The present disclosure describes a coaxial cable-connector assembly. The coaxial cable-connector assembly including a coaxial cable, a coaxial connector, and a polymeric sleeve. The outer connector body is swaged or crimped onto the polymeric sleeve. An end of a corrugated outer conductor of the coaxial cable is flared radially outwardly to form a flared end that secures the polymeric sleeve onto the coaxial cable. The polymeric sleeve separates the corrugated outer conductor of the coaxial cable from the outer conductor body of the coaxial connector to prevent direct radial electrical connection therebetween and the polymeric sleeve axially forces the flared end of the outer conductor of the coaxial cable in contact with a shoulder of the outer connector body of the coaxial connector. Additional coaxial cable-connector assemblies and related methods of assembling the same are described herein.

An electrical connector for an electrical cable having a contact element for connection to an electrical conductor of the electrical cable. The electrical connector has an integrated cleaning tool for the electrical conductor. The cleaning tool is arranged along a feed direction for the electrical cable on the cable side upstream of the contact element. It is provided that the cleaning tool is designed to remove or at least retain particles, residues of a sheathing and/or contaminants adhering to the electrical conductor before the electrical conductor contacts the contact element of the electrical connector arranged downstream in the feed direction within the scope of a connector assembly process.

An electrical plug connector for a cable has a compression sleeve and a stop element that is axially adjacent to and connected to the compression sleeve. The compression sleeve has an inner lateral surface thread that is screwable to an outer lateral surface thread of an outer conductor of the cable. The outer conductor is clampable between the compression sleeve and an axial end region of the stop element, and in an assembled state, a longitudinal axis of the compression sleeve, is tilted relative to a longitudinal axis of the stop element; or b) a normal vector of a plane spanned by an edge between an end face and an inner lateral surface of the stop element is rotated by orientation angle (φ.sub.A) relative to the longitudinal axis of the compression sleeve; or c) the edge has a helical course in a longitudinal axis direction of the plug connector.

The present invention relates to a boot and connector assembly. The boot has a through hole passing therethrough and a boot body enclosing the through hole, the boot body comprising: a neck sealing portion presenting a substantially cylindrical shape, wherein the neck sealing portion has an inner diameter maintained substantially constant; a body portion located at the proximal side of the neck sealing portion and presenting a generally cylindrical shape, wherein the body portion has an inner diameter and an outer diameter that are both greater than the inner diameter and the outer diameter of the neck sealing portion; and a gap passing portion connecting the neck sealing portion to the body portion and having a substantially frustoconical shape, wherein the gap passing portion has an inner diameter gradually increasing from the inner diameter of the neck sealing portion to the inner diameter of the body portion, and an outer diameter gradually increasing from the outer diameter of the neck sealing portion to the outer diameter of the body portion. The boot of the present disclosure effectively solves the problem that the boot interferes with other components so that the boot is unable to extend to the antenna panel when the mounting space is small, and also has the advantages of simple to manufacture, convenient to mount and high efficiency.

A coaxial cable-connector assembly includes a coaxial cable, a coaxial connector, and a rear body. The coaxial cable includes: an inner conductor; a dielectric layer circumferentially surrounding the inner conductor; an outer conductor circumferentially surrounding the dielectric layer, the outer conductor having an inner surface and an outer surface; and a jacket circumferentially surrounding the outer conductor. The coaxial connector includes: an inner contact electrically connected with the inner conductor; an outer connector body spaced apart from and circumferentially surrounding the inner contact, the outer connector body including a first securing feature; and a dielectric spacer interposed between the inner contact and the outer body. The rear body has a main section and a front collet with forwardly-extending fingers, the fingers engaging the outer surface of the outer conductor of the cable, the fingers including a second securing feature, wherein the second securing feature engages the first securing feature to maintain the outer connector body and the rear body in position on the cable.

The invention is characterized in that a HF coaxial cable is designed as a conventional corrugated sheath cable comprising a cable outer conductor, in the form of a metal corrugated tube, having a line impedance Z.sub.k and a minimum bending radius r.sub.k,min specified by the manufacturer as a characteristic feature of the coaxial cable; in corrugated sheath cable, directly or indirectly following the straight plug connector, is bent to have a bending radius r.sub.α, where 0.2 r.sub.k,min≦r.sub.α≦0.9 r.sub.k,min, which alters the line impedance Z.sub.k by a maximum of 1 ohm. The bend with the bending radius r.sub.α is produced by cold forming corrugated sheath cable with the introduction of bending forces and tensile forces directed along said corrugated sheath cable.

A coaxial connector assembly includes: a first plurality of first coaxial connectors mounted within a shell, the shell defining a plurality of electrically isolated cavities, each of the first coaxial connectors being located in a respective cavity; a plurality of first coaxial cables, each of the coaxial cables attached to a respective one of the first coaxial connectors; a second coaxial connector mounted within the shell, the second coaxial connector being smaller that the first coaxial connectors; and a second coaxial cable attached to the second coaxial connector, the second coaxial cable being smaller than the first coaxial cables.

A coaxial cable-connector assembly includes a coaxial cable, a coaxial connector, and a rear body. The coaxial cable includes: an inner conductor; a dielectric layer circumferentially surrounding the inner conductor; an outer conductor circumferentially surrounding the dielectric layer, the outer conductor having an inner surface and an outer surface; and a jacket circumferentially surrounding the outer conductor. The coaxial connector includes: an inner contact electrically connected with the inner conductor; an outer connector body spaced apart from and circumferentially surrounding the inner contact, the outer connector body including a first securing feature; and a dielectric spacer interposed between the inner contact and the outer body. The rear body has a main section and a front collet with forwardly-extending fingers, the fingers engaging the outer surface of the outer conductor of the cable, the fingers including a second securing feature, wherein the second securing feature engages the first securing feature to maintain the outer connector body and the rear body in position on the cable.

An RF connector having an integral weather protection system for protecting the connector from water, ice, salt, debris and other foreign damage. The connector comprises a Weather Protection (WP) assembly circumscribing a connector body, which, in turn, sealably mounts to a coaxial cable. The WP assembly comprises a housing, a compliant sealing ring and a biasing element. The WP housing sealably mounts over an end of the connector body and defines an aperture at an opposite end thereof to receive the coaxial cable and facilitate axial translation of the housing relative to the connector body. The compliant sealing ring has an inwardly facing sealing surface which defines a diameter dimension. And, the biasing element is reconfigurable from an expanded to a collapsed state in response to axial displacement of the housing relative to the connector body. Operationally, the biasing element engages the compliant ring to expand the diameter dimension of the biasing element around a portion an interface port, and closes over a sealing surface of the interface port to seal the compliant ring against the sealing surface

A connector assembly for earth-bonding of a corrugated stainless steel tubing system is disclosed. The collector assembly incorporates a fitting to hold a tubing at least at one opening of the fitting, a collet at inner side of the at least one opening to enable sealing of the tubing, and a nut configured on outer side of the one or more opening of the fitting. The connector assembly can include one or more holes positioned at pre-defined positions on the fitting or nut to electrically couple one or more earth-bonding means at the one or more holes. The earthing means can include an earthing cable coupled to the fitting or the nut by an earth-bonding clamp or a tightening screw, which can be connected to an electrical earth or electric zero potential for providing earth-bonding.