A method is described for electrically connecting a coaxial conductor to a circuit carrier, in particular a printed circuit board. The circuit carrier has a top side and a bottom side, and printed conductors are situated at least on the top side of the circuit carrier. The coaxial conductor also includes an inner conductor and an outer conductor, the coaxial conductor being led, at least partially, from the bottom side of the circuit carrier through a feedthrough provided in the circuit carrier. In addition, at least one first contact conductor is used for electrically connecting the outer conductor to at least one first printed conductor of the circuit carrier, and at least one second contact conductor is used for electrically connecting the inner conductor to at least one second printed conductor of the circuit carrier. The first and the second contact conductors each have a press-in connection at at least one of their contact points with the circuit carrier or with the coaxial conductor.

A connection device includes a rod-shaped electrode, a plurality of cylindrical electrodes through which the rod-shaped electrode passes, the plurality of cylindrical electrodes being sequentially exposed on a surface in order from a front end side of the rod-shaped electrode, an insulation section configured to insulate the rod-shaped electrode and the plurality of cylindrical electrodes from each other, and a plurality of connection terminals electrically connected to the rod-shaped electrode and the plurality of cylindrical electrodes in a vicinity of a rear end of the rod-shaped electrode, the plurality of connection terminals being protruded from a rear side.

A connection device includes a rod-shaped electrode, a plurality of cylindrical electrodes through which the rod-shaped electrode passes, the plurality of cylindrical electrodes being sequentially exposed on a surface in order from a front end side of the rod-shaped electrode, an insulation section configured to insulate the rod-shaped electrode and the plurality of cylindrical electrodes from each other, and a plurality of connection terminals electrically connected to the rod-shaped electrode and the plurality of cylindrical electrodes in a vicinity of a rear end of the rod-shaped electrode, the plurality of connection terminals being protruded from a rear side.

The present disclosure relates to a coaxial connector, and particularly, a coaxial connector including a fixing module which is connected to a first PCB, and a contact module which is coupled movably to the fixing module, and provided to be contactable to a second PCB facing the first panel, in which the contact module includes a contact body which is made of a conductive material, and has a hollow formed therein, a contact pin which is made of a conductive material, and disposed to penetrate the hollow of the contact body, and a contact insulator which is disposed in the hollow of the contact body to insulate the contact pin and the contact body by partitioning the contact pin and the contact body, and the contact module is configured so that the contact body, the contact pin, and the contact insulator are integrally formed to be assembled to the fixing module by a singular process, thereby providing the advantages which may reduce the cost of a product, and improve the quality of the product by improving a contact rate.

The present disclosure relates to a coaxial connector, and particularly, a coaxial connector including a fixing module which is connected to a first PCB, and a contact module which is coupled movably to the fixing module, and provided to be contactable to a second PCB facing the first panel, in which the contact module includes a contact body which is made of a conductive material, and has a hollow formed therein, a contact pin which is made of a conductive material, and disposed to penetrate the hollow of the contact body, and a contact insulator which is disposed in the hollow of the contact body to insulate the contact pin and the contact body by partitioning the contact pin and the contact body, and the contact module is configured so that the contact body, the contact pin, and the contact insulator are integrally formed to be assembled to the fixing module by a singular process, thereby providing the advantages which may reduce the cost of a product, and improve the quality of the product by improving a contact rate.

An improved F-connector can be mounted perpendicularly on a printed circuit board to reduce radiated emissions by using an integrated shield flange on the F-connector body. The improved F-connector is attached to a shield frame that is part of an RF shield containment box mounted on the printed circuit board. In one embodiment, the shield flange is integral to the improved F-connector body and is manufactured to fill the gap between an RF shield frame and a corresponding RF shield cover. The improved F-connector with integral shielding flange mounted on the shield frame utilizes the shield flange of the improved F-connector to fill the physical gaps between the shield cover the improved F-connector. With reduced or eliminated physical gaps, the radiated emission of the assembly are either reduced or eliminated.

An improved F-connector can be mounted perpendicularly on a printed circuit board to reduce radiated emissions by using an integrated shield flange on the F-connector body. The improved F-connector is attached to a shield frame that is part of an RF shield containment box mounted on the printed circuit board. In one embodiment, the shield flange is integral to the improved F-connector body and is manufactured to fill the gap between an RF shield frame and a corresponding RF shield cover. The improved F-connector with integral shielding flange mounted on the shield frame utilizes the shield flange of the improved F-connector to fill the physical gaps between the shield cover the improved F-connector. With reduced or eliminated physical gaps, the radiated emission of the assembly are either reduced or eliminated.

A cable connection structure includes cables and a substrate having an electrode thereon. The cables are configured to be connected to the electrode. Each cable includes: a core wire formed of conductive material; a tubular inner insulator for covering an outer circumference of the core wire; a shield which extends along a longitudinal direction of the inner insulator and includes conductors for covering an outer circumference of the inner insulator, and has an exposed portion for exposing the inner insulator; and an outer insulator for covering an outer circumference of the shield. The shield including a region where the exposed portion is formed, the inner insulator, and the core wire are exposed in a stepped manner toward a distal end of each cable. The substrate includes a first electrode configured to be electrically connected to the core wire, and a second electrode configured to be electrically connected to the shield.

A cable connection structure includes cables and a substrate having an electrode thereon. The cables are configured to be connected to the electrode. Each cable includes: a core wire formed of conductive material; a tubular inner insulator for covering an outer circumference of the core wire; a shield which extends along a longitudinal direction of the inner insulator and includes conductors for covering an outer circumference of the inner insulator, and has an exposed portion for exposing the inner insulator; and an outer insulator for covering an outer circumference of the shield. The shield including a region where the exposed portion is formed, the inner insulator, and the core wire are exposed in a stepped manner toward a distal end of each cable. The substrate includes a first electrode configured to be electrically connected to the core wire, and a second electrode configured to be electrically connected to the shield.

Embodiments may comprise forming a rigid, tubular outer housing of an electrically conductive material; inserting an electrical cable longitudinally into the outer housing, the electrical cable having an inner conductor and a dielectric jacket surrounding the inner conductor; and, reshaping at least one longitudinal segment of the outer housing to fix the electrical cable inside the outer housing.