A wire harness including: a tube that is made of metal; a plurality of electrical wires that are inserted into the tube; and a plurality of shields that are formed by braided wires in which conductive strands are woven into a tubular shape, and include tubular portions that respectively cover portions of the electrical wires located outside the tube, wherein portions at one end of the plurality of shields are put together and are fixed to the tube.

A cable termination that enables the attachment of SMA connectors to controlled-impedance cables with a conductive foil wrap shield; for the separate ferrule embodiment, the sheath is stripped back on the cable, exposing the foil shield surrounding the dielectric; a ferrule is slid or clamped over the foil shield and bonded; the face of the ferrule is dressed so that the foil shield and dielectric are flush with the ferrule face and the signal conductor protrudes from the face this cable subassembly is installed in the boss of a housing that prevents movement of the ferrules relative to each other and so that each ferrule face is aligned with an opening in the boss through which an SMA connector barrel is attached to the ferrule a cover secures the cable subassembly in the housing.

An electrical connector includes an insulating body and a terminal module. The terminal module includes a first terminal module, a second terminal module, and a shielding piece. The first terminal module includes a number of first conductive terminals. Each first conductive terminal includes a first elastic contact arm and a first tail portion. The second terminal module includes a number of second conductive terminals. Each second conductive terminal includes a second elastic contact arm and a second tail portion. The shielding piece includes a connecting portion and a number of ground terminals. The ground terminals include a number of first ground elastic arms arranged in a same row as the first elastic contact arms and a number of second ground elastic arms arranged in a same row as the second elastic contact arms. As a result, the shielding performance of the electrical connector is improved.

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 includes an insulating body and a terminal module. The terminal module includes a first terminal module, a second terminal module, and a shielding piece. The first terminal module includes a number of first conductive terminals. Each first conductive terminal includes a first elastic contact arm and a first tail portion. The second terminal module includes a number of second conductive terminals. Each second conductive terminal includes a second elastic contact arm and a second tail portion. The shielding piece includes a connecting portion and a number of ground terminals. The ground terminals include a number of first ground elastic arms arranged in a same row as the first elastic contact arms and a number of second ground elastic arms arranged in a same row as the second elastic contact arms. As a result, the shielding performance of the electrical connector is improved.

The present disclosure provides a connector enabling a size reduction by simplifying a configuration. A connector 11 includes a housing 21 in which a plurality of shielded cables 14 are held while being partially inserted, and cores of the plurality of shielded cables 14 are connected to a plurality of terminals 13a of a mating connector 13 by connecting the housing 21 to the mating connector 13. The connector 11 includes an electromagnetic shielding shell 22 for covering the outer surface of the housing 21 and a shield terminal 27 to be provided between the plurality of shielded cables 14 in the housing 21, connected to shield members of the plurality of shielded cables 14 and connected to a ground terminal 13b of the mating connector 13 by connecting the housing 21 to the mating connector 13.

A cable connector includes a base and a mating portion extending downwardly from a lower side of the base, and an upper and a lower platform around an upper side of the base. First and second rows of contacts include connecting sections. The connecting sections of the first row are exposed upon the lower platform and the connecting sections of the second row are exposed upon the upper platform. Upper and lower rows of wires are located above the housing. Two grounding brackets are mounted upon the upper and lower platforms. Each bracket includes bulged sections and tails. Inner conductors of the wires are connected to the connecting sections of the differential-pair contacts, the braiding layers of the wires are sandwiched between the bulged sections and the housing in the vertical direction, and the tails are connected to the connecting sections of the grounding contacts.

A cable connector includes a number of cables and an electrical connector. Each cable includes a core wire, an insulating layer wrapped on the core wire and a shielding layer wrapped on the insulating layer. The electrical connector includes an insulating body, a number of conductive terminals and a shielding shell. Each conductive terminal includes a contact portion for mating with a mating connector and a tail portion connected with the core wire. The cable connector further includes a ground shield mounted to the cables. The ground shield is connected with the shielding layers of the cables, and the ground shield is connected with the shielding shell. Compared with the prior art, the present disclosure improves the shielding performance of the cable connector by providing connecting the ground shield, the shielding layers and the shielding shell together.

A connector system, method and apparatus for an EMI enclosure such as a Gauss/Faraday cage or chamber. The connector system, method and/or apparatus includes one or more individual conductors located within the EMI enclosure to eliminate EMI/E&H field effects with respect to applications such as a small form factor cable applications, high density cable applications, and a high speed (e.g., greater than 1 Gbps) multiconductor copper-based cable applications. This approach therefore isolates individual or multiple cable signals (e.g., single conductors) within individual Gaussian/Faraday cages to eliminate EMI/E&H field effects for small form factor, high density, high speed (e.g., >1 Gbps) multiconductor copper based cable applications.

An electrical connector includes a substrate and multiple terminals. The substrate is provided with multiple accommodating holes running through the substrate vertically. A shielding member is provided on a lower surface of the substrate. The terminals are correspondingly accommodated in the accommodating holes respectively. The terminals include multiple signal terminals and at least one ground terminal. An interval exists between the ground terminal and the shielding member. The ground terminal has a conducting portion extending downward out of a corresponding accommodating hole. The conducting portion is soldered to a main circuit board through a solder, and the solder is in contact with the conducting portion and the shielding member. According to the present invention, the conducting portion of the ground terminal is connected with the shielding member through the solder, thereby reducing a spurious charge, reducing the capacitance, and improving a high frequency.