The present application relates to an electrical connector and an electronic product. The electrical connector includes a metal terminal; an insulating body configured to fixing the metal terminal; a metal shield covering an outer side of at least a portion of the insulating body; a metal latch connected to the insulating body, and provided with a ground terminal thereon, and wherein the insulating body, the metal shield, and the metal latch enclose an accommodating space; and a brazing solder disposed at least partially within the accommodating space, and the brazing solder being configured to be melted during welding and to fixedly connect the metal shield and the metal latch after being cooled, such that the metal shield is electrically connect to the metal latch.

A cable connector includes a contact module, wires and grounding bars. The contact module includes a pair of subunits commonly sandwiching a metallic shielding plate. Each subunit includes contacts integrally formed within an insulator, the contacts includes a plurality of differential-pair contacts and grounding contacts alternately arranged with each other. Each contact includes a front contacting section and a rear tail section, the tail sections of the grounding contacts being unified with a transverse bar. Each wire has a pair of inner conductors respectively soldered to the tail sections of the corresponding differential-pair contacts, and an outer braiding layer surrounding the pair of inner conductors and mechanically and electrically connected to the transverse bar. Each grounding bar includes a plurality of rear tabs respectively connected to the braiding layers, and a plurality of front tabs respectively connected to the tail sections of the corresponding grounding contacts.

A contact assembly includes a contact array having contacts including signal contacts and ground contacts. The signal contacts include signal intermediate portions extending between signal mating beams and signal contact tails. The ground contacts include ground intermediate portions extending between ground mating beams and ground contact tails. The contact assembly includes front and rear contact holders. The contact assembly includes a ground bus bridge extending between each of the ground contacts to electrically common each of the ground contacts. The ground bus bridge is integral with the ground contacts and extends across the signal intermediate portions in close proximity to the signal intermediate portions for resonance control of signals transmitted along the signal contacts.

A cable connector includes a housing, a terminal module and a cable connected to the terminal module. The terminal module includes multiple groups of conductive terminals. At least one group of conductive terminals include two signal terminals, a first ground terminal and a second ground terminal. The at least one group of conductive terminals include a connecting portion connecting the first ground terminal and the second ground terminal. The cable includes signal wires electrically connected to the signal terminals and a ground shielding layer wrapped around a periphery of the signal wires. The connecting portion is at least partially wrapped and fixed on the ground shielding layer. With this arrangement, it is easy to connect the ground terminals and the cable ground shielding layer in order to achieve a better shielding effect.

A routing assembly for an electronic device has a plurality of connectors ports and each of the connector ports contains a first connector connected to one or more cables. Cables are directly terminated, at first ends thereof, to terminals of the first connectors and the cables can be embedded in a routing substrate. The routing substrate has an opening which accommodates a chip package. Second ends of the cables are terminated to second connectors arranged in the package opening and the second connectors are in turn connected to the chip package.

A connector-equipped multicore cable includes a connector including a first end portion and a second end portion and a multicore cable including a plurality of coaxial electrical wires and connected to the first end portion. The connector includes, at the second end portion, a cover that is made of a metal and that covers a connector terminal. The plurality of coaxial electrical wires each include a first shield layer. The first shield layer and the cover are electrically connected to each other.

An electrical connector connected with a cable connector connected to cables. The cable connector comprises a plurality of ground terminals, a plurality of signal terminals, and an electromagnetic shielding member. The electrical connector comprises a circuit board, a plurality of ground conductive pads, a plurality of signal conductive pads, and a shielding ground conductive pad. The circuit board comprises two electrical connecting areas that are parallel to each other along first direction. The plurality of ground conductive pads are disposed on a surface of the circuit board at intervals. At least one signal conductive pad is disposed between two adjacent ground conductive pads along second direction that is perpendicular to the first direction. Each of the signal conductive pads being directly connected with the corresponding signal terminal and not directly connected to the cables. The shielding ground conductive pad is disposed on the surface of the circuit board.

An angled subassembly of an angled connector includes an angled shield having a first shield section and a second shield section extending at a bend angle with respect to the first shield section, a cable disposed in the first shield section and the second shield section of the angled shield, and an inner ferrule disposed around the cable within the angled shield. The cable has a wire and a foil disposed around the wire. The inner ferrule electrically connects the foil to the angled shield.

An angled subassembly of an angled connector includes an angled shield and a cable disposed in the angled shield. The angled shield has a first shield section and a second shield section extending at a bend angle with respect to the first shield section. The cable has a first portion positioned in the first shield section and a second portion positioned in the second shield section. The second portion extends at the bend angle with respect to the first portion.

A manufacturing method for assembling a high voltage vertical disk ferrule, the ferrule being stamped and having a vertical disk-like structure, which is not necessarily round or does not necessarily have any roundness. The high voltage disk ferrule has an opening residing and traveling over the wire core and/or a wire braided shield, to which an end portion of the wire braided shield is affixed thereto the ferrule, or between two ferrules, such that a portion of the wire braided shield is flared and substantially perpendicular to the direction along which the wire core extends. The high voltage vertical disk ferrule slides over the core insulation, towards the outer insulation when the wire is pushed. The end portion/flared portion of the braided shield and the high voltage vertical disk ferrule, or the end portion/flared portion of the braided shield between at least two high voltage vertical disk ferrules are soldered, welded, or brazed together. The wire braided shield develops a natural spring force against the ferrule, and causes it to be accordioned, pleated, or folded against itself, and therefore pushes the vertical disk ferrule forward.