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M!N!MAL 5 CH - Raspberry Pi 5 Case

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M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
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M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
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M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
M!N!MAL 5 CH - Raspberry Pi 5 Case 3d model
This model is restricted by licensing terms. 

Design This is the reduced to the max case / housing / sleeve for the Raspberry Pi 5 in the version with cooling. Since the guys a Raspberry did such a great job providing a perfect cooling fan / heatsink for the Pi 5 there is no more need for any fan mounts (like on our models for the Pi 0, 3 and 4). So this case provides enough space for the Pi5 with the Raspberry Pi Active Cooler. Since the cooler is very small you will find two versions of the case, one that provides just the space needed but has the Ethernet and USB sockets still looking out of the case (the 'slim' version) and one going up the full height, covering Ethernet and USB ports (the 'full' version). Like all its predecessors it is still a foldable, print in place housing with live hinges that is less than 2mm bigger than the Raspberry itself. All interfaces are accessible and the board itself is covered and protected. Above that it prints as one piece, the assembly is easy and no tools or screws are needed. Just print (in less than an hour), fold and use it… The design does consist of a frame and the top and bottom shells, which do have subparts that can provide openings to all interfaces on the board (GPIO, DSI, CSI,...) and the fan if removed from the part before printing. The shell itself can be printed without perimeters and top / bottom layers, just infill, and will then contribute to maximize the airflow.

Construction The case itself has a wall thickness of 0.8mm, optimized for printing with 0.4mm nozzles. The live hinges are exactly one layer (with a layer height of 0.2 mm) high and all openings can easily be bridged with standard cooling settings. All corners and edges (as far as possible) have rounded with fillets clipped at 35 degrees to avoid any overhangs that would need supports. Once the part is imported you can split it into parts (or even objects if you do not move it) and manipulate / delete the interface and fan openings as well as the shell infill.

Since this minimum of a case could be a starting point for your own Raspberry Pi Zero project we also included a STEP file…

Slicing, Printing The part prints with standard settings (0.4 mm nozzle, 0.2 mm layer height, 2 perimeters, 4 bottom / 5 top layers) without any issues but in case you want to take it one step further and optimize the result there are two recommendations, one for opaque and one for transparent / translucent filaments:

(Not only) for opaque materials we suggest to orient the infill at 90 degrees (based on the orientation the file has) since the infill lines of the first layer do then run perpendicular to the live hinges, which is good for their strength and also give a nice outside with beads oriented at the part geometry. Besides that you may also want to set the perimeter count to just 1 in order to get less “frame” around the infill areas. The top layers should be set to 0, bottom layers to 5 and infill should be set to 100% concentric, which gives the best result for the pins and tubes (especially when we have just 1 perimeter). Usually the part should print without brim which also gives you nice, clean edges.

The super transparent version is a bit more tricky since it uses just one orientation for infill lines. Layer height and perimeters are the same as for the opaque version above but the top and bottom layers both need to be set to zero. The infill is at 100% aligned rectilinear infill set at an angle of 90 degrees. Again no brim will be needed.

If you want the airy top and bottom shell you just have to (after splitting into parts) set the top and bottom layers as well as the perimeter count to 0. We had the best results with an infill of 40% with cubic, gyroid or rectelinear infill since these provide enough stability for the shall and many other available patterns do not make sense here since they disintegrate without perimeters and bottom / top layers.

In any case auto cooling should be enabled since the layer times are very low towards the end. If you still experience issues with curled areas you might want to try to print two parts at the same time, then all parts should have sufficient cooling time between the layers.

Just one last thing: We recommend “initializing” live hinges direct after printing, and on the print bed when taking the parts off. Just fold them when still warm and you will have a much nicer bend at the live hinges…

Assembly Not much of an assembly actually, place the Raspberry in the case, fold the top and click in place.

Happy printing!


4 Likes22 DownloadsAugust 9, 2024



4 Likes22 DownloadsAugust 9, 2024
This model is restricted by licensing terms.