After running several optimisation scenarios and choosing the final design of a part, the manufacutring process can be simulated. For this the Print-Geometry with all Maching Allowances should be used. With Simufact Additive the selective laser melting process as well as the binder jetting process for metals can be performed. The process simulation can provide information regarding the distortion, temperature or any manufacturing issue like a recoater contact. Furthermore, a distortion compensation can be done. This results in a pre-compensated geometry which should be used for the manufacturing. This geometry takes all deformations during the manufacturing process into consideration to create a suitable geometry with less distortion to fullfill the tolerances of shape and position.
In the following the Part Consolidation example is used for the selective laser melting process simulation.
With Simufact Additive the final optimised part can be imported as a STL-file or a NURBS-Geometry. Custom machines can be set up or one can be choosen from a large selection from all well-known machine manufacturer.
The part can be orientated free in the building space. Moreover, the orientation assitant can be used. Especially, for generative designed parts the orientation assistant can help to find the best building position regarding self-determined criterias which is not always immediatley recognizable by vision.
In this case the best postition is determined regarding support area, support volume and build risk. With the 3D ball in the upper left corner, the position can nearly seamless varied.
In Simufact Additive support structures can be created automatically or already created ones can be imported.
From the Simufact Material library already created materials can be choosen or new materials can be implemented. In this case AlSi10Mg alloy is selected.
In the next step the Manufacturing and optimisation stages can be set up. E.g. the distortion compensation can be activated. After the first run through a pre-distorted shape will be analysed. If this shape fits the conditions (e.g. max. 0.2 mm distortion) the final print-shape is determined.
Nevertheless, the stages of the building process can be set. E.g. the cutting from the baseplate and the support removal which also have a big impact on the manufactured part.
The last step before starting the simulation is to create the voxel mesh which is used for the FE-Analysis. The FE-Analysis can also be influenced with various parameters.
During the process simulation every voxel layer and every manufacturing step is displayed. After finishing the simulation several results are visualised. In the picture below the surface deviation between the initial shape (Norm-Geometry) and the simulated distorted part is shown.
When the initial shape would be manufactued, a distortion from around 1 mm can be expected. Simufact Additive created a pre-compensated geometry and runs once again a manufacturing simulation.
The pre-compensated geometry would result in a maximum distortion of 0.16 mm.
This is just a example workflow how a process simulation can be used. For more information regarding Simufact Additive please contact the Simufact Additive Team.
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