A plug-in device enclosing Ai (Artificial intelligent) and IoT (Internet of Things) and a method for linking AC wiring devices and AC loads via cascading optical grid for exchanging at least one of two way communication through the optical cascading grid, enabling to introduce and assign AC switches and AC outlets and link optically the entire electric device of a residential and commercial units and communicate the power consumed and the loads statuses, at all time, and limiting the WiFi communication to a single transmitter at the time, to ensure no error communication.

A physiological signal monitoring device includes a sensing member and a transmitter connected to the sensing member and including a circuit board that has electrical contacts, and a connecting port, which includes a socket communicated to the circuit board and a plurality of conducting springs. The sensing member is removably inserted into the socket. The conducting springs are electrically connected to the electrical contacts and the sensing member for enabling electric connection therebetween. Each of the conducting springs is frictionally moved by the sensing member during insertion of the sensing member into the socket and removal of the sensing member from the socket.

A physiological signal monitoring device includes a sensing member and a transmitter connected to the sensing member and including a circuit board that has electrical contacts, and a connecting port, which includes a socket communicated to the circuit board and a plurality of conducting springs. The sensing member is removably inserted into the socket. The conducting springs are electrically connected to the electrical contacts and the sensing member for enabling electric connection therebetween. Each of the conducting springs is frictionally moved by the sensing member during insertion of the sensing member into the socket and removal of the sensing member from the socket.

A connector for providing both a fluidic and electrical connection is disclosed, said connector having a proximal end, a distal end and an elongated body in between, characterized in that the elongated body has an inner cavity spanning throughout its length, and the distal end comprises: a) an inner body portion comprising a first inner electrical contact and b) an outer body portion comprising a second outer electrical contact having a spring element. The connector is easily adaptable to many kind of fluidic actuators and particularly to pipette instruments usually found in laboratory practice and developed to adapt fluidic actuators and pipette instalments to work according to the Coulter principle in every working condition, in particular to adapt the electrical and fluidic connection between a sensing tip and an instrumented pipette.

A connector includes a first connecting assembly and a second connecting assembly, wherein the first connecting assembly and the second connecting assembly are fitted with each other. The first connecting assembly includes a first inner core and at least two first electric wires, and each of the first electric wires is electrically connected in a first end portion of the first inner core. The second connection assembly includes a second inner core and at least two second electric wires, and each of the second electric wires is electrically connected in a first end portion of the second inner core. A second end portion of the second inner core is provided with a connecting portion, and the connecting portion is inserted in a second end portion of the first inner core, so that the first electric wire is in an electrical communication with the second electric wire.

A connector includes a first connecting assembly and a second connecting assembly, wherein the first connecting assembly and the second connecting assembly are fitted with each other. The first connecting assembly includes a first inner core and at least two first electric wires, and each of the first electric wires is electrically connected in a first end portion of the first inner core. The second connection assembly includes a second inner core and at least two second electric wires, and each of the second electric wires is electrically connected in a first end portion of the second inner core. A second end portion of the second inner core is provided with a connecting portion, and the connecting portion is inserted in a second end portion of the first inner core, so that the first electric wire is in an electrical communication with the second electric wire.

The present invention provides a high-power board-to-board floating connector that comprises a male header and a female socket. The male head comprises a first electrode, a first housing and a first insertion element. The female socket comprises a second electrode, a second housing, a floating member, and a second insertion element. The second housing combines with the floating member to form a connection part which can be slightly moved in one or more directions, so that the male head can be connected to the female socket in a permissible range, and then the first electrode is electrically connected to the second electrode.

A connector includes a first connecting assembly and a second connecting assembly, wherein the first connecting assembly and the second connecting assembly are fitted with each other. The first connecting assembly includes a first inner core and at least two first electric wires, and each of the first electric wires is electrically connected in a first end portion of the first inner core. The second connection assembly includes a second inner core and at least two second electric wires, and each of the second electric wires is electrically connected in a first end portion of the second inner core. A second end portion of the second inner core is provided with a connecting portion, and the connecting portion is inserted in a second end portion of the first inner core, so that the first electric wire is in an electrical communication with the second electric wire.

A connector includes a first connecting assembly and a second connecting assembly, wherein the first connecting assembly and the second connecting assembly are fitted with each other. The first connecting assembly includes a first inner core and at least two first electric wires, and each of the first electric wires is electrically connected in a first end portion of the first inner core. The second connection assembly includes a second inner core and at least two second electric wires, and each of the second electric wires is electrically connected in a first end portion of the second inner core. A second end portion of the second inner core is provided with a connecting portion, and the connecting portion is inserted in a second end portion of the first inner core, so that the first electric wire is in an electrical communication with the second electric wire.

A modified socket mechanism comprises a printed circuit board and a connector component located on a first face of the printed circuit board. The modified socket mechanism may comprise a first region of electrical contacts located on the first face. The first region of electrical contacts may be designed to interface with a processor module. The modified socket mechanism may also comprise a second region of electrical contacts located on a second face of the printed circuit board. The second region of electrical contacts may be designed to interface with a motherboard. The modified socket mechanism may also comprise a first electrical connection between the connector component and the first region of electrical contacts through the printed circuit board. Finally, the modified socket mechanism may also comprise a second electrical connection between the first region of electrical contacts and the second region of electrical contacts through the printed circuit board.