A bracket for suspending multiple line segments at an elevated location is disclosed. The bracket has a back portion to engage against a supporting surface at the elevated location. The back portion has a left segment and a right segment. The bracket has at least one of a left arm extending from the left segment or a right arm extending from the right segment. The bracket has at least one of a first left seat extending from the left arm, a second left seat extending from the left arm, a first right seat extending from the right arm, or a second right seat extending from the right arm. At least one of the multiple line segments are supported by at least one of the first left seat, the second left seat, the first right seat, or the second right seat.

A bracket for suspending multiple line segments at an elevated location is disclosed. The bracket has a back portion to engage against a supporting surface at the elevated location. The back portion has a left segment and a right segment. The bracket has at least one of a left arm extending from the left segment or a right arm extending from the right segment. The bracket has at least one of a first left seat extending from the left arm, a second left seat extending from the left arm, a first right seat extending from the right arm, or a second right seat extending from the right arm. At least one of the multiple line segments are supported by at least one of the first left seat, the second left seat, the first right seat, or the second right seat.

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.

An apparatus for controlling tension in a pulling rope that is attached to a flying, unmanned aerial device or drone may utilize a cylinder around which the rope is wound, a shaft that longitudinally passes through the cylinder, a disc brake rotor that is mounted to the shaft, a brake caliper that is mounted circumferentially at a periphery of the disc brake rotor, and a brake lever that tensions a cable that is attached to, and movable to control movement of, the brake caliper, which may be hydraulic, against surfaces the disc brake rotor. The brake lever may be hand actuated and mounted to a handlebar. A frame may be part of the apparatus and support apparatus components and may have a protruding hitch portion that inserts into a vehicle's receiver hitch. An adjustable pulling rope guide support through which the rope is threaded, mounts to the frame.

An apparatus for controlling tension in a pulling rope that is attached to a flying, unmanned aerial device or drone may utilize a cylinder around which the rope is wound, a shaft that longitudinally passes through the cylinder, a disc brake rotor that is mounted to the shaft, a brake caliper that is mounted circumferentially at a periphery of the disc brake rotor, and a brake lever that tensions a cable that is attached to, and movable to control movement of, the brake caliper, which may be hydraulic, against surfaces the disc brake rotor. The brake lever may be hand actuated and mounted to a handlebar. A frame may be part of the apparatus and support apparatus components and may have a protruding hitch portion that inserts into a vehicle's receiver hitch. An adjustable pulling rope guide support through which the rope is threaded, mounts to the frame.

A boom mountable breaker system and a method of using same for interrupting electrical transmission through a portion of an energized conductor downstream of a desired break location. The method includes: mounting the jumper onto the energized conductor across the desired break location so as to form an electrically conductive first parallel electrical path; installing an in-line opener in the energized conductor at the desired break location on the energized conductor; positioning the breaker at the desired break location on the energized conductor, and electrically connecting the breaker, while open, across the desired break location and across the opposite ends of the jumper so as to form a second parallel electrical path when the breaker is closed; closing the breaker to thereby complete the second parallel electrical path; removing the jumper from across the desired break location; and, opening and then removing the breaker.

An aerial inspection system is provided, including an unmanned aerial vehicle (UAV) having an articulated arm coupled thereto. An end effector is coupled to a second end of the articulated arm, the end effector sized and shaped to extend at least partially around an aerial cable in close proximity. One or more sensors are positioned along an inner surface of the end effector, and provide feedback to a control unit. In response, the control unit adjusts a position of at least one of the UAV, the articulated arm, and the end effector such that the end effector maintains a close, non-contact position with respect to the cable.

Connection joint for cables for a cable stringing plant, comprising at least one first tubular element (18) to which a first segment (22) of a flexible member (19) is attached and positioned rotatable, at least with respect to a longitudinal axis (L) of the joint, inside a second tubular element (23) open at a first end and closed at the other end by a bottom wall (25); the bottom wall (25) comprises at least one hole (26) from which a second segment (27) of the flexible member (19) emerges; the second segment (27) is attached to a portion (32) of a third tubular element (31); the second and third tubular elements (23, 31) are provided on opposite ends with a corresponding hole (29, 35) directed substantially in a longitudinal direction and able to house a respective segment of cable (11a, 11b) to be laid.

Connection joint for cables for a cable stringing plant, comprising at least one first tubular element (18) to which a first segment (22) of a flexible member (19) is attached and positioned rotatable, at least with respect to a longitudinal axis (L) of the joint, inside a second tubular element (23) open at a first end and closed at the other end by a bottom wall (25); the bottom wall (25) comprises at least one hole (26) from which a second segment (27) of the flexible member (19) emerges; the second segment (27) is attached to a portion (32) of a third tubular element (31); the second and third tubular elements (23, 31) are provided on opposite ends with a corresponding hole (29, 35) directed substantially in a longitudinal direction and able to house a respective segment of cable (11a, 11b) to be laid.

The disclosures concerns a wire guide assembly with at least one sheave for stringing utility cable about utility structures such as towers and telephone poles. A wire guide assembly comprises: a plurality of plates forming a housing, a sheave, and a side gate with an elongated guide arm extending therefrom, wherein the side gate is pivotally attached to a plate of the housing forming a channel corresponding to a volume between the sheave, the side gate, and the housing, with the guide arm attached to the housing at an angle between 45 and 90 degrees. The wire guide assembly is further characterized in that the wire guide assembly can be used in suspension, or attached to a cross arm of a utility structure, wherein the elongated guide arm extending outwardly from assembly can be utilized for catching utility wire as it is introduced to the assembly via a helicopter.