Device having a support for aerially suspending an optical fiber termination box to which an optical cable is routed. Features of the device are adapted to transfer cable load to the support thereby bypassing the optical fiber termination box, which can help to prevent damage to the optical fiber termination box and the optical fibers it supports.

A cable storage wheel for communication cables is provided. The cable storage wheel has a channel that receives the communication cable and a plurality of cable tie features. The cable tie features are positioned for receipt of cable ties to secure the communication cable in the channel in a manner that minimizes or eliminates contact between the wire ties and the communication cable. In this manner, the cable storage wheel is configured and designed to encourage the user to wrap the wire ties around the storage wheel and, not the communication cable. The cable tie features are, in some embodiments, slots, notches, openings, channel supports, and any combinations thereof.

A cable retention device useful for fiber optic cable retention, suspension and anchoring, of the drop type and is provided with a retaining element and a housing element, which once coupled retain a drop between them allowing the manipulation of the drop.

The present disclosure describes a grommet formed of a polymeric material and adapted for bundling a plurality of discrete cables, comprising a main body having a generally cylindrical profile surrounding an interior cavity, the main body further having a length, a thickness, and a longitudinal axis; and a central member integrally coupled to the main body and located within the interior cavity of the main body, the central member extending generally parallel to the longitudinal axis of the main body. Methods of bundling cables are also provided.

The disclosed method may include (1) mechanically coupling a first fiber optic cable duct to a powerline conductor, (2) attaching an end of the first fiber optic cable duct to a first port of a duct coupler, (3) attaching an end of a second fiber optic cable duct to a second port of the duct coupler, where the duct coupler forms a contiguous channel with the first fiber optic cable duct and the second fiber optic cable duct, (4) mechanically coupling the second fiber optic cable duct to the powerline conductor, and (5) installing a contiguous fiber optic cable within the contiguous channel. Various other methods, apparatuses, and systems are also disclosed.

A fiber distribution hub comprises a housing, a first side panel and a second side panel comprising one or more ports, and at least one cover disposed between the first side panel and the second side panel and forming an interior compartment. The interior compartment may include cable managers. A mounting structure aerially strand mounts the fiber distribution hub. Fiber distribution hubs comprising a first fiber distribution hub, a second fiber distribution hub configured to couple to the first fiber distribution hub, and a mounting structure configured to aerially strand mount the fiber distribution hub are also disclosed.

A method for overhead transmission line installation includes tension pulling a transmission line over a path between a first support structure having a first mounting location and a second support structure having a second mounting location extending from the first mounting location to a first transition location on the second support structure, to a second transition location on the first support structure, and to the second mounting location. The transmission line is mounted at the first mounting location and the second mounting location. The mounting provides a slack portion of the transmission line between the first mounting location and the second mounting location. A portion of the slack portion is mounted proximate to the first mounting location or the second mounting location to provide an overhead transmission line extending between the first mounting location and the second mounting location and a remainder of the slack portion.

A flexible optical fiber connector comprises a first housing component configured to couple to a terminating connector, and a second housing component configured to receive an optical fiber for termination in the terminating connector. The first housing component and the second housing component are further configured to receive a pushable connector therethrough. A flexible optical fiber connector assembly comprises a flexible connector and a terminating connector coupled thereto. The flexible connector assembly is configured to couple to an adapter held by a holder coupled to a port.

The present disclosure describes a grommet formed of a polymeric material and adapted for bundling a plurality of discrete cables, comprising a main body having a generally cylindrical profile surrounding an interior cavity, the main body further having a length, a thickness, and a longitudinal axis; and a central member integrally coupled to the main body and located within the interior cavity of the main body, the central member extending generally parallel to the longitudinal axis of the main body. Methods of bundling cables are also provided.

A fiber optic network includes a fiber distribution hub including at least one splitter and a termination field; a plurality of drop terminals optically connected to the fiber distribution hub by a plurality of distribution cables; and a distributed antenna system (DAS). The DAS includes a base station and a plurality of antenna nodes. The base station is optically connected to the fiber distribution hub and the antenna nodes are optically connected to the drop terminals. Example splitters include a passive optical power splitter and a passive optical wavelength splitter. Signals from a central office can be routed through the passive optical power splitter before being routed to subscriber locations optically connected to the drop terminals. Signals from the base station can be routed through the wavelength splitter before being routed to the antenna nodes.