A mounting device includes a panel portion, and a fastener receiving structure provided within a perimeter of the panel portion. The fastener receiving structure can include a flexure mechanism to enable at least a portion of the fastener receiving structure to flex with insertion of a fastener into the flexure mechanism that attaches the panel portion against an underlying surface.

A mounting device includes a panel portion, and a fastener receiving structure provided within a perimeter of the panel portion. The fastener receiving structure can include a flexure mechanism to enable at least a portion of the fastener receiving structure to flex with insertion of a fastener into the flexure mechanism that attaches the panel portion against an underlying surface.

A spliced LED box body includes at least four LED boxes arranged in rows and columns and spliced with each other, wherein connecting components are provided on opposite adjacent splicing surfaces of the LED box. The connecting components include a first connecting component, a second connecting component, a third connecting component and a fourth connecting component. The first connecting component and third connecting component are arranged on two adjacent side surfaces of the LED box, the second connecting component is arranged on a side surface of the LED box opposite to the first connecting component, and the fourth connecting component is arranged on a side surface of the LED box opposite to the third connecting component. When two adjacent LED boxes are spliced, the first connecting component and the second connecting component are matched and connected, and the third connecting component and the fourth connecting component are matched and connected.

A spliced LED box body includes at least four LED boxes arranged in rows and columns and spliced with each other, wherein connecting components are provided on opposite adjacent splicing surfaces of the LED box. The connecting components include a first connecting component, a second connecting component, a third connecting component and a fourth connecting component. The first connecting component and third connecting component are arranged on two adjacent side surfaces of the LED box, the second connecting component is arranged on a side surface of the LED box opposite to the first connecting component, and the fourth connecting component is arranged on a side surface of the LED box opposite to the third connecting component. When two adjacent LED boxes are spliced, the first connecting component and the second connecting component are matched and connected, and the third connecting component and the fourth connecting component are matched and connected.

A distribution box includes a box body, a cover plate, and at least one guiding rail. The box body has several side plates and a base plate. An opening is formed by surrounding an end of each side plate. The base plate is connected to another end of each side plate. The cover plate is detachably engaged with the box body and closes the opening. The guiding rail is disposed inside the box body and has an open end facing toward the opening. At least one electrical accessory slides into the guiding rail from the open end and is engaged with the guiding rail. With the open end facing toward the opening, the electrical accessory could be easily disassembled and assembled without reserving an installation space at a position adjacent to the open end for providing other electrical accessories, which provides an effect of saving installation space.

A distribution box includes a box body, a cover plate, and at least one guiding rail. The box body has several side plates and a base plate. An opening is formed by surrounding an end of each side plate. The base plate is connected to another end of each side plate. The cover plate is detachably engaged with the box body and closes the opening. The guiding rail is disposed inside the box body and has an open end facing toward the opening. At least one electrical accessory slides into the guiding rail from the open end and is engaged with the guiding rail. With the open end facing toward the opening, the electrical accessory could be easily disassembled and assembled without reserving an installation space at a position adjacent to the open end for providing other electrical accessories, which provides an effect of saving installation space.

A jumper bus bar may include a frame and a terminal assembly. The frame is to be seated along a surface of a housing of an electrical box. The terminal assembly features a first fork terminal perpendicular to the frame and a second fork terminal perpendicular to the frame. The first fork terminal is adjacent the second fork terminal. The terminal assembly also includes a slot to receive a terminal of a fuse or relay, the slot being coplanar with the frame.

A jumper bus bar may include a frame and a terminal assembly. The frame is to be seated along a surface of a housing of an electrical box. The terminal assembly features a first fork terminal perpendicular to the frame and a second fork terminal perpendicular to the frame. The first fork terminal is adjacent the second fork terminal. The terminal assembly also includes a slot to receive a terminal of a fuse or relay, the slot being coplanar with the frame.

A leafless joint apparatus that couples an enclosure housing to an enclosure cover or door. Similar to previous hinge apparatuses, the leafless joint apparatus can include a knuckle and a pintel or pin to facilitate pivot operations (e.g., the cover pivoting open). However, the leafless joint apparatus does not rely on leafs that attach by means of fasteners (e.g., screws or the like) and therefore can facilitate sliding operations (e.g., the cover can slide open). Thus, the leafless joint apparatus can facilitate access to an interior of the enclosure by way repositioning the cover of the enclosure via a pivot or hinging operation or via a sliding operation that can partially or fully expose the interior of the enclosure and even, if desired, slide entirely off, decoupling from the enclosure housing.

The present disclosure provides an electrical power supply structure comprising a plurality of insulated pipes, each insulated pipe extending longitudinally and configured to carry high amperage electrical power, a barrier support plate comprising one or more openings for receiving the plurality of insulated pipes, the barrier support plate configured for mounting over a hole through a floor of a building, a first support structure extending longitudinally upward from an upper side of the barrier support plate, and a second support structure extending longitudinally downward from a lower side of the barrier support plate through the hole. Each of the first and second support structures comprises a longitudinally extending enclosure having a plurality of transversely extending conductor support members for supporting the plurality of insulated pipes, and the plurality of insulated pipes are grouped by phase.