A safety device for modules that store windings of communication lines, includes a metallic rod whose ends are configured to receive metallic screws to secure the rod on a base of a given module. End sections of the rod extend to a height at least equal to the height of the stored windings. Intermediate sections of the rod extend in opposite directions from the end sections, substantially parallel to the module base. Outer ends of the intermediate sections at least coincide with the outer periphery of the stored windings. A central section of the rod has opposite ends adjoining the outer ends of the intermediate sections. The central section rises over a path that at least coincides with the outer periphery of the stored windings. The end sections of the rod capture the windings, and the central section prevents them from dropping below the module during a building fire.

There is provided a method of installing spiral hangers about a messenger line installed between first and second utility poles with a cable being lashed to the messenger line with a lashing wire. The method includes attaching a first and second spiral hangers to the messenger line between first and second utility poles with the first spiral hanger disposed about the messenger line and the cable. The method includes removing the lashing wire from being around the messenger line and the cable adjacent the second spiral hanger. The method includes moving the second spiral hanger towards the second utility pole. The method includes attaching a successive spiral hanger to the messenger line between the spiral hangers, and repeating the moving of the second spiral hanger and attaching another successive spiral hanger.

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 method may include (1) coating a segment of fiber optic cable with an adhesive substance, (2) forming a coil of the segment of fiber optic cable, (3) deforming the coil into a noncircular shape defining a slot external to the coil while obeying a minimum bend radius requirement for the segment of fiber optic cable, and (4) activating the adhesive substance to stabilize the noncircular shape of the coil. Various other methods and apparatuses, such as those for performing the deforming operation, are also disclosed.

The disclosed robotic system may include (1) a drive subsystem that translates the robotic system along a powerline conductor and (2) a rotation subsystem coupled to the drive subsystem, where (a) the rotation subsystem is coupled to a container that defines an arcuate volume about an axis such that the container partially surrounds the powerline conductor when the axis aligns with the powerline conductor, (b) the container carries a segment of fiber optic cable coupled to the powerline conductor, and (c) the rotation subsystem, while the drive subsystem translates the robotic system along the powerline conductor, rotates the container about the powerline conductor while the axis is aligned with the powerline conductor such that the segment of fiber optic cable is wrapped helically about the powerline conductor. Various other systems and methods are also disclosed.

The disclosed system may include (1) a drive subsystem that translates along a powerline conductor, (2) a rotation subsystem that rotates a segment of fiber optic cable about the powerline conductor while the drive subsystem translates along the powerline conductor such that the segment of fiber optic cable is wrapped helically about the powerline conductor, and (3) an extension subsystem that (a) mechanically couples the rotation subsystem to the drive subsystem, and (b) selectively extends the rotation subsystem away from the drive subsystem and the powerline conductor to avoid obstacles along the powerline conductor. Various other systems and methods are also disclosed.

A safety device for modules that store windings of communication lines, includes a metallic rod whose ends are configured to receive metallic screws to secure the rod on a base of a given module. End sections of the rod extend to a height at least equal to the height of the stored windings. Intermediate sections of the rod extend in opposite directions from the end sections, substantially parallel to the module base. Outer ends of the intermediate sections at least coincide with the outer periphery of the stored windings. A central section of the rod has opposite ends adjoining the outer ends of the intermediate sections. The central section rises over a path that at least coincides with the outer periphery of the stored windings. The end sections of the rod capture the windings, and the central section prevents them from dropping below the module during a building fire.

The disclosed system may include (1) a spool that carries a length of fiber optic cable to be installed on a powerline conductor, where the spool defines multiple axes of rotation, and (2) a motion subsystem that carries the spool, where the motion subsystem (a) causes the system to travel along the powerline conductor, (b) revolves the spool helically about the powerline conductor at a first rate related to a second rate at which the system travels along the powerline conductor, and (c) rotates the spool about the multiple axes of rotation while revolving the spool helically about the powerline conductor to helically wrap the fiber optic cable about the powerline conductor. Various other systems, apparatuses, and methods are also disclosed.

There is provided a method of installing spiral hangers about a messenger line installed between first and second utility poles with a cable being lashed to the messenger line with a lashing wire. The method includes attaching a first and second spiral hangers to the messenger line between first and second utility poles with the first spiral hanger disposed about the messenger line and the cable. The method includes removing the lashing wire from being around the messenger line and the cable adjacent the second spiral hanger. The method includes moving the second spiral hanger towards the second utility pole. The method includes attaching a successive spiral hanger to the messenger line between the spiral hangers, and repeating the moving of the second spiral hanger and attaching another successive spiral hanger.

The disclosed systems for suspending cable (e.g., fiber optic cable) from an overhead powerline may include a payload subsystem for housing and dispensing a cable, a rotation subsystem for winding the cable around the powerline, an extension subsystem for raising at least a portion of the payload subsystem vertically upward from the powerline, a stabilization subsystem for stabilizing the system at least when the payload system is extended away from the powerline by the extension subsystem, and a drive subsystem for driving the system along the powerline. Various other related systems, devices, mechanisms, and methods are also disclosed.