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.

An electrical connector assembly including an electrical connector and a circuit board is provided. The electrical connector has a metallic plate and a plurality of terminals. The metallic plate separates the terminals into two different areas. The metallic plate has a first lateral surface. The circuit board is assembled to the electrical connector. The circuit board has a plurality of pads, a second lateral surface, and top and bottom surfaces opposite to each other. The pads are disposed on the top and bottom surfaces respectively. The second lateral surface is boarded between the top and bottom surfaces. The circuit board further includes at least one grounding circuit exposed from the second lateral surface and facing toward the first lateral surface. The metallic plate is electrically conducted to the grounding circuit by the first lateral surface when the circuit board is assembled to the electrical connector.

The present disclosure provides an electrical plug including a first temperature detection element and a second temperature detection element. When the processor determines that the temperature of the contact pins is greater than or equal to a temperature threshold according to a first detection signal outputted by the first temperature detection element and a second detection signal outputted by the second temperature detection element, the processor disables the electrical plug to transmit the input power to a load. When one of the temperature detection elements fails, the electrical plug determines whether the temperature of the electrical plug is greater than or equal to the temperature threshold according to the other one of the temperature detection elements. The electrical plug meets the redundant design required for functional safety to avoid unexpected hazards caused by the failure of a single temperature detection element. Therefore, the stability of the electrical plug is enhanced.

An electrical power supply cord includes a wire cable comprising a plurality of separate conductors, a plurality of plug terminals connected to the plurality of separate conductors, a molded inner plug encasing a connection between the plurality of plug terminals and the plurality of separate conductors, and an in-mold bonding adhesive disposed intermediate the connection between the plurality of plug terminals and the plurality of separate conductors and the molded inner plug.

Connector paddle cards are provided with an improved wiring connection geometry that reduces impedance mismatch. One illustrative embodiment is a printed circuit board having, on at least one surface: edge connector traces arranged along a first edge for contacting electrical conductors in a socket connector; an outer set of electrodes arranged parallel to a second edge for attaching exposed ends of sheathed wires in a cable (“outer wires”); and an inner set of electrodes arranged parallel to the second edge for attaching exposed ends of sheathed wires in a cable (“inner wires”), with the electrodes in the inner set being staggered relative to the electrodes in the outer set.

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 receptacle connector with a cable-clamped structure of the invention includes a housing, an electrical module and a cable clamping module. The electrical module is disposed in the housing and includes a circuit board, a plurality of contacting terminals and a plurality of prick type terminals. The circuit board is disposed in the housing. The contacting terminals and the prick type terminals are disposed on the printed circuit board. The cable clamping module includes a first clamping member, a second clamping member and a cable clamper, wherein the first clamping member engages the second clamping member, and the cable clamper is pivoted to the first clamping member. A cable extends through the first clamping member and the second clamping member engaging the first clamping member, the cable clamper presses the cable with the first positioning portion positioned in the second positioning portion of the first clamping portion.

A power supply includes a cover body, a metal plate, a metal clip, a circuit board and a housing. The metal plate is partially disposed in a first space of the cover body. The metal clip is disposed in the first space and electrically connected to the metal plate, and includes an upper spring piece, a lower spring piece and a connecting piece. The connecting piece has a fixing portion corresponding to a gap between the upper and lower spring pieces. The circuit board includes an input portion and an output portion. The input portion is disposed in the gap, and has a protruding part for engaging with the fixing portion. The housing includes an output interface and an opening communicating with an accommodating space of the housing. The cover body is connected to the opening. The output interface is electrically connected to the output portion.

The present disclosure describes a signal transmission device based on molded interconnect device and laser direct structuring (MID/LDS) technology, comprising: a shielding shell (1); and a photoelectric conversion module (2), which includes a carrier (21), an electrical module (22) and an optical module (23). The photoelectric conversion module (2) is fixed inside the shielding shell (1), wherein the first recessed structure (201) accommodates a driving chip (211), a photoelectric conversion chip (212) and an optical module (23), and the second recessed structure (202) accommodates an electrical module (22), the driving chip (211), the photoelectric conversion chip (212) and the conductive terminal (215) are electrically connected to each other, and the carrier (21) is designed by integral molding based on the MID/LDS technology. In t present disclosure, the design space in the shielding shell can be effectively saved.

To reduce crosstalk between bond wires, one illustrative integrated circuit includes an array of photoemitters arranged along a centerline, with adjacent photoemitters having contact pads on opposite sides of the centerline. An illustrative assembly includes an integrated circuit chip having an array of photoemitter contact pads; a printed circuit board having a recess in which the integrated circuit chip is mounted; and bond wires connecting the contact pads with respective contact pads on the printed circuit board. An illustrative cable connector includes a module that optically couples optical fibers to an array of photoemitters on an integrated circuit chip mounted to a printed circuit board. Each photoemitter has contact pads connected to the printed circuit board contact pads by bond wires, the bond wires for each photoemitter being routed in an opposite direction relative to the bond wires for any adjacent photoemitters in the array.