An electrical connector that has a conductive shell supporting at least one signal contact therein and that has a front end for mating with a mating connector and a back end opposite the front end for electrically connecting to a coaxial cable. A ground connection is located inside of the conductive shell. A coupling member is rotatably coupled to the conductive shell and has an engagement feature for mechanically engaging a support panel associated with the mating connector. A sealing member is disposed on the conductive shell that is configured to provide an environmental seal between the conductive shell and the support panel when the conductive shell is mated with the mating connector.

A coaxial cable connector has a body and a longitudinal axis bounding an interior of the body. A pawl is carried in the interior of the body for engaging with a coaxial cable applied to the interior and for preventing the removal of the cable after having been applied to the interior. The pawl moves out of and into interference with the cable in response to the introduction of the cable into the interior and to the retraction of the cable along the longitudinal axis, respectively.

A connector includes an inner sleeve through which a central conductor and an insulator of a coaxial cable are passed and an outer sleeve through which the central conductor, the insulator and a shield member of the coaxial cable are passed, the inner sleeve including projection portions that are arranged in a circumferential direction, project outward in a radial direction and are inserted between the insulator and the shield member of the coaxial cable, and at least one of the projection portions is elastically displaceable in the radial direction, the outer sleeve including an inner peripheral surface that covers the projection portions and tapers in a first direction directed toward the front end of the coaxial cable along the coaxial cable, the shield member of the coaxial cable being sandwiched between the projection portions of the inner sleeve and the inner peripheral surface of the outer sleeve.

An electrical connector adapted to be electrically connected with a cable includes a fixing assembly, an insulation body, and a conductive terminal overmolded in the insulation body. The fixing assembly includes a receiving portion extending in an axial direction of the electrical connector. An end of the cable is inserted into the receiving portion from a first end of the receiving portion. The insulation body extends from a second end of the receiving portion. The conductive terminal includes a mounting portion mounted in the insulation body and a contact portion extending out of the insulation body. The mounting portion is electrically connected with a conductor of the cable by a bolt member.

An electronics housing includes: a housing body; and a printed circuit board. The housing body has a connecting device for connecting a conductor, in particular a shield conductor, of a cable to the printed circuit board. The connecting device has a receiving body in which a receiving space with an opening for the conductor is formed. A cover for the opening is provided and is movable between an open position, in which the cover opens the opening for inserting an uninsulated conductor section of the conductor into the receiving space, and a closed position, in which the cover closes the opening at least in sections. The receiving body of the connecting device is disposed such that the printed circuit board is arrangeable with at least one contact section in the receiving space, and, in a closed position, the cover presses the uninsulated conductor section.

A cable connector assembly includes a circuit board, a plurality of grounding elements and a plurality of cables. Rear ends of an upper surface and a lower surface of the circuit board are equipped with a plurality of contact pads and a plurality of grounding pads. The plurality of grounding elements are soldered to the plurality of the grounding pads. Two sides of each grounding element have two clamping portions. Each cable includes an inner conductor, an inner insulating layer, a shielding layer and an outer insulating layer arranged in an inside-to-outside direction. The inner conductors of the plurality of the cables are electrically connected with the plurality of the contact pads, the shielding layer of each cable is mounted in one grounding element. The shielding layer of each cable is clamped between the two clamping portions of the one grounding element.

An electrical connector that has a conductive shell supporting at least one signal contact therein and that has a front end for mating with a mating connector and a back end opposite the front end for electrically connecting to a coaxial cable. A ground connection is located inside of the conductive shell. A coupling member is rotatably coupled to the conductive shell and has an engagement feature for mechanically engaging a support panel associated with the mating connector. A sealing member is disposed on the conductive shell that is configured to provide an environmental seal between the conductive shell and the support panel when the conductive shell is mated with the mating connector.

A coaxial connector and a coaxial cable forming a cable assembly. The coaxial connector includes a cable entry side for entry of the coaxial cable and an opposite coupling side for coupling with the coaxial counter connector along the connector axis. The coaxial connector includes an inner contact element electrically connected with an inner conductor of the coaxial cable; an outer contact element electrically connected with an outer conductor of the coaxial cable; a dielectric connector element radially arranged between the inner contact element and the outer contact element; a connector housing arranged around the outer contact element; wherein the inner contact element is axially locked against the dielectric connector element and the dielectric connector element is axially locked against the connector housing such that the coaxial cable is strain relieved in an axial direction with respect to the connector housing.

A cable connector including: a body; a nose having a forward nose portion, a rearward nose portion that is configured to be coupled with the body, and a recessed nose portion; a coupler configured to be coupled with the forward nose portion; a conductor configured to be supported in the body and the nose portion; and a biasing portion configured to be received in the recessed nose portion. The coupler is configured to be rotatably coupled to the nose; and the biasing portion is configured to biasingly provide an electrical ground path between the nose and the coupler so as to improve an electrically conductive connection between an outer conductor of a coaxial cable and the coupler when the coupler is not connected to an interface port, when the coupler is loosely coupled to the interface port, and when the coupler is fully tightened to the interface port.

A connector assembly that includes a receptacle with inner and outer shells which have a front end for mating with a mating connector and a back end configured to connect to a printed circuit board. Receptacle primary and secondary ground connections are located on one of the shells. A plug with an outer shell that supports a pin contact to mate with the socket contact. The outer shell of the plug has a front end for mating with the front end of the receptacle and a back end that is configured to connect to a coaxial cable. Plug primary and secondary ground connections are located on the outer shell. When the receptacle and plug are mated, the primary ground connections form a primary grounding path through the assembly and the secondary ground connections form a secondary grounding path through the assembly, thereby electrically connecting the plug with the board.