A connector includes an insulator, a plurality of pairs of terminals provided on the insulator, and a resistance element. The plurality of pairs of terminals include at least one pair of cable terminals electrically connected with a cable and at least one pair of vacant terminals that are unused. The resistance element is electrically connected between each pair of vacant terminals.

A magnetic connector includes a first insulating housing, a printed circuit board, a plurality of magnetic bodies, a plurality of terminals and a second insulating housing. The first insulating housing has a bottom wall, a side wall, a recess being defined between the bottom wall and the side wall. The printed circuit board is received in the recess. The magnetic bodies are mounted to the printed circuit board. The terminals are mounted to the printed circuit board. The second insulating housing is mounted to the top of the first insulating housing and is covered the recess. The magnetic bodies and the terminals are exposed from a top surface of the second insulating housing. As described above, the magnetic bodies are mounted to the printed circuit board, and then the magnetic bodies are magnetized. Hence, manufacture cost of the magnetic connector is saved.

Disclosed are an input/output terminal for connecting an electronic device to an external device and an electronic device comprising the input/output terminal, the input/output terminal comprising: a signal pin allowing signals to be transmitted/received between the electronic device and the external device; a ground pin connected to a ground part of the electronic device; and a resistant material disposed at the end part of the signal pin or the ground pin. Other various embodiments are possible.

A waterproof socket connector includes an inner insulator, a plurality of terminals fastened in the inner insulator, at least one resistor, a conductive element, a grounding element, a shell, a sealing element and an outer insulator. The plurality of the terminals are a plurality of charging terminals and detection terminals. The at least one resistor is mounted to the detection terminals. The charging terminals are connected to the conductive element. The detection terminals are connected to the grounding element. The charging terminals are connected to the grounding element. The shell surrounds the inner insulator. A rear end of the shell is hollow to form an inner space. The sealing element is filled in the inner space. The outer insulator surrounds the inner insulator, the plurality of the terminals, the shell, the sealing element, the at least one resistor, the conductive element and grounding element.

A cable includes an electrical connector at one end and a sensor at the other end. The connector includes a terminal module having a plurality of contacts embedded within an insulator wherein each contact has a resilient contacting section exposed upon to an exterior in a first vertical direction, and a soldering section exposed in a second vertical direction to be connected to the corresponding wires of the cable and selectively further to a resistor. The sensor includes a case enclosing an LED (Light Emitting Diode) and a PD (Photo Diode both of which are respectively connected to the corresponding contacts respectively soldered to the corresponding wires.

A stator according to an aspect of the present disclosure includes a connector molding portion including a base portion and a mounting portion and a receiver side terminal. The connector molding portion is provided with a communication hole which includes a first concave portion including an inner opening inside a housing extending through the base portion in an X direction and a second concave portion including a bottom surface opening on a bottom surface of the mounting portion extending through the base portion in a Y direction and communicates the inside and outside of the housing through the first concave portion and the second concave portion. The first concave portion penetrates the base portion in the X direction through an outer opening. A rear surface covering portion is provided to close the outer opening.

The present invention discloses a charging socket lead frame assembly and a charging socket. The charging socket lead frame assembly has a lead frame which has a frame body and an electrical connection structure arranged in the frame body. The lead frame is adapted to be installed in a cavity of a charging socket, and a plurality of terminals of the charging socket are adapted to pass through the frame body. One end of the electrical connection structure is exposed from the frame body to electrically connect with a lead of a temperature sensor. The lead frame is arranged in non-electrical contact with at least one signal terminal of the charging socket. Therefore, the structure of the lead frame can be simplified and the manufacturing difficulty and cost can be reduced.

A charging inlet assembly includes a housing having a DC section with DC terminals received in DC terminal channels for mating with a DC charging connector and AC terminals, including a proximity terminal, received in AC terminal channels for mating with an AC charging connector. The charging inlet assembly includes an HMI assembly coupled to the rear of the housing having a control circuit board, a charging indicator coupled to the control circuit board visible from the front of the housing to indicate a charging status of the charging inlet assembly, and a proximity resistor assembly coupled to the housing. The proximity resistor assembly includes a resistor coupled to the control circuit board and a cable connector connected between the control circuit board and the proximity terminal.

A charging inlet assembly includes a housing having a DC section having DC terminals received in DC terminal channels for mating with the DC charging connector and AC terminals received in AC terminal channels for mating with the AC charging connector. The DC terminals include a proximity terminal and a ground terminal. The proximity and ground terminals include terminating ends received in a rear cavity of the housing. The charging inlet assembly includes a proximity resistor assembly received in the rear cavity having a resistor, a first resistor conductor coupled between the resistor and the terminating end of the proximity terminal, and a second resistor conductor coupled between the resistor and the terminating end of the ground terminal.

A contact module includes a frame assembly having a leadframe and a dielectric frame partially encasing the leadframe. The leadframe includes ground conductors each having a transition portion extending between a mating end configured to be mated to a mating connector and a terminating end configured to be terminated to one of a circuit board or a cable conductor. The dielectric frame includes dielectric material encasing at least a portion of each transition portion. Each mating end extends from the dielectric frame for connection with the mating connector. Each terminating end extends from the dielectric frame for connection with the circuit board or the cable conductor. The contact module includes resistive elements within the dielectric frame. Each resistive element is coupled in series with the transition portion of the corresponding ground conductor.