Disclosed in the present disclosure is an electromagnetic compatibility type cable locking joint. The electromagnetic compatibility type cable locking joint comprises a joint main body, a joint cap, a sealing ring, and a shielding member. The joint main body has a central hole, and an inner step is provided in the central hole. The sealing ring is connected to the end of the joint main body, and a positioning groove is formed between the sealing ring and the inner step. The joint cap is connected to the sealing ring, the shielding member comprises an upper ring, a lower ring, and an arc-shaped elastic piece. A plurality of arc-shaped elastic pieces are uniformly arranged in a circle. The upper end of each arc-shaped elastic piece is formed on the upper ring, and the lower end of each arc-shaped elastic piece is formed on the lower ring.

A cable gland and methods for earthing, grounding, bonding, and electromagnetic capability with armored, metal-clad, and metallic-sheathed cable types. The cable gland comprises a gland body, a plurality of extensions, an elastomer seal, a compression member configured to rotate the plurality of extensions towards to the elastomer seal, and an earthing insert mounted in the gland body configured to electrically connect a cable to a neutral and/or grounded conductor. The cable gland is configured to provide an air-tight seal between the exterior of the cable and the elastomer seal through rotation of the plurality of extension upon the elastomer seal. The cable gland may include an o-ring and nut to secure the cable gland to a planar body. The earthing insert comprises a grounding spring in electrical communication with a metallic portion of the cable and a neutral and/or grounded conductor.

A connector for joining respective axial extremities of associated first and second axial sections of electrical conduit which includes a cylindrical sleeve that has an interior surface and an exterior surface as well as a first axial extremity and a second axial extremity and a geometric axis. The cylindrical sleeve has an exterior surface proximate to the first axial extremity that includes a first peripheral rib extending around the entire circumferential extent of the exterior surface. The first peripheral rib has an outside diameter that is greater than the diameter of the cylindrical sleeve proximate to the first axial extremity. The cylindrical sleeve has an exterior surface proximate to the second axial extremity that includes a second peripheral rib extending around the entire circumferential extent of the exterior surface, the rib has an outside diameter is greater than the diameter of the cylindrical sleeve proximate to the second axial extremity.

A connector for coupling a conduit to an electrical enclosure includes a body and a lock nut. The body extends longitudinally between a proximal enclosure end and a distal conduit end. The body has an enclosure port at the enclosure end, a conduit port at the conduit end, and an internal passage extending between the enclosure port and the conduit port. The enclosure end has radially opposed first and second retention tabs. The body has external body threads located distally of the retention tabs. Each of the retention tabs extend radially outward of a longitudinal projection of the external threads. The lock nut is mated with the external body threads. The lock nut has an enclosure engagement end opposed to distal facing enclosure engagement sides of the retention tabs. The lock nut is rotatable on the external body threads to advance the enclosure engagement end toward the retention tabs.

An insert for a clamping device for clamping an armour layer of a cable in a cable gland is disclosed. The insert comprises a body (54) adapted to be received in a cable gland and defining an aperture (60) for receiving an inner part of a cable. A clamping portion (62) is adapted to engage an armour layer of the cable to clamp the armour layer between the clamping portion and a clamping member of the clamping device when the clamping member is arranged outwardly of the clamping portion. At least part of the clamping portion is displaceable inwards as a result of engagement of the clamping portion with the armour layer clamped between the clamping portion and the clamping member.

A gland assembly includes a gland body (3) and a cap nut (5) connected by screw threads (25). A cable holding device (11) is received within the cap nut (5) and has a plurality of fingers (19) configured to apply a gripping force to a cable (7) extending through the gland assembly in response to a torque applied to the cap nut (5). The fingers (19) are configured to increase the gripping force on the cable (7) in response to a linear force applied to the elongate member.

A splice sealing device including a first electric cable having an electrical conductor and an insulative cover, a second electric cable having a further electrical conductor and insulative cover, a junction joining the electrical conductors of the first and second electrical cables, a housing which has at least two housing parts mated to each other and which delimits an inner space for accommodating the junction, and a first cable exit in the housing. The first cable extends through the first cable exit, which includes a first chamber accommodating a first cable seal positioned on the first insulative cover of the first cable and sealing the first cable against the housing. The first cable exit is an integral part of a first housing part, and the first cable exit includes an annular wall axially delimiting the first chamber to the outside in extension direction of the first cable.

A cable-holding device with sealing assembly includes a body having a main unit, a first connecting portion and a second connecting portion, a sealing assembly on the body, and an adjustment element on the second connecting portion. The body has a connecting hole, and the second connecting portion is extended with plural clamping arms. The sealing assembly includes a first sealing portion outside the first connecting portion, a second sealing portion inside the clamping arms to form a tightening port, and a connecting portion between the first sealing portion and the second sealing portion. On the second connecting portion, the adjustment element includes a first movement state which forms a tightening state on the tightening port, and a second movement state which changes the tightening port from the tightening state into a non-tightening state gradually.

A flange assembly for supporting a cable has a flange body and an armor retainer. The flange body and the armor retainer are configured to support a cable by compressing an armor layer of the cable against the armor retainer. The armor retainer and the flange body are separate pieces, that are removably attachable to one another.

To achieve high waterproofness, a grommet that is attached so as to cover a shield pipe and a corrugated tube so as to bridge therebetween includes a pipe-side end portion that is formed in a tubular shape capable of being sealingly connected to an outer circumferential side of the pipe, and a corrugated-side end portion that is formed in a tubular shape capable of being sealingly connected to an outer circumferential side of the corrugated tube. A plurality of sealing lips that closely contact to an outer surface of the shield pipe are formed on an inner surface of the pipe-side end portion. The sealing lips are disposed inside and outside a width region W that is fastened by a fastening band disposed on an outer surface of the pipe-side end portion.