A coaxial connector includes a plug and a receptacle that are electrically connectable to each other. The plug includes a first contact, a holder, a first tubular shell, and a shield member. The receptacle includes a second contact, a case, and a second tubular shell. The second contact includes a bottom portion, a pair of standing portions, and an extension. The pair of standing portions include respective contact portions having a wide shape and can clamp an end portion of the first contact. The extension includes a tip portion that is to be fixed to a substrate, a hold that is held by the case, and an elastic portion that is elastically deformable. The elastic portion can undergo elastic deformation in a direction orthogonal to a direction in which the contact portions extend.

The present invention relates to a cavity filter and a connecting structure included therein. The cavity filter includes: an RF signal connecting portion spaced apart, by a predetermined distance, from an outer member having an electrode pad provided on a surface thereof; and a terminal portion configured to electrically connect the electrode pad of the outer member and the RF signal connecting portion so as to absorb assembly tolerance existing at the predetermined distance and to prevent disconnection of the electric flow between the electrode pad and the RF signal connecting portion, wherein the terminal portion includes: a first side terminal contacted with the electrode pad; and a second side terminal having a housing space in which a part of the first side terminal is housed, and connected to the RF signal connecting portion, wherein the first side terminal is provided as an elastic deformable body whose part is radially widened or narrowed against an assembly force provided by an assembler. Therefore, the cavity filter can efficiently absorb assembly tolerance which occurs through assembly design, and prevent disconnection of an electric flow, thereby preventing degradation in performance of an antenna device.

The present disclosure concerns a connector system, e.g., for connecting an electrical component with a circuit board. The connector system includes an electrical heater-function-component having an electrical component-contact-surface for an electrical connection of the electrical heater-function-component. A circuit-board having an electrical board-contact surface is provided for an electrical connection of the circuit-board. A connector assembly connects the heater-function-component with the circuit-board. The connector assembly is arranged at the electrical component-contact-surface and the electrical board-contact-surface for connecting the heater-function-component with the circuit-board.

It is aimed to provide a connector device excellent in the reliability of a connecting operation. A connector device (A) is provided with a second housing (21) to be mounted on a second circuit board (C), a plurality of fixed terminal units (28) to be mounted in the second housing (21) and connected to the second circuit board (C), a plurality of movable terminal units (35) individually rockable with the plurality of fixed terminal units (28) as fulcrums and to be being individually connected to a plurality of first terminal units (16), and a coupling member 50 including a hooking portion (51) to be hooked to the plurality of movable terminal units (35), the coupling member 50 integrally rocking the plurality of movable terminal units (35).

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 present invention relates to a fixed connector including a body fixedly inserted into a substrate, a signal pin having one side inserted into the body and the other side extending from the one side to be disposed on the substrate, and a dielectric coupling the signal pin and the body, wherein a portion of the signal pin has an L shape to be in contact with the substrate, and the portion of the signal pin is exposed to an outside of the body.

A connector is disposed on a board in a first direction and includes a housing, a contact, and a movable. The housing is provided with a bottom surface facing the board and a through hole formed along the first direction. The contact is held in the through hole and has its end portion on a board side exposed at the bottom surface via the through hole. The movable terminal is formed as a separate member from the contact, disposed at a close position to the contact in the through hole, and movable in the first direction relative to the contact. One end of the movable terminal in the first direction is fixed to the board and projects from the bottom surface in accordance with movement of the movable terminal, and a projection amount of the one end changes depending on a position of the movable terminal in the first direction.

A circuit arrangement (1), in particular for an electrically driven motor vehicle, has at least one bus bar (5) which is connected electrically to a supplier (2) and which is connected to a first consumer (3) at a first transfer point (6) and to a second consumer (4) at a second transfer point (7). Both the first and the second transfer point (6, 7) are formed as flexible contact points.

The present invention relates to a connector for preventing a characteristic impedance mismatch, the connector including a stationary module fixed, by soldering, to any one (hereinafter, referred to as a ‘first panel’) of two panels disposed in parallel with each other, the stationary module having therein an impedance matching space (hereinafter, referred to as a ‘matching space’), a moving module disposed to move to the inside or outside of the matching space of the stationary module and provided to be in contact with the other (hereinafter, referred to as a ‘second panel’) of the two panels, and an elastic member disposed in the matching space of the stationary module and configured to elastically support the moving module on the second panel, in which the elastic member, together with an external conductor part of the moving module, performs a function of blocking static electricity, which makes it possible to manufacture a product with a reduced size and prevent a characteristic impedance mismatch.

The present invention relates to a connector for preventing a characteristic impedance mismatch, the connector including a stationary module fixed, by soldering, to any one (hereinafter, referred to as a ‘first panel’) of two panels disposed in parallel with each other, the stationary module having therein an impedance matching space (hereinafter, referred to as a ‘matching space’), a moving module disposed to move to the inside or outside of the matching space of the stationary module and provided to be in contact with the other (hereinafter, referred to as a ‘second panel’) of the two panels, and an elastic member disposed in the matching space of the stationary module and configured to elastically support the moving module on the second panel, in which the elastic member, together with an external conductor part of the moving module, performs a function of blocking static electricity, which makes it possible to manufacture a product with a reduced size and prevent a characteristic impedance mismatch.