In a fiber connection structure with optical connectors according to one embodiment, among m first connector port groups, arrangement orders of colors of a plurality of the optical fibers in (2×j−1)th (j is a natural number satisfying 1≤j and 2×j≤m) first connector port groups are the same, and among the m first connector port groups, arrangement orders of the colors of the plurality of optical fibers in (2×j)th first connector port groups are the same. The arrangement order of the colors of the plurality of optical fibers in the (2×j)th first connector port group is a reverse order of the arrangement order of the colors of the plurality of optical fibers in the (2×j−1)th first connector port group.

A fiber optic telecommunications device includes a frame and a fiber optic module. The fiber optic module includes a main housing portion defining fiber optic connection locations for connecting cables to be routed through the frame and a cable management portion for guiding cables between the main housing portion and the frame. The main housing portion of the fiber optic module is slidably mounted to the frame, the main housing portion slidable between a retracted position and an extended position in a sliding direction. The cable management portion of the fiber optic module includes a radius limiter slidably coupled to both the main housing portion and the frame, wherein movement of the main housing portion with respect to the frame slidably moves the radius limiter with respect to the main housing portion along the sliding direction.

A cable storage system that may include a mounting portion that is configured to extend from a wall portion of a cable storage enclosure, and an envelope portion. The envelope portion may be configured to contain a coil of cable. The envelope portion may include an envelope opening portion that may be located on an edge portion of the envelopment portion. The mounting portion may be configured to support the envelope portion though the envelope opening portion. The envelope portion may be configured to support the coil of cable in the envelope portion so as to restrict the coil of cable from expanding and interfering with contents of the cable storage enclosure.

A printing apparatus includes a first substrate provided with a first connector, a second substrate provided with a second connector, and an optical cable that couples the first connector with the second connector and transmits an optical signal. The optical cable is arranged movable in a curved shape in a storage space between the first substrate and the second substrate.

A splice holder tray has a splice holder section that includes a plurality of inclined channels. Each of the plurality of inclined channels includes a first portion presenting a cross section area that is measured on a reference plane, two opposite lateral openings, and a top opening and a bottom opening. The bottom opening has an area smaller than the cross section area.

An optical fibre enclosure comprises a housing coupled with a base panel and a plurality of staggered ports housed on a front surface of the housing. In particular, the plurality of staggered ports is arranged in two or more columns and two or more rows such that the plurality of staggered ports in the two or more columns is aligned to one or more column axes and the plurality of staggered ports in adjacent rows is not aligned to one or more row axes creating a space at a lower portion of at least one of the two or more columns.

A bending device for forming a product from a workpiece includes a shaft driven to rotate by a motor, an actuator including an extendable end configured to secure a portion of the workpiece, and a die coupled to the shaft and driven about an axis. The die includes a peripheral portion including a channel configured to receive the workpiece. The channel includes a first end and a second end offset from the first end in a direction parallel to the axis. Rotation of the die about the axis causes the workpiece to bend along the channel.

One embodiment is directed to a method of tracking, using an automated infrastructure management (AIM) system, connections made using a breakout cable. The breakout cable comprises a plurality of breakout connectors at a breakout end of the breakout cable. The method comprises identifying a sequence for adding or removing connections involving the breakout connectors of the breakout cable, identifying events associated with adding or removing connections involving the breakout connectors of the breakout cable, and associating the breakout connectors of the breakout cable with added or removed connections based on the identified sequence and the identified events. Other embodiments are disclosed.

This disclosure provides a fiber optic cable management system for cable distribution, organization and management. The fiber optic cable management system may provide features for cable routing, protection, separation and slack storage for the fiber optic cables placed, disposed or passed through the fiber optic cable management system. In one example, the fiber optic cable management system includes a front housing having a ceiling, a bottom structure, and side panels connecting the ceiling and the bottom structure. A rear housing is connected to the front housing. The rear housing has a frame assembly connected to the ceiling and the bottom structure. A plurality of patch panel supports disposed in the front housing configured to receive a patch panel assembly. A ceiling cable management structure formed on the ceiling, wherein the ceiling cable management structure defines at least two troughs on the ceiling.

A flexible printed circuit board and optical network allocation device comprising same. The flexible printed circuit board comprises a circuit board body (1), a plurality of protruding interfaces (101) on the circuit board body, an adhesive layer (2) covering the upper surface of the circuit board body (1), components (102), and an uplink interface (103) used for information interaction with the components (102) on the circuit board body (1). Each protruding interface (101) is provided with an electronic label read/write interface (1011) used for reading electronic label information on an optical fiber head and an indicator (1012). The adhesive layer (2) is provided with an open window region (201) in the middle. The components (102) are immobilized on the upper surface of the circuit board body (1) and located in the open window region (201) of the adhesive layer, and are connected to the electronic label read/write interface (1011), the indicator (1012), and the uplink interface (103) respectively, used for controlling and monitoring the read/write information of the electronic label read/write interface (1011) and controlling on/off of the indicator (1012).