mesh elements. If set to 0.0, the size will be set automatically. This property can also be changed in the Gmsh dialog in the field Max element size.
  • DatenCharacteristic Length Min: The minimal size of the mesh elements. If set to 0.0, the size will be set automatically. This property can also be changed in the Gmsh dialog in the field Min element size.
  • DatenCoherence Mesh:
    • true (default); duplicate mesh nodes will be removed
    • false
  • DatenElement Dimension: The dimension of the mesh elements. This property can also be changed in the Gmsh dialog in the field Mesh element dimension.
    • From Shape (default); the dimension will be determined from the dimension of the object that is meshed
    • 1D
    • 2D
    • 3D
  • DatenElement Order: The mesh element order. This property can also be changed in the Gmsh dialog in the field Mesh order. introduced in version 0.20
    • 1st
    • 2nd (default)
      Note: If you use the solver Elmer you may get this error: ERROR:: GetEdgeBasis: Can't handle but linear elements, sorry. This means the solver equation cannot handle 2nd order meshes. Use either 1st order meshes then, or check the FreeCAD Wiki page for the solver equation for possible options to handle 2nd order meshes.
  • DatenGeometrical Tolerance: The geometrical tolerance for the mesh to match the object edges. The default 0.0 means that Gmsh's default of 1e-8 is used.
  • DatenGroups Of Nodes: All nodes and not only the elements will be saved for each physical mesh group. Physical groups are collections of mesh entities (points, curves, surfaces and volumes). They and are identified by their dimension and by a tag. For example a mesh of the same object region is internally tagged the same. So all surfaces of this region will form one physical group.
  • DatenHigh Order Optimize: If and how meshes with DatenElement Order = 2nd are optimized. The optimization is done by a deformation of the element borders.
    introduced in version 0.20 Gmsh supports different optimization algorithms. Elastic is an algorithm in which the mesh elements are treated as a collection of deformable viscoelastic solids. 1st order meshes cannot be optimized because their element borders are linear an cannot be deformed.
  • DatenMesh Size From Curvature introduced in version 0.20: The number of mesh elements per times the radius of the curvature. To get a finer mesh at small corners or holes, this value can be increased for better results

Effect of Mesh Size From Curvature'; left: set to 12, right: deactivated

  • DatenOptimize Netgen: Whether the mesh will be optimized using the 3D mesh generator Netgen to improve the quality of tetrahedral elements. Note: since Netgen can only create tetrahedral elements, this option is ignored for meshes whose DatenElement Dimension is not 3D.
  • DatenRecombination Algorithm introduced in version 0.20: The algorithm used for DatenRecombine 3D All and also for DatenRecombine All. For more info, see section Element Recombination and for technical details see the Gmsh documentation.
  • DatenRecombine 3D All introduced in version 0.20: Applies a recombination 3D-algorithm to all volumes. Tetrahedra will be recombined into prisms, hexahedra or pyramids if possible.
  • DatenRecombine All: Applies a recombination algorithm to all surfaces. Triangles will be recombined into quadrangles when possible.
  • DatenOptimize Std Optimizes the mesh to improve the quality of tetrahedral elements.
  • DatenSecond Order Linear: Option if second order nodes (if DatenElement Order set to 2nd) and/or mesh refinement points are created by linear interpolation.
    • true; linear interpolation is used
    • false (default); curvilinear interpolation is used
  • DatenSubdivision Algorithm introduced in version 0.22: allows the creation of quadrilateral and hexahedral elements by subdivision
    • None; doesn't use any subdivision algorithm
    • All Quadrangles; creates quadrilateral elements by subdivision
    • All Hexahedra; creates hexahedral elements by subdivision
    • Barycentric; creates triangular elements by barycentric subdivision

Hinweise

Nonpositive Jacobians

When you get a meshing error about nonpositive Jacobians, you can try out the following strategies:

  • Set DatenSecond Order Linear to true but keep DatenElement Order at 2nd.
  • Set DatenElement Order to 1st.
  • Use a smaller element size by reducing the DatenCharacteristic Length Max.
  • If solver ccxtools is used and the run button is used (not the task panel) the nodes of nonpositive jacobian elements will be green.

Mesh Growth

At edges and small geometric entities, the mesh has to be smaller than in areas without edges. So the mesh element size grows away from the edges. The growing strategy of Gmsh is to grow between edges of different sizes. So the growing fails when an area has the same sized edges like for example this tube:

Failing mesh growing because the cylindrical area is surrounded by the same edges

To enable a sensible mesh growing, you must in this case add an edge to the area. In the example, this would be a circle in the middle of the cylinder. The circle is added as part of a BooleanFragments compound (to form a CompSolid), see the project file of the example.

Sensible mesh growing due to the additional edge in the middle of the cylindrical area

Element Recombination

Elements can be recombined in two ways, on the surface of objects so that triangles will be recombined into quadrangles if possible and in the volume of objects so that tetrahedra will be recombined into prisms, hexahedra or pyramids if possible. Thinking about the geometry, it becomes clear that the recombination result depends strongly on the geometry of the body and that recombining a 3D body only at the surface will mostly lead to strange results.

To illustrate this, look at the image below. A cuboid body is meshed using the standard settings (tetrahedra, 2nd order mesh). This is the subimage at the upper left. The image at the upper right shows the result, when additionally the elements are recombined only at the surface of the body. The result is bad because the changed surface elements don't fit to the unchanged volume elements. So DatenRecombine All alone usually only makes sense for 2D meshes.
When we use now also DatenRecombine 3D All, the result is better, see the lower left subimage. However, the result doesn't show a great difference compared to the mesh without recombinations. Since our body is a cuboid, it is therefore sensible to use a recombination algorithm that tries to create cuboids as well. And this result is shown in the subimage at the lower right.

The Simple recombination algorithm will leave some triangles in the mesh in case the recombining leads to badly shaped quads. In such cases use a full-quad recombination algorithm, which will automatically perform a coarser mesh followed by the recombination, smoothing and subdividing. See forum topic

Effect of mesh element recombination.
Upper left: standard mesh.
Upper right: recombination only at the surface using the Simple algorithm.
Lower left: recombination at the surface and in the volume using the Simple algorithm.
Lower right: recombination at the surface and in the volume using the Simple full-quad algorithm


FEM

Constraints

Anwenderdokumentation
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