A circuit board including a through-hole into which a press-fit terminal portion is inserted in a depth direction; an inner wall land provided on an inner wall of the through-hole; and a plurality of inner layer lands which are provided in an inner layer of the circuit board, are planes substantially parallel to a mounting surface of the circuit board, and are in contact with the inner wall land. The inner wall land has a first region that is in contact with the press-fit terminal portion and a second region that is not in contact with the press-fit terminal portion. Among the plurality of inner layer lands, a first inner layer land, which is an inner layer land disposed on an identical surface with the first region of the inner wall land, is wider than a second inner layer land which is an inner layer land disposed on an identical surface with the second region of the inner wall land.

A power conversion device includes a printed circuit board, whose mounting surface is opposite to an annular surface formed by an annular stator that constitutes a motor, arranged to be separated from the annular surface with a predetermined distance, and mounted with a Hall element that detects a rotation position of a rotor of the motor on a mounting surface on a side of the stator; an inverter IC that is mounted on the mounting surface on the side of the stator of the printed circuit board to supply a high-frequency current to the stator; and an overheat detection unit that is mounted on the mounting surface on the side of the stator of the printed circuit board and detects an overheated state of the inverter IC. When the overheat detection unit detects an overheated state, the inverter IC restricts or stops a current to be supplied to the stator.

A wiring substrate includes a first substrate and an electronic component mounted on an upper surface of the first substrate. A first pad is formed on an uppermost wiring layer of the first substrate. A connection terminal is formed on the electronic component and is located proximate to the first pad in a plan view. The wiring substrate further includes a connection member formed on the first pad to electrically connect the first pad and the connection terminal. The connection member includes a rod-shaped core and a solder layer, which is coated around the core and joined to the first pad. The solder layer includes a bulge that spreads from the core of the connection member in a planar direction. The bulge is joined to the connection terminal of the electronic component.

A semiconductor module comprises a semiconductor device; a substrate, on which the semiconductor device is attached; a molded encasing, into which the semiconductor device and the substrate are molded; at least one power terminal partially molded into the encasing and protruding from the encasing, which power terminal is electrically connected with the semiconductor device; and an encased circuit board at least partially molded into the encasing and protruding over the substrate in an extension direction of the substrate, wherein the encased circuit board comprises at least one receptacle for a pin, the receptacle being electrically connected via the encased circuit board with a control input of the semiconductor device.

A selective segment via plating process for manufacturing a circuit board selectively interconnects inner conductive layers as separate segments within the same via. Plating resist is plugged into an inner core through hole and then stripped off after an electroless plating process. Stripping of the electroless plating on the plating resist results in a plating discontinuity on the via wall. In a subsequent electroplating process, the inner core layer can not be plated due to the plating discontinuity. The resulting circuit board structure has separate electrically interconnected segments within the via.

A method is described for solderless electrical press-in contacting of conductive press-in pins in circuit boards, the method comprising the following steps: Providing a circuit board having at least one contacting opening for press-in contacting; providing at least one press-in component having at least one conductive press-in pin; providing a sonotrode for exerting a force and for applying ultrasonic energy. In order to electrically and mechanically contact press-in pins to a circuit board by means of ultrasonic press-in technology, it is provided that the press-in component together with its press-in pin, is fixated during a press-in step, in particular held firmly in place, and that a force and ultrasonic energy are directly applied to the circuit board by means of the sonotrode such that the circuit board is pressed at the location of its contacting opening onto the press-in pin, not directly acted upon by the sonotrode, of the press-in component.

LED board interconnect schemes for illuminable assemblies are provided. Multiple LED boards may form a partial perimeter along an illuminable assembly. The multiple LED boards and interconnects must fit within a limited width and height of the illuminable assembly. In some implementations, an interconnect board and spring connectors are used to provide a low-profile electrical interconnection while maintaining co-planarity of the LEDs across the LED boards.

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.

A hermetically sealed filtered feedthrough for an active implantable medical device includes a first conductive leadwire extending from a first end to a second end, the first leadwire second end extending outwardly beyond the device side of an insulator hermetically sealed to a ferrule for the feedthrough. A circuit board supporting a chip capacitor is disposed adjacent to a device side of the insulator and has a circuit board passageway. The first leadwire first end resides in the circuit board passageway. A second conductive leadwire on the device side has a second leadwire first end disposed in the circuit board passageway with a second leadwire second end extending outwardly beyond the circuit board to be connectable to AIMD internal electronics. The second leadwire first end is connected to the first leadwire first end and a capacitor internal metallization in the circuit board passageway. The circuit board further comprises a ground electrode plate that is connected to the ground termination of the chip capacitor and to the ferrule.

3D electrical integration is provided by connecting several component carriers to a single substrate using contacts at the edges of the component carriers making contact to a 2D contact array (e.g., a ball grid array or the like) on the substrate. The resulting integration of components on the component carriers is 3D, thereby providing much higher integration density than in 2D approaches.