A power distributor (200) with at least two incoming lines (101-103) and a method for manufacturing such a power distributor is suggested. Each incoming line comprises a conductor (106,107) and an individual screen (114). The conductors of the incoming lines are connected at a connection point (V1,V2), which is enclosed by a screen shield (201) that contacts each individual screen (114) of the incoming lines. The screen shield (201) is made from electrically conducting plastic material. Screen shields made from electrically conducting plastic material is easier to manufacture and less expensive than metal screen shields.

A cable assembly comprising a termination with at least one conductive, compressible member and a conductive ground shield. The conductive, compressible member may be held within a connector module forming the termination such that the conductive compressive member is pressed against, and therefore makes electrical contact with, both an outer conductive layer of the cable and ground structures within the connector module. In some embodiments, these connections may be formed using a conductive, compressible member with an opening configured to receive the end of the cable therethrough. The conductive ground shield may be configured to compress the conductive, compressible member, and to cause the conductive, compressible member to electrically contact the cable's conductive layer. The conductive, compressible member may be formed from a compressible material and may comprise a plurality of conductive particulates configured to provide electrically conductive paths.

An electrical connector assembly includes a cable assembly having a cable bundle of cables and a conductive cable shield surrounding and providing electrical shielding for the cable bundle. The cable assembly includes an electrical connector a housing holding contacts and a conductive backshell having a cavity that receives the electrical connector to provide electrical shielding for the electrical connector. The backshell has a cable channel at a rear of the backshell that receives the cable. A ground spring is coupled to the cable and positioned between the cable bundle and the cable shield. The ground spring includes spring members engaging the inner surface of the cable shield and biasing the cable shield radially outward. The ground spring is received in the cable channel and forces the outer surface of the cable shield outward against the backshell to electrically connect the cable shield to the backshell.

An electrical connector with electromagnetic shielding function includes a circuit board, a plurality of cables and a shielding component. The circuit board includes a plurality of conductive pads and a ground component. Each of cables includes a wire core and a shielding layer for covering the wire core. One end of the wire core is exposed from the shielding layer, and the wire cores of the cables are electrically connected to the conductive pads respectively. The shielding component is configured on the circuit board and electrically connected to the ground component. The shielding component forms a plurality of shielding grooves for covering the conductive pads and the cables. Each of the shielding grooves includes a contact portion configured to contact the shielding layer and a shielding portion configured to cover the exposed wire core of the cables to provide electromagnetic shielding to the cables.

A cable assembly comprising a termination with at least one conductive, compressible member and a conductive ground shield. The conductive, compressible member may be held within a connector module forming the termination such that the conductive compressive member is pressed against, and therefore makes electrical contact with, both an outer conductive layer of the cable and ground structures within the connector module. In some embodiments, these connections may be formed using a conductive, compressible member with an opening configured to receive the end of the cable therethrough. The conductive ground shield may be configured to compress the conductive, compressible member, and to cause the conductive, compressible member to electrically contact the cable's conductive layer. The conductive, compressible member may be formed from a compressible material and may comprise a plurality of conductive particulates configured to provide electrically conductive paths.

A connector assembly (10) is disclosed in which a connector part (12) and a cable manager part (20) are provided. The cable manager part (20) can be provided with a rear housing (40), a lacing fixture part (30), and a grounding part (50). In one aspect, the grounding part (50) provides grounding contact between an inserted cable (4) and the connector part (12). In one aspect, the grounding part (50) secures the connector part (12) to the rear housing part (40). In one example, a connector assembly (110) is provided with a grounding arrangement (150) including a plurality of deflectable grounding members (152) and provides grounding contact between the inserted cable (4) and the connector part (112). In one aspect, the grounding members (152) each provide two points of contact against the cable (4).

An electric connector includes a tubular conductive shell, covers provided outside the shell to cover at least part of the shell, and a movable cover coupled to the cover through a rotary shaft. The cover has locking pieces on a cable side. The movable cover has locking pieces to be engaged with the locking pieces. At least one of the locking piece or the locking piece includes multiple locking pieces arranged along a circumferential direction of a circle about the rotary shaft. The locking pieces and the locking pieces form a ratchet mechanism, and have such a structure that the locking pieces and the locking pieces are movable in an approaching direction and movement in a direction in which the locking pieces and the locking pieces are separated from each other is restricted.

An electrical connector assembly comprising: an insulative housing with a front mating slot and a rear receiving cavity; a combo contact module assembly received within the receiving cavity and including a sideband contact module sandwiched between a pair of high speed contact modules; each high speed contact module including an upper unit and a lower unit assembled with each other in a vertical direction; each of the upper unit and the lower unit including a front subunit and a rear subunit; each of the front subunit and the rear subunit includes differential pair contacts alternately arranged with grounding contacts in a transverse direction; and a metallic grounding bar discrete from the grounding contacts mechanically and electrically connecting to the grounding contacts.

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 cable card assembly includes a circuit card and cables terminated to the circuit card. Each cable has signal conductors, an insulator, and a cable shield. The cable card includes conductor holders forward of the insulators manufactured from a dielectric material and having conductor channels that receive the signal conductors. The cable card assembly includes ground shields coupled to the circuit card providing electrical shielding for the cables. Each ground shield includes a side walls and an end wall. The end wall has an end wall connecting portion coupled to the cable shield. The first side wall has a first side wall connecting portion coupled to the cable shield. The second side wall has a second side wall connecting portion coupled to the cable shield.