Technologies for providing shared memory for accelerator sleds includes an accelerator sled to receive, with a memory controller, a memory access request from an accelerator device to access a region of memory. The request is to identify the region of memory with a logical address. Additionally, the accelerator sled is to determine from a map of logical addresses and associated physical address, the physical address associated with the region of memory. In addition, the accelerator sled is to route the memory access request to a memory device associated with the determined physical address.

Network rack systems for physically supporting modules of a network element and cable management structures for maintaining network cables in an organized manner are provided. An auxiliary side cabinet, according to one implementation, includes a frame configured for physical attachment to a side portion of a main rack structure, where the main rack structure is configured to support a plurality of modules of a Network Element (NE). The auxiliary side cabinet further includes a front plane connected to a front portion of the frame. Also, the auxiliary side cabinet includes one or more connector panels supported on the front plane. Each of the one or more connector panels is configured to support a plurality of connectors. The plurality of connectors are configured for communication with associated connectors of the modules of the NE via cables. Also, the plurality of connectors are configured as high pin count connectors.

A cable backplane system includes cable backplanes each including a tray configured to be coupled to a chassis and a plurality of cable connector assemblies mounted to the tray. The tray has a plate extending between a front and a rear with mounting locations receiving corresponding cable connector assemblies. The trays are oriented parallel to each other with front openings between the fronts of the plates and rear openings between the rears of the plates. Each cable connector assembly has a housing holding contacts terminated to corresponding cables. Each cable connector assembly has a holder mounted to the corresponding mounting location of the plate. The holder is mounted to the plate and removable from the plate through the rear opening at the rear of the plate.

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 equipment rack including a chassis configured to support an electronic device within a moveable drawer. The electronic equipment rack may further include a cable management arm coupled to a front side of the electronic equipment rack by a first hinge. The cable management arm may include a cable management structure and may further include a cable anchor point at which a fixed portion of the cable management structure is held at a fixed distance from a reference point located on the chassis. The cable management arm may be configured to be rotatable around the first hinge between a closed position and an open position in which the moveable drawer is configured to be moved inward and outward relative to the chassis. The electronic equipment rack may further include a communication connector located proximate an end of the cable management structure.

A cable management device in a server chassis able to hold and safeguard a greatly extended range of cable lengths, and server chassis including same, comprises connecting assembly, sliding rail assembly, and cable management assembly. The sliding rail assembly includes parallel first and second sliding rails, the first sliding rail including outer, middle, and inner rails, and the second sliding rail including similar outer, middle, and inner rails. The assembly includes first to fourth sliding arms, together with a supporting bar. The first sliding arm is movably connected to the outer rail of the second sliding rail, and the fourth sliding arm is movably connected to the inner rail of the first sliding rail. One end of the supporting bar is connected to the middle rail of the first sliding rail, the other end is connected to the middle rail of the second sliding rail.

A cable manager connected to a network rack that routes cables in and around the network rack. The cable manager includes a body with plurality of fingers extending from the body. The distal end of at least one finger includes a hinge pin holder. The cable manager also includes a door hingedly attached to the fingers extending from the body. The door has a front, a back, edges, and at least one hinge pin receptacle positioned along the edges of the door. The hinge pin receptacle houses a magnet to enable the door to attach to the hinge pin holder of the at least one finger to hold the door in a closed position.

Provided are a heat sink capable of suppressing overcooling of an electronic component which should not be overcooled and highly efficiently cooling only an electronic component which should be cooled, and a circuit device including the same. A heat sink includes a pipe and a cooling block. At least one projection is formed in the cooling block. The pipe is in contact with the projection. The pipe is arranged with a spacing from a portion of the cooling block other than the projection.

An electronic equipment chassis comprises a chassis housing and two or more cooling compartments in the chassis housing. At least a first one of the two or more cooling compartments in the chassis housing utilizes a first type of cooling for a first set of electronic equipment housed therein, and at least a second one of the two or more cooling compartments in the chassis housing utilizes a second type of cooling for a second set of electronic equipment housed therein. The first type of cooling comprises liquid immersion cooling and the second type of cooling comprises non-liquid immersion cooling.

A bracket system mounts to a ladder rack for positioning a fiber trough system above the ladder rack. The bracket arrangement includes a bridge with a slider bar that allows for multiple positions of the fiber trough system relative to the ladder rack in a horizontal direction.