A rotatable power strip outlet assembly that includes a power strip housing, a plurality of electrical sockets formed on a front surface of the power strip housing, and a rear plug support member rotatably coupled to the power strip housing, that includes a front surface, a rear surface, and an electrical plug disposed on the rear surface of the rear plug support member and with electrical prongs extending outwardly away from the rear surface of the rear plug support member and electrically coupled to the plurality of electrical sockets, wherein the power strip housing is operably configured to selectively rotate at least 270° with respect to the rear plug support member to reorient the power strip housing while plugged into an electrical outlet.

Provided is an electrical connection device (1) including a connector (2) having a hollow connecting cavity (21), each of two opposite sides of the connecting cavity is connected to a conductive plug (22) electrically coupled with the connecting cavity (21). The connecting cavity (21) is form by a plurality of flexible conductive materials. When in use, the grid-like connecting cavity (21) made of the flexible conductive materials can be elongated, compressed, or radially twisted, and is adaptive to changes in relative displacement at various angles at various angles in the axial direction or radial direction between different electrical connecting bases, thereby preventing degradation of performance of electrical connection due to the changes in relative displacement.

Provided is an electrical connection device (1) including a connector (2) having a hollow connecting cavity (21), each of two opposite sides of the connecting cavity is connected to a conductive plug (22) electrically coupled with the connecting cavity (21). The connecting cavity (21) is form by a plurality of flexible conductive materials. When in use, the grid-like connecting cavity (21) made of the flexible conductive materials can be elongated, compressed, or radially twisted, and is adaptive to changes in relative displacement at various angles at various angles in the axial direction or radial direction between different electrical connecting bases, thereby preventing degradation of performance of electrical connection due to the changes in relative displacement.

A rotatable power strip outlet assembly that includes a power strip housing, a plurality of electrical sockets formed on a front surface of the power strip housing, and a rear plug support member rotatably coupled to the power strip housing, that includes a front surface, a rear surface, and an electrical plug disposed on the rear surface of the rear plug support member and with electrical prongs extending outwardly away from the rear surface of the rear plug support member and electrically coupled to the plurality of electrical sockets, wherein the power strip housing is operably configured to selectively rotate at least 270° with respect to the rear plug support member to reorient the power strip housing while plugged into an electrical outlet.

A rotatable power strip outlet assembly that includes a power strip housing, a plurality of electrical sockets formed on a front surface of the power strip housing, and a rear plug support member rotatably coupled to the power strip housing, that includes a front surface, a rear surface, and an electrical plug disposed on the rear surface of the rear plug support member and with electrical prongs extending outwardly away from the rear surface of the rear plug support member and electrically coupled to the plurality of electrical sockets, wherein the power strip housing is operably configured to selectively rotate at least 270° with respect to the rear plug support member to reorient the power strip housing while plugged into an electrical outlet.

A powering surface assembly includes an electric power transfer arrangement connected to a power source, and having at least one of a conductive fabric, a conductive foam, or an inductive transmitter coil. A light assembly includes an electric power receiving arrangement, which electrically couples with the electric power transfer arrangement when the light assembly is attached to the surface assembly, such that power is transferred from the power source to the light assembly. The electric power receiving arrangement includes at least one of electrical contacts which contact the conductive fabric or the conductive foam, or an inductive receiver coil that inductively couples with the inductive transmitter coil.

A powering surface assembly includes an electric power transfer arrangement connected to a power source, and having at least one of a conductive fabric, a conductive foam, or an inductive transmitter coil. A light assembly includes an electric power receiving arrangement, which electrically couples with the electric power transfer arrangement when the light assembly is attached to the surface assembly, such that power is transferred from the power source to the light assembly. The electric power receiving arrangement includes at least one of electrical contacts which contact the conductive fabric or the conductive foam, or an inductive receiver coil that inductively couples with the inductive transmitter coil.

An automotive glazing including a glass substrate, an electrically connectable material positioned on the glass substrate, a connector comprising a base and a terminal, a conductive material positioned between the electrically connectable material and the connector, and an anchoring material at least partially surrounding the connector. The terminal of the connector at least partially extends out of the anchoring material, and the anchoring material provides pressure against the connector and binds the connector to the electrically connectable material on the glass substrate.

An automotive glazing including a glass substrate, an electrically connectable material positioned on the glass substrate, a connector comprising a base and a terminal, a conductive material positioned between the electrically connectable material and the connector, and an anchoring material at least partially surrounding the connector. The terminal of the connector at least partially extends out of the anchoring material, and the anchoring material provides pressure against the connector and binds the connector to the electrically connectable material on the glass substrate.

An electrical interface can include one or more connector devices that facilitate communication between components while they are connected. The connector devices can provide a secure communication and/or power link that resists infiltration by foreign object debris (“FOD”) as well as redundant electrical pathways. The connector devices can further provide mechanisms that are lightweight, are operable in a broad range of temperatures (e.g., low temperatures), accommodate displacement without loss of electrical continuity, and are of low resistance and induction. The connector devices can further provide a kickoff force upon separation of the components.