Aspects of the present disclosure describe aerial fiber optical cable localization using distributed acoustic sensing (DAS) that advantageously may determine the locality of electrical transformers affixed to utility poles along with the aerial fiber optical cable as well as any length(s) of fiber optical cable between the poles. Further aspects employ survey manned or unmanned, aerial or terrestrial survey vehicles that acoustically excite locations along the fiber optical cable and associate those DAS excitations with global positioning location (GPS).

A cable clamp for clamping drop cables to main span cables. The cable clamp has a body that includes an elongated drop cable guide, an elongated main span cable guide, and main body section between the drop cable guide and the main span cable guide. The body has a lower body half and an upper body half. The lower body half is movable relative to the upper body half between at least one open position and a clamping position. When the body is in a clamping position the lower body half and upper body half of the drop cable guide form a drop cable opening, and the lower body half and upper body half of the main span cable guide form a main span cable opening. A stem extends through the lower body half of the main body section and is releasably secured to the upper body half of the main body section such that rotational movement of the stem is translated to movement of the lower body half relative to the upper body half. The stem has a collar and a spring is positioned on the stem between the collar and the lower body half of the main body section to normally bias the body to the clamping position.

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.

An object of the present disclosure is to make it possible to adjust a balance of tension applied to an optical cable fixed to a utility pole.

A disclosed utility pole includes: a through hole (12) that is disposed on an upper side of a utility pole (10) and through which optical cable (21) can pass; and a cap (22) disposed in a gap between the through hole (12) and the optical cable (21), in which the cap (22) is fixed to the through hole (12).

A mounting system for suspending an enclosure from an aerial strand at a location near a pole is disclosed. The mounting system includes a hanger arrangement configured to clamp to the aerial strand with the enclosure hung below the aerial strand at a location where a center of gravity of the enclosure is laterally offset from the aerial strand such that a weight of the enclosure generates torque about the aerial strand. The mounting system includes a rod for securement to the hanger arrangement and to the pole for transferring the torque generated by the weight of the enclosure from the hanger arrangement to the pole such that the enclosure is prevented from rotating about the aerial strand toward a position where the center of gravity of the enclosure is located directly beneath the aerial strand.

A cable clamp for clamping drop cable clamp assemblies to main span cables. The cable clamp has a body that includes a main span cable guide and holders for supporting one or more drop cable clamp assemblies. The body has a lower body half and an upper body half. The lower body half is movable relative to the upper body half between an open position and a clamping position. When the body is in a clamping position the lower body half and upper body half of the main span cable guide form a main span cable cradle. A stem extends through the lower body half of the main body section and is releasably secured to the upper body half of the main body section such that rotational movement of the stem is translated to movement of the lower body half relative to the upper body half. The stem has a collar and a spring is positioned on the stem between the collar and the lower body half of the intermediate body section to normally bias the body to the clamping position.

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 clamp assembly includes a body having a jaw receiving cavity. A jaw actuator assembly is positioned within the jaw receiving cavity. A first jaw member is positioned within a first jaw guide associated with the body and the jaw receiving cavity and is operatively coupled to the jaw actuator assembly. A second jaw member is positioned within a second jaw guide associated with the body and the jaw receiving cavity and is operatively coupled to the jaw actuator assembly. The first and second jaw members are movable within the jaw receiving cavity between a loading position and a clamping position. The jaw actuator assembly moves the jaw members from the loading position and the clamping position. The clamp assembly applies sufficient clamping or gripping force on the fiber optic cable to hold the fiber optic cable without degrading or damaging the fiber optic cable resulting in signal loss.

A cable clamp for clamping drop cables to main span cables. The cable clamp has a frame, a jaw assembly and a stem. The frame has a main body, a drop cable body and a main cable body. The jaw assembly is operatively coupled to the main body and has a drop cable jaw and a main cable jaw. The drop cable jaw is movable along the main body between an open position and a closed position. The main cable jaw is movable along the main body between an open position and a closed position. The main cable jaw can be automatically moved from the open position to the closed position. The stem is operatively coupled to the main body and the jaw assembly so that the stem can selectively block the main cable jaw in the open position and release the main cable jaw so that can automatically move to the closed position.

Systems described herein provide antenna elements, each of which contains an antenna array and electronics, built into a fiber optic aerial cable to form a hybrid cable. The hybrid cable has a fiber buffer tube including one or more fiber cores, an outer sheath surrounding the fiber buffer tube, and a distributed array of antenna elements around portions of the outer sheath along a length of the hybrid fiber optic cable. Each of the antenna elements includes an antenna and control electronics for the antenna.