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Week 12:Project-1-Meshing of Door Inner Panel Challenge
MESHING THE PLASTIC COMPONENT OF A CAR SIDE DOOR USING HYPERMESH Aim: To extract the mid surface of the given plastic component and mesh the model according to the given quality criteria and apply thickness. Procedure:In order to accomplish the above objective we need to follow following steps: Import the CAD model into…
Durga Varaprasad
updated on 02 Jul 2021
MESHING THE PLASTIC COMPONENT OF A CAR SIDE DOOR USING HYPERMESH
Aim: To extract the mid surface of the given plastic component and mesh the model according to the given quality criteria and apply thickness.
Procedure:In order to accomplish the above objective we need to follow following steps:
- Import the CAD model into hypermesh.
- Geometry clean up of the model.
- Extraction of mid surface using various techniques.
- Perform the 2d-mesh on the mid surface.
- Eliminate the elemental failure as per the quality criteria.
- Apply the thickness and convert the shell elements into solid elements.
Step 1: Import the CAD model into Hypermesh:
We import the CAD file into the hypermesh and radioos as profile,using import geometry in the menu bar.
Step 2: Geometry clean up for the given model:
In order to extract the midsurface we make sure that the cad model imported is free from topology errors i.e any deformation occurs while importing the file into hypermesh or any errors present in the cad file itself or any overlapping of surfaces.If any such errors are present we eliminate those errors.In this model we delete the surfaces which are not useful and also fixed some gaps present between the surfaces.
Step 3: Extraction of mid surface using various techniques:
Now the given plastic component is free from topological errors,now we can proceed to extract the mid surface of the component.We first extract the midsurface using auto extraction method.
Due to extraction of midsurface using auto extraction method there are some surfaces gets overlapped and some surfaces gets distorted due to the complexity of the model.
so we delete those surfaces created by auto mid-surface and we extract those surfaces using manual surface extraction method i.e we first duplicate the required surface and then we offset the duplicate surface to the required dimension based on the surface thickness.
We also carried out several geometry edit in order to obtain good quality mesh.We toggle the unwanted topology edges.Some surfaces are extended and trimmed some fillets are eliminated which makes the mesh fails in quality checks.Now the midsurface is extracted properly as shown in the figure.
Step 4: Perform the 2d-mesh on the mid surface:
- In order to mesh the midsurface we make sure that the extracted mid surface geometry is clean.
- We mesh components using automesh in 2d mesh pannel.
- We mesh the midsurface by assigning the element size as 4mm and element shape as mixed.
- We mesh the complex surfaces first in order to maintain the proper mesh flow and make meshing easier.
- While meshing the midsurface we make sure that the we maintain the trias percentage as low as possible.
- While meshing curved or complex surfaces if the mesh doesn't properly catch the surface properly then we increase or decrease the node count so that mesh attaches the surface properly.
- We use the rebuild or smooth option while meshing in order to maintain the proper mesh flow.
Step 5:Eliminate the elemental failure as per the quality criteria:
- After meshing the midsurface by assigning the target length as 4mm and shape as mixed i.e(quad and tria).
- We make sure the mesh we generated on the midsurface pass the given quality criteria.
| S.N | Quality Criteria | Value |
| 1 | Aspect Ratio | 5 |
| 2 | Skewness | 45 |
| 3 | Warping | 15 |
| 4 | Taper | 0.5 |
| 5 | Min. Length | 2mm |
| 6 | Max. Length | 6mm |
| 7 | Min angle Quad | 45 |
| 8 | Max angle Quad | 135 |
| 9 | Min angle Tria | 20 |
| 10 | Max angle Tria | 120 |
| 10 | Tria % | 10 |
- This is performed in 2d>quality index>check elements.
- We use various options like rebuild,smooth,split elements,create elements,move node,drag trias etc in order to eliminate the errors caused due to the violation of quality criteria.
- We eliminate the rotating quads and the trias present near the topology edges.
- We also reduce the trias concentration by dragging the trias to the free ends or combing the opposite trias by dragging them near to each other.
Step 6: Apply the thickness and convert the shell elements into solid elements:
- After completion of meshing the midsurface,we now assigning the thickness to the midsurfaces.
- For assigning the thickness we create the property and in property we add the thickness value to the property and then we assign the property to the required surfaces in the midsurfaces compnent.
- Due to the given CAD model is plastic component,the thickness was not same for all the surfaces so we need to create the different thickness required for the different surfaces.
- The thickness we assign for the different surfaces are as shown below;
Conclusion: The given plastic component is meshed by extracting its mid surface and we assigned the thickness as required.
The mesh that is generated also passes the quality checks.
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