A PCB assembly includes a second PCB disposed adjacent to a first PCB and have a second hole facing a first hole, an upper plate disposed at an upper of the first and second hole and have a third hole disposed at the upper of the first hole and a fourth hole disposed at the upper of the second hole, a holder disposed at a lower of the first and second hole and have a lower plate having a fifth hole disposed at the lower of the first hole and a sixth hole disposed at the lower of the second hole, a first fixing screw penetrating through the third first, and fifth hole, and a second fixing screw penetrating through the fourth, second and sixth hole, and the lower plate includes a protrusion penetrating through the second PCB coupling the first PCB and the second PCB.

An independent loading mechanism for use with a CPU connector includes a metallic frame cooperating with a back plate module to sandwich a printed circuit board therebetween. A plurality of screw nut units are provided around the four corners of the frame. A plurality of hollow spacers are secured to the corresponding through holes of the frame so as to allow the corresponding screw nut units moveable relative to the frame along the vertical direction within a range larger than a thickness of the frame, thus avoiding improper interference between the screw nut units and the corresponding screw posts of the back plate module during sequential screwing.

Provided is a frame assembly for fixing a plurality of stacked battery cells. The frame assembly may include: a frame including an upper surface, a first side surface connected to a first end of the upper surface and a second side surface connected to a second end of the upper surface, the frame being configured to enclose the plurality of battery cells; a plurality of first bus bars disposed on the first side surface; a plurality of second bus bars disposed on the second side surface; and a flexible printed circuit board disposed along the upper surface, the first side surface, and the second side surface of the frame, the flexible printed circuit board being configured to sense the plurality of battery cells.

A semiconductor package assembly includes a circuit board, a heat dissipating element and a semiconductor device. The circuit board includes a conductive pattern. The heat dissipating element is located on the circuit board, where the heat dissipating element is connected to the conductive pattern. The semiconductor device is located on the circuit board and next to the heat dissipating element, where the semiconductor device is thermally connected to the heat dissipating element through the conductive pattern.

A semiconductor package assembly includes a circuit board, a heat dissipating element and a semiconductor device. The circuit board includes a conductive pattern. The heat dissipating element is located on the circuit board, where the heat dissipating element is connected to the conductive pattern. The semiconductor device is located on the circuit board and next to the heat dissipating element, where the semiconductor device is thermally connected to the heat dissipating element through the conductive pattern.

The present invention provides a camera module and a molding circuit board assembly, circuit board and application thereof, the circuit board comprising a digital circuit unit, an analog circuit unit and a substrate. The digital circuit nit and the analog circuit unit are respectively formed on the substrate, and the digital circuit unit and the analog circuit unit are conductively connected to each other, wherein at least one part of the analog circuit unit has a safe distance from the digital circuit unit, so as to prevent an electromagnetic wave generated by a circuit of the digital circuit unit from interfering with an electrical signal transmitted and processed by the analog circuit unit, thereby improving the stability and reliability of the transmission and the processing of the electrical signal by the circuit board.

A supporter for electronic parts includes: an adsorption plate which is attached to an upper surface of a first electronic part among the first electronic part and a second electronic part where the first electronic part and a second electronic part are spaced apart from each other on a plane; and a supporting member which includes 1) a first support part which supports a lower surface of the second electronic part and 2) a connection part which connects the adsorption plate and the first support part. On the plane, about 70-90% of the area of the first support part is overlapped with the second electronic part.

A fixing device for fixing a display card on a circuit board, includes a backplane and a support bracket. The backplane includes a substrate plate, and a first engaging part. The substrate plate is fixed on the display card. The first engaging part is disposed on the substrate plate. The support bracket includes at least one support leg and a second engaging part. The support leg includes a first end and a second end. The first end is connected with the circuit board. The second engaging part is connected with the second end and engaged with the first engaging part.

A power semiconductor module has a substrate, load and auxiliary connector elements, and a plastic body, which preferably is a housing or a housing frame and which has a channel. The channel being for the arrangement of a compensating portion of a press-fit contact element. The press-fit contact element has a press-fit portion, a compensating portion and a foot portion, the compensating portion being elastic in a longitudinal direction of the press-fit contact element and having at least two O-shaped sub-portions arranged in succession in the longitudinal direction and having a constriction arranged between two sub-portions.

A light source module includes a light-emitting device having an upper surface and a lower surface and including: at least one light-emitting element and a plurality of conductive regions on the upper surface of the light-emitting device; a mounting substrate having an upper surface on which a lower surface side of the light-emitting device is located, the mounting substrate including conductive patterns on the upper surface of the mounting substrate, each conductive pattern including a device-side connecting portion and an external side connecting portion; and a plurality of conductive members each having a first end bonded to a respective one of the device-side connecting portion and a second end opposite to the first end, the second end being in contact with a respective one of the conductive region by elasticity to electrically connect the respective one of the conductive regions and a respective one of the conductive patterns.