A lock mechanism for a faceplane infrastructure coupled externally from a faceplate of a modular device includes a locking bar, a locking bar engagement element, and a securing device. When the lock mechanism is assembled and in a locked state, the locking bar is housed within the modular device. Further, when the lock mechanism is assembled and in the locked state, the locking bar engagement element is fixedly coupled to a first portion of the faceplane infrastructure and removably engaged with the locking bar through an aperture in the faceplate of the modular device. Moreover, when the lock mechanism is assembled and in the locked state, the securing device locks the first portion of the faceplane infrastructure to the faceplate of the modular device.

An example modular cable management system, that includes a base to attach to a support structure and a number of cable management modules to attach to the base. The base may include an attachment feature that is to attach to the supporting structure to vertically support the base, and an arm that extends from the attachment feature to which the cable management modules attach. The cable management module may include a clip and a loom. The clip may be attachable to the arm such that the clip is rotatable about a longitudinal axis of the arm and may be removable from the arm. The loom may be attachable to and removable from the clips and configured to hold multiple cables.

A lock mechanism for a faceplane infrastructure coupled externally from a faceplate of a modular device includes a locking bar, a locking bar engagement element, and a securing device. When the lock mechanism is assembled and in a locked state, the locking bar is housed within the modular device. Further, when the lock mechanism is assembled and in the locked state, the locking bar engagement element is fixedly coupled to a first portion of the faceplane infrastructure and removably engaged with the locking bar through an aperture in the faceplate of the modular device. Moreover, when the lock mechanism is assembled and in the locked state, the securing device locks the first portion of the faceplane infrastructure to the faceplate of the modular device.

An electronic interconnect includes a board, a rotatable connector, and a heat sink. The board extends along a plane, and the rotatable connector is connected to the board. The rotatable connector is configured to allow rotation about an axis parallel to the plane, between a first position and a second position. The heat sink is connected to the rotatable connector and extends a first distance from the board in the first position and a second, greater distance from the board in the second position.

A server which can be connected from the back or from the front includes a case and a compute node disposed in the case. The case has a front board and an opposite rear board. The compute node has a plurality of ports for connecting to external cables. The front board has a first opening defined thereon, the rear board has a second opening defined thereon, and the second opening faces the first opening. The compute node is capable of being loaded into the case facing a first direction, such that the plurality of ports are exposed from the first opening. The compute node is also capable of being loaded into the case facing a second direction, opposite to the first direction, such that the plurality of ports are exposed from the second opening.

An example modular cable management system, that includes a base to attach to a support structure and a number of cable management modules to attach to the base. The base may include an attachment feature that is to attach to the supporting structure to vertically support the base, and an arm that extends from the attachment feature to which the cable management modules attach. The cable management module may include a clip and a loom. The clip may be attachable to the arm such that the clip is rotatable about a longitudinal axis of the arm and may be removable from the arm. The loom may be attachable to and removable from the clips and configured to hold multiple cables.

The disclosure provides a server including a housing, a plurality of hash boards, a power module and an electrical connection board. Each hash board is slidably arranged in a first accommodating space. The plurality of hash boards and the power module are respectively connected to the electrical connection board. The power module supplies power to the plurality of hash boards through the electrical connection board. The electrical connection board includes two conductive connection boards, each of which is provided with a plurality of conductive pins. The pins form multiple pairs of conductive pins in one-to-one correspondence. Each pair of conductive pins corresponds to each hash board and is electrically connected to supply power to the hash board. Each pair of conductive pins is detachably matched with each hash board to connect or disconnect the power supply path of the hash board.

Rack configurations provide increased storage device density without compromising cooling or immediate device availability. A device rack has a frame including posts which define an interior containing system board(s) with electronic device connectors. The system board is fixed relative to the frame, and the rack is devoid of sliding rails and cable management arms for the devices, thereby reducing rack weight and mechanical complexity. A vertical plenum within the rack between loaded system boards carries cooling air for the devices and may also permit use of a service robot to install or replace hot-pluggable hard disk drives or other devices, which can be arranged in columns. As one objective measure of the increased density provided, a connector density is at least a specified number of hundreds of mechanically and electronically releasably connectable electronic device connectors per cubic meter within the rack.

Rack configurations provide increased storage device density without compromising cooling or immediate device availability. A device rack has a frame including posts which define an interior containing system board(s) with electronic device connectors. The system board is fixed relative to the frame, and the rack is devoid of sliding rails and cable management arms for the devices, thereby reducing rack weight and mechanical complexity. A vertical plenum within the rack between loaded system boards carries cooling air for the devices and may also permit use of a service robot to install or replace hot-pluggable hard disk drives or other devices, which can be arranged in columns. As one objective measure of the increased density provided, a connector density is at least a specified number of hundreds of mechanically and electronically releasably connectable electronic device connectors per cubic meter within the rack.

A method for connecting communication cables includes at least an input cable, an output cable, and a cable adapter. The input cable may include a plurality of input wires, each of the plurality of input wires communicatively connected to an input port. The output cable may include a plurality of output wires, each of the plurality of output wires communicatively connected to an output port. The cable adapter may be for communicatively interconnecting the input cable and the output cable. The cable adapter may include a container, a lid and a plurality of attachment mechanisms. The lid may be movably attached to the container. The plurality of attachment mechanisms may be located in the container, each of the plurality of attachment mechanisms capable of communicatively and reversibly connecting one of the plurality of input wires with one of the plurality of output wires.