Provided is a cable connector which includes: a housing; and a cable holder capable of holding one end side of the cable. The cable holder includes at least three first to third engagement portions on each of opposing outer side surfaces, in a direction along a lead-out direction where the cable held on the one end side by the cable holder is led out from the cable holder, the first engagement portion is placed on a side far from the cable lead-out side of the cable holder, the second engagement portion is placed on a side near the lead-out side, and the third engagement portion is placed between the first engagement portion and the second engagement portion, the housing includes at least three first to third corresponding engagement portions capable of engaging respectively with the first to third engagement portions, on each of opposing inner side surfaces, it is configured in such a manner that, upon the first to third engagement portions engaging with the first to third corresponding engagement portions, respectively, the cable holder is capable of being placed at least at a first engagement position and a second engagement position with respect to the housing, at the first engagement position, the first and second engagement portions are in engagement with the first and second corresponding engagement portions, respectively, while the third engagement portion has not yet engaged with the third corresponding engagement portion, and at the second engagement position, all the first to third engagement portions are in engagement with the first to third corresponding engagement portions, respectively.

A resin molded product includes a plate portion having a plate-like shape and having assembly locations in which a mating member is assembled on both surfaces of the plate portion in a plate thickness direction, a reference portion provided on one surface of the plate portion and used for alignment with the mating member, and a through hole which penetrates the reference portion in the plate thickness direction and opens on the both surfaces of the plate portion. The reference portion has a columnar shape extending in the plate thickness direction, and the through hole opens at an extending end of the reference portion and extends in the plate thickness direction to open on the other surface of the plate portion. The plate portion further includes a terminal provided so as to extend in the plate thickness direction at the assembly location on the other surface.

The present invention relates to an FPC connector housing, more particular to a DDRS connector housing. The invention also relates to a method for producing the connector housing as well as to a cavity mold suitable for the production of the connector housing. The cavity mold comprises a double gating system with centrally positioned injection gates. The connector housing can be used in a connector for mounting on a flexible printed circuit (FPC) assembled in various kinds of electrical and/or electronic devices.

An electric connector assembly includes an insulating housing, a plurality of rows of contact terminals disposed in the insulating housing and including a plurality of signal terminals and a plurality of ground terminals, and a conductive shell assembled on the insulating housing. The conductive shell contacts and is connected with the ground terminals to electrically connect the ground terminals together.

The present disclosure generally relates to a novel concept of forming an adapter for an automotive application to be used for connecting a breakout box in-between an electrical control unit (ECU) of a vehicle and an electrical wiring system comprised with the vehicle. The adapter is formed using a 3D printer based on a construction of an electrical connector design provided with the ECU. The present disclosure also relates to a corresponding system and a computer program product.

The present disclosure generally relates to a novel concept of forming an adapter for an automotive application to be used for connecting a breakout box in-between an electrical control unit (ECU) of a vehicle and an electrical wiring system comprised with the vehicle. The adapter is formed using a 3D printer based on a construction of an electrical connector design provided with the ECU. The present disclosure also relates to a corresponding system and a computer program product.

A Type C female side connector includes a terminal part, a body part, a steel plate, and a casing part; the terminal part is inserted in the body part; the body part is inserted in the casing part; the steel plate is inserted in the body part; the casing part has a suction portion formed in a flat plate structure on another side corresponding to an opening; the suction portion is integrated with the casing part; two sides of the suction portion expand to be sucked by a suck disc during manufacturing process. The present invention applies the suck disc portion to fulfill a sufficient area for automatic suction effect during manufacturing process, and includes a triple fix effect to strengthen the stability of the body part and the casing part.

A Type C female side connector includes a terminal part, a body part, a steel plate, and a casing part; the terminal part is inserted in the body part; the body part is inserted in the casing part; the steel plate is inserted in the body part; the casing part has a suction portion formed in a flat plate structure on another side corresponding to an opening; the suction portion is integrated with the casing part; two sides of the suction portion expand to be sucked by a suck disc during manufacturing process. The present invention applies the suck disc portion to fulfill a sufficient area for automatic suction effect during manufacturing process, and includes a triple fix effect to strengthen the stability of the body part and the casing part.

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.

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.