A coaxial cable connector comprising an inner sleeve, a nut and an outer sleeve, wherein the inner sleeve includes a first outer flange, a first rear extension portion, and a first surface being between the first outer flange and the first rear extension portion; the nut includes an inner threaded surface, and a first inner flange being between the first outer flange and the first surface; the outer sleeve includes a second rear extension portion and a second inner flange being on the first surface and an annular space formed between the first and second rear extension portions, wherein the outer sleeve further comprises a second outer flange disposed on the out surface of the outer sleeve outside the annular space, wherein the second outer flange has a maximum diameter greater than an outer diameter of the second inner flange, and an axial distance between a front end of the second outer flange and a rear end of the outer sleeve is greater than twice of that between the front end of the second outer flange and a front end of the annular space.

The invention relates to an assembly comprising a plug connector and a cable (1) which is connected thereto and which has an inner conductor (2), a shielding (3), an insulation (4) between the inner conductor (2) and the shielding (3), and a jacket (5) pot which surrounds the aforementioned components, wherein a sleeve is added between the insulation (4) and the shielding (3) at a free IT end section of the cable (1), and a tubular component surrounds the shielding (3) and the sleeve.

The invention relates to an assembly comprising a plug connector and a cable (1) which is connected thereto and which has an inner conductor (2), a shielding (3), an insulation (4) between the inner conductor (2) and the shielding (3), and a jacket (5) pot which surrounds the aforementioned components, wherein a sleeve is added between the insulation (4) and the shielding (3) at a free IT end section of the cable (1), and a tubular component surrounds the shielding (3) and the sleeve.

A terminal of the present disclosure is the terminal to be connected to a wire including a core and includes a terminal body and a sliding portion. The terminal body includes a sandwiching portion. The sliding portion is slidable in a front-rear direction between a partial locking position and a full locking position. The sliding portion includes a pressurizing portion configured to press the sandwiching portion at the full locking position to sandwich the core in a first direction by the sandwiching portion, at least a pair of first contact portions configured to contact the core in the first direction when the core is inserted into the sliding portion, and at least a pair of second contact portions configured to contact the core in a second direction intersecting the first direction when the core is inserted into the sliding portion.

An electric energy transmission joint and a preparation method therefor. The electric energy transmission joint includes an electric energy transmission copper part, an electric energy transmission aluminum part (9), and an aluminum wire (3). The electric energy transmission copper part includes a fixer (1) for connection with an electric consumption device, and a connector (2) for connection with the electric energy transmission aluminum part (9). A first through hole is provided inside the electric energy transmission aluminum part (9), and a second through hole is provided inside the connector (2). An aluminum conductive core (4) exposed by stripping an insulation layer (5) from a front end of the aluminum wire (3) is inserted into a cavity formed by the connection of the first through hole and the second through hole. The electric energy transmission aluminum part (9) is connected to the aluminum wire (3) by crimping. The electric energy transmission copper part has the advantages of light weight, fast production, and reduced production cost.

An electric energy transmission joint and a preparation method therefor. The electric energy transmission joint includes an electric energy transmission copper part, an electric energy transmission aluminum part (9), and an aluminum wire (3). The electric energy transmission copper part includes a fixer (1) for connection with an electric consumption device, and a connector (2) for connection with the electric energy transmission aluminum part (9). A first through hole is provided inside the electric energy transmission aluminum part (9), and a second through hole is provided inside the connector (2). An aluminum conductive core (4) exposed by stripping an insulation layer (5) from a front end of the aluminum wire (3) is inserted into a cavity formed by the connection of the first through hole and the second through hole. The electric energy transmission aluminum part (9) is connected to the aluminum wire (3) by crimping. The electric energy transmission copper part has the advantages of light weight, fast production, and reduced production cost.

A crimping die including a first die piece having a recess portion and a second die piece having a protrusion portion is provided. An inner wall surface of the recess portion has a bottom wall surface and recess-side lateral end surfaces. An outer surface of the protrusion portion has a top end surface and protrusion-side lateral end surfaces. The bottom wall surface has a recess-side projection portion, a recess-side concave portion, and a recess-side curvature changing portion. The top end surface has a protrusion-side projection portion, a protrusion-side concave portion, and a protrusion-side curvature changing portion. A sign of curvature of the bottom wall surface changes at a boundary portion in the recess-side curvature changing portion with respect to the recess-side concave portion. A sign of curvature of the top end surface changes at a boundary portion in the protrusion-side curvature changing portion with respect to the protrusion-side concave portion.

A crimp ferrule includes an assembly portion assembled on a non-circular internal cross section of a multi-core cable and a diameter compensation portion forming a circular external cross section of the crimp ferrule on the multi-core cable. The assembly portion and the diameter compensation portion are arranged successively in an axial direction of the crimp ferrule.

A sealed stranded wire assembly includes one or more stranded wires. The one or more stranded wires includes a solid portion formed on or attached to the length of the one or more stranded wires. The solid portion prevents liquid, dust, or other contaminants from traveling along the length of the one or more stranded wires through voids within the one or more stranded wires.

A printed circuit board plug-in connection is provided for transmitting the highest possible currents between a printed circuit board and an electrical cable, the printed circuit board plug-in connection being manufactured as simply and economically as possible. For this purpose, a plug-in connection having a slotted pin contact is proposed. Said pin contact is arranged in an insulating body and can be inserted directly into a passage contact opening of a printed circuit board in order to establish electrical contact. The insulating body has detent arms, which releasably engage in detent openings of the printed circuit board in a locking manner at the same time. By means of dovetail connections, several insulating bodies can be fastened to each other, i.e., can be cascaded with each other. A strain relief element can also be fastened to an insulating body by means of the dovetail connection in order to provide strain relief for individual conductors of the cable.