An electrical connector assembly can include a housing having a connection opening configured to receive a conductor, and a lug channel in communication with the connection opening. The assembly can also include one or more lug motion resistance features extending from at least one of the housing and the lug. The one or more lug motion resistance features are configured to resist motion of the lug toward the closed position to retain the lug in the open position.

An electrical connector assembly can include a housing having a connection opening configured to receive a conductor, and a lug channel in communication with the connection opening. The assembly can also include one or more lug motion resistance features extending from at least one of the housing and the lug. The one or more lug motion resistance features are configured to resist motion of the lug toward the closed position to retain the lug in the open position.

A manual service disconnect for the in-vehicle electric current, which has a switch seat, a safety plug assembly, and a protection cover. The switch seat has a seat portion and a plug holder. The plug holder is provided with multiple power legs. The seat portion is hollow inside and has a plug port and a wire opening. The plug holder is disposed in the seat portion and faces the plug port. The power legs project from the wire opening. The safety plug assembly has a plug portion matching the seat portion and a plug head disposed on the plug portion. The protection cover is disposed on the seat portion and covers the wire opening to cover the power legs for protection.

A manual service disconnect for the in-vehicle electric current, which has a switch seat, a safety plug assembly, and a protection cover. The switch seat has a seat portion and a plug holder. The plug holder is provided with multiple power legs. The seat portion is hollow inside and has a plug port and a wire opening. The plug holder is disposed in the seat portion and faces the plug port. The power legs project from the wire opening. The safety plug assembly has a plug portion matching the seat portion and a plug head disposed on the plug portion. The protection cover is disposed on the seat portion and covers the wire opening to cover the power legs for protection.

Remote control devices may control electrical loads and/or load control devices of a load control system without accessing electrical wiring. The remote control device may be mounted over a mechanical switch that is installed in a wallbox. The remote control device may include a control unit and a faceplate assembly. The faceplate assembly may include a mounting frame, an adapter plate, and a faceplate. The mounting frame may be configured to abut a bezel of the mechanical switch such that that the faceplate is spaced away from the bezel of the mechanical switch to enable the mounting ring to extend through respective openings in the adapter plate and the faceplate.

A transfer assembly is for a switching assembly of an electrical enclosure. The switching assembly includes an electrical switching apparatus having an operating handle structured to move from an OFF position to an ON position. The transfer assembly includes a driving handle; a first shaft member coupled to the driving handle; a second shaft member structured to be coupled to the operating handle; and a transmission assembly having a first component and a second component, the first component being coupled to the first shaft member, the second component being coupled to the second shaft member. The transfer assembly is structured to move from a FIRST position to a SECOND position. When the transfer assembly moves from the FIRST position to the SECOND position, the first component drives the second component, thereby causing the second shaft member to move the operating handle from the OFF position to the ON position.

A transfer assembly is for a switching assembly of an electrical enclosure. The switching assembly includes an electrical switching apparatus having an operating handle structured to move from an OFF position to an ON position. The transfer assembly includes a driving handle; a first shaft member coupled to the driving handle; a second shaft member structured to be coupled to the operating handle; and a transmission assembly having a first component and a second component, the first component being coupled to the first shaft member, the second component being coupled to the second shaft member. The transfer assembly is structured to move from a FIRST position to a SECOND position. When the transfer assembly moves from the FIRST position to the SECOND position, the first component drives the second component, thereby causing the second shaft member to move the operating handle from the OFF position to the ON position.

A barrier includes a cover and an attachment apparatus and is usable with an electrical interruption device. The attachment apparatus includes a number of attachment structures that are situated on the cover and that are each structured to be engaged with at least one of the housing of the electrical interruption device and a number of terminal assemblies of the electrical interruption device. The cover is configured to overlie at least a portion of the electrical interruption device and to resist the entry of a probe of known dimensions into electrical contact with components that are electrified even when the electrical interruption device is in an OFF condition.

In particular embodiments, a smart speaker includes a speaker, a housing with a speaker grille portion, a circuit board, and one or more indirect input sensors (e.g. an antenna or a proximity sensor). The grille can comprise a first plurality of openings. The circuit board can reside behind the grille and in front of the speaker (e.g. in the path of sound transmission from the speaker). The circuit board can be a substrate for the one or more indirect input sensors. The circuit board can further comprise a second plurality of openings, at least some of which align with at least some of the openings in the grille, thereby providing sound transmission through the circuit board, while providing improved access for the sensors to the local environment in the vicinity of the smart speaker. Several embodiments enable the region behind the speaker grille to accomplish the dual functions sensing the local environment and sound transmission. For example, an indirect input sensor may detect aspects of the local environment (e.g. hand gestures made by a user, or the location of a person) and activate one more aspects of the smart speaker in response (e.g. illuminate a display).

In particular embodiments, a smart speaker includes a speaker, a housing with a speaker grille portion, a circuit board, and one or more indirect input sensors (e.g. an antenna or a proximity sensor). The grille can comprise a first plurality of openings. The circuit board can reside behind the grille and in front of the speaker (e.g. in the path of sound transmission from the speaker). The circuit board can be a substrate for the one or more indirect input sensors. The circuit board can further comprise a second plurality of openings, at least some of which align with at least some of the openings in the grille, thereby providing sound transmission through the circuit board, while providing improved access for the sensors to the local environment in the vicinity of the smart speaker. Several embodiments enable the region behind the speaker grille to accomplish the dual functions sensing the local environment and sound transmission. For example, an indirect input sensor may detect aspects of the local environment (e.g. hand gestures made by a user, or the location of a person) and activate one more aspects of the smart speaker in response (e.g. illuminate a display).