An electronic device including a coin-cell battery is provided. The electronic device further includes a housing, a battery comprising a first surface, a second surface, and a third surface, a first electrode disposed in the first surface and a second electrode disposed in the second surface, a first electrode tap, a second electrode tap, and a printed circuit board connecting the first electrode tap to the second electrode tap of the battery on the third surface. Soldering parts are formed on a first surface of the printed circuit board to connect an end of the first electrode tap to a first contact portion of the printed circuit board and an end of the second electrode tap to a second contact portion of the printed circuit board, respectively. A solder flow control member is formed on a second surface of the printed circuit board.

A multilayer structure includes a first insulating layer including a first body of an anodized oxide material, a first via conductor penetrating through the first body, and a first internal wiring layer electrically connected to the first via conductor, a second insulating layer including a second body of the anodized oxide material, a second via conductor penetrating through the second body, and a second connection pad electrically connected to the second via conductor, and a solder hump provided on one of the first internal wiring layer and the second connection pad and between the first insulating layer and the second insulating layer. The first via conductor, the first internal wiring layer, the second connection pad, and the second via conductor are electrically connected to each other through the solder bump.

Aspects of the invention include a press-fit pin for mechanically and electrically connecting to a through-hole of a substrate. The press-fit pin can include a press-fit portion configured to be deformed upon insertion into the through-hole against a plated surface of the through-hole. A surface mount technology (SMT) pad can be coupled to a first end of the press-fit portion. The SMT pad can include a conductive material. The press-fit pin can further include a trace extension coupled to the SMT pad. The trace extension can extend from the SMT pad in a direction perpendicular to the press-fit portion. The press-fit pin can include a tip portion coupled to a second end of the press-fit portion.

The invention relates to a method for manufacturing a component (1) comprising a printed circuit board (2) and a number of electrical components (3) arranged thereon. According to the invention, the electrical components (3) are pre-fixed on the printed circuit board (2), which is formed of plastic, by means of a fixing adhesive (9) and then completely encapsulated with an UV-adhesive (8).

A high-current contact device includes a first contact element transmitting electrical energy, a circuit carrier, a first data contact transmitting data, and a data interface. The first contact element extends through the circuit carrier along a mating axis at a feedthrough. A conductor track of the circuit carrier electrically connects the first data contact to the data interface. A carrier of the circuit carrier is injection-molded and mechanically supports the first data contact, the conductor track, and the data interface.

An electronic device includes a first board, a second board, and support pillars. The support pillars hold the first board and the second board mutually separated. The first board has a first surface on which an electronic component is mounted. The first board has a second surface that includes depressed portions into which the support pillars extending from the second board are inserted.

A 3D printed circuit apparatus includes a 3D printed circuit having a surface layer and one or more wires embedded under the surface layer, and a conductive metal pin that is cut to a desired length and inserted into the 3D printed circuit in order to attain contact with the wire or wires embedded under the surface layer.

A printed circuit assembly (PCA) that provides for a method of rebuilding an electrically operated automatic transmission solenoid module. The PCA allows for a repairable yet rugged interconnection of several solenoids that reside within the span of the module assembly.

A power semiconductor module includes an insulating circuit substrate; a printed circuit board disposed over the insulating circuit substrate; and a plurality of terminals each having a rod-shaped portion and including a first protrusion and a second protrusion each protruding laterally form a side face of the rod-shaped portion; wherein at least one of the plurality of terminals is inserted to one of the through-holes of the printed circuit board and is locked to the one of the through-holes via the first protrusion, and wherein at least another one of the plurality of terminals is inserted to another one of the through-holes of the printed circuit board and is locked to said another one of the through-holes via the second protrusion, and an end of the at least another one of the plurality of terminals is electrically connected to a conductive plate on the insulating circuit substrate.

A connectable assembly is provided and includes a body defining a recess, a male conductive element supportively disposed proximate to the body and a conductive compliant (CC) plug disposed within the recess for establishing a radially compliant, axially free running electrical connection with the male conductive element.