Technologies for dividing work across one or more accelerator devices include a compute device. The compute device is to determine a configuration of each of multiple accelerator devices of the compute device, receive a job to be accelerated from a requester device remote from the compute device, and divide the job into multiple tasks for a parallelization of the multiple tasks among the one or more accelerator devices, as a function of a job analysis of the job and the configuration of each accelerator device. The compute engine is further to schedule the tasks to the one or more accelerator devices based on the job analysis and execute the tasks on the one or more accelerator devices for the parallelization of the multiple tasks to obtain an output of the job.

A modular computer cabinet include an interchangeable interconnection device configured to interconnect the interconnection switch with the rackable element, the interchangeable interconnection device including a wall for connecting to a rackable element, the connection wall extending along a second plane orthogonal to the first plane of the rackable element, the connection wall including a third blindly connectable connector configured to be blindly connected to the first blindly connectable connector included in the rackable element, a cable connected to the third connector of the connection wall, the interconnection cable including a fourth connector configured to be connected to the second connector of the plurality of second connectors included in the interconnection switch.

Cable management systems for use with a chassis includes a device holding apparatus, a device holding apparatus track, a chassis track and a cable carrier. The cable carrier may carry one or more cables and engage a portion of each of the chassis track and the device holding apparatus track when the device holding apparatus is in, or being moved between, a first position and a second position.

Electrical interconnect systems for a server power shelf are disclosed. An electrical interconnect system, which can include multiple connectors and a printed circuit board or other wiring, can allow a control circuit, such as a shelf management controller (SMC), to be accessible via a front or rear of a server power shelf. The control circuit can be communicatively coupled to the backplane of the server power shelf through the electrical interconnect system in either the front or rear position without having to reconfigure or redesign a server power shelf configuration. Further, the control circuit can be hot swappable from both the front-loading position and the rear loading position. Even further, when utilized in the front-loading position, neither the electrical interconnect system nor the control circuit occupy a slot of the server power shelf intended for a power supply or reduce a number of power supplies the shelf can include.

A system includes a network element having a housing that is configured for front-to-rear airflow; and a cooling apparatus located adjacent to the network element and having a housing that forms a cavity that is closed by the housing of the network element, wherein the cooling apparatus includes one or more fan units that are accessible via front access and wherein the one or more fan units are configured to draw the front-to-rear airflow from the network element into the cavity. This enables a front-to-back airflow design with rear fan access to be converted into a front-to-back airflow design with front fan access.

A component for a cage is for holding electronic devices in a computing system. The component includes a cover with a hook, an emboss, and a main panel. The cover may be couplable to the cage by the hook and emboss. The component also includes a partition with a primary panel. The partition may be couplable to the cage by the primary panel. The cover is detachable from the partition. After the cover is detached from the partition, the cover may be rotated approximately 180 degrees and reinstalled into the cage. The cover may also include another emboss to fix the cover into the cage when the cover is installed in a rotated position. The cage may also include a top portion and a bottom portion. The top and bottom portions of the cage may include features that assist the partition and the cover to maintain a fixed position.

A chassis input/output (I/O) module adapted for use in a front region of a mass storage chassis assembly is provided. The chassis I/O module in one example includes an I/O module shell, a main I/O connector externally available on the I/O module shell, a plurality of sub-assembly connectors externally available on the I/O module shell, one or more power supply modules, and an interface module electrically coupled to the main I/O connector, the plurality of sub-assembly connectors, and the one or more power supply modules, with the interface module configured to regulate operations of one or more mass storage sub-assemblies installed in the mass storage chassis assembly, regulate provision of electrical power from the one or more power supply modules to the one or more mass storage sub-assemblies, and facilitate exchange of electrical signals between the one or more mass storage sub-assemblies and the main I/O connector.

A front cable management assembly for a server rack includes a first assembly bracket and a second assembly bracket and a cable rail movably coupled to the first and the second assembly brackets. The first and the second assembly brackets are to be mounted to a front of a server rack. The cable rail is positioned in between the first and the second assembly brackets and is to move to a first position and a second position while movably coupled to the first and the second assembly brackets.

An equipment rack, mounting rails for the equipment rack, and associated methods. The mounting rails are selectively movable on a frame of the equipment rack and can be clamped to secure the mounting rails to the frame. A clamp of the mounting rail can include a clamp arm having a clamped position and an unclamped position and a lever arm for moving the clamp arm between the clamped and unclamped positions.

A rotor assembly for use with an electric machine assembly includes a plurality of magnets and a rotor frame having a pair of opposing end plates and a plurality of circumferentially spaced longitudinal members extending between the opposing end plates. The opposing end plates and the plurality of longitudinal members combine to define a plurality of openings that are each configured to receive a magnet of the plurality of magnets. At least one of the opposing end plates includes a plurality of fins extending therefrom in a direction opposite the longitudinal members.