A clamping assembly for attaching a grounding conductor to a pipe having a protective coating includes an elongate conductive strap and a clamp. The conductive strap is sufficiently long to circumferentially surround the pipe and has longitudinally spaced sharp projections that are sufficient to penetrate the protective coating around the pipe to make an electrical coupling between the strap and a conductive part of the pipe beneath the protective coating. The clamp is coupled to the grounding conductor and clamps the conductive strap to the pipe at a tension sufficient to maintain an electrical connection between the conductive part of the pipe and the grounding conductor without the need for any welding of the grounding conductor to the pipe and without the need for any stripping of the protective coating from the pipe.

A shield structure includes a hollow tubular shield member, a shield shell having a plate-like shell body which is formed with a through hole, and a plate-like bent piece which is extended from an inner edge of the shell body that defines the through hole and which is bent to rise from the shell body, and an annular member which surrounds and fastens the bent piece, wherein at least one bent piece of the shield shell is extended from the inner edge of the shell body, and when the annular member surrounds and fastens the bent piece an outer surface of which is covered with a leading end in the longitudinal direction of the shield member, the leading end is clamped between the annular member and the bent piece.

A shield structure includes a hollow tubular shield member, a shield shell having a plate-like shell body which is formed with a through hole, and a plate-like bent piece which is extended from an inner edge of the shell body that defines the through hole and which is bent to rise from the shell body, and an annular member which surrounds and fastens the bent piece, wherein at least one bent piece of the shield shell is extended from the inner edge of the shell body, and when the annular member surrounds and fastens the bent piece an outer surface of which is covered with a leading end in the longitudinal direction of the shield member, the leading end is clamped between the annular member and the bent piece.

A cable assembly comprising a termination with at least one conductive, compressible member and a conductive ground shield. The conductive, compressible member may be held within a connector module forming the termination such that the conductive compressive member is pressed against, and therefore makes electrical contact with, both an outer conductive layer of the cable and ground structures within the connector module. In some embodiments, these connections may be formed using a conductive, compressible member with an opening configured to receive the end of the cable therethrough. The conductive ground shield may be configured to compress the conductive, compressible member, and to cause the conductive, compressible member to electrically contact the cable's conductive layer. The conductive, compressible member may be formed from a compressible material and may comprise a plurality of conductive particulates configured to provide electrically conductive paths.

A plug connector suitable for use as an airbag squib connector is presented. The plug connector includes a connector housing, having a plug-in portion and at least one female contact terminal that is arranged at least partially in the plug-in portion. The plug connector further includes a grounding contact, having an intermediate section and a contact section formed from sheet metal. The sections have respective main surfaces and circumferential edges. The contact section is configured to electrically contact a corresponding grounding contact of a counter-connector. The intermediate section branches off from the contact section. The main surfaces of the intermediate section and the contact section are parallel to the mating direction.

A heavy-duty plug-in connector has a ground terminal that can be conveniently assembled and can comprise the greatest possible number of electrical crimp plug-in contacts (4,5). For this purpose, ground plug-in contacts (4′, 5′), likewise of a crimping configuration, are fitted in formations (13, 13′, 23, 23′) of the contact carriers (1, 2) for electrical contacting with metallic protective earthing elements (3, 3′, 3″, 3″). For said contacting, the formations (13, 13′, 23, 23′) have a respective opening (130, 130′) or passage (230, 230′). In the formations (13, 13′, 23, 23′), not only ground plug-in contacts (4′, 5′) but also further plug-in contacts (4, 5) are arranged, so that the number of plug-in contacts (4, 5) of the plug-in connector is increased considerably.

A heavy-duty plug-in connector has a ground terminal that can be conveniently assembled and can comprise the greatest possible number of electrical crimp plug-in contacts (4,5). For this purpose, ground plug-in contacts (4′, 5′), likewise of a crimping configuration, are fitted in formations (13, 13′, 23, 23′) of the contact carriers (1, 2) for electrical contacting with metallic protective earthing elements (3, 3′, 3″, 3″). For said contacting, the formations (13, 13′, 23, 23′) have a respective opening (130, 130′) or passage (230, 230′). In the formations (13, 13′, 23, 23′), not only ground plug-in contacts (4′, 5′) but also further plug-in contacts (4, 5) are arranged, so that the number of plug-in contacts (4, 5) of the plug-in connector is increased considerably.

A method for manufacturing a metal shell of an electrical connector, includes: S1: providing a tube, where a mating opening is formed at an opening of the tube, for a tongue of a mating connector to be inserted therein; S2: rolling a perimeter of the mating opening inward to form a flanging, where the flanging is configured to guide the mating connecter to enter the tube; and S3: cutting the flanging using laser, so that an aperture of the mating opening is enlarged to a predetermined size. A metal shell manufactured by the above method, and an electrical connector having the metal shell.

A dielectric barrier for use with a lightning arrestor connector comprises a plurality of physically connected cells defining a hollow, tubular side wall, with each cell including a frame formed from dielectric material and an aperture that creates a void within the frame. The dielectric barrier is configured to be positioned between an inner conductor and an outer conductor and provides a low resistance path from one conductor to the other conductor when the voltage between the two conductors exceeds a threshold value.

A dielectric barrier for use with a lightning arrestor connector comprises a plurality of physically connected cells defining a hollow, tubular side wall, with each cell including a frame formed from dielectric material and an aperture that creates a void within the frame. The dielectric barrier is configured to be positioned between an inner conductor and an outer conductor and provides a low resistance path from one conductor to the other conductor when the voltage between the two conductors exceeds a threshold value.