An electrical connection structure includes a case in which a first electric motor and a second electric motor are housed, and electrical equipment that controls the first electric motor or the second electric motor. The first electric motor is electrically connected to a first three-phase terminal of the electrical equipment via a connecting member. The second electric motor is electrically connected to a second three-phase terminal of the electrical equipment via the connecting member. On the electrical equipment side, the first three-phase terminal and the second three-phase terminal are arranged in series. On the case side, a first electric motor side three-phase terminal, which is connected to the first electric motor, in the connecting member, and a second electric motor side three-phase terminal, which is connected to the second electric motor, in the connecting member, are arranged in parallel.

An electrical connection structure includes a case in which a first electric motor and a second electric motor are housed, and electrical equipment that controls the first electric motor or the second electric motor. The first electric motor is electrically connected to a first three-phase terminal of the electrical equipment via a connecting member. The second electric motor is electrically connected to a second three-phase terminal of the electrical equipment via the connecting member. On the electrical equipment side, the first three-phase terminal and the second three-phase terminal are arranged in series. On the case side, a first electric motor side three-phase terminal, which is connected to the first electric motor, in the connecting member, and a second electric motor side three-phase terminal, which is connected to the second electric motor, in the connecting member, are arranged in parallel.

A hinged dead front for an enclosure of an electrical panelboard, said enclosure defined by a rear panel, an operative left side panel, an operative right side panel and a door, wherein the rear panel of said enclosure is provided with hinged mounting bracket assemblies on which said dead front is hingeably mounted; and latch stopping bracket assemblies configured to engage with locking elements fitted on said dead front.

A hinged dead front for an enclosure of an electrical panelboard, said enclosure defined by a rear panel, an operative left side panel, an operative right side panel and a door, wherein the rear panel of said enclosure is provided with hinged mounting bracket assemblies on which said dead front is hingeably mounted; and latch stopping bracket assemblies configured to engage with locking elements fitted on said dead front.

A prefabricated electrical module and system along with fabrication and installation methods are provided. The prefab electrical module includes a circuit breaker panel casing that houses multiple circuit breakers, and a chase extending upwardly from the panel casing that stows coiled lengths of homerun wiring attached to the circuit breakers. During transport, a temporary panel casing front cover protects the panel casing front, and a forwardly protruding guard cover with an upwardly projecting hoisting handle shields the front and top of the chase and wiring. During installation, a hoisting bracket is attached at the top of the stud bay into which the prefab electrical module will be installed. A drill-powered winch is then used to lift the module to the proper height in the bay. The panel casing, chase, wiring, and breakers remain in the wall. The hoisting bracket, temporary panel casing front cover, guard cover, drill, and winch are reusable.

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.

An energized parts guard is disclosed comprising a panel of substantially rigid, electrically insulative material wherein the substantially rigid panel further comprises a first one or more apertures and a second one or more apertures. The first one or more apertures are so dimensioned to accept one or more circuit breakers inserted into the first one or more apertures such that there is less than a 12.5 mm gap between the panel and the circuit breaker on at least two sides of the one or more circuit breakers. The second one or more apertures are positioned to facilitate access to at least one terminal of each of the one or more circuit breakers when the one or more circuit breakers are inserted into the first one or more apertures.

An energized parts guard is disclosed comprising a panel of substantially rigid, electrically insulative material wherein the substantially rigid panel further comprises a first one or more apertures and a second one or more apertures. The first one or more apertures are so dimensioned to accept one or more circuit breakers inserted into the first one or more apertures such that there is less than a 12.5 mm gap between the panel and the circuit breaker on at least two sides of the one or more circuit breakers. The second one or more apertures are positioned to facilitate access to at least one terminal of each of the one or more circuit breakers when the one or more circuit breakers are inserted into the first one or more apertures.

A simulated protected loads panel system for managing energy consumption and obviating the need to install a physical protected loads panel in conjunction with an energy storage system, comprising a controller, in operable communication with electrical current and/or voltage sensors and relays, which is configured to control the amount of and/or distribution of electrical power from a source of electrical power to an electrical load based on user preference, energy storage system charge, and/or available or anticipated power generation and/or usage.

A distribution board shield. The distribution board shield includes a drape formed of an elongated non-conductive material having a top end, a bottom end, a rear surface and a front surface. A connector is used to attach the drape within a distribution panel box so that the drape covers exposed bar buses, breaker busses and wires within the working area.