An electronic component mounting structure includes a first land, a second land making a pair with the first land, an electronic component having a chip shape and including a first electrode connected to the first land and a second electrode connected to the second land, a first wiring pattern connected to the first land, and a second wiring pattern connected to the second land and including a first partial pattern overlapping a portion of a body of the electronic component in planar view, the portion being not covered with the pair of electrodes, a second partial pattern formed integral with the first partial pattern and overlapping the first electrode of the electronic component in planar view, and a third partial pattern formed integral with the second partial pattern and parallel to the first wiring pattern.

According to one embodiment, a electronic module includes a circuit board including an electronic component mounted thereon, a flexible conducting member including a conductor including a portion covered with a covering member and a portion exposed from an edge of the covering member and soldered to the circuit board, and an engagement member engaging with the flexible conducting member to place the engaged flexible conducting member in a predetermined position on the circuit board and is attached to the circuit board by an attachment method the same as a method of mounting the electronic component on the circuit board.

An inductor includes a magnetic core, a first winding, a first electrically conductive standoff, and a second electrically conductive standoff. The magnetic core includes opposing first and second outer surfaces separated from each other in a first direction. The first winding has first and second ends, and the first winding is wound around at least a portion of the magnetic core. The first electrically conductive standoff is connected to the first end of the first winding, and the first electrically conductive standoff extends along the magnetic core in the first direction from the first outer surface to the second outer surface. The second electrically conductive standoff is connected to the second end of the first winding, and the second electrically conductive standoff extends along the magnetic core in the first direction from the first outer surface to the second outer surface.

According to an embodiment of the present disclosure, since the electronic components are fixed on the PCB by the clamp, post processing, such as soldering or application of an adhesive, may be not needed. Also, since the PCB can be spaced from the adjacent configurations by the clamp, the efficient layout of the PCB is possible, resulting in an improvement of productivity of the PCB. In accordance with an aspect of the present disclosure, there is provided a clamp comprises a fixing part configured to surround at least one part of the outer surface of an electronic component, a connection part extending from the fixing part, and penetrating a Printed Circuit Board (PCB), an interference part provided in at least one of the fixing part or the connection part, and configured to be interfered by the PCB and a spacing part protruding from at least one of the connection part or the fixing part.

An assembly provides a dual function for mounting a port connector on a circuit board and also secures a capacitor to the circuit board. The assembly includes the circuit board and a monolithic plastic frame having a flange, a snap structure, a capacitor cradle, and a socket section. The flange has a fastening structure for fastening the frame to the circuit board. The snap structure for a snap-in attachment of the port connector to the frame is arranged near an end edge of the circuit board. The capacitor cradle for holding a cylindrical capacitor is formed adjacent to the snap structure and is elevated from the circuit board by an air gap. The socket section bears socket contacts for receiving capacitor contact leads.

A holder structure for mounting light indicators on printed circuit boards using surface mount technology at a position elevated above the surface of the board is provided with a body member including a top wall, a bottom wall, opposed sidewalls, a front wall, and a rear wall, all being formed integrally together. Two spaced-apart recesses are formed and aligned vertically in the front wall of the body member terminating in respective first and second interior wall portions. The first interior wall portion has openings formed on diametrically opposed sides of a vertical partition and lying in a horizontal plane parallel to the bottom wall. The second interior wall portion has openings formed on diametrically opposed sides of a transverse partition and lying in a plane which is rotated a predetermined number of degrees from a vertical plane perpendicular to the bottom wall.

An embodiment of the present disclosure provides a circuit board including: an insulating layer including a first area on one surface on which an electronic component is mounted and a second area adjacent to the first area; a connection pad disposed in the first area; and a solder resist layer covering the one surface of the insulating layer and being opened to expose the connection pad. At least a portion of the solder resist layer extends from the second area to the first area, and a portion of the insulating layer is exposed from the solder resist layer in the first area.

An electrolytic capacitor is provided that contains a capacitor element, a case, and anode and cathode terminations having first and second external components. The first external components are perpendicular to a lower surface of the case, while the second external components are parallel to the lower surface of the case and extend outwardly away from the front and rear surfaces of the case, respectively. Further, the second external components are mounted to a circuit board such that at least a portion of the capacitor is embedded in the board and such that the second external components are parallel to and in contact with a mounting surface of the circuit board. The particular arrangement of the external components of the terminations stabilizes the capacitor when it is embedded into the board to minimize flexing against the board and cracking or delamination of the capacitor.

A signal processing board includes a six-layer substrate. A plurality of signal transmission planes are formed in a first layer, a third layer, a fourth layer, and a sixth layer. A first ground plane is formed in a second layer. A first power supply plane is formed in a fifth layer and electrically connected to the first semiconductor element. A second power supply plane is formed in the fifth layer and electrically connected to the second semiconductor element. A second ground plane is formed in the fifth layer. A first bypass capacitor is electrically connected to the first power supply plane and the second ground plane. A second bypass capacitor is electrically connected to the second power supply plane and the second ground plane.

A semiconductor storage device includes: a printed circuit board; a nonvolatile memory disposed on the printed circuit board; a memory controller disposed on the printed circuit board and configured to operatively control nonvolatile memory; a capacitor disposed on the printed circuit board and configured to supply power to the nonvolatile memory and the memory controller; and at least one holder that holds the capacitor at an end portion of the printed circuit board. The holder includes a connecting portion connected to the end portion of the printed circuit board, and a pair of arm portions extending from the connecting portion toward an outside of the printed circuit board and configured to sandwich a body portion of the capacitor from both sides in a thickness direction of the printed circuit board.