The method of mounting an electronic component onto a substrate by a reflow process, the electronic component having at least one first terminal provided along one side of the electronic component and at least one second terminal provided along another side of the electronic component opposed to the one side, the substrate having a first copper foil pattern to which the at least one first terminal is soldered and a second copper foil pattern to which the at least one second terminal is soldered, the method including applying a first solder cream portion to the first copper foil pattern and applying a second solder cream portion to the second copper foil pattern.

An electrical connection box includes: a box main body; an electric circuit body loaded into the box main body; a grounding member provided in the electric circuit body; a belt-like grounding metal plate extending from the grounding member to the outside of the box main body; a fixing bracket extending integrally with the box main body and including the grounding metal plate; and a bolt through hole formed through a tip end portion of the fixing bracket to electrically connect the grounding metal plate to a bolt to be inserted.

The disclosure relates to a method for contacting a contact surface on a flexible circuit board with a metal contact outside the flexible circuit board, with the aid of a press-fit pin. An attachment piece having a sleeve for receiving the press-fit pin is a mechanically and electrically coupled to the flexible circuit board.

A microchip includes a PCB, a first contact feature positioned along a first area of the PCB, a second contact feature positioned along a second area of the PCB that is disposed opposite the first area, a contact frame including first and second contact members respectively coupled to the first and second contact features for signal communication between the first and second contact features and an external electronic device, and a housing enclosing an interior region of the microchip and carrying the first and second contact members of the contact frame.

Aspects of the embodiments include an edge card and methods of making the same. The edge card can include a printed circuit board (PCB) comprising a first end and a second end, the first end comprising a plurality of metal contact fingers configured to interface with an edge connector, and the second end comprising a through-hole configured to mate with a post of a screw, the PCB further comprising an aperture proximate the second end of the PCB. The PCB can also include a thermal conduction element secured to the PCB, the thermal conduction element supporting an integrated circuit package, the integrated circuit package received by the aperture, wherein the thermal conduction element contacts the PCB proximate the through-hole and the thermal conduction element is configured to conduct heat from the integrated circuit towards the second portion of the printed circuit board.

A connector device that includes a circuit board; a connector attached to the circuit board; a plurality of collars for external attachment; a first molded resin that is made of a first resin material whose melting point or softening point is 230 C. or less, and covers the entire circuit board and part of the connector; and a second molded resin that is welded to the first molded resin, is made of a second resin material whose melting point or softening point is higher than that of the first resin material for the first molded resin, and covers outer circumferences of the collars.

A board element for board-to-board interconnect formation is provided. An embodiment includes embedding a signal via element in the board element and cutting through respective sections of the board element and the signal via element to expose a new board element edge and an outwardly facing surface of the signal via element.

A connector assembly is disclosed to reduce discontinuity impedance between golden finger connectors and components on a circuit board. The assembly includes a circuit board including a connector edge. A plurality of connectors is formed on the connector edge on a first surface of the circuit board. A ground plane is formed on part of the circuit board on a second opposite surface of the first surface. The ground plane leaves the second opposite surface under the connector edge exposed. A ground loop is formed on the second opposite surface under at least two of the plurality of connectors.

A method for modifying a low-cost small form factor pluggable optical-electrical bidirectional transceiver (hereinafter SFP transceiver) by converting the SFP transceiver into a dual-in-line package. Such conversion enables the SFP transceiver to be soldered directly on a printed circuit board of a line replaceable unit of an avionics system, thereby eliminating the concern that the SFP transceiver may become detached due to vibration during aircraft operation. The method also includes a sealing process to protect the contact pads on the SFP transceiver, thereby eliminating any concern that the contact pads could corrode due to long-term moisture and humidity exposure. The product of the method is a ruggedized SFP transceiver capable of withstanding the rigors of operating in a harsh avionics environment onboard an aircraft.

Aspects of the embodiments include an edge card and methods of making the same. The edge card can include a printed circuit board (PCB) comprising a first end and a second end, the first end comprising a plurality of metal contact fingers configured to interface with an edge connector, and the second end comprising a through-hole configured to mate with a post of a screw, the PCB further comprising an aperture proximate the second end of the PCB. The PCB can also include a thermal conduction element secured to the PCB, the thermal conduction element supporting an integrated circuit package, the integrated circuit package received by the aperture, wherein the thermal conduction element contacts the PCB proximate the through-hole and the thermal conduction element is configured to conduct heat from the integrated circuit towards the second portion of the printed circuit board.