The present disclosure provides a printed circuit board with a plated through hole. The through hole covered by a solder pad at both ends of the through hole. At least two pins are plugged into the through hole, one of which with its head end being thermal contacted with one of the solder pads. Another pin's head end being thermal contacted with the other solder pad. The at least two pins are thermal contacted with one another. Thermal dissipation rate is increased with the structure of the through hole.

A circuit board structure includes a dielectric substrate, at least one embedded block, at least one electronic component, at least one first build-up circuit layer, at least one second build-up circuit layer, at least one conductive through hole, and a fine redistribution layer (RDL). The embedded block is fixed in a through cavity of the dielectric substrate. The electronic component is disposed in an opening of the embedded block. The first build-up circuit layer is disposed on a top surface of the dielectric substrate and electrically connected with the electronic component. The second build-up circuit layer is disposed on a bottom surface of the dielectric substrate and covers the embedded block. The conductive through hole is disposed in a via of the embedded block and electrically connects the first and the second build-up circuit layers. The fine RDL is disposed on and electrically connected to the first build-up circuit layer.

An electronic assembly including a thermal capacitor. An electronic substrate of the electronic assembly includes one or more insulating layers and one or more conductor layers provided along the one or more insulating layers. The one or more conductor layers including a conductive material. A shape memory thermal capacitor is received in the electronic substrate. The shape memory thermal capacitor includes a shape memory core including a shape memory material.

An axial field rotary energy device has a PCB stator panel assembly between rotors with an axis of rotation. Each rotor has a magnet. The PCB stator panel assembly includes PCB panels. Each PCB panel can have layers, and each layer can have conductive coils. The PCB stator panel assembly can have a thermally conductive layer that extends from an inner diameter portion to an outer diameter portion thereof. Each PCB panel comprises discrete, PCB radial segments that are mechanically and electrically coupled together to form the respective PCB panels.

Disclosed are an embedded circuit board and a fabrication method therefor. The embedded circuit board comprises: a circuit board body; signal transmission layers (1200), wherein the signal transmission layers are arranged on two opposite sides of the circuit board body; bonding layers, wherein the bonding layers are arranged between at least one signal transmission layer and the circuit board body and used for bonding the signal transmission layer to the circuit board body; metal bases which are embedded in the circuit board body and are electrically connected to the signal transmission layers on two opposite sides of the circuit board body; conductive parts which are arranged at the positions in the bonding layers corresponding to the metal bases, and are electrically connected to the signal transmission layer and the metal bases; and magnetic cores embedded in the circuit board body.

A substrate is described with a thermal dissipation structure sintered to thermal vias. In one example, a microelectronic module includes a recess between first and second substrate surfaces. One or more thermal vias extend between the first substrate surface and the interior recess surface, wherein each of the thermal vias has an interior end exposed at the interior recess surface. A sintered metal layer is in the recess and in physical contact with the interior end of the thermal vias and a thermal dissipation structure is in the recess over the sintered metal layer. The thermal dissipation structure is attached to the substrate within the recess by the sintered metal layer, and the thermal dissipation structure is thermally coupled to the thermal vias through the sintered metal layer.

Provided are a heat sink capable of suppressing overcooling of an electronic component which should not be overcooled and highly efficiently cooling only an electronic component which should be cooled, and a circuit device including the same. A heat sink includes a pipe and a cooling block. At least one projection is formed in the cooling block. The pipe is in contact with the projection. The pipe is arranged with a spacing from a portion of the cooling block other than the projection.

An electronic device includes: a first printed circuit board (PCB) including a first plate and a first hole formed in the first plate, a second PCB including a second plate, an interposer including a third plate positioned between the first plate and the second plate, a plurality of first vias connecting the first plate and the third plate, a plurality of second vias connecting the second plate and the third plate, and a first reinforcement portion positioned in the first hole to bond the first plate and the third plate.

A heat transfer member-equipped substrate includes a heat transfer member installed in a through hole of a substrate; a heat generating component; and a solder portion soldering the heat generating component to the heat transfer member, a nickel base plating formed on the heat transfer member, and the solder portion bonded to the nickel base plating where a gold plating that suppresses oxidization of the nickel base plating is blended into the solder portion. The heat transfer member includes a first and a second heat transfer portion bonded to each other, the first heat transfer portion made of a first metal, the second heat transfer portion made of a second metal formed on at least a portion of a surface of the second heat transfer portion, and the second heat transfer portion being a plate shape that protrudes from a circumference of the first heat transfer portion.

A circuit board structure includes a dielectric substrate, at least one embedded block, at least one electronic component, at least one first build-up circuit layer, and at least one second build-up circuit layer. The dielectric substrate includes a through cavity penetrating the dielectric substrate. The embedded block is fixed in the through cavity. The embedded block includes a first through hole and a second through hole. The electronic component is disposed in the through hole of the embedded block. The first build-up circuit layer is disposed on the top surface of the dielectric substrate and covers the embedded block. The second build-up circuit layer is disposed on the bottom surface of the dielectric substrate and covers the embedded block.