A first component, such as an electrical connector, can be mechanically connected to a second component, such as a surface, and separately electrically bonded to the second component using a third component, such as foil. The third component can be ultrasonically welded to the first component and separately ultrasonically welded to the second component. In some cases, multiple third components can be utilized to cover a seam between the first and second components.

A connector connection structure includes: a first connector; a second connector electrically connected to the first connector; a unit to which the first connector is ground-connected; and a seal member sealing a gap between the first connector and the unit. The unit has a hole portion that includes a first portion and a second portion having a diameter smaller than a diameter of the first portion. The first connector includes shield shell provided with a contact portion having a contact part that is to abut an inner peripheral surface. A radius of the first portion is larger than a distance from a central axis of an electric wire of the first connector to a contact part in a neutral state. A core wire of the electric wire is electrically connected to a terminal portion of the second connector via a terminal portion of the first connector.

A connector connection structure includes: a first connector; a second connector electrically connected to the first connector; a unit to which the first connector is ground-connected; and a seal member sealing a gap between the first connector and the unit. The unit has a hole portion that includes a first portion and a second portion having a diameter smaller than a diameter of the first portion. The first connector includes shield shell provided with a contact portion having a contact part that is to abut an inner peripheral surface. A radius of the first portion is larger than a distance from a central axis of an electric wire of the first connector to a contact part in a neutral state. A core wire of the electric wire is electrically connected to a terminal portion of the second connector via a terminal portion of the first connector.

Provided is a connector module providing superior shielding performance with small number of components. The connector module includes a terminal module having a center conductor, a tubular insulator holder supporting the center conductor and a tubular conductive shell, and a shield case. A bottom portion of the shield case includes a protruding portion bent from an edge of an opening portion through which the terminal module extends and protruding in a cylindrical form. The terminal module is joined to the shield case with an outer circumferential face of the conductive shell and an inner circumferential face of the protruding portion being placed in face contact with each other.

The connector includes: an axial member that is a cylindrical conductor; a central contact disposed inside along a central axis of the axial member; an insulating member interposed between the axial member and the central contact and which holds the central contact; a first flange and a second flange provided on an outer peripheral surface of the axial member; and a metal spring provided along an outer peripheral surface of the axial member. The metal spring includes: a C-shaped metal spring body; curved parts; elastic pieces that extend from the curved parts so as to face an outer peripheral surface of the metal spring body; inner protrusions provided on an inner peripheral surface of the metal spring body so as to protrude inside the metal spring body; and outer protrusions provided on outer peripheral surfaces of the elastic pieces so as to protrude outside the elastic pieces.

The technology of this application relates to a connector assembly including a metal housing, a conducting piece, a wire, and a shield layer. The metal housing includes a shield cavity. The conducting piece is accommodated in the shield cavity. The wire is partially located in the shield cavity and is electrically connected to one end of the conducting piece. The shield layer is wrapped around the wire. At least two electrical connecting parts are disposed on an outer surface of the shield layer. The at least two electrical connecting parts face different directions and are respectively electrically connected to parts, of the metal housing, that the at least two electrical connecting parts face, to reduce impact of crosstalk of the connector assembly. The connector assembly is intended to reduce impact of crosstalk of the connector assembly, to provide the connector assembly and the electronic device that meet an application requirement of 112 Gbps.

Connectors that support high-speed data transfers and have a high signal quality, good reliability, and are readily manufactured. One example can provide a connector receptacle that supports high-speed data transfers and has a high signal quality by employing contacts that are directly attached to a flexible circuit board.

The invention relates to an electrical plug-in connection, comprising an electrical connector and a mating electrical connector, which can be connected to the electrical connector. The mating electrical connector has an actuating element, which can be moved between a home position (P.sub.0) and a locking position (P.sub.1) and is designed to cooperate with a guiding element of the electrical connector in such a way that the plug-in connection, proceeding from a pre-latching position, assumes a locked position when the actuation element is moved from the home position (P.sub.0) into the locking position (P.sub.1). The electrical connector has a toothing and the mating electrical connector has a mating toothing, which corresponds to the toothing of the electrical connector, the toothing and the mating toothing mesh with one another in the locked position of the plug-in connection.

The invention relates to an electrical plug-in connection, comprising an electrical connector and a mating electrical connector, which can be connected to the electrical connector. The mating electrical connector has an actuating element, which can be moved between a home position (P.sub.0) and a locking position (P.sub.1) and is designed to cooperate with a guiding element of the electrical connector in such a way that the plug-in connection, proceeding from a pre-latching position, assumes a locked position when the actuation element is moved from the home position (P.sub.0) into the locking position (P.sub.1). The electrical connector has a toothing and the mating electrical connector has a mating toothing, which corresponds to the toothing of the electrical connector, the toothing and the mating toothing mesh with one another in the locked position of the plug-in connection.

The present disclosure provides a connector assembly. The connector assembly includes a wire-end connector. The wire-end connector includes a wafer, a shield plate and a twin-ax cable. The wafer includes a frame and a terminal group. The terminal group is supported by the frame. The terminal group includes a signal terminal pair and a ground plate. The ground plate includes a ground terminal on both sides of the signal terminal pair. The shield plate is electrically connected to the ground plate. The shield plate includes an opening that penetrates the shield plate. The twin-ax cable includes a pair of conductors and a ground portion. The pair of conductors extend into the opening of the shield plate and are electrically connected to the signal terminal pair. The ground portion electrically connects at least one of the shield plate and the ground plate.