A connector assembly with overvoltage protection includes: a housing having a cavity therein; a printed circuit board residing in the cavity of the housing; an overvoltage unit mounted on the printed circuit board and configured to create an open electrical circuit when experiencing a voltage higher than a predetermined threshold; a plurality of first electrical contacts adjacent a first edge of the printed circuit board and electrically connected to the overvoltage unit, each of the plurality of first electrical contacts configured to receive a respective one of a plurality of electrical conductors of a hybrid jumper cable; a plurality of second electrical contacts adjacent a second edge of the printed circuit board and electrically connected to the overvoltage unit, each of the plurality of second electrical contacts configured to receive a respective one of a plurality of electrical conductors of a piece of communications equipment; and a plurality of optical connectors mounted within the cavity configured to receive optical fibers of the hybrid jumper cable and the piece of communications equipment.

An electronic component unit to be applied to an electric connection box for a wire harness includes: a substrate that has an electronic component mounted thereon and includes a terminal electrically connected to the electronic component; a casing including: a housing space portion for housing the substrate therein; and a plurality of slide assembling units that are provided in the housing space portion and each of which allows the substrate to be inserted and assembled therethrough; and a connection unit that is provided in an opening in the casing, into which the terminal of the substrate is inserted, and the connection unit is configured to electrically connect the terminal to a conductive wiring member. At least one substrate is assembled to any one of the slide assembling units and is retained between the casing and the connection unit.

Embodiments discussed herein refer to electric vehicle charging ports having integrated contactless communication units (CCUs). The electric vehicle charging ports include male and female connector assemblies that can be coupled together in a manner that enables consistent and reliable operation of contactless communications and power transfer. The connector integrates power and alignment such that when two connector assemblies are coupled together, power connections are made in combination with establishing contactless communications links between counterpart CCUs in both connector assemblies. The fixed alignment of the connector assemblies ensures that contactless communication channels, spanning between the connector assemblies, are aligned to enable consistent and reliable operation of contactless communications. The CCUs, which conduct contactless communications, may be integrated in the connector assemblies at fixed positions that enable CCUs of one connector assembly to be aligned with CCUs of another connector assembly when they are coupled together.

Embodiments discussed herein refer to connectors that enable two structures or devices to be coupled together in a manner that enables consistent and reliable operation of contactless communications and power transfer. The connector integrates power and alignment such that when two connectors are coupled together the power connections are also responsible for connector alignment. The connector alignment ensures that contactless communication channels, spanning between the connectors, are aligned to enable consistent and reliable operation of contactless communications.

The present disclosure provides a high-voltage connecting mechanism, an electrical energy transmission apparatus and a motor vehicle. The high-voltage connecting mechanism includes: a male-end connecting mechanism and a female-end connecting mechanism, in which the male-end connecting mechanism comprises a first cable, a plug-in terminal, a male-end housing integrally formed with the first cable and the plug-in terminal, and a male-end shielding shell disposed outside the male-end housing; the female-end connecting mechanism includes a mating terminal, a second cable, a mating terminal, a female-end housing integrally formed with the second cable and the mating terminal. By means of plugging cooperation of the male-end shielding shell and the female-end shielding shell, and an electrical connection with a cable shielding layer, an electromagnetic interference in the high-voltage connecting mechanism can be effectively shielded, and an electromagnetic interference with other devices can be reduced.

The handheld electronic user device default charging and data port micro USB Female connector is divided by an interface which is composed of a microchip and two micro USB Female connectors configured to separate the power transmission channel and data transmission channel to create two separate connections and then handheld electronic user device default charging and data port micro USB Female connector is replicated with the above said two micro USB Female connectors which is secured to handheld electronic user device protective case back wall outer surface away from the edges or mounted on a Popup Door which is sunk into the handheld electronic user device body through the back cover.

The connector includes a circuit board having a number of electronic components, a transmission assembly joined to the circuit board to a side of the electronic components, a first shielding member on the circuit board shielding the transmission assembly, a second shielding member on the circuit board shielding the electronic components, and a cover on and shielding the first and second shielding members. The connector can be produced to meet different needs by using a common first shielding member joined to a second shielding member adapted to a specific requirement such as dimension, shape, etc., thereby reducing the production and stock costs. The transmission assembly and the electronic components are shielded by the first and second shielding members, respectively, which are further shielded by the cover so as to prevent RF signal leakage and to achieve superior transmission quality.

A video transmission connector component comprises a video transmission connector and a circuit substrate. The circuit substrate at least includes a regulation module; wherein the circuit substrate is coupled with a pin group of the video transmission connector through a first pad set arranged on the circuit substrate; wherein the regulation module includes a control unit and a redriver. The redriver is configured to couple to at least one signal transmission pin of the pin group of the video transmission connector. Wherein the control unit is coupled to the redriver and the redriver receives at least one relay parameter which is used to adjust signals transmitting to the at least one signal transmission pin.

The invention describes an adapter part (2, 9) for a modular lighting assembly (1) comprising a number of light-emitting diodes (4) mounted on a separate base part (3), which adapter part (2, 9) comprises a number of first electrical connectors (21) arranged to connect the light-emitting diodes (4) to an external power supply; at least one electrical component (5) arranged in a body of the adapter part (2, 9); and a number of second electrical connectors (22) arranged to connect external circuitry to an electrical component (5) arranged in the body of the adapter part (2, 9). The invention further describes a modular lighting assembly (1) comprising a base part (3) upon which a number of light-emitting diodes (4) is mounted; and an adapter part (2, 9) according to the invention. The invention also describes a method of assembling such a modular lighting arrangement (1), comprising the steps of connecting a first adapter part (2, 9) according to the invention to a separate base part (3); choosing a number of electrical components (5, 6) on the basis of an application requirement of the modular lighting arrangement (1); and arranging an electrical component (5, 6) in the adapter part (2, 9) such that an electrical connection is formed between a contact surface of the electrical component (5, 6) and a second electrical connector (22) of the adapter part (2, 9).

A connector for being attached to a power-supply unit including a switching element and for mating with a mating connector of a wire harness, the connector including a connecting terminal including an end portion connected to an output terminal in a casing of the power-supply unit, a housing fixed to the casing and enclosing at least a portion of the connecting terminal, a current sensor enclosed in the housing so as to detect a magnetic field generated by an electric current flowing through the connecting terminal, and a signal line for transmitting an output signal of the current sensor.