A PCB that constructs circuit traces, vias, and connection pads by filling recessed areas, grooves, holes, and/or counter bores with conductive material. The recessed areas are filled with conductive ink or plating solutions by a number of methods. Capillary action aids in the filling of the recessed areas. Pressure, vacuum and or gravity can aid the filling. Layers of the PCB or similar type devices can be bonded together both mechanically and electrically to accomplish 3D connections of circuits. Ground and power plane durability and conductivity is enhanced by the inclusion of small grooves over the conductive plane.

A component carrier includes a stack with at least one electrically conductive layer structure and/or at least one electrically insulating layer structure. The at least one electrically conductive layer structure includes a first trace. A tapering trench is formed in the at least one electrically insulating layer structure beside and below the first trace. A method of manufacturing the component carrier is also described.

A method of manufacturing a component carrier includes forming a poorly adhesive structure on at least one layer structure, thereafter removing part of the poorly adhesive structure to thereby define a lateral limit of the poorly adhesive structure, thereafter attaching at least one further layer structure to the at least one layer structure and to the poorly adhesive structure, and forming a cavity by removing material of the at least one further layer structure above the poorly adhesive structure.

A wiring substrate includes an insulating layer including resin and filler particles, and an embedded wiring layer including wirings and embedded in the insulating layer such that the wirings are filling grooves formed on a surface of the insulating layer, respectively. The embedded wiring layer is formed such that the inter-wiring distance between the closest two wirings of the wirings in the embedded wiring layer is in the range of 2 μm to 8 μm, and the insulating layer is formed such that the maximum particle size of the filler particles is 50% or less of the inter-wiring distance.

In an electrical device, a model series of electrical devices, and a production method, in particular for a converter, having a circuit board including circuit traces, the circuit board has two similar and/or identical contact area arrays, the contact area arrays in particular transitioning into each other through rotation and/or displacement. A first contact area array of the contact area arrays is fitted with a first power module, and the second contact area array is able to be fitted with a second power module, e.g., so that a respective electric motor is able to be supplied from the respective power module.

The invention relates to an electronic device comprising a printed circuit board (14) and comprising an electronic component (16) arranged on a first surface (15) of the printed circuit board (14). The printed circuit board (14) has a cutout (23) extending from a second surface (24) of the printed circuit board (14), said second surface being situated opposite the first surface (15), in the direction of the electronic component (16). The electronic device comprises a coolant container (25), which has an opening closed by the second surface (24) of the printed circuit board (14). The invention additionally relates to a method for producing such an electronic device.

The present invention relates to a manufacturing method of a metal PCB assembly for a vehicle lamp and the metal PCB assembly made by the method. The manufacturing method of a metal PCB assembly for a vehicle lamp comprises a step S100 in which a material of a metal PCB 14 is prepared, a step S110 in which a circuit pattern 22 and a plurality of unit patterns 16 are formed and cut from the material of a metal PCB 14 to form a metal PCB 14, a step S120 in which a bending groove 24 is formed on a bottom surface of the metal PCB 14, a step S130 in which each of the unit patterns 16 is protruded forward around the bending groove 24 of the metal PCB 14 such that each of the unit patterns 16 is bent to be inclined from the metal PCB 14, and a step S140 in which a stepwise injection molded products 12 is coupled with the metal PCB 14 while the unit pattern 16 is protruded.

Provided is a method of manufacturing an electrical connection structure which includes a female connection structure having an inner conductive material inside an insertion hole of a female connection member, and a male connection structure having a conductive column configured to be inserted into and fixed to the insertion hole to be in contact with the inner conductive material, and formed to protrude from a male connection member. The method includes preparing insulating members used for the female connection member and the male connection member, and forming the inner conductive material and the column by patterning a conductive material on each of the insulating member using a photolithography process.

The present application provides an asymmetric board, which includes the first master board, the second master board, and the insulating dielectric layer sandwiched between the first master board and the second master board, and the depth control grooves are disposed in the connection position between the units on the asymmetric board, and located on the surface of the second master board and extending a toward the side of the first master board, the depth control grooves provide space for the expansion of the second master board, reduce the stress of the units, and reduce the warping of the second master board. When the number of the depth control grooves in the first direction and/or the second direction is greater than 0, the depths of the depth control grooves increase by X from a center to an edge of the asymmetric board, and the X is greater than or equal to 0.

The invention provides a card substrate for carrying a chip module, the card substrate has a first surface and a second surface opposite to the first surface, and a concave portion for accommodating the chip module, the concave portion includes a first concave portion, and a second concave portion further recessed from a bottom wall of the first concave portion, in a left-right direction, a size of the second concave portion gradually narrows from a middle to both sides, and in an up-down direction, the size of the second concave portion gradually narrows from the middle to both sides. The card substrate of the invention can provide good support and protect for the chip module.