Raspberry Pi developers and hackers looking for an professional way to store and manage more than one Raspberry Pi mini PC might be interested in this new rack system designed specifically for the ...

The Raspberry Pi has inspired many a hacker to take the inexpensive (~$35) microcomputer to the enterprise level. From bitcoin miners to clusters, the Raspberry Pi has found itself at the heart of ...

Raspberry Pi enthusiasts searching for a 3D printable compact Raspberry Pi rack, may be interested in a new design published to the Pursa Printers Prints Library. The Raspberry Pi boards are all ...

The Turing Pi cluster board is available for preorder from Turing Machines Inc. This Mini-ITX-sized motherboard can support up to seven Raspberry Pi Compute Modules, essentially creating a server rack ...

Things are cooler when rack-mounted, and [KellerLab] aims to make that all far more accessible with the HomeRacker, a modular and 3D-printable rack building system designed to let you rack-mount ...

TECHBASE ClusBerry Rack supports up to four Raspberry Pi CM4 based modules which can be added and removed on the fly thanks to a lockable mechanism that reminds me of hot-swappable drives found in NAS ...

Designed by Rapid Analysis in Australia, the Xerxes Pi is a cross-vendor compute module carrier board that fits into a 1U rack and supports Raspberry Pi CM4/CM5, Radxa CM5, Banana Pi CM4/CM5, and ...

This project was designed in FreeCAD 1.0.2. It is my first ever CAD designed project, so there was a little bit of learning involved. Luckily I measured twice and printed once, so everything turned ...

Pi-Raq is an open-source 1U rack-mount Raspberry Pi computer with a 1,024x100pixel (10x1in, 250x25mm) LCD occupying much of the front. The manufacturer is EarthLCD of California, which is using the ...

Raspberry Pi project to monitor server rack health status and cycle through vital stats. It originated from a different project to monitor server health can be adapted to other uses. Check out the ...

pi = { 'size': [56,85,2], for x in [pi['size'][0] + 2 * p['outer-offset'], -pi['size'][0] - 2 * p['outer-offset']] for y in [pi['size'][1] + 2 * p['outer-offset ...