A wiring circuit board includes an insulating layer and a conductive layer disposed on a front surface of the insulating layer. The conductive layer includes a first wiring, a first terminal electrically connected to the first wiring, a second wiring independent of the first wiring and having a thick thickness T2 with respect to a thickness T1 of the first wiring, and a second terminal electrically connected to the second wiring. The surfaces of the first terminal and the second terminal are disposed at generally the same position in a thickness direction.

A production method and a power electronic connecting device for a power semiconductor module, wherein the connecting device is designed as a flexible film stack of a first and a second electrically conductive film and an electrically insulating film arranged therebetween, wherein at least one of the electrically conductive films is structured in itself and thus forms a plurality of film conductor tracks, wherein a first one of these film conductor tracks has, in a first section, a first average thickness and, in a second section, a second average thickness which is at least 10%, preferably at least 20%, smaller than the first average thickness.

A method for producing a circuit board arrangement includes: providing a first circuit board substrate, providing a second circuit board substrate, arranged substantially planar-parallel to the first circuit board substrate, the first circuit board substrate having an underside and the second circuit board substrate having an upper face, the upper face and the underside being arranged opposite one another, providing first terminal contacts, applied to the underside of the first circuit board substrate, providing second terminal contacts, applied to the upper face of the second circuit board substrate, applying solder paste cylinders to the first terminal contacts, the solder paste cylinders applied to the first terminal contacts by a solder-paste application process with solder paste, the applied solder paste cylinders having in each case a solder-paste-cylinder upper face, and arranging the second terminal contacts of the second circuit board substrate on the solder-paste-cylinder upper faces of the solder paste cylinders.

A resin multilayer board includes a substrate including a stack of resin layers, and a first metal pin including a first end portion exposed at a first main surface of the substrate and penetrating through at least one of the resin layers in a thickness direction, wherein a gap is provided at a portion of an interface between a lateral side of the first metal pin and the resin layer.

A wiring substrate includes: an insulating substrate comprising a principal face; a wiring line located on the principal face; and a protruding portion on a side of the wiring line, the protruding portion being smaller in thickness than the wiring line and protrudes from the side along the principal face.

A multi-layer circuit board is formed multiple layers of a catalytic layer, each catalytic layer having an exclusion depth below a surface, where the cataltic particles are of sufficient density to provide electroless deposition in channels formed in the surface. A first catalytic layer has channels formed which are plated with electroless copper. Each subsequent catalytic layer is bonded or laminated to an underlying catalytic layer, a channel is formed which extends through the catalytic layer to an underlying electroless copper trace, and electroless copper is deposited into the channel to electrically connect with the underlying electroless copper trace. In this manner, traces may be formed which have a thickness greater than the thickness of a single catalytic layer.

A multi-layer circuit board is formed multiple layers of a catalytic layer, each catalytic layer having an exclusion depth below a surface, where the cataltic particles are of sufficient density to provide electroless deposition in channels formed in the surface. A first catalytic layer has channels formed which are plated with electroless copper. Each subsequent catalytic layer is bonded or laminated to an underlying catalytic layer, a channel is formed which extends through the catalytic layer to an underlying electroless copper trace, and electroless copper is deposited into the channel to electrically connect with the underlying electroless copper trace. In this manner, traces may be formed which have a thickness greater than the thickness of a single catalytic layer.

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.

This application provides a printed circuit board. The printed circuit board includes a first outer conducting layer, a second outer conducting layer, and at least one insulation medium layer sandwiched between the first outer conducting layer and the second outer conducting layer. The printed circuit board includes a gold finger area and a soldering area. A total thickness of all conducting layers in the gold finger area is greater than that of all conducting layers in the soldering area. Because the total thickness of all conducting layers in the gold finger area is relatively thick, resistance of the gold finger area can be reduced, and a through-current capability of the gold finger area is improved. In addition, the total thickness of all conducting layers in the soldering area is relatively thin, so that a sufficient soldering temperature and a good soldering effect can be ensured.

A component carrier includes an electrically insulating layer structure having a first main surface and a second main surface with a through hole extending through the electrically insulating layer structure between the first main surface and the second main surface. An electrically conductive bridge structure connects opposing sidewalls of the electrically insulating layer structure delimiting the through hole. A vertical thickness of the electrically insulating layer structure is not more than 200 μm and a narrowest vertical thickness of the bridge structure is at least 20 μm.