Selecting an Adaptivity Technique
Three adaptivity techniques are available in Abaqus: Arbitrary Lagrangian-Eulerian (ALE) adaptive meshing; varying topology adaptive remeshing (this functionality is not applicable to the 3DEXPERIENCE Platform); and mesh-to-mesh solution mapping, to enable rezoning analysis. Table 1 shows that the adaptivity techniques can be classified according to
their applicability to achieving particular goals, either accuracy or control of mesh distortion;
their impact on mesh definitions, either through smoothing a single mesh or through generating multiple dissimilar meshes; and
when adaptivity occurs with respect to analysis steps.
Accuracy | Distortion control | Single mesh | Multiple meshes | Adaptivity occurs | |
---|---|---|---|---|---|
ALE adaptive meshing | Throughout a step | ||||
Adaptive remeshing (not applicable to the 3DEXPERIENCE Platform) | Separately from analysis steps | ||||
Mesh-to-mesh solution mapping | Between analysis steps |
ALE Adaptive Meshing
Arbitrary Lagrangian-Eulerian (ALE) adaptive meshing provides control of mesh distortion. ALE adaptive meshing uses a single mesh definition that is gradually smoothed within analysis steps. ALE adaptive meshing is available for limited applications in Abaqus/Standard and is more generally applicable in Abaqus/Explicit. The term ALE implies a broad range of analysis approaches, from purely Lagrangian analysis, in which the node motion corresponds to material motion, to purely Eulerian analysis, in which the nodes remain fixed in space and material “flows” through the elements. Typically ALE analyses use an approach between these two extremes. The ALE feature is distinct from the Eulerian analysis capability in Abaqus/Explicit, which is described in Eulerian Analysis.
You can use adaptive meshing to control element distortion in cases where large deformation or loss of material occurs. Figure 1 illustrates a case where adaptive meshing limits mesh distortion in a bulk forming simulation.
Unlike other adaptivity techniques, adaptive meshing operates on your original mesh definition and is, therefore, useful only when a single mesh can be effective for the duration of a simulation. The mesh is adapted through smoothing of the mesh nodes. This smoothing is typically applied frequently within analysis steps. ALE adaptive meshing requires only one analysis job. See About ALE Adaptive Meshing for details.
Mesh-to-Mesh Solution Mapping
Mesh-to-mesh solution mapping is available only in Abaqus/Standard. You can use this technique to control element distortion in cases where large deformation occurs by replacing the mesh and continuing the analysis. Figure 2 illustrates a case where solution mapping is used in conjunction with a new mesh to overcome difficulties associated with element distortion.
Mesh replacement, or rezoning, involves the creation of multiple Abaqus jobs, each of which represents the configuration of the model in distinct, sequential periods of the simulation history. You use mesh replacement when a single mesh cannot be effective for the duration of a simulation. Each mesh subsequent to the initial configuration reflects a solution-dependent deformed configuration of the model. Therefore, analyses that use mesh replacement are sequentially dependent, and Abaqus uses mesh-to-mesh solution mapping to propagate solution variables from one analysis to the next. In contrast to adaptive remeshing, each mesh replacement job represents a component of the overall analysis history—no single mesh and no single analysis job represent your entire analysis. See Mesh-to-Mesh Solution Mapping for details.