Introduction: Raspberry Pi Platform
It is common to use hats to mount additional circuitry on top of your Raspberry Pi. But if all you want is a two dollar voltage regulator you do not want to buy a twenty dollar hat. This platform is designed to give your Raspberry Pi a second story where more components can live. This instructable is a discussion of a highly customizable 3D design meant to be printed. All of the primary files are written in a Free CAD program called..... FreeCad. The design is parametric in the sense that some of the dimensions may be modified using a built in spreadsheet.
Step 1: Tools
You will need the following to realize the benefits of this instructable:
- FreeCAD: download see: FreeCAD: An open-source parametric 3D CAD modeler https://www.freecadweb.org/
- Files for this project: russ-hensel/PiPlatform: Mounting platform for Raspberry Pi and other Modules 3D Printed, FreeCad files https://github.com/russ-hensel/PiPlatform
- 3D Printer: I print in PLA, but should work in any reasonable material
Step 2: Customize
Unless you are doing a project just like the design is setup for you will probably need to make at least some modifications. The pictures above show some extreme settings for height. To do the following you will need to learn a bit about FreeCAD. ( setting the height might be used to control the cooling of the Raspberry Pi.
Step 3: Choose Your Parts
Select the parts you want to print. The platform in the title picture has the main platform, a mounting bracket and an extension. For the use on top of the Pi you will need to set the height of the platform to clear the usb jacks. Also you may want height in the platform or holes to keep the Pi cool. I have tried to give the parts somewhat useful names:
- main_platform_punched_and_ .... this is the main platform which sits on top of the Pi, pretty much all the prints of this project will include this part. It is supported by 4 feet which match up with the holes in the in the Pi. You can adjust the height above the board using the spreadsheet, and in a similar way the thickness of the platform. The next parts are optional.
- extension_platform_punched .... this extends the platform over the usb and Internet ports. Use it only if your platform is high enough to go over the ports. ( 15 mm )
- bracket_with_fillet .... this is the bracket for mounting the Pi, "standing on end".
- The other parts may be used, but are not really "finished", but you might want to use them to get rid of features that you do not like.
After selecting the parts you want use ( Part workbench -> Part -> Boolean -> Union )
To help select the parts I normally make the entire model invisible ( View -> Visibility -> Hide all objects ) and then make visible ( in the model view point to the part and click the space bar ) only the parts I want to print. Then you need to also select the parts. I do this in the model view where I click on the parts I just made visible, click on the first, control click on the rest, you can see the parts selected i the 3D view.
You will get a new part: "Fusion xx", you might rename it "platform, but" you need not keep it around long, so perhaps it does not need a rename.
Step 4: The Spreadsheet
If you change a value in the spreadsheet it will change some feature of the design. The two that are meant to be useful are:
- height .... this is the distance from the top of the Pi to the bottom of the platform. A setting of 15 or more lifts the platform above the usb and Internet ports. This may have several advantages, cooling, clearance, and the ability to extend the platform using the "extension_platform_punched".
- thick .... this is the thickness of the platform ( and extensions, bracket.... ). I have found that 2 mm seems to be enough, 3 mm seems super strong.
Step 5: The "Punch" Sketches
If you want to mount parts to the platform you need some mounting holes. Additionally you may want to lighten up the structure by punching holes in it. Because of this most of the surfaces have sketches associated with them. All you have to do is adjust those sketches. For example add circles... and those will become holes in the associated part. Existing parts of the sketch may be deleted, or simply pushed out of the way ( off to the side of the surface they are on ) for possible reuse later.
Step 6: Mesh and Export
Take the fusion ( from above ), it is the whole thing that will print, you need to get it in stl format to feed your slicer. Select the fusion, and create a mesh ( Mesh Design Workbench -> Meshes -> Create Mesh from Shape -> - ) ( I use .1mm standard mesh ) Again this creates a new part the fusion ( meshed ). It will appear right on top of the fusion so you may or may not want to tinker with the part visibilities.
My meshed parts have often had defects that create problems in printing. FreeCad has some tools for fixing them. Run them to be safe:
Meshes -> Evaluate and Repair function. Use it. Sometimes it finds things other times not. Why not be safe?
Now select the fusion ( meshed ) and use ( Any Workbench -> File -> Export ...name the file and select stl as the type ) This is the file you need to slice.
Give this a good name to make it easy to find later: "platform.stl" perhaps.
You can find a similar work flow in another of my projects Any Size Enclosure You Want: 4 Steps (with Pictures)
Step 7: Printing
Here is what I have found useful, your results or needs may vary.
- If you software can check or repair the stl file do it.
- I almost always like a brim, a couple of mm.
- Flip this upside down, you may have guessed that.
- I have found that 50% infill is strong enough.
- So far I have used PLA. Should work in anything you can print.