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 includes an internal dam. The internal dam includes a plurality of filaments to inhibit curable liquid from flowing through the dam and between the dam and one or more conductors of a cable.

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 conductor shielding termination assembly can include a housing tube defining an inner diameter housing channel therethrough. 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 clamping assembly configured to clamp around the housing tube and/or the conductor to axially lock the housing tube and the conductor and to trap a shielding termination between the housing tube and the clamping assembly. The clamping assembly can form a clamping inner diameter channel sized to receive a shielded portion of the conductor.

The present disclosure discloses a cable pressing structure and a lamp. The cable pressing structure adapted to fix a cable on a carrying base, includes: a main portion and a first connecting portion and a second connecting portion provided at both ends of the main portion, respectively. The cable pressing structure is configured to being detachably connected to the carrying base through the first connecting portion and the second connecting portion, and press and fix the cable on the carrying base; the main portion has a first side surface and a second side surface facing away from each other, a first cable pressing portion is provided on the first side surface, and a second cable pressing portion is provided on the second side surface. The cable pressing structure has a first installation state and a second installation state.

The disclosure relates to a contact-making system for electromagnetically compatible high-current applications. The contact-making system includes a screw bushing, an actuating element and a clamping element. The clamping element includes at least one inner lateral surface and at least a first end face. The screw bushing includes a connecting thread on a first side of the screw bushing, for connection to a connecting geometry. The actuating element includes a counterpressure end face. An inner radius of the clamping element is reduced by means of a radial force. The actuating element is screwed to the first side of the screw bushing, where the radial force is applied to at least the first end face of the clamping element by screwing the actuating element to the screw bushing, and the counterpressure end face of the actuating element is brought into contact with a first end face of the clamping element.

A screw connection system can screw together at least one reinforced long molded part that includes at least one pressure element and a connecting part. The pressure element has a pressure contour. The connecting part has a clamping fixture. The clamping fixture includes a first inner clamping wall and a second outer clamping wall, between which a groove is formed. The pressure element can be applied to the connecting part, whereby the second outer clamping wall of the clamping fixture can be deformed by the pressure contour. The second clamping wall may be deformed radially inwards by the pressure contour. The second clamping wall may be deformable in the direction of the first clamping wall. The second clamping wall may be deformed such that it comes into contact with the first clamping wall when no reinforcement of a long molded part is arranged in the clamping fixture.

A cable gland assembly includes a gland nut defining a longitudinal axis. The gland nut includes an interior wall defining a gland nut opening and the interior wall includes a stop. A bushing is disposed within the gland nut opening proximate the stop. The bushing defines a bushing opening configured to receive a cable therein. A sleeve is moveably disposed within the gland nut opening adjacent the bushing. The cable gland assembly also includes a body defining a body opening configured to receive at least a portion of the cable therein. The body is configured to couple to the gland nut, and upon tightening of the gland nut to the body, the gland nut moves along the longitudinal axis compressing the bushing between the gland nut and the sleeve and around the cable. When the sleeve engages with the stop, further compression of the bushing is restricted.

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 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.