Cable connector installation tools are provided. In one aspect, a tool includes removable nubs configured to set trim distances from the end of a cable to a blade in the tool. In another aspect, a tool includes jaws configured to force end connector components together, one of which being temporarily engaged by an interface nub.

Cable connector installation tools are provided. In one aspect, a tool includes removable nubs configured to set trim distances from the end of a cable to a blade in the tool. In another aspect, a tool includes jaws configured to force end connector components together, one of which being temporarily engaged by an interface nub.

A cable termination that enables the attachment of SMA connectors to controlled-impedance cables with a conductive foil wrap shield; for the separate ferrule embodiment, the sheath is stripped back on the cable, exposing the foil shield surrounding the dielectric; a ferrule is slid or clamped over the foil shield and bonded; the face of the ferrule is dressed so that the foil shield and dielectric are flush with the ferrule face and the signal conductor protrudes from the face this cable subassembly is installed in the boss of a housing that prevents movement of the ferrules relative to each other and so that each ferrule face is aligned with an opening in the boss through which an SMA connector barrel is attached to the ferrule a cover secures the cable subassembly in the housing.

The present disclosure is generally directed to a connector assembly that includes an increased outer diameter of the connector member relative to the equivalent G-type connector and an increased inner diameter of the receptable member relative to the equivalent G-type receptacle (also referred to as a seizure nut) to achieve higher current carrying capacity and target frequency rates of up to 3.0 Ghz, for example. In one preferred example, this results in a connector assembly consistent with the present disclosure having a connector member with an outer diameter of at least 10.70 mm, and more preferably 10.76±0.01 mm, rather than the 9.4 mm diameter of existing G-type connectors. Despite this increased diameter, a seizure assembly consistent with the present disclosure can achieve a functional impedance of 75 ohms to maintain nominal signal quality.

The present disclosure is generally directed to a connector assembly that includes an increased outer diameter of the connector member relative to the equivalent G-type connector and an increased inner diameter of the receptable member relative to the equivalent G-type receptacle (also referred to as a seizure nut) to achieve higher current carrying capacity and target frequency rates of up to 3.0 Ghz, for example. In one preferred example, this results in a connector assembly consistent with the present disclosure having a connector member with an outer diameter of at least 10.70 mm, and more preferably 10.76±0.01 mm, rather than the 9.4 mm diameter of existing G-type connectors. Despite this increased diameter, a seizure assembly consistent with the present disclosure can achieve a functional impedance of 75 ohms to maintain nominal signal quality.

A coaxial cable connector includes a body configured to engage a coaxial cable having a conductive electrical grounding property, a post configured to engage the body and the coaxial cable when the connector is installed on the coaxial cable, a nut configured to engage an interface port at a retention force, and a conductive insert received inside the nut. The conductive insert is configured to increase the retention force between the nut and the interface port so as to provide an electrical ground connection between the interface port and the nut when the nut is in a loosely tightened position on the interface port, and/or the conductive insert is configured to make the electrical ground connection with the interface port before a center conductor of the coaxial cable makes an electrical connection with an internal contact of the interface port when the nut is coupled with the interface port.

A coaxial cable connector includes a body configured to engage a coaxial cable having a conductive electrical grounding property, a post configured to engage the body and the coaxial cable when the connector is installed on the coaxial cable, a nut configured to engage an interface port at a retention force, and a conductive insert received inside the nut. The conductive insert is configured to increase the retention force between the nut and the interface port so as to provide an electrical ground connection between the interface port and the nut when the nut is in a loosely tightened position on the interface port, and/or the conductive insert is configured to make the electrical ground connection with the interface port before a center conductor of the coaxial cable makes an electrical connection with an internal contact of the interface port when the nut is coupled with the interface port.

A cable connector includes a housing, a conductive insert affixed within the housing, a first conductive plug, and a second conductive plug. The housing defines a first port, a second port, a third port, and a fourth port. The first conductive plug and the second conductive plug are removably affixed to the housing. The first conductive plug further includes a dust cap and an insulating pin that is rotationally fixed to the dust cap. The first conductive plug provides a single structure that is configured to block moisture and engage the first center conductor against the first end of the conductive insert. Alternatively, the first conductive plug may include a dust cap, an insulator and a pin that are rotationally affixed to one another.

A coaxial cable connector assembly includes a coupler, a rear body assembly rotatably engaged with the coupler, the rear body assembly including a stationary retention member defining an stationary retention member inner channel surface and one or more stationary retention member grooves extending inwardly from the stationary retention member inner channel surface, a movable retention member that is movable with respect to the stationary retention member in an axial direction, the movable retention member defining a movable retention member inner channel surface and one or more movable retention member grooves extending inwardly from the movable retention member inner channel surface, the one or more movable retention member grooves defining a movable retention member groove surface, and one or more compression rings positioned at least partially within the one or more stationary retention member grooves.

An electrical connector is presented herein. The electrical connector includes an insulator that is formed of a dielectric material and defines a cavity extending therethrough. The cavity has a plurality of cylindrical sections. A first cylindrical section of the plurality of cylindrical sections has a diameter that is larger than a diameter of adjoining second and third cylindrical sections of the plurality of cylindrical sections on each side of the first cylindrical section. The insulator is preferably formed using an additive manufacturing process, such as stereolithography, digital light processing, fused deposition modeling, fused filament fabrication, selective laser sintering, selecting heat sintering, multi-jet modeling, multi-jet fusion, electronic beam melting, laminated object manufacturing, or 3D printing.