An insulator for a bracket arm of a stanchion that supports an electrical or other cable has a combination of tab pairs with lips that grip a flange portion of the arm, to hold the insulator against vertical upward force, a base preferably comprised of special ribbing to carry vertical load, and downwardly extending leg pairs that slidably engage vertical surfaces of the arm, to resist lateral and twisting loads.

A post insulator, a post insulator keeper, and a method of securing a conductor on a post insulator are provided. A post insulator includes: an electrically insulative case including an abutment surface defining a recess; and a keeper rotatably coupled to the case between an open position in which a conductor is receivable into the recess, and a closed position to maintain the conductor in the recess.

A post insulator, a post insulator keeper, and a method of securing a conductor on a post insulator are provided. A post insulator includes: an electrically insulative case including an abutment surface defining a recess; and a keeper rotatably coupled to the case between an open position in which a conductor is receivable into the recess, and a closed position to maintain the conductor in the recess.

An overhead power distribution line (10) comprises a tension resistant pole (101), two composite crossbeams (102) and tension resistant fixing members (103). A middle portion of the composite crossbeam (102) is horizontally secured on the tension resistant pole (101), and end portions of the composite crossbeam (102) are connected to the tension resistant fixing members (103). The tension resistant fixing members (103) enable the two composite crossbeams (102) to integrally connect and are for fixing conducting lines. With the above configuration, two composite crossbeams (102) are secured on the same horizontal plane of the tension resistant pole (101), thus satisfying vertical tension of a tension resistant requirement. Further, by using composited crossbeam bodies (102), a dry arc distance is significantly increased, and electrical lightning resistance performance is enhanced, preventing incidents such as line disconnection and flashover caused by lightning strike. The composite crossbeams (102) are maintenance-free and do not require periodical inspection and maintenance, significantly reducing labor costs. The use of crossbeams (102) can further eliminate the use of tension insulators and simplify the structure of lines.

A bracket for mounting cables on an antenna pole includes: a pair of L-shaped members, each of the L-shaped members including a main panel, a pair of jaws extending from opposite edges of the main panel, and a flange extending generally perpendicularly to the main panel, wherein the main panel includes a plurality of first mounting apertures, and wherein the flange includes a plurality of second mounting apertures; a pair of rods, each rod extending through a first mounting aperture of each of the L-shaped members; and a securing component that engages each rod to fix the members relative to each other.

A post insulator includes an insulating post including a first end and a second end that are opposite to each other, a high-voltage-end grading ring connected to the first end of the insulating post, the high-voltage-end grading ring being insulated from the insulating post, a grounding-end grading ring connected to the second end of the insulating post, the grounding-end grading ring being insulated from the insulating post, and a charge control ring disposed on an outer surface of the insulating post, the charge control ring being insulated from the insulating post, and the charge control ring being configured to accumulate surface charges.

A high performance differential cable comprises a bulk differential cable formed with a dielectric core having a central cavity and a plurality of wire guides on the outer perimeter. A pair of differential signal conductors (DSC) may be divided into two sets of wires. The smaller wires provide higher signal transmission speeds with lower losses. A paddle board at each end of the bulk differential cable comprises an interconnecting structure for combining signals from the two sets of wires into the two DSCs.

A high performance differential cable comprises a bulk differential cable formed with a dielectric core having a central cavity and a plurality of wire guides on the outer perimeter. A pair of differential signal conductors (DSC) may be divided into two sets of wires. The smaller wires provide higher signal transmission speeds with lower losses. A paddle board at each end of the bulk differential cable comprises an interconnecting structure for combining signals from the two sets of wires into the two DSCs.

A high performance differential cable comprises a bulk differential cable formed with a dielectric core having a central cavity and a plurality of wire guides on the outer perimeter. A pair of differential signal conductors (DSC) may be divided into two sets of wires. The smaller wires provide higher signal transmission speeds with lower losses. A paddle board at each end of the bulk differential cable comprises an interconnecting structure for combining signals from the two sets of wires into the two DSCs.

A high performance differential cable comprises a bulk differential cable formed with a dielectric core having a central cavity and a plurality of wire guides on the outer perimeter. A pair of differential signal conductors (DSC) may be divided into two sets of wires. The smaller wires provide higher signal transmission speeds with lower losses. A paddle board at each end of the bulk differential cable comprises an interconnecting structure for combining signals from the two sets of wires into the two DSCs.