Difference between revisions of "3D Modeling"
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| − | In order to make things from either 3D printers or CNC routers/mills that have 3 or more degrees of movement, you need a 3D model. | + | In order to make things from either 3D printers (or CNC routers/mills that have 3 or more degrees of movement), you need a 3D model. |
While your first experience with one of these machines may use an existing test model or one you've downloaded from a site like Thingiverse, eventually you may want to create things of your own. | While your first experience with one of these machines may use an existing test model or one you've downloaded from a site like Thingiverse, eventually you may want to create things of your own. | ||
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| + | The general workflow for 3D modeling and printing is: first, model the part, second, turn it into instructions suitable for the machine you're using to make the part, then third, feed the instructions to the machine and fabricate the part. | ||
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| + | This page will only deal with the first step; how to model a part, and it will not cover how to use specific software. | ||
Here is a very out-of-date list of some free 3D modeling applications: [http://www.hongkiat.com/blog/25-free-3d-modelling-applications-you-should-not-miss/ 25 free 3D modeling applications] | Here is a very out-of-date list of some free 3D modeling applications: [http://www.hongkiat.com/blog/25-free-3d-modelling-applications-you-should-not-miss/ 25 free 3D modeling applications] | ||
| − | + | This page deals with 3D modeling with the intent of printing the part on a 3D printer like our LulzBot and Makerbot Replicator printers, and not 3D modeling for CNC fabrication. | |
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| + | Regardless of what modeling software the model you use, there are a few considerations you must make: | ||
| + | |||
| + | Minimum size. The part may not be larger than the printable area of the printer you are using. Larger items can be made by dividing your object into components that are assembled after printing. | ||
| + | |||
| + | Minimum size. Parts must be large enough to resolve, large enough for the print-head to extrude something that holds together. | ||
| + | |||
| + | Parts must be manifold. Manifold is a term that means the surface of the part is contiguous and complete, and with regards to 3d printing, also not zero thickness. Imagine a soccer ball shape: that would be 'manifold,' but if the soccer ball were missing one polygon, it would not be manifold. In order to print such a shape, either the walls of the part need to be thickened, or the gaps or holes need to be patched. Some models created with common software, particularly SketchUp, can be impossible to print without serious repair and reworking, because the models include many holes or gaps and are often composed of zero-thickness planes rather than solid shapes with volume. 'Manifold' is also referred to as 'water-tight.' | ||
| − | + | After the part is modeled it needs to be turned into commands the 3D printer can recognize, a step called 'slicing' since it turns the solid shape into a series of paths and printer commands to move and start and stop the extruder, that build up the part layer by layer. The final step in 3D modeling, then, is to save the part in a format that the slicing software can recognize. Common formats include STL, but vary depending on the specific software and workflow you will be using. | |
Revision as of 16:18, 25 September 2013
In order to make things from either 3D printers (or CNC routers/mills that have 3 or more degrees of movement), you need a 3D model.
While your first experience with one of these machines may use an existing test model or one you've downloaded from a site like Thingiverse, eventually you may want to create things of your own.
The general workflow for 3D modeling and printing is: first, model the part, second, turn it into instructions suitable for the machine you're using to make the part, then third, feed the instructions to the machine and fabricate the part.
This page will only deal with the first step; how to model a part, and it will not cover how to use specific software.
Here is a very out-of-date list of some free 3D modeling applications: 25 free 3D modeling applications
This page deals with 3D modeling with the intent of printing the part on a 3D printer like our LulzBot and Makerbot Replicator printers, and not 3D modeling for CNC fabrication.
Regardless of what modeling software the model you use, there are a few considerations you must make:
Minimum size. The part may not be larger than the printable area of the printer you are using. Larger items can be made by dividing your object into components that are assembled after printing.
Minimum size. Parts must be large enough to resolve, large enough for the print-head to extrude something that holds together.
Parts must be manifold. Manifold is a term that means the surface of the part is contiguous and complete, and with regards to 3d printing, also not zero thickness. Imagine a soccer ball shape: that would be 'manifold,' but if the soccer ball were missing one polygon, it would not be manifold. In order to print such a shape, either the walls of the part need to be thickened, or the gaps or holes need to be patched. Some models created with common software, particularly SketchUp, can be impossible to print without serious repair and reworking, because the models include many holes or gaps and are often composed of zero-thickness planes rather than solid shapes with volume. 'Manifold' is also referred to as 'water-tight.'
After the part is modeled it needs to be turned into commands the 3D printer can recognize, a step called 'slicing' since it turns the solid shape into a series of paths and printer commands to move and start and stop the extruder, that build up the part layer by layer. The final step in 3D modeling, then, is to save the part in a format that the slicing software can recognize. Common formats include STL, but vary depending on the specific software and workflow you will be using.