A pluggable module includes a housing and cables arranged as a cable bundle extending from a module cavity of the housing. Each cable includes first and second conductors and an insulator surrounding the conductors. Each cable is obround shaped having generally flat first and second ends and semi-circular first and second sides between the first and second ends. The pluggable module includes a cable organizer coupled to the cable bundle to position the cables relative to each other. The cable organizer has cable channels receiving and holding the cables such that at least a first subset of the cables are oriented with the first and second ends non-parallel to the first and second ends of a second subset of the cables.

A pluggable module includes a housing and cables arranged as a cable bundle extending from a module cavity of the housing. Each cable includes first and second conductors and an insulator surrounding the conductors. Each cable is obround shaped having generally flat first and second ends and semi-circular first and second sides between the first and second ends. The pluggable module includes a cable organizer coupled to the cable bundle to position the cables relative to each other. The cable organizer has cable channels receiving and holding the cables such that at least a first subset of the cables are oriented with the first and second ends non-parallel to the first and second ends of a second subset of the cables.

A crimp ferrule includes an assembly portion assembled on a non-circular internal cross section of a multi-core cable and a diameter compensation portion forming a circular external cross section of the crimp ferrule on the multi-core cable. The assembly portion and the diameter compensation portion are arranged successively in an axial direction of the crimp ferrule.

A crimp ferrule includes an assembly portion assembled on a non-circular internal cross section of a multi-core cable and a diameter compensation portion forming a circular external cross section of the crimp ferrule on the multi-core cable. The assembly portion and the diameter compensation portion are arranged successively in an axial direction of the crimp ferrule.

The present disclosure provides a connector assembly. The connector assembly includes a wire-end connector. The wire-end connector includes a wafer, a shield plate and a twin-ax cable. The wafer includes a frame and a terminal group. The terminal group is supported by the frame. The terminal group includes a signal terminal pair and a ground plate. The ground plate includes a ground terminal on both sides of the signal terminal pair. The shield plate is electrically connected to the ground plate. The shield plate includes an opening that penetrates the shield plate. The twin-ax cable includes a pair of conductors and a ground portion. The pair of conductors extend into the opening of the shield plate and are electrically connected to the signal terminal pair. The ground portion electrically connects at least one of the shield plate and the ground plate.

A multi-line electrical assembly that includes a multi-line cable (14), including a multiplicity of insulated conductive wires (59); and a multi-line electrical plug (16), physically connected to the cable. The plug has a housing (56) and a plurality of spaced-apart printed circuit hoards (PCBs, 48), housed in the housing and having a first end (47) that is connected to the cable and having a second end (46), separated from the first end. Further, the PCBs bear a plurality of conductive traces (50), at least some of the traces being electrically connected to the wires proximal to the first end. The traces terminate proximal to the second end.

The invention relates to a method for processing an electrical cable (2), according to which a braided cable shield (6) of the cable (2), which is exposed along a longitudinal axis (L) of the cable (2) from a cable end (5) which is to be processed to a first stripping position (P.sub.A1), is, by means of brushing with at least one drivable brush (10), folded back towards a cable end facing away from the cable end (5) to be processed. According to the invention, a defined fold-back position (P.sub.U) for the braided cable shield (6) is determined along the longitudinal axis (L) of the cable (2). Before and/or during brushing, a front end of the forming sleeve (12), said front end facing the cable end (5) to be processed, is placed onto the cable (2) and positioned at the fold-back position (P.sub.U) in order to fold back the braided cable shield (6) onto the forming sleeve (12) starting from the fold-back position (P.sub.U). According to the invention, the fold-back position (P.sub.U) is determined in such a way that the fold-back position (P.sub.U) deviates from the first stripping position (P.sub.A1) and/or that the forming sleeve (12) has an end-face stop surface (20) for the braided cable shield (6).

The invention relates to a method for processing an electrical cable (2), according to which a braided cable shield (6) of the cable (2), which is exposed along a longitudinal axis (L) of the cable (2) from a cable end (5) which is to be processed to a first stripping position (P.sub.A1), is, by means of brushing with at least one drivable brush (10), folded back towards a cable end facing away from the cable end (5) to be processed. According to the invention, a defined fold-back position (P.sub.U) for the braided cable shield (6) is determined along the longitudinal axis (L) of the cable (2). Before and/or during brushing, a front end of the forming sleeve (12), said front end facing the cable end (5) to be processed, is placed onto the cable (2) and positioned at the fold-back position (P.sub.U) in order to fold back the braided cable shield (6) onto the forming sleeve (12) starting from the fold-back position (P.sub.U). According to the invention, the fold-back position (P.sub.U) is determined in such a way that the fold-back position (P.sub.U) deviates from the first stripping position (P.sub.A1) and/or that the forming sleeve (12) has an end-face stop surface (20) for the braided cable shield (6).

The described connector assemblies are useful in wire-to-board systems. Some assemblies include a free-end connector that is attached to a twin-ax cable, and a fixed-end connector that is attached to a board. Embodiments include a free-end terminal set including a first signal terminal, a second signal terminal and a ground plate. The ground plate has a horseshoe shape and provides a ground terminal on opposing sides of the first and second signal terminals. Additionally, embodiments include a locking system between the free-end connector and fixed-end connector, and lead designs for the fixed-end connector utilizing a similar horseshoe shape as that used for the ground plate of the free-end connector.

The present disclosure relates to an integrated multipole connector, and more particularly, an integrated multipole connector that can be used as a multipole connector integrating a plurality of connectors to which different current capacities and shielding structures are applied.