11/07/2024 | News release | Distributed by Public on 11/06/2024 15:39
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Design Cube
Our helpful design aid demonstrates part features that are too thin or too thick, bad bosses, right and wrong ribs, and other considerations to be mindful of while designing parts for injection molding.
Proto Labs, Inc.
5540 Pioneer Creek Dr.
Maple Plain, MN 55359
United States
P: 877-479-3680
F: 763-479-2679
E: [email protected]
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Evaluating build direction, support structures, radii placement and wall thickness to optimize printed parts.
Because 3D-printed parts are built up layer by layer, designing CAD files for 3D printing can present unique challenges for engineers. Even the laws of gravity play a part! The following design considerations are critical to follow across all CAD software applications.
If you are designing or optimizing a part for 3D printing, the first decision to make is the intended build direction. While shorter heights typically translate into shorter build times and lower cost, in the end, accuracy and strength are usually more important.
In general, it is best to have the more detailed side of the part facing up during the print. Cylindrical features are most accurate with the cylindrical cross-section in the draw plane. Generally, the goals of optimization are to reduce the need for support material and to reduce the impact of material shrink that occurs from drastic changes in cross-section. Check out this article for more details on how orientation impacts 3D-printed parts.
For most additive technologies that require supports, surfaces 45 degrees and steeper are self-supporting. Eliminating unnecessary supports is a great way to mitigate costs, as any supports that are added also add to material cost, print time, and labor to remove. Some specific materials and processes may require 55 degrees or steeper to be self-supporting, while SLS and MJF do not require supports at all. For those two, this rule does not apply.
One of the easiest ways to improve accuracy and strength of 3D-printed parts is to add radii to all internal and external hard corners that the design allows. This can mitigate the material shrink that happens layer-by-layer, making the parts more accurate with less surface defects. It also spreads out stress that accumulates in interior corners and makes the parts stronger and less likely to crack under load.
For some materials and printing processes (like titanium printed via DMLS), radii are required to keep the parts from cracking during the printing process due to material shrink. Even a radius as small as 0.020 in. (0.5mm) can be enough to mitigate this risk.
Many printing technologies are susceptible to material shrink, which can affect tolerances and aesthetics. This is most noticeable when the parts undergo drastic changes in cross-section during the print. It is best to core out thick areas and leave the cavity accessible to the environment so that the supports or excess material can be removed after the print.
If printing in FDM, this rule can often be ignored. The partial infill of FDM allows parts to have a relatively uniform wall thickness, even if the CAD model itself undergoes large thickness transitions.
Still have questions about the best way to handle your application? Reach out to us at 877-479-3680 or [email protected].
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Proto Labs, Inc.
5540 Pioneer Creek Dr.
Maple Plain, MN 55359
United States
877-479-3680
[email protected]
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