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.

A support device for supporting a cable includes a central support portion having a first side and a second side. The support device also includes a first leg portion extending between a first end and a second end, the first leg portion having a first helical winding. The support device also includes a second leg portion extending between a third end and a fourth end, the second leg portion having a second helical winding. The support device further includes a hanger portion attached to the central support portion. The hanger portion includes structure that cooperates with an associated attachment structure. The first leg portion is attached to the central support portion and the second leg portion is attached to the central support portion. The first helical winding and the second helical winding are configured to receive the cable.

The clamping device may include (1) a monitoring device for a powerline conductor, where the monitoring device includes (a) at least one detection component that detects at least one physical characteristic at a location of the monitoring device, (b) a transmitter that wirelessly transmits data indicating the at least one physical characteristic, and (c) a receiver that wirelessly receives data indicating the at least one physical characteristic from at least one other monitoring device, where the transmitter retransmits the data indicating the at least one physical characteristic from the at least one other monitoring device, and (2) a container that retains the monitoring device such that one or more of the at least one detection component is maintained proximate the powerline conductor. The clamping device clamps a fiber optic cable to the powerline conductor to restrict movement of the fiber optic cable relative to the powerline conductor.

A mid-span optical fiber cable support system is provided. The system includes a mid-span clamp system engaging a main span cable to support a mid-span later drop cable run. The mid-span clamping system includes a main span cable clamp engaging the main span cable, and a drop cable clamp engaging the drop cable. The drop cable clamp is supported from the main span cable such that the second portion of the drop cable extends away from the main span cable such that a load applied by the drop cable at the drop cable clamp is substantially perpendicular to the preferential bend axis of the main span cable. In addition, the main span cable clamp includes a bend strain reducing curved surface.

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.

The disclosed system may include (1) a plurality of monitoring devices, where each of the plurality of monitoring devices is located at a different location along a powerline conductor and may include (a) at least one detection component that detects at least one physical characteristic at the location of the monitoring device along the powerline conductor, and (b) a transmitter that wirelessly transmits data indicating the at least one physical characteristic, and (2) a data injection device that (a) wirelessly receives the data indicating the at least one physical characteristic detected by the plurality of monitoring devices at the different locations along the powerline conductor, (b) transforms the data into an optical signal, and (c) injects the optical signal onto a fiber optic cable for transmission to a data collection subsystem. Various other systems and methods are also disclosed.

A mid-span optical fiber cable support system is provided. The system includes a mid-span clamp system engaging a main span cable to support a mid-span later drop cable run. The mid-span clamping system includes a main span cable clamp engaging the main span cable, and a drop cable clamp engaging the drop cable. The drop cable clamp is supported from the main span cable such that the second portion of the drop cable extends away from the main span cable such that a load applied by the drop cable at the drop cable clamp is substantially perpendicular to the preferential bend axis of the main span cable. In addition, the main span cable clamp includes a bend strain reducing curved surface.

A conduit for laying a cable includes a suspension wire, one or more hangers held by the suspension wire and having an accommodation space that accommodates the cable, and a groove extending along an axial direction of the suspension wire. The groove has an opening connected to the accommodation space. The opening has a width smaller than a maximum width of an interior of the groove.

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 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.