In some examples, a cable guide can include a translator including a protrusion with an opening and a retention mechanism to retain the translator in a housing. The cable guide can include a cable flange including an arm and an attachment annulus. The cable guide can include a coupling mechanism to couple the translator to the cable flange, where the arm is disengaged from the housing when the cable guide is in a disengaged position and the arm is engaged with the housing and the cable flange and the housing are to form a pathway when the cable guide is in an engaged position.

A wire management system including a cord cover. A kit of the wire management system can include a plurality of cord covers having various sizes or shapes to enable arrangement over cords or cables of various lengths without having to cut the cord covers to particular sizes. Various connectors can be used to cover or couple adjacent cord covers.

A bracket assembly that secures a cable to a ladder rung with first and second beam flanges extending from a beam web. The bracket assembly includes a bracket and a tether connected to the bracket. The bracket has a rung attachment portion configured to receive the second beam flange and a cable attachment portion extending from the rung attachment portion. The tether has a retention pin. The tether is slidable between an initial position and a latched position. In the latched position, the retention pin moves into engagement with the rung attachment portion to engage the second beam flange thereby latching the ladder rung to the bracket assembly.

System and method for supporting an electrical, conductor-carrying set of end to end pipes or enclosures to form an Iso Phase bus for electrical power transmission. The multiple tubular components are axially aligned in the field by a system comprising a saddle support with support legs, brackets for the support legs wherein the brackets secure to the upper flange of an I-beam on a steel support held in the ground. The brackets are adjustably secured to the legs of the saddle support and to the flange of the I-beam. In addition, an over the top enclosure, thin metal strap is provided which is also secured to the bracket and to the flange of the I-beam. Adjustments of the orientation of one enclosure to the adjacent connecting enclosure is able to be done in three axis.

An earth wire holder for a cable tray having two spaced-apart side bars, wherein the earth wire holder is in the form of a spring clamp having a side bar receptacle enclosed by two mounting arms for connecting the spring clamp to the upper edge of a side bar and having an undercut earth wire receptacle enclosed by two holding arms, wherein, when the spring clamp is mounted on the upper edge of the side bar, the mounting arms bear against the side bar under prestress, and the spacing between the holding arms in the section thereof enclosing the earth wire receptacle is smaller than the diameter of the earth wire to be introduced therein.

A wire management bracket for wireless charger is provided, including: a carrying seat, a wire management dial, and a ring seat; the carrying seat having an exposed accommodating groove located in central area, a groove wall of the accommodating groove having a notch; the wire management dial being disposed on the carrying seat and located at the other end surface where the accommodating groove located, the wire management dial being rotatable, having a neck on circumference, and a square groove at center; the ring seat being pivotally connected to the circumference of the carrying seat, and the angle between the ring seat and the carrying seat being adjustable, and when folded, the ring seat being tightly close to the carrying seat and allowing the wire management dial to be located in the central area of the ring seat.

A wire harness has less differences of the amount of deflection caused by the self weight when the wire harness is constructed by arranging the plurality of the electric wire having the different cross-sectional area of the conductor. A wire harness has first and second electric wires arranged side by side in a direction intersecting an axial direction of the electric wires. Each of the first and second electric wires includes a conductor with a plurality of elemental wires, the second electric wire has a larger conductor cross-sectional area than the first electric wire has, the second electric wire has the larger outer diameter of the elemental wires composing the conductor than the first electric wire has, and the second electric wire contains a same or smaller number of elemental wires composing the conductor in comparison with the first electric wire.

A mounting bracket for an electrical box can be configured for use with a support that has a first and a second rail. The mounting bracket can include a first attachment device that is secured to mounting body and a second attachment device that is secured to the mounting body opposite the first attachment device. To secure the mounting bracket to the support, the first attachment device can be configured to engage one of the first rail or the second rail and the second attachment device can be configured to engage the other of the first rail or the second rail. Each of the first and second attachment devices can include a first arm configured to extend on a first side of the corresponding first or second rail, and a second arm configured to extend on a second side of the corresponding rail, opposite the first arm

Methods and devices for reducing stress and for increasing the load-bearing capacity of cable racks supporting electrical power and communication conduits and cables having increased versatility for conduit and cable sizes and quantities. Underground devices including rack arms for these applications are desirably made from plastic or composite materials. Rack arms desirably include openings for tying down the conduits and cables atop the arms. While non-metallic materials are designed to withstand environmental stresses, they typically have strength and rigidity properties less than the metallic structures previously used in such applications. Non-metallic rack arms with such openings may be reinforced locally with a stress attenuator or with ribs to increase their load-bearing and buckling capacity and to reduce their stress, strain and deflection under load. A stress attenuator may be made by increasing the in-molded thickness of the web in areas adjacent to or surrounding the tie-down openings.

A cable guide device of an articulated robot is disclosed. The disclosed cable guide device can comprise: a base; at least one rotary arm rotatably coupled to the base in an articulated form; at least one cable passing through the base so as to be connected to the rotary arms; a cable guide block coupled to a driving unit within the base; a sliding groove formed on the outer peripheral surface of the cable guide block; and a cable friction reducing device member which is coupled to a portion of the cable accommodated in the base and which rotates along the sliding groove together with the portion of the cable according to the rotation of the rotary arms.