The present invention is a connector for connecting an electrical cable having cladding to an aperture in an electrical panel. The assembled connector has a spring, a shell, and a insulator along a longitudinal axis. The spring has a base from which two insertion tabs extend coaxial with the axis and the shell has two side walls to prevent over-insertion of the cladding into the connector. The insertion tabs of the spring have hook latches extending past the insulator that lock the connector in the panel, and the insulator has pressure buttons for flexing the insertion tabs during insertion and removal of the connector to the electrical panel.

A cable gland for providing strain relief and sealing for a cable that can be coupled to a device. The cable gland includes a sealing gland having a sealant. Upon assembly of the cable gland, the sealing gland is compressed in a manner that can releases, or otherwise can facilitate the displacement of, the sealant about an interface between a portion of the cable and the sealing gland, and/or into spaces between exposed insulative jackets and/or conductors of the cable. The sealant can include a curable viscous sealant that is housed within a package of the sealing gland, the package being configured to rupture upon compression of the sealing gland. Alternatively, the sealant can be a malleable sealant material that can be pressed or otherwise displaced to form a seal between the sealing gland and cable and/or into the spaces between exposed insulative jackets and/or conductors of the cable.

A cable has a corrugated armor exterior surface, and a split bushing defines an interior surface which conforms to the corrugated exterior surface. The bushing is split radially in one place to form a gap which may be opened to allow the bushing to open, or the bushing is split radially at two or more places to form two or more parts, and is fitted about the corrugated exterior surface. The bushing defines first and second external chamfer surfaces. A connector includes a body having external threads and a chamfer which urges against the first bushing chamfer. A nut has internal threads which engage the external threads of the body, and a chamfer which urges against the second bushing chamfer. As the nut is tightened onto the body, wedge action on the first and second bushing chamfers compresses the bushing around the corrugated exterior surface to secure the connector to the cable.

A device for the sealed closing of an opening for one or more elongate parts to pass through includes a sealing and/or clamping element with at least two interacting first and second parts that are axially displaceable relative to one another, and a pressure contour acting axially onto the sealing and/or clamping element. A first axial displacement of the pressure contour and an axial displacement of the at least one second part relative to the at least one first part causes a first change in geometry of the at least one first part transversely to the displacement direction. Also, a further axial displacement of the pressure contour causes a further change in geometry of the at least one first part transversely to the displacement direction such that the opening is sealed around the one or more elongate parts passing therethrough.

A cable has a corrugated armor exterior surface, and a split bushing defines an interior surface which conforms to the corrugated exterior surface. The bushing is split radially in one place to form a gap which may be opened to allow the bushing to open, or the bushing is split radially at two or more places to form two or more parts, and is fitted about the corrugated exterior surface. The bushing defines first and second external chamfer surfaces. A connector includes a body having external threads and a chamfer which urges against the first bushing chamfer. A nut has internal threads which engage the external threads of the body, and a chamfer which urges against the second bushing chamfer. As the nut is tightened onto the body, wedge action on the first and second bushing chamfers compresses the bushing around the corrugated exterior surface to secure the connector to the cable.

A cable gland for providing strain relief and sealing for a cable that can be coupled to a device. The cable gland includes a sealing gland having a sealant. Upon assembly of the cable gland, the sealing gland is compressed in a manner that can releases, or otherwise can facilitate the displacement of, the sealant about an interface between a portion of the cable and the sealing gland, and/or into spaces between exposed insulative jackets and/or conductors of the cable. The sealant can include a curable viscous sealant that is housed within a package of the sealing gland, the package being configured to rupture upon compression of the sealing gland. Alternatively, the sealant can be a malleable sealant material that can be pressed or otherwise displaced to form a seal between the sealing gland and cable and/or into the spaces between exposed insulative jackets and/or conductors of the cable.

A cable gland includes a bushing. The bushing may include a rib on an interior surface of the bushing to facilitate sealing and gripping of a cable received in the cable gland. The bushing may comprise or be formed from a silicone rubber material.

A cable gland assembly includes a hub body defining an internal passage. The cable gland assembly further includes an intermediate body defining an internal passage, wherein the hub body receives the intermediate body, the intermediate body having a first end and a second end opposite the first end, wherein the second end of the intermediate body includes a threaded engagement portion. A gland nut having a first end and an opposite second end, the first end of the gland nut snap-fits to the threaded engagement portion of the intermediate body to secure a cable in the cable gland. A union nut having a first end and a second end, the first end of the union nut is threadedly coupled to the second end of the hub body, the second end of the union nut having a shoulder.

In one or more embodiments, system and method for providing molded seal glands for cables are disclosed. In an embodiment, the system for providing molded seal gland for cables includes at least one cable and a seal gland for the cables where the seal gland is molded to at least one cable forming an assembly that is ready for installation in a panel or an enclosure. In an embodiment, the method for providing molded seal gland for cables includes molding the seal gland for the cable to at least one cable forming an assembly such that they are ready for installation in a panel or an enclosure.

A conduit body including a connector port, a fastener member including a body and a cylindrical channel extending therethrough movably secured to the connector port, and a first seal member arranged in the cylindrical channel. The connector port being configured to form a liquid-tight connection with a liquid-tight flexible conduit by positioning the conduit to axially extend through the cylindrical channel and connecting an end of the flexible conduit to the connector port in the first channel. The first seal member being configured to elastically deform to fill a space between the fastener member, connector port, and flexible conduit, to retain the flexible conduit in the first channel. The conduit body can include a ground cone for connecting to the flexible conduit in the first channel, and a second seal member configured to elastically deform to fill an area between the flexible member and conduit body at the connector port.