A charging system for a battery-operated machine is disclosed. The charging system includes a charging receptacle having a power connection and a signal connection, with the charging receptacle configured to receive electrical current via the power connection from a power supply plug. The charging system further includes a heat rejection element thermally coupled to the charging receptacle, a temperature sensor, and a charging controller operatively coupled to the temperature sensor and the charging receptacle. The charging controller is configured to receive a temperature signal from the temperature sensor, the temperature signal being indicative of a charging-receptacle temperature. The charging controller is further configured to transmit, via the signal connection to the connected plug, a control signal to adjust (e.g., raise or lower) the electrical current supplied to the power connection.

In one embodiment, a configurable system may be capable of verification and include a modular control unit configured to control power. The modular control unit may include a first contact element configured to receive the power, a backplate, and at least one device control assembly. Other embodiments may include a system configured for dynamically assignable pairings. Further embodiments may include a backplate configured to control power to at least one load device, the backplate including one or more power control elements. Additional embodiments may include a system including a receptacle. The system with the receptacle may include a modular control unit, a backplate, a contact element, and at least one device control assembly configured to be removably coupled to the backplate.

A connector for a networking cable assembly includes a substrate, a first set of contacts on a first surface of the substrate that electrically connect to leads of a first cable, and a second set of contacts on the first surface of the substrate that electrically connect to leads of a second cable. The first set of contacts are spaced apart from the second set of contacts in a first direction by an amount that enables the second cable to be stacked on the first cable and passed over the first set of contacts to electrically connect to the leads of the second cable.

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.

A board-to-board plug, comprising an insulating seat (20) integral to a metal insert (30), several signal terminals (40) arranged inside the insulating seat (20), and a shielding housing (10) coated outside the insulating seat (20). The insulating seat (20) comprises an engagement end (21) provided with terminal slots (214), terminal blocks (24) formed by extending from the engagement end (21) to the rear direction, and a pair of extension arms (22) formed by extending from both transverse sides of the terminal block (24) to the rear direction. The metal insert (30) comprises a board body portion (31) formed between a pair of extension arms (22), and several grounding terminals (37) bent from the front end of the board body portion (31) and extending into the terminal slots (214). The grounding terminals (37) and the signal terminals (40) are arranged at intervals.

A charging connector includes a housing and a cover. The housing includes a normal fitting part and a quick fitting part. The normal fitting part has a normal frontage to which a normal charging connector is finable. The quick fitting part has a quick frontage to which a quick charging connector is finable. The cover is configured to close the quick frontage. The quick fitting part has a terminal insertion hole through which a terminal of the quick charging connector is insertable inside the quick fitting part. The cover has a first protrusion extending toward the terminal insertion hole and holding the cover on the housing with the first protrusion being inserted into the terminal insertion hole.

The present disclosure relates to the technical field of electronic device accessories, more particularly to a connector, a data wire and an electronic device. The connector includes a first electrical connecting structure including a connecting base and an adapter board disposed thereon, and a second electrical connecting structure including a fixing base and a conductive member that are rotatably connected. The fixing base forms a clamping groove for the adapter board to be inserted into, and the conductive member is fixed in the fixing base and exposed from the clamping groove. The connecting base further includes a splint which includes portions respectively disposed on both sides of the adapter board in the thickness direction thereof, and is disposed on the outer side of the fixing base, so that the outer side thereof is the structure of the fixing base and the splint in sequence.

An electronic apparatus that is capable of reducing occurrence of malfunction when an accessory is attached without enlarging an accessory shoe device. The electronic apparatus includes an accessory shoe device and a controller. The accessory shoe device is electrically connectable with an accessory and has terminals that are arranged in a line in a first direction that intersects perpendicularly with an attaching direction of the accessory. The controller is electrically connected to the terminals. At least one of the terminals differs from the other terminals in a length of an externally exposed part in a second direction that intersects perpendicularly with both the attaching direction and the first direction.

An electrical connector is provided with a segmented design supporting multiple connector configurations with commonality across the configurations that simplifies connector selection and qualification. The connector includes multiple segments, each with an insulative housing portion into which may be inserted power terminals in one or more configurations or signal terminals. A first-type power terminal may carry a first maximum power and a second-type power terminals may carry a second maximum power greater than the first maximum power, but the segments may be configured with mating contacts with similar properties. The connectors may have a mezzanine configuration configurable in a stack height selected from a wide range of stack heights, with fine-grained resolution. Terminals in all stack heights may have similar mating and mounting portions, differing only in the height of a body portion.

A high-speed connector includes an insulating housing, and a first terminal assembly mounted in the insulating housing. The first terminal assembly includes a plurality of first terminals, a first base body and a first conductive film. The plurality of the first terminals include at least two first grounding terminals and at least two first signal terminals. At least one portion of a bottom of the first base body extends downward to form at least one first protruding portion. The at least two first signal terminals penetrate through the at least one first protruding portion. The first conductive film is covered to the at least one first protruding portion. The first conductive film has a first metal layer. The first metal layer is electrically connected with the at least two first grounding terminals to form a grounding structure.