A mating module includes a conductive terminal, a cable, a first metal shield member and a second metal shield member. The cable includes a core electrically connected to the conductive terminal, an insulating layer wrapped on the core, and a shielding layer wrapped on the insulating layer. The first metal shield member includes a first mounting piece. The second metal shield member includes a second mounting piece. The cable further includes a protruding piece connected to the shielding layer. The protruding piece is directly or indirectly clamped by the first mounting piece and the second mounting piece. As a result, the shielding effect of the mating module is improved. The present disclosure also relates to a cable connector having the mating module.

A shield connector is provided with a dielectric 40 including a plurality of accommodation chambers 44 defined in a width direction by a separation wall portion 43, and a plurality of inner conductors 21 having a shape elongated in a front-rear direction and individually accommodated in parallel in the plurality of accommodation chambers 44. The separation wall portion 43 is formed with a front opening 53 and a rear opening 60 for interposing air layers between the accommodation chambers 44 adjacent via the separation wall portion 43.

A connection module includes a first assembly and a second assembly. The first assembly has a rest portion for resting thereon an exposed portion of a covered electrical wire for differential signal transmission. A cable accommodates the covered electrical wire in a jacket. The exposed portion is not covered with the jacket, exposing a covering of the covered electrical wire. The second assembly has a presser portion pressing the exposed portion rested on the rest portion against the rest portion. A position of the exposed portion is determined by combining the first assembly with the second assembly.

Provided is a connector module provided on an end of a communication cable, the connector module comprising a first terminal, a connector member that houses the first terminal, a tubular shield member that covers the outer circumference of the connector member, and a tubular conductive rubber member disposed in contact with the inner circumferential surface of the shield member, wherein the shield member comprises a housing part in which the conductive rubber member is disposed on the side where the end of the communication cable is inserted, the maximum outer diameter of the conductive rubber member when not compressed by the housing part exceeds the minimum inner dimension of the housing part and is equal to or less than the maximum inner dimension of an opening in the housing part, and at least a portion of the inner circumferential surface of the housing part comprises an inclined surface.

Guide element for electrical cores in a cable with at least four guide tracks, one for each electrical core of the cable, wherein the guide tracks run in such a way that at a first end of the guide element, at least two cores exchange places relative to a second end of the guide element opposite the first end.

The application deals with a male or female connector for automotive applications with at least one signal contact having an elongated male pin or a female signal contact portion; wherein a section of the signal contact is covered by a molded part that is manufactured by overmolding the section of the signal contact. The application further deals with a method for producing a male or female connector for automotive applications; including the steps of providing at least one signal contact having an elongated pin or a female signal contact portion; and overmolding a section of the at least one signal contact.

Assembly comprising a cable having at least two signal wires, and a connector connected to the shielded cable, wherein the connector comprises at least two elongated inner signal contacts each connected to a wire of the cable, wherein the connector comprises a shielding portion formed of an inner shield and an outer shield, and wherein the inner shield at least approximately completely surrounds the wires of the cable and the outer shield at least partially surrounds the inner shield.

An aspect of the present disclosure is directed to a connector. The connector is suited to connectorizing exactly two conductors. The connector includes a forward connector body, a rear connector body, a metal frame and exactly two electrical contacts. The rear connector body interfaces with the forward connector body. Further, the metal frame, which includes a shielding interface, surrounds at least a portion of both the forward and rear connector bodies. The electrical contacts extend from the rear connector body into the forward connector body. A first of the electrical contacts is electrically coupled to a first conductor of a shielded cable and the second of the electrical contacts is electrically coupled to a second conductor of the shielded cable. The shield interface of the metal frame is electrically coupled to the shield of the shielded cable.

A connector assembly includes at least one elongated inner signal contact having a first connection portion. The first connection portion includes a tube-like main section and a funnel-shaped end section. The first connection portion further includes an insulating element. The insulating element defines at least one elongated cavity designed to accommodate the elongated inner signal contact. A maximum outer cross-sectional dimension of the funnel-shaped end section is greater than a minimum cross-sectional dimension of the elongated cavity.

A cable shield tunnel for an electrical device includes a ground bus and a floor shim, discrete from the ground bus, and coupled to a circuit card and forming a cable tunnel that receives an end of a cable. The ground bus includes an end wall extending along a first end of the cable tunnel, a first side wall extending from the end wall along a first side of the cable tunnel, and a second side wall extending from the end wall along a second side of the cable tunnel opposite the first side. The first and second side walls are configured to be coupled to the circuit card. The floor shim is provided at a second end of the cable tunnel opposite the first end and is positioned between the cable and the circuit card.