! Deletes full body that will be replaced by CMS bodyĬmsel, s, BODY1_CMS_PART_ ! ** part named selection for deletion **Ĭmsel,u, interA_CMS_PART_ ! ** don't delete interface nodes **Įt, etmax+1, 50 ! define substructure element type For example, the named selection for the body for this instance is BODY1_CMS_PART_. Being a assembled analysis, the named selection has the Analysis name with underscores '_' in place of spaces and wrapped-around the analysis name. Beside contacts, the command snippet similar to the previous post was created. The contacts are bonded in this example to the master nodes. Paste all the myse.* files in this directoryīoth the CMS and non-CMS body should already be assembled here. Right click on Solution to 'Open Solver File Directory'Ħ. Copy all files that begins with myse.* (about 9 files)ĥ. Right click on Solution to 'Open Solver File Directory'ģ. The quick and dirty way of doing so would be to. The purpose of this step is to have Analysis C be given access to the CMS superelement created previously in Analysis A. The prior flamingo dance should do the trick but it is wise to verify the nodes on the CMS body has lower numbers than those of the non-CMS body in Analysis C before proceeding.Ĭopying myse* Superelement Files to Analysis C
Right click on Analysis C's Model to 'Update'
Right click on Analysis C's Model to 'Update Upstream Components'ħ. Drag the Model from Analysis B to Model in Analysis CĦ. Double-click on Analysis C's Model to open up Mechanicalĥ. Right click on Analysis C's Model to 'Update Upstream Components'Ĥ. Drag the Model from Analysis A3 to Analysis C4 as in Figure 2ģ. In WB, create a new Modal Analysis in which will be Analysis CĢ. The sequence for the following tap dance may be critical to get the sequencing just right:ġ. Setting up Analysis C by Assembling A & B
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