An enclosure, one input cable and multiple output cables extending through the enclosure, a plurality of circuit breakers and ground-fault circuit interrupters in the enclosure and electrically connected to respective ones of the output cables, and a junction in the enclosure to which the input cable is electrically connected and to which the circuit breakers and ground-fault circuit interrupters are electrically connected. The output cables each include a connector for connection to an electric-powered machine, so that multiple of the machines can be powered and protected by a single power cabinet with a single power-supply connection.

An enclosure and a method of making the enclosure is provided that includes mixing stainless steel, rubber, and polycarbonate to produce a material mixture that is electrically conductive. Carbon black powder and polyethylene are blended to produce an electrically resistive additive for dissipating static electricity. At least one injection mold for the enclosure is positioned in fluid communication with an exit end of a heating barrel. The weatherproof material mixture is injected into an entry end of the heating barrel to produce a melted weatherproof material mixture. The electrically resistive additive is introduced through a lateral port of the heating barrel proximate to the exit end to partially mix with the melted weatherproof material mixture to produce an injection mixture. The injection mixture into the at least one injection mold to produce the enclosure that is weatherproof, electrically conductive, and electrically resistive.

A submersible control system with a control panel. The control panel has a frame to house electronic components. The frame has a connection opening for wiring required for an electrical connection to the electrical components. An outer door is attached to the frame to be water-tight to the frame in a closed position thereof. A conduit is sealed to be water-tight with respect to the connection opening. The conduit is filled with an epoxy for water-tight sealing an interior of the conduit to the wiring fed through the conduit. The control panel will remain water-tight for at least 24 hours after being submerged.

An electrical/electronics power distribution cabinet is disclosed which includes internal components enabling the cabinet to be quickly and easily reconfigured for allowing all cabling to exit an upper end of the cabinet or a lower end of the cabinet. The cabinet includes fully isolated top and bottom panelboard circuit breaker areas and a movable internal wall portion that helps to form an isolated compartment to route electrical cabling within the interior area of the cabinet, while keeping the cabling associated with the two panelboard circuit breaker areas fully separate from one another. This enables access to one of the top or bottom panelboard circuit breaker areas for service or reconfiguration without the need to access the other.

A top hat enclosure for use with an electrical panel, the electrical panel including at least one breaker and at least one panel pass-through aperture, includes a housing having at least one worker-accessible opening, a cover configured to cover the opening, and at least one enclosure pass-through aperture, wherein the enclosure pass-through aperture is configured to align with the panel pass-through aperture, and wherein the housing is configured to be disposed adjacent the electrical panel; and at least one finger-safe and/or tool-safe terminal configured to be wired to a breaker in the electrical panel through the enclosure pass-through aperture and the panel pass-through aperture.

A cable feedthrough for feeding at least one cable into a housing with an opening is provided. The cable feedthrough includes a covering comprising at least two housing shells, the covering having at least one opening, wherein a separating plane of the housing shells extends centrally through the opening, wherein to seal the housing, at least one elastic and/or flexible sealing element is provided that comprises a cable passage with a slit extending to the lateral edge of the cable passage, and wherein a counter pressure plate is provided that comprises at least one cable passage and covers the opening, the counter pressure plate cooperating with the sealing element and the covering to seal the housing. The sealing element is arranged with a predetermined oversize between the covering and the counter pressure plate and is under pressing force, as a result of which the sealing element is compressed.

An assembly includes a ring frame having first and second open sides and an electrical connector block; a mounting structure to which the ring frame is secured; a plurality of power and signal cable connection points defined on the ring frame; and a plurality of power and signal cables coupled to the power and signal cable connection points and the connector block. First and second covers are secured to the ring frame. Each of the first and second covers is open on one side facing the ring frame and defines a mounting cavity. A plurality of heat-dissipating electronic components are mechanically and thermally coupled to the first and second covers and located in the mounting cavities. The heat-dissipating electronic components are releasably electrically coupled to the electrical connector block.

An enclosure and a method of making the enclosure is provided that includes mixing stainless steel, rubber, and polycarbonate to produce a material mixture that is electrically conductive. Carbon black powder and polyethylene are blended to produce an electrically resistive additive for dissipating static electricity. At least one injection mold for the enclosure is positioned in fluid communication with an exit end of a heating barrel. The weatherproof material mixture is injected into an entry end of the heating barrel to produce a melted weatherproof material mixture. The electrically resistive additive is introduced through a lateral port of the heating barrel proximate to the exit end to partially mix with the melted weatherproof material mixture to produce an injection mixture. The injection mixture into the at least one injection mold to produce the enclosure that is weatherproof, electrically conductive, and electrically resistive.

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.

A landscape advertising light, box type miniaturized substation, belonging to the field of substations. The landscape advertising light box type miniaturized substation includes a box body; the box body is internally provided with a ring main unit, a transformer and an integrated low-voltage cabinet; the integrated low-voltage cabinet includes an incoming switch, a capacitor switch, a capacitor and an outgoing switch which are electrically connected in sequence; an output end of the ring main unit is electrically connected with an input end of the transformer, and an output end of the transformer is electrically connected with an input end of the incoming switch; a display screen is disposed outside the box body.