Thickness Mapping

The thickness mapping feature allows the user to map the thickness data from an external forming result file to the corresponding model in OptiStruct.

Consider a situation, when a component obtained from sheet metal forming needs to be analyzed further in an assembly model, after accounting for the thickness variation from forming.

Examples of such scenarios include stamping of an automotive door panel using HyperForm, followed by a full vehicle durability analysis using OptiStruct. In such cases, the thickness mapping featured in OptiStruct, can be used.


Figure 1. Thickness Mapping Feature Overview
Note:
  • In the OptiStruct model file, an initial thickness needs to be defined and the thickness mapping feature will overwrite a new thickness distribution for the elements specified in the thickness mapping definition.
  • The thickness mapping feature works even when the following attributes are different between the forming result file and the OptiStruct model file:
    • Mesh – Element types, Element ID, Node ID, Element order
    • Orientation of the components being mapped (in the presence of relocation)

Problem Setup Example

The following example of the thickness mapping process in an input file.
.
.
$ USING ASSIGN TO REFERENCE THE FORMING RESULT FILE
ASSIGN, MAP, 100,"forming_result.k"

$ REQUESTING THICKNESS OUTPUT FOR VISUALIZATION
THICKNESS(CORNER)=ALL

BEGIN BULK
$ DEFINITION OF MAP ENTRY
MAP, 1, THICK, 12, 100

$ SET OF ELEMENTS TO WHICH THE MAPPING MUST BE APPLIED
SET, 12, ELEM, LIST    
+, ALL  
.
.
Figure 2 shows mapping across dissimilar mesh types.


Figure 2. (a) Forming result file from which thickness data needs to be mapped; (b) OptiStruct model file to which the thickness data is mapped

Relocation

The method of relocation (RELOC) is used in cases when the model in the forming result file and the model in OptiStruct are oriented differently, in which case, the regular mapping would not work.

Input Format

Relocation can be specified in the MAP Bulk Data Entry in the form of a continuation line.
(1) (2) (3) (4) (5) (6) (7) (8) (9) (10)
MAP ID TYPE SID ASID SCALE
RELOC RTYPE PA1 PA2 PA3 PB1 PB2 PB3

There are 2 types of relocation available, which are explained below.

MATCH Option

When the orientations are different between the forming result and the OptiStruct model, the regular mapping process might not work.

In such cases, relocation with the MATCH option can be used, by specifying RTYPE = MATCH in the continuation line. Usage of relocation with MATCH option requires the definition of 3 matching grid ID pairs, denoted by PAi in the OptiStruct model and PBi in the forming result, where (i =1, 2, 3).

These 3 grid ID pairs will be used as a reference to perform the mapping operation.


Figure 3. Principle of RELOC (MATCH) in case of mapping across different orientations

If the grid IDs defined with PA1, PA2, PA3 do not match with the grid IDs defined using PB1, PB2, PB3, respectively, OptiStruct will produce an error message.

Consider the following case where the forming result file and the OptiStruct model file have the same geometry but have different orientations.


Figure 4. (a) Model in forming result, (b) OptiStruct model
Figure 5 shows the definition of the grid ID pairs in the OptiStruct model and the forming result file.


Figure 5. Definition of grid ID pairs in case of relocation with MATCH
Figure 6 shows the thickness distribution in the forming result file.


Figure 6. Thickness distribution in the forming result file

The effect of relocation with MATCH can be seen in Figure 7(a) where the thicknesses have been mapped correctly.

Figure 7(b) shows the incorrectly mapped thickness, to illustrate that the regular mapping (without relocation) will fail when the forming result file and OptiStruct models have different orientations.


Figure 7. Effect of relocation with MATCH option. (a) Correct mapping with relocation; (b) Incorrect mapping without relocation

MIRROR Option

The previously discussed relocation method with MATCH will fail for cases when the forming result file and the OptiStruct model file are mirror images of each other and mapping needs to be performed.

In such cases, relocation with the MIRROR option can be used, by specifying RTYPE = MIRROR in the continuation line.

Usage of relocation with MATCH option requires the definition of 3 grid ID pairs, denoted by PAi in the OptiStruct model and PBi in the forming result, where (i =1, 2, 3).

The grid ID pairs must be defined in such a way that the points defined by PA1, PA2 and PA3 are mirror images of PB1, PB2 and PB3, respectively. The thicknesses are mirrored from the forming result file about the plane defined by PB1, PB2 and PB3.

Consider the following case where the forming result file and the OptiStruct model file have the same geometry but are mirror images of each other (about the XZ plane).


Figure 8. (a) Model in forming result; (b) OptiStruct model
Figure 9 shows the definition of the grid ID pairs in the OptiStruct model and the forming result file.


Figure 9. Principle of relocation with MIRROR. The mirror plane is automatically defined based on the grids - PB1, PB2 and PB3
Figure 10 shows the thickness distribution in the forming result file.


Figure 10. Thickness distribution in the forming result file

The effect of relocation with MIRROR can be seen in Figure 11(a) where the thicknesses have been mapped correctly.

Figure 11(b) shows the incorrectly mapped thickness, to illustrate that the relocation with MATCH will fail when the forming result file and OptiStruct model file are mirror images of each other.


Figure 11. Effect of relocation with MIRROR option. (a) Correct mapping with MIRROR; (b) Incorrect mapping when MIRROR is not used