An electrical device cover assembly having a hinge pin lock is disclosed. The electrical device cover assembly comprises a base having at least a first base hinge aperture and a lid having at least a first lid hinge aperture. The lid is hingedly coupled to the base along an axis by at least a first pin coupled to both the first base hinge aperture and the first lid hinge aperture. The hinge pin lock comprises an opening sized to receive a portion of at least the first pin in a direction normal to the axis, and at least a first locking surface. The hinge pin lock is directly and releasably coupled to the first pin such that the first locking surface is between a first pin capture surface of the first pin and a head of the first pin. The electrical device cover assembly may further comprise a second pin.

An apparatus includes an enclosure, a power switch, one or more power converters and a wire. The enclosure may include a door. The power switch may be mounted inside the enclosure and configured to switch electrical power from a line-side power line to a load-side power line. The load-side power line may be configured to transfer the electrical power outside of the enclosure to an industrial control panel. The one or more power converters may be configured to generate a low-voltage electrical power from the electrical power. The wire may be configured to transfer the low-voltage electrical power outside of the enclosure.

An apparatus includes an enclosure, a power switch, one or more power converters and a wire. The enclosure may include a door. The power switch may be mounted inside the enclosure and configured to switch electrical power from a line-side power line to a load-side power line. The load-side power line may be configured to transfer the electrical power outside of the enclosure to an industrial control panel. The one or more power converters may be configured to generate a low-voltage electrical power from the electrical power. The wire may be configured to transfer the low-voltage electrical power outside of the enclosure.

A specialized in-wall mounting apparatus encapsulates a virtualized hardware box and related electronic components in a uniquely-vertical and inverse orientation. The specialized in-wall mounting apparatus holds the virtualized hardware box vertically and inversely (i.e. upside down) with mounting brackets to position the front plate of the virtualized hardware box to face the ground, the rear plate to face up, and the body of the virtualized hardware box to be parallel to a vertical wall. Preferably, the specialized in-wall mounting apparatus is partially embedded in the vertical wall, with a carved-in section on the vertical wall. The apparatus may also optionally incorporate a thermal dissipation meshed screen front door. Furthermore, instead of utilizing a conventional MDF room, multiple specialized in-wall mounting apparatuses may be embedded in multiple office rooms in a distributed manner to connect multiple virtualized hardware boxes and PoE switches through in-wall distributed Ethernet cabling and fiber backbone.

A specialized in-wall mounting apparatus encapsulates a virtualized hardware box and related electronic components in a uniquely-vertical and inverse orientation. The specialized in-wall mounting apparatus holds the virtualized hardware box vertically and inversely (i.e. upside down) with mounting brackets to position the front plate of the virtualized hardware box to face the ground, the rear plate to face up, and the body of the virtualized hardware box to be parallel to a vertical wall. Preferably, the specialized in-wall mounting apparatus is partially embedded in the vertical wall, with a carved-in section on the vertical wall. The apparatus may also optionally incorporate a thermal dissipation meshed screen front door. Furthermore, instead of utilizing a conventional MDF room, multiple specialized in-wall mounting apparatuses may be embedded in multiple office rooms in a distributed manner to connect multiple virtualized hardware boxes and PoE switches through in-wall distributed Ethernet cabling and fiber backbone.

A reusable electrical panel cover for protecting an electrical panel box made of a sturdy rectangular box-shaped panel cover with two length-edge sides and two width-edge sides, a front, a plurality of small openings for attaching the reusable electrical panel cover to an electrical panel box, at least one cutout in the front for access through the reusable electrical panel cover to the electrical panel, and at least one breakaway portion on one width-edge side and at least one breakaway portion on one length-edge side, with each breakaway portion having a breakaway edge.

A reusable electrical panel cover for protecting an electrical panel box made of a sturdy rectangular box-shaped panel cover with two length-edge sides and two width-edge sides, a front, a plurality of small openings for attaching the reusable electrical panel cover to an electrical panel box, at least one cutout in the front for access through the reusable electrical panel cover to the electrical panel, and at least one breakaway portion on one width-edge side and at least one breakaway portion on one length-edge side, with each breakaway portion having a breakaway edge.

An apparatus includes an enclosure, a power switch, one or more power converters and a wire. The enclosure may include a door and one or more apertures. The enclosure may be mechanically attachable to an external side of an industrial control panel with the apertures aligned to one or more openings in a wall of the industrial control panel. The power switch may be mounted inside the enclosure and configured to switch electrical power from a line-side power line to a load-side power line. The load-side power line may be configured to transfer the electrical power through at least one of the apertures. The power converters may be configured to generate a low-voltage electrical power from the electrical power. The wire may be configured to transfer the low-voltage electrical power through at least one of the apertures.

An apparatus includes an enclosure, a power switch, one or more power converters and a wire. The enclosure may include a door and one or more apertures. The enclosure may be mechanically attachable to an external side of an industrial control panel with the apertures aligned to one or more openings in a wall of the industrial control panel. The power switch may be mounted inside the enclosure and configured to switch electrical power from a line-side power line to a load-side power line. The load-side power line may be configured to transfer the electrical power through at least one of the apertures. The power converters may be configured to generate a low-voltage electrical power from the electrical power. The wire may be configured to transfer the low-voltage electrical power through at least one of the apertures.

A breaker panel cover extension can be installed above or below a breaker panel and can hide imperfections or openings in drywall immediately above or below the breaker panel. The cover extension can include a panel member having a top edge, a bottom edge, a left edge, and a right edge defining an area of the panel member. The panel member having a front face and a rear face. A thin and narrow bottom flange extends downwards from the bottom edge and away from the panel member. The thin and narrow flange can extend along the length of the bottom edge. On the rear face of the panel member, below the top edge, two or more brackets can be coupled to the rear face of the panel member. Each bracket can have a coupling member configured to engage the cover extension to the drywall.