A cable management unit including a support assembly for mounting a patch panel, such as to a wall. The support assembly may include first and second anchor members adapted to be anchored to the wall, and first and second support arms hingedly coupled to the first and second anchor members at first and second hinge points, respectively. The first and second support arms may be adapted to be coupled to the patch panel. A chassis the patch panel may be supported by the first and second support arms. The first and second support arms may be configured to pivot about the first and second hinge points respectively between storage and access positions. The first and second support arms may extend outward from the wall in the access position and may be substantially parallel to the wall in the storage position.

A fiber optic cable distribution box has an interface compartment for interfacing a first set of fibers when routed inside the compartment, with a second set of fibers associated with a fiber optic cable that is routed to the box. A drum region is disposed beneath the interface compartment. The drum region includes a cylindrical wall for supporting a fiber optic cable wound about the wall. The drum region is formed so that the box can turn about the axis of the cylindrical wall when a cable is paid out from the drum region. The interface compartment and the drum region are constructed so that the first set of fibers inside the interface compartment, originate from an inside end portion of the cable wound on the drum region.

A splice closure apparatus and a fiber optic distribution network are provided. The splice closure apparatus includes a housing forming a plenum and an opening. A mount plate is affixed in the plenum within the housing, A signal splitter device is affixed to the mount plate. A fiber optic cable stub is extended through the opening of the housing. The cable stub includes an input optical fiber operably connected to the signal splitter device. The cable stub includes an output optical fiber operably connected to the signal splitter device.

A drop terminal mounting system includes a fiber drop terminal having a housing and a base attached to the housing. The housing includes an outer surface containing a plurality of receptacles and cooperatively defines an inner cavity with the base. The drop terminal mounting system further includes a bracket having a first fastening region and a second fastening region adapted to secure the drop terminal to the bracket.

A flexible cable support includes a first elongated member, a second elongated member and a base. The first elongated member and the second elongated member extend along a longitudinal axis. The base may connect the first elongated member and second elongated member. The first elongated member, the base, and the second elongated member define a longitudinal recess which is configured to receive a cable.

An assembly for pulling, pushing, or blowing a plurality of preterminated fiber optic cables of a multi fiber cable through a duct includes a sleeve, a rod configured to be coupled with the sleeve, and a plurality of dust caps. The sleeve is configured to receive to be coupled with a multi fiber cable and to permit a plurality of preterminated fiber optic cables of the multi fiber cable to pass through the sleeve, and the rod includes a first end configured to be coupled with the sleeve. Each of the plurality of dust caps is configured to be coupled with a ferrule of one of the preterminated fiber optic cables, and each of the plurality of dust caps is configured to be coupled with the rod, thereby coupling the preterminated fiber optic cables with the rod. The preterminated fiber optic cables are configured to be assembled with a fiber optic connector, the deployment assembly has a cross-sectional footprint that is smaller than a cross-sectional footprint of a fiber optic connector that is configured to be assembled with the preterminated fiber optic cable, and the plurality of preterminated fiber optic cables are configured to be pushed, pulled, or blown together through a duct having an inner diameter than is less than a cross-sectional footprint of a fiber optic connector that is configured to be assembled with the preterminated fiber optic cable.

A factory processed and assembled optical fiber arrangement is configured to pass through tight, tortuous spaces when routed to a demarcation point. A connector housing attaches to the optical fiber arrangement at the demarcation point (or after leaving the tight, tortuous spaces) to form a connectorized end of the optical fiber. A fiber tip is protected before leaving the factory until connection is desired.

The disclosure provides an optic fiber connector, including a ferrule, a holder, a connector body having a plurality of first locking slots, a spring sleeved onto the holder, and a retainer having a plurality of locking hooks. The ferrule is assembled to the holder. The spring, the holder, and the ferrule are received in a space formed between the retainer and the connector body by locking the locking hooks with the locking slots respectively, wherein the spring is compressed by locking such that the retainer, the holder, the spring, and the connector body are abutted with each other.

An object of the present invention is to provide a cable route design method that makes it possible to select a route for routing a communication cable in consideration of an influence of an air-conditioning airflow under a double floor. According to the present cable route design method, cables are routed such that an air-conditioning space under a double floor becomes as uniform as possible, a floor is modeled in a mesh structure, and one of cable routing patterns is applied to each of meshes and an air-conditioning airflow is calculated by a finite volume method, thereby indexing (an evaluation value) an air-conditioning efficiency. This enables comparison between a plurality of cable routing ideas, making it possible to find an optimal routing route.

An optical fiber distribution terminal assembly comprises a housing having a rear housing portion and a front housing portion moveable between an open position and a closed position defining an interior. The housing further defines at least one port for passage of a optical fiber distribution cable. A rotatable reel is located in the interior of the housing, the reel carrying a length of optical fiber distribution cable. A distribution module, also located in the housing, is operative to distribute source fibers of the optical fiber distribution cable to individual subscriber cables.