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.

A connector includes a body having a central bore and a first grounding contact surface, a post disposed within the central bore and having an outwardly projecting flange configured to produce a first portion of a mating interface, and a conductive coupler. The post portion has a tubular sleeve configured to mechanically and electrically engage a prepared end of a coaxial cable. The conductive coupler has an engagement surface at a first end configured to mechanically and electrically engage an interface port, a lip at a second end configured to produce a second portion of the mating interface, and a second grounding contact surface opposing the first grounding contact surface. The first and second portions are configured to slide along the mating interface to rotate about an elongate axis of the connector. The connector includes a conductive ring disposed between the first and second grounding contact surfaces and configured to produce an electrical path between the body and the conductive coupler.

A load-bearing connector connection includes two half-flanges encapsulated in a coupling body extending from a first end to a second end. The two assembled half-flanges cover the end of a cable having a plurality of plugs and a helical armor. The two half-flanges include on the inner face thereof a part of the threading engaging with the threading of the helical armor. A locking ring is positioned at the level of a plug housing adjacent to the first end of the coupling body. The coupling body is screwed to the plug housing. The second end of the coupling body is adjacent to a coupling nut. The coupling nut traverses the cable and is assembled with the coupling body by screwing.

A conductor shielding termination assembly can include a housing tube defining an inner diameter housing channel therethrough and having housing threads on an outer diameter thereof. The housing tube can be made of conductive material. The assembly can include a shoulder bushing configured to insert within the inner diameter housing channel of the housing tube. The shoulder bushing can define an inner diameter bushing channel sized to receive an unshielded portion of a conductor. The assembly can include a jam nut comprising a nut inner diameter channel sized to receive a shielded portion of the conductor and nut threads on an inner diameter thereof configured to mesh with the housing threads. The jam nut and housing tube can be configured to trap a shielding termination within the meshed housing threads and jam nut threads.

A multiphase connector for electric powertrain systems includes a terminal block and a plug member that are, at least in part, made from electrically conductive metal. The terminal block has at least one socket surrounding a retaining spring and the plug member has at least one contact pin configured to be inserted in to the at least one socket. The plug member can be engaged with the terminal block without use of installation tools and includes one or more cable gland assembly in contact with a shield of a shielded cable.

A coaxial cable connector comprising a sleeve, nut, post, and annular flange is provided. The post is assembled to the nut, the annular flange to the post, and post, annular flange and nut to the sleeve. The nut has a plurality of nut sides, and a plurality of crests between the plurality of nut sides, each having a raised ridged pattern thereon. Each raised ridged pattern comprises a first plurality of grooves having a first groove helix angle and a second plurality of grooves having a second groove helix angle, intersecting the first plurality of grooves, forming a plurality of peaks. Following assembly, a plurality of deformed indentations is formed on an inner surface of the sleeve via the plurality of peaks of the nut.

An assembly for a coaxial connector is described. The assembly, in one embodiment, includes a coupler, a grip ring and a seal member.

A grounding device for maintaining a ground path between a component of a connector and an interface port when the grounding device flexes includes a sealing member configured to form a conductive ground path between a component of a connector and an interface port. The sealing member comprises a sealing portion that is configured to overlie a grounding portion toward a radial direction of the connector when the connector is assembled, and the sealing portion and the grounding portion of the sealing member are configured to flex when a force is applied to the sealing member so as to maintain a ground path between the component of the connector and the interface port when the sealing portion and the grounding portion flex and when a force is applied to the sealing member during operation of the connector.

A connector includes, in one embodiment, a first component, a coupling element configured to engage the first component, and a second component configured to engage the first component. The second component, in one embodiment, is configured to produce a spring, pushing or biasing force.

A cable connector includes: a back portion comprising a rearward end and a forward end opposite the rearward end; a conductive portion configured to be supported within the back portion and comprising a rearward end portion; and a biasing portion configured to be received by the conductive portion. In an assembled state, the biasing portion is configured to be compressed in an axial direction between the conductive portion and the back portion; and the biasing portion is configured to urge the conductive portion into contact with a front assembly to provide a secure electrical grounding path between the conductive portion and the front assembly.