High density optical fiber distribution sub-rack comprising: a chassis for housing a plurality of shelves, the chassis comprising at least two shelf storage areas placed side by side with each other, at least one shelf housed in one of the at least two storage areas of the chassis, the at least one shelf having an internal hollow seat for connection modules, the at least one shelf comprising one or more connection modules having a plurality of adapters for interconnection optical fibers, the connection modules being arranged in the internal hollow seat of the at least one shelf at the frontal face of the at least one shelf, wherein the at least one shelf is guided so as to be movable towards the external of the chassis by the succession of a translation movement and a rotation movement of the at least one shelf.

A horizontal cable manager connected to a network rack that routes cables in and around the network rack. The horizontal cable manager includes a body with a back and a plurality of fingers extending from the back of the body. The distal end of at least one finger includes a hinge pin holder. The horizontal cable manager also includes a door hingedly attached to the fingers extending from the body. The door has a front, a back, a top edge, a bottom edge, and at least one hinge pin receptacle positioned along the top edge or the bottom edge 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

A data center includes a floor; a side wall configured to partition a space above the floor into a room; a plurality of server columns arranged in a row direction on the floor, each of the plurality of server columns including a plurality of servers that are arranged to form a column in a column direction; an inclined ceiling that increases in height from a first side toward a second side in the column direction; and a first cable tray configured to hold a first cable, the first cable tray being provided in a space below the inclined ceiling on the first side in the column direction, and extending along the row direction.

A cable management apparatus for a portable rack-mounted electronics enclosure includes a first arm portion configured to mount the apparatus to the portable rack-mounted electronics enclosure, a second arm portion rotationally coupled to the first arm portion, the second arm portion comprising a guide configured for guiding cables routed to electronics housed within the portable rack-mounted electronics enclosure, and a latch mounted to the first arm portion or the second arm portion, the latch being movable to a latched position for preventing rotation of the second arm portion relative to the first arm portion and to an unlatched position for allowing rotation of the second arm portion relative to the first arm portion.

A cable conduit for distribution panels in network technology is provided comprising a first section for fastening and a second section for guiding cables, in which the first section is embodied such that the cable conduit, seen in the plug-in direction(s) of the distribution panel, can be arranged in front of a distribution panel such that the first section is arranged at a first part of the cable conduit and the second section is arranged at least partially at a second part of the cable conduit, which can be separated from the first part of the cable conduit and after the separation can be reconnected to the first part of the cable conduit, as well as a distribution panel comprising such a cable conduit.

A data center includes a floor; a side wall configured to partition a space above the floor into a room; a plurality of server columns arranged in a row direction on the floor, each of the plurality of server columns including a plurality of servers that are arranged to form a column in a column direction; an inclined ceiling that increases in height from a first side toward a second side in the column direction; and a first cable tray configured to hold a first cable, the first cable tray being provided in a space below the inclined ceiling on the first side in the column direction, and extending along the row direction.

The present invention provides a system for managing and storing cables comprising a storage tray slidably mounted in a housing enclosure for coiling, spooling and/or storing cables of various lengths. The cable management system of the present invention minimizes or eliminates cable strain during technician access and cable storage. Located within the tray are elements including a routing system comprising spooling elements and cable guiding walls configured to define compartments for storage of the cables and cable routing paths. The tray further comprises cable openings extending along both sides of the tray configured to allow a portion of the cable length to extend from the muting elements and out the side of the tray. The cable management system also comprises two cable guides maintain the cable in a fixed position relative to the side of the housing when the tray is moved.

A routing tool for the installation of a fiber optic cable along a cable support includes a cable support frame having a mounting interface, wherein the cable support frame is selectively attachable to and detachable from the cable support, and a dispensing platform configured to have the fiber optic cable arranged thereon and selectively attachable to and detachable from the cable support frame. The dispensing platform is configured to be rotatable relative to the cable support frame about a rotational axis. The rotational axis is configured to be laterally offset from the mounting interface. A method of installing a fiber optic cable using the routing tool includes attaching the cable support frame to the cable support, attaching the dispensing platform to the cable support, and dispensing the fiber optic cable from the routing tool to route the cable along the cable support.

A patch cable and system for interconnecting a pair of terminals, each of the terminals comprising a terminal RFID transponder comprising a unique ID, and for use with a cradle comprising a cradle RFID antenna. The patch cable comprises a pair of connectors, one of the connectors at each end of and interconnected by a guided transmission medium, a connector RFID antenna associated with each of the pair of connectors, a cable RFID transponder positioned along the patch cable between the connectors for communicating with the cradle RFID antenna. When the cable RFID transponder is brought into proximity with the cradle RFID antenna, RF signals emitted by the cradle RFID antenna provide power to and communications with the cable RFID transponder for powering the connector RFID antennas and retrieving the unique IDs of the pair of terminals and communicating the unique IDs to the cradle.

A patch cable and system for interconnecting a pair of terminals, each of the terminals comprising a terminal RFID transponder comprising a unique ID, and for use with a cradle comprising a cradle RFID antenna. The patch cable comprises a pair of connectors, one of the connectors at each end of and interconnected by a guided transmission medium, a connector RFID antenna associated with each of the pair of connectors, a cable RFID transponder positioned along the patch cable between the connectors for communicating with the cradle RFID antenna. When the cable RFID transponder is brought into proximity with the cradle RFID antenna, RF signals emitted by the cradle RFID antenna provide power to and communications with the cable RFID transponder for powering the connector RFID antennas and retrieving the unique IDs of the pair of terminals and communicating the unique IDs to the cradle.