An electrical connector includes: an insulative housing having a base portion; a number of conductive terminals affixed to the insulative housing and arranged in two rows, each conductive terminal comprising a contacting portion, and each row of conductive terminals comprising a pair of grounding terminals and a number of internal terminals located between the pair of grounding terminals; a metal shielding plate affixed to the insulative housing and sandwiched between the two rows of conductive terminals; and a main shell enclosing the insulative housing; wherein a distance between the contacting portions of the internal terminals and the metal shielding plate is greater than a distance between the contacting portions of the grounding terminals and the metal shielding plate.

An anti-loose data cable contains: an interface element, a first protective fixing layer, a second protective fixing layer, a third protective fixing layer, a positioning head, and a USB cable. The interface element is welded with the USB cable, on a connection area of the interface element and the USB cable is fixed the first protective fixing layer, and the interface element and the first protective fixing layer are accommodated in the second protective fixing layer, wherein a main part of the second protective fixing layer is accommodated in the third protective fixing layer, and the third protective fixing layer and the positioning head are integrally formed together.

In the case of a connector comprising two plug parts that can be plugged into one another with front housing parts adapted to one another (100, 200) as well as electrical contact elements (120, 220) adapted to one another, where-in the two front housing parts (100, 200) in the plugged together state overlap on regions facing one another (225), provision is made in particular that the two front housing parts (100, 200) outwardly seal the plug connection resulting from plugging the two plug parts together by means of a sealing lip (125) arranged on the one front housing part (100) as well as by means of an annular groove (230) arranged on the respective other front housing part (200), which is surrounded inwardly by annular rotary sealing surfaces (235, 235′) and surrounded outwardly by an annular rotary collar (225).

The connector includes: at least one contact; a housing to which the contact is arranged; a shell formed into a cylindrical shape inside of which the housing is disposed; and a joining member formed of a resin material; wherein the housing and the contact form an integral unit by means of the joining member, and the joining member is closely fitted within an inner surface of the shell or the joining member is integrally coupled to the inner surface of the shell. Thus, the number of components of the connector can be reduced but the manufacturing flexibility thereof can be increased and the connector can be easily miniaturized and manufactured.

The connector includes: at least one contact; a housing to which the contact is arranged; a shell formed into a cylindrical shape inside of which the housing is disposed; and a joining member formed of a resin material; wherein the housing and the contact form an integral unit by means of the joining member, and the joining member is closely fitted within an inner surface of the shell or the joining member is integrally coupled to the inner surface of the shell. Thus, the number of components of the connector can be reduced but the manufacturing flexibility thereof can be increased and the connector can be easily miniaturized and manufactured.

An electrical connector includes: a metallic cover; an insulative frame molded inside the metallic cover; a metal injection molded (MIM) support and a contact module received by the MIM support, the contact module having a rear base, a front tongue, and an upper and a lower rows of contacts extending through the base and exposing to two opposite faces of the tongue, the MIM support having a pair of side arms flanking the two rows of contacts; and an insulator molded outside the MIM support and the contact module and secured to the insulative frame.

A method for producing a multi-core cable includes arranging first and second contact elements in a contact carrier having first and second longitudinal channels connecting a contacting side to a cable side, and first and second through-openings respectively crossing the first and second longitudinal channels, and a second through-opening crossing the second longitudinal channel. The first and second longitudinal channels and the first and second through-openings are sealed in a fluid-tight manner by inserting two first sealing pieces into the first through-opening and two second sealing pieces into the second through-opening. In an injection-molding method, a connecting piece is formed connecting the contact carrier to the outer sheath of the cable by overmolding at least a rear section of the contact carrier comprising the first and second through-openings and a section of the cable protruding on the cable side.

A charging connector is provided. The charging connector includes a body having a first body end and a second body end. The charging connector also includes a cable connected to the first body end. The cable houses at least one conductor. The charging connector also includes at least one contact positioned at the second body end and electrically coupled to the at least one conductor. The charging connector also includes a mating interface connected to the second body end. The mating interface has a shroud and at least one contact dome that encloses the at least one contact. The at least one contact dome is at least partially formed of a first material having a first flammability resistance, and the shroud is at least partially formed of a second material having a second flammability resistance. The first flammability resistance is higher than the second flammability resistance.

A midboard cable connector assembly with a board connector and a cable connector. The board connector has terminals precisely positioned with respect to engagement features. A cable connector likewise has terminals precisely positioned with respect to complementary engagement features. When the connectors are pressed together for mating, the terminals of one or both connectors deform, generating a force that separates the connectors until the engagement features engage and block further backward motion. As the mating position is defined by the locations of the engagement features, the connectors can be designed with low over travel and a resulting short stub length, which promotes high frequency performance. High frequency performance is further promoted by a ground conductor interconnecting the beams forming mating contact portions of ground terminals, reducing the length of unconnected segments and by a cable clamp plate with complaint compression features that reduce distortion of the cables.

A plug connector for flexible conductor films having film-insulated conductors, includes a plug connector housing in which at least one plug contact element is arranged, and a connection region in which blades electrically conductively connected to the at least one plug contact element penetrate and fix at least one film-insulated conductor and produce an electrical contact. The plug connector housing includes two housing parts which can be pushed into one another, of which the first housing part supports the blades and the at least one plug contact element electrically conductively connected thereto, and the second housing part receives and supports the flexible conductor film and has the at least one blade receptacle which is adapted to the blades and whose boundary surfaces are designed such that the at least a part of the blades is bent towards the film-insulated conductor when the two housing parts are pushed into one another.