A printed circuit board with built-in vertical heat dissipation ceramic block, and an electrical assembly are disclosed. The electrical assembly includes the board and a plurality of electronic components. The printed circuit boards includes a dielectric material layer defining at least one through hole, at least one ceramic block corresponding to the through hole, at least one fixing portion for joining the ceramic block to the through hole of the dielectric material layer, a metal circuit layer provided on upper surfaces of the dielectric material layer and the ceramic block, and a high thermal conductivity layer provided on lower surfaces of the dielectric material layer and the ceramic block. The printed circuit board allows the location and size of the ceramic block to be modified according to requirements, so as to implement complicated circuit designs, achieve good effect of thermal conduction, control thermal conduction path, and reduce manufacturing cost.

A component carrier having a stack with at least one electrically insulating layer structure and/or at least one electrically conductive layer structure and an array of exposed highly thermally conductive cooling structures integrally formed with the stack and defining cooling channels in between is disclosed.

A circuit board includes a circuit board main body including a first through hole and a second through hole, a first inlay member inserted into the first through hole, and a second inlay member inserted into the second through hole. A first end surface of the first inlay member includes a first end portion on the side of the second inlay member, a second end portion on the opposite side of the second inlay member, a first area including the first end portion, and a second area including the second end portion. A first end surface of the second inlay member includes a third end portion on the side of the first inlay member, a fourth end portion on the opposite side of the first inlay member, a third area including the third end portion, and a fourth area including the fourth end portion. The circuit board further includes a first resist provided in the second area, and a second resist provided in the fourth area.

An assembly (1) comprises at least one base plate (2), a counter plate (3) connected thereto, and an electro-optical element (4). The base plate (2) is provided with at least one conductor track (7) for connecting the electro-optical element (4), and with at least one heat transfer element (5) for dissipating heat from the electro-optical element (4). The heat transfer element (5) is a heat-conductive operative connection between the electro-optical element (4) and the counter plate (3).

The disclosure relates to an electronic device including a thermally and electrically conductive transmission element configured to dissipate heat from a heat source, wherein the transmission element is at a first electric potential and includes rounded edges. The electronic device further includes a heat sink at a second electric potential and an electrically insulating layer arranged between the heat sink and the transmission element in order to connect the transmission element to the heat sink in a thermally conductive manner.

A component carrier includes: i) a first layer stack (comprising at least one first electrically conductive layer structure and/or at least one first electrically insulating layer structure, ii) a component embedded in the first layer stack, where a main surface of the component is essentially flush with an outer main surface of the first layer stack iii) a second layer stack comprising at least one second electrically conductive layer structure and/or at least one second electrically insulating layer structure, and iv) a thermally conductive block embedded in the second layer stack. The layer stacks are connected with each other so that a thermal path from the embedded component via the thermally conductive block up to an exterior surface of the component carrier has a minimum thermal conductivity of at least 7 W/mK, in particular at least 40 W/mK. Further, a method of manufacturing the component carrier is described.

A circuit board includes a conductive metal layer, at least one insulating layer, at least one thermally conductive insulating layer and a heat dissipation element. The conductive metal layer is mainly used to transmit electronic signals. The insulating layer is connected to the conductive metal layer. The thermally conductive insulating layer is sandwiched between the conductive metal layer and the insulating layer, and thermally contacts the conductive metal layer, and is used for thermally conducting the heat of the conductive metal layer. The heat dissipation element is in thermal contact with the thermally conductive insulating layer, and is used to conduct the heat of the thermally conductive insulating layer to the outside through a heat dissipation channel.

An integrated circuit/printed circuit board (IC-PCB) assembly comprises a PCB and a heatsink plate. The PCB has a first side including a first patterned conductive layer with one or more thermal pads onto which one or more heat slugs of one or more ICs mount, and a second, opposing side including a second patterned conductive layer with a heatsink plate receiving pad onto which the heatsink plate mounts. The heatsink plate has one or more posts that project from a mounting surface of the heatsink plate, and when the heatsink plate is mounted to the heatsink plate receiving pad, each post extends from the second side of the PCB, through a matching hole in the PCB, and to an associated thermal pad located on the first side of the PCB.

A semiconductor storage device has a substrate, a semiconductor chip, a capacitor, and a heatsink. The semiconductor chip is mounted on the substrate. The capacitor is mounted on the substrate and overlaps with the semiconductor chip in a thickness direction of the substrate. The heatsink has fins and the capacitor is mounted in the heatsink.

Provided is a mounting structure that can bond a first heat dissipation element to a second substrate through a hole in a first substrate without using a binder such as solder, an adhesive, or the like. A mounting structure of the present disclosure includes a first substrate (10) in which a penetrating hole (11) is formed, a second substrate (20) and a first heat dissipation element (30) overlapped with both surfaces of the first substrate (10), respectively, so as to cover the penetrating hole (11), and a second heat dissipation element (40) sandwiched and attached between the second substrate (20) and the first heat dissipation element (30) inside the penetrating hole (11).