A wiring board includes an insulating substrate including a cutout portion that opens in a main surface of the insulating substrate and a side surface of the insulating substrate, an inner surface electrode on an inner surface of the cutout portion, an external electrode on the main surface of the insulating substrate, and a connecting section where the inner surface electrode and the external electrode are connected to each other. The connecting section is thicker than the inner surface electrode and the external electrode.

A wiring board manufacturing method includes: forming a first groove structure in a first principal surface of a base by scanning with laser light in a first irradiation pattern such that the first groove structure has a first width; irradiating an inside of the first groove structure with laser light in a second irradiation pattern that is different from the first irradiation pattern to form recessed portions inside the first groove structure; and forming a first wiring pattern by filling the first groove structure with a first electrically-conductive material to form a first wiring pattern whose shape matches with a shape of the first groove structure in a top view.

A connection structure includes: a support column member extending in one direction from one end to an opposite end, with the one end attached to an installation object and the opposite end having formed therein a screw hole, the support column member being configured to be non-insertable into the through hole; a surrounding member provided on a first surface of the printed board and configured to surround the opening of the through hole and to allow the opposite end of the support column member to be inserted into the surrounding member; and a fastener configured to fix the support column member to the printed board by being screw-engaged into the screw hole of the support column member inserted into the surrounding member, from a second surface side opposite to the first surface of the printed board.

A connection structure includes: a support column member extending in one direction from one end to an opposite end, with the one end attached to an installation object and the opposite end having formed therein a screw hole, the support column member being configured to be non-insertable into the through hole; a surrounding member provided on a first surface of the printed board and configured to surround the opening of the through hole and to allow the opposite end of the support column member to be inserted into the surrounding member; and a fastener configured to fix the support column member to the printed board by being screw-engaged into the screw hole of the support column member inserted into the surrounding member, from a second surface side opposite to the first surface of the printed board.

A framed stencil for surface mount technology (SMT) is provided. The frame assembly includes a frame member and a binding insert. The frame member includes an inner perimeter portion and an outer perimeter portion that cooperates with the inner perimeter portion to define an elongated channel. The outer perimeter portion includes a first cantilever portion that extends over the elongated channel and towards the inner perimeter portion. The binding insert is configured for releasable insertion into the elongated channel. The binding insert includes a base and a tongue. The base configured to interface with a mesh substrate to facilitate coupling therebetween. The tongue is coupled to the base and extends substantially horizontally from the base. When the binding insert is inserted into the elongated channel, the tongue extending beneath the first cantilever portion to facilitate retention of the binding insert to the frame member. Methods are also provided.

A method for mechanically connecting a first electronic component, in particular a circuit board element, to a second electronic component, in particular a second circuit board element, includes arranging and orienting the first electronic component, which includes a first through-opening in a first direction, above the second electronic component in the first direction in such a way that a second through opening in the first direction or a blind hole in the first direction is arranged at least partially below the first through-opening in the first direction. The method further includes introducing a casting compound into the first through-opening and into the second through-opening or into the first through-opening and into the blind hole, and setting the casting compound in order to fix the first electronic component in relation to the second electronic component.

A printed wiring board in the present disclosure includes a core layer, a first buildup layer, a second buildup layer, and a through hole. The core layer has a conductor circuit located on a surface of an insulator. The first buildup layer containing a first resin is laminated on a surface of the core layer. The second buildup layer containing a second resin is laminated on a surface of the first buildup layer. The through hole extends through the core layer, the first buildup layer, and the second buildup layer. The first resin and the second resin are different from each other. The second buildup layer includes a plurality of filled vias filled with a conductor which are located around a circumference of an opening of the through hole.

A stripline radio-frequency (RF) connection interface is provided and includes first and second printed circuit boards (PCBs). The first PCB includes a first trace, ground planes at opposite sides of the first trace, dielectric material interposed between the first trace and the ground planes and a first end. The first end is formed as a first rabbet at which the first trace is exposed. The second PCB includes a second trace, ground planes at opposite sides of the second trace, dielectric material interposed between the second trace and the ground planes and a second end. The second end is formed as a second rabbet, which is substantially identical to the first rabbet, at which the second trace is exposed. The first and second ends are mated in a shiplap joint to electrically couple the first and second traces.

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.

An electrical assembly that includes a substrate having an aperture. A flat conductor is mounted to the substrate and extends over at least a portion of the aperture, with a ring terminal in contact with the flat conductor adjacent to the aperture. A lead wire connects to the ring terminal and is spaced from the substrate, and a fastener extends through the ring terminal and flat conductor, secured in the aperture, and securing the ring terminal against the flat conductor.