A connection assembly, including: a first connector having a first end and a second end, and a first surface extending between the first end and the second end, the first connector including press fit pins extending away from the first surface, each of the press fit pins including: a rod portion; a connecting portion having a first shape; a second connector having a first end and a second end, including: a dielectric carrier having a first surface extending between the first end and the second end of the second connector, receptacles positioned within the first surface of the dielectric carrier, each of the receptacles including: a cylindrical region, a tapered region having a second shape that corresponds to the first shape of the connection portion, wherein, when the first connector is coupled to the second connector, the press fit pins are positioned within respective receptacles of the receptacles.

An electrical device housing comprises a body defining a component space, a pin support structure, and an alignment element. The pin support structure is arranged within the component space and defines a plurality of openings sized to receive and support a plurality of conductive pins of a connector to be secured to the housing. The alignment element is formed on an exterior surface of at least one of a top or bottom side of the housing and is located to engage with a corresponding alignment element formed on the other one of the top or bottom side of another one of the housings.

An eye-of-needle terminal, comprising a base portion (1), a pin portion (3), and an elastic portion (2) disposed between the base portion and the pin portion. The elastic portion is provided with an eye-of-needle hole (4), and the extension direction of the eye-of-needle hole is the same as that of the elastic portion. The eye-of-needle hole comprises flared holes (42) located at both ends and a connecting hole (41) located between the two flared holes. The width of the end of each flared hole facing the connecting hole is greater than the width of the end distant from the connecting hole. Thereby not only ensuring that the eye-of-needle terminal is very easy to insert, but also ensuring that the eye-of-needle terminal forms a good connection with a conductive through hole after being inserted and does not easily come out of the conductive through hole.

A backplane connector includes a housing and a number of wafers assembled to the housing. Each wafer includes a number of conductive terminals, an insulating frame and a metal shield. The housing includes an insulating housing and a metal shell fixed to the insulating housing. The insulating housing includes a number of slots for positioning the wafers. The metal shell is provided with a mating surface and a number of terminal receiving grooves. The contact portions of the conductive terminals are exposed in the corresponding terminal receiving grooves. The present disclosure improves the structural strength of the backplane connector and reduces the risk of damage the mating surface due to the push or collision of a mating connector.

An electrical interconnect for passing high speed signals through an electronic system with a high density of signals and high signal integrity. The interconnect includes an electrical connector and a transition portion of a printed circuit board to which the connector is mounted. Signal conductors are connected to pads on the surface of the PCB using edge-to-pad mounting. The pads align with intermediate portions of the signal conductors such that transitions within the connector that could degrade signal integrity are avoided. The signal conductors may be positioned as individually shielded broadside coupled pairs extending in rows within the connector. Surface traces on the PCB connect the pads to signal vias aligned for vertical routing out of the connector footprint. Ground planes underlying the surface traces facilitate a transition from the signal paths in the connector to those in the PCB with low mode conversion avoiding resonances in the connector shields.

In a connector, movement of a contact is appropriately restricted in detaching a counter connector from the connector. The connector fittable with the counter connector in a first direction includes the contact and a housing. The contact includes: a press-fitted portion press-fitted into the housing in a second direction intersecting the first direction; an extension portion that extends from the press-fitted portion in a third direction intersecting the first and the second directions; and a contact portion that extends from the extension portion and contacts the counter contact. The housing includes a protrusion portion that protrudes from a rising portion in the third direction. In a state where the press-fitted portion is press-fitted in the housing, a surface of a distal end portion in the third direction of the extension portion contacts the protrusion portion, which surface faces a side where the counter connector is situated.

A printed circuit board corner connector designed to connect a first printed circuit board to a second printed circuit board, having a substantially flat contact body, from which a first connection end for connecting to the first printed circuit board extends, wherein two soldering pins for producing a soldered connection to the second printed circuit board protrude from a lateral surface of the contact body, wherein depressions are provided on lateral surface lying opposite lateral surface in positions corresponding to the soldering pins.

A method of forming a semiconductor device includes providing a power electronics carrier including a structured metallization layer disposed on an electrically insulating substrate, mounting one or more semiconductor dies on a portion of the structured metallization layer, forming an encapsulant body of electrically insulating material that covers the power electronics carrier and encapsulates the one or more semiconductor dies, securing a press-fit connector to the power electronics carrier with a base portion of the press-fit connector being disposed within an opening in the encapsulant body and with an interfacing end of the press-fit connector being electrically accessible from outside the encapsulant body.

A power converter, for a vehicle that is at least partially electrically powered, has a first printed circuit board with DC link capacitors, a circuit breaker group for each alternating current phase, and terminals for alternating current busbars and direct current busbars. A second printed circuit board has a control apparatus for actuating the circuit breaker groups. Also, it has a respective signal pin carrier for the respective circuit breaker group. The signal pin carrier connects the first and the second printed circuit board. Thus, signals between the first and the second printed circuit board can be transmitted via the respective signal pin carrier. The signal pin carrier has six signal pins that are arranged on a plastic carrier.

An electrical connector includes an insulating body, a number of first conductive terminals, a number of second conductive terminals, and a number of cables. The first conductive terminals include a number of first signal terminals and a number of first ground terminals. The second conductive terminals include a number of second signal terminals and a number of second ground terminals. The cables include a number of first cables electrically connected with the first signal terminals and a number of second cables electrically connected with the second signal terminals. The first ground terminals and the second ground terminals are connected to each other and are adapted to be electrically connected to a circuit board. With this arrangement, the present disclosure avoids ground return through cables, thereby simplifying the grounding method and improving the stability of signal transmission. The present disclosure also discloses an electrical connector assembly having the electrical connector.