This electrical connection socket for relaying exchange of electrical signals between a first electrical component and a second electrical component, is provided with: a metallic casing which has a communication hole for communication between the upper surface and lower surface of the metallic casing, to the lower surface side of which the first electrical component is attached, and to the upper surface of which the second electrical component is attached; a signal pin which is disposed in the communication hole so as to be separated from the inner wall surface of the communication hole, one end of which is electrically connected to a terminal of the first electrical component, and the other end of which is electrically connected to a terminal of the second electrical component; an annular first holding member which is, in the upper region of the communication hole, press-fitted in the communication hole; and an annular second holding member which is, in the lower region of the communication hole, press-fitted to the outer circumferential surface of the signal pin, wherein the signal pin is fixed in the communication hole so as to be held by the metallic casing from above and from below via the first and second holding members.

A conductive terminal comprises a pair of abutting plate-shaped body parts having a front side and a rear side opposite to each other in a thickness direction thereof, and a left side and a right side opposite to each other in a width direction thereof. An insertion part extends from one of the two body parts. The terminal further includes a pair of first supporting wings arranged on the front side and the rear side of the body parts and aligned with each other at edges of the left side of the two body parts, respectively, and a pair of second supporting wings arranged on the front side and the rear side of the two body parts and aligned with each other at edges of the right side of the two body parts, respectively.

A contact includes a hollow box-shaped main body portion into which a plate-shaped counterpart contact is inserted in an insertion direction. A pair of inward slantwise elastic piece portions are provided in a manner extending in the insertion direction from a pair of opposed edge portions of the insertion opening of the main body portion into the main body portion. The pair of elastic piece portions have contact portions arranged in mutually proximal portions. A pair of restricting portions provided on the main body portion are arranged to restrict the amount of deformation of the pair of elastic piece portions when the counterpart contact is inserted. (Selected figure: FIG. 6)

The present disclosure provides a connector that comprises a housing and wafers. The housing comprises a top wall and a bottom wall separated from each other in a mounting direction. The wafers are mated to the housing in a mating direction and supported by the housing. A first wafer is configured to be limited in the mounting direction. A second wafer is configured to be limited in the mating direction. A possible benefit from a match between a limiting block of the first wafer and a limiting groove of the housing and a match between the limiting block of the first wafer and a limiting opening of the housing is that the first wafer is less easy to move between the top wall and the bottom wall of the housing along the mounting direction and can be more firmly supported by the housing.

A routing assembly for an electronic device has a plurality of connectors ports and each of the connector ports contains a first connector connected to one or more cables. Cables are directly terminated, at first ends thereof, to terminals of the first connectors and the cables can be embedded in a routing substrate. The routing substrate has an opening which accommodates a chip package. Second ends of the cables are terminated to second connectors arranged in the package opening and the second connectors are in turn connected to the chip package.

An electrical connector includes a mating section for receiving the mating tab therein. The mating section has a first contact arm and a second contact engagement arm. The first contact engagement arm is spaced from the second contact engagement arm by a first slot. The first contact arm has a first length which is different than a second length of the second contact arm. A first normal force exerted by the first contact arm on the mating tab is equal to a second normal force exerted by the second contact arm.

An electric connection socket for relaying electric signals between a circuit substrate and an electric component includes: a metal housing which has a through hole enabling communication between the top surface and the bottom surface thereof, and on the top surface of which the electric component is mounted and on the bottom surface of which the circuit substrate is mounted; and a signal pin inserted into the through hole to configure a coaxial line between the inner wall surfaces of the through hole, and which is electrically connected at one end to a signal path pad electrode of the circuit substrate and is electrically connected at the other end to a signal path terminal of the electric component. The metal housing is arranged on the circuit substrate such that an air gap is formed between the bottom surface of the metal housing and the top surface of the circuit substrate.

A printed circuit board (PCB)-mounted contactor including a PCB with planar surface, source and load terminals fixed to the PCB, and a contact. The contact is supported by the PCB and is movable between open and closed positions. Movement of the contact is parallel to the planar surface. Electrical assemblies having PCB-mounted contactors and methods of controlling current flow in electrical systems with PCB-mounted contactors are also described.

In some embodiments, an apparatus includes a first connector including a first housing portion having top and bottom surfaces and a second connector including a second housing portion having top and bottom surfaces. The second housing portion has a form factor substantially corresponding to a form factor of the first housing portion. A circuit board having top and bottom surfaces is permanently coupled to the first housing portion and to the second housing portion such that a first portion of the bottom surface of the circuit board contacts at least a portion of the top surface of the first housing portion and a second portion of the bottom surface of the circuit board contacts at least a portion of the top surface of the second housing portion. A contact assembly is coupled to the first housing portion and electrically and directly engages a portion of the bottom surface of the circuit board.

A contacting device for electrical contacting of a printed circuit board with a coil body for a solenoid valve for a brake device for a vehicle, including: a helical electrically conductive contact spring which is configured to be contacted or being contactable with the printed circuit board at a first spring end and configured to be contacted or being contactable with the coil body at a second spring end, situated opposite the first spring end, to enable a resilient electrical contacting of the printed circuit board with the coil body; and a pin which is receivable or has been received in an interior space of the contact spring, the pin being configured to support the contact spring from the interior space in a received state received in the interior space. Also described are a related solenoid valve, method, and computer readable storage medium.