A load contact module for a charging plug-in connection includes: a load contact, which is designed to electromechanically contact a load contact to be inserted and/or slid on; a mounting portion, which is designed to connect the load contact module to a support of a charging plug and/or of a charging socket; and a temperature sensor for the temperature monitoring of a charging process, wherein the temperature sensor has a distance from the mounting portion.

A detection device for detecting an insertion depth of a terminal of a cable connector inside a housing of the cable connector includes a positioning assembly and a detection assembly. The positioning assembly positions the housing of the cable connector. The detection assembly includes a first driving device, a sensing element mounted on the first driving device and movable by the first driving device, and a displacement sensor mounted on the first driving device and movable in a moving direction of the sensing element by the first driving device. The displacement sensor is connected to the sensing element and senses a displacement of the sensing element.

Each of a feeding unit and a connector unit is provided with power supply ports and ground ports. In at least one of a connection of the power supply ports of the feeding unit and the power supply ports of the connector unit and a connection of the ground ports of the feeding unit and the ground ports of the connector unit, the number of parallel lines in at least a partial section is changed according to a length of the connection. In this way, a voltage drop between the feeding unit and the connector unit is adjusted.

Provided are an adapter, a terminal device and an adapter system. The adapter includes: a universal serial bus type-C (USB-C) plug cooperatively connected to a USB-C interface of the terminal device, a USB socket cooperatively connected to a charging plug, and a headset socket cooperatively connected to a headset plug, where a first communication pin of the USB-C plug is connected to a first communication pin of the USB socket, a second communication pin of the USB-C plug is connected to a second communication pin of the USB socket, a first sound channel pin and a second sound channel pin of the USB-C plug are connected to a right sound channel signal pin and a left sound channel signal pin of the headset socket in one-to-one correspondence.

A semiconductor package includes a package substrate, a semiconductor chip on the package substrate, the semiconductor chip including a logic chip and a memory stack structure on the logic chip, a connector and a connector terminal below the package substrate, a molding layer that covers the semiconductor chip, the molding layer having a recess region on a top surface of the molding layer, a housing that covers the molding layer, and an air gap on the semiconductor chip, the air gap being defined by the housing and the recess region of the molding layer, and the molding layer separating the air gap from the memory stack structure of the semiconductor chip.

A connector has a case, a circuit board, a thermal diffusing unit, and a first heat sink. The circuit board is mounted in the case and has a heating source. The thermal diffusing unit abuts the inner surface of the case and the heating source of the circuit board. A heat transfer coefficient of the thermal diffusing unit is larger than a heat transfer coefficient of the case. The first heat sink abuts the thermal diffusing unit and is exposed from the case. A heat transfer coefficient of the first heat sink is larger than the heat transfer coefficient of the case. By the first heat sink abutting the thermal diffusing unit and exposed from the case, and the heat transfer coefficients of both the thermal diffusing unit and the first heat sink being larger than that of the case, the heat dissipation efficiency is improved.

A high-voltage plug connection part for a high-voltage plug connector of a high-voltage electrical system of a motor vehicle, the high-voltage electrical system, and the motor vehicle are disclosed herein. The high-voltage plug connector can be coupled to at least one high-voltage line. The high-voltage plug connection part has at least one integrated temperature sensor which is designed to detect a sensor signal that characterizes the temperature of the at least one high-voltage line and provide the detected sensor signal to an analysis device in order to monitor the temperature of the at least one high-voltage line.

A cable system for a truck trailer with connectors having a main power connection, a ground connection, and one, two, or more communication cable connections. Connectors include at least a power and ground connection for electrically connecting an individual trailer to the cable system. A master control circuit may be included in the trailer nosebox, and the master control circuit configured to send commands to slave control circuits mounted within the connectors. The slave control circuits in the connectors are configured to receive a control command sent by the master control circuit that may include an address, mode identifiers, or other indications of which connectors in the cable system should take action, and what actions should be taken.

A self-aligning mechanical mount and electrical connection system for an electronic module comprises a mechanical mount assembly configured to be integrated into or attached to a base frame and defining a mount connection position assurance (CPA) feature for self-aligning and securing of the electronic module therein, and an electrical connection assembly configured to be integrated into or attached to the mechanical mount assembly and comprising a modular electrical connector (i) being electrically connected to an electrical backbone wire cable and (ii) defining a connector CPA feature for self-aligning the modular electrical connector with a corresponding electrical connector integrated into or attached to the electronic module when the electronic module is secured in the mechanical mount assembly.

The present invention is an RFID-enabled electrical connector with connector position assurance (“CPA”) features. The RFID tag is only readable after the CPA features have been fully deployed. The electrical connector is comprised of at least two parts, a socket and a plug. In the illustrated embodiment, a connector housing is positioned between the socket and plug, with both the socket and plug connecting to the connector housing. Until the CPA feature has been fully deployed, the RFID tag is covered by an electrically conductive material, preferably an electrically conductive plastic. The RFID tag can only be properly read after the CPA feature has been fully deployed. To prevent signal leakage, the RFID tag can alternately be placed inside a five-sided box fabricated from electrically conductive material, preferably electrically conductive plastic.