A rigid-flex printed circuit board includes an inner circuit substrate, two adhesive sheet layers formed on the inner circuit substrate, two shielding structures, and two outer circuit layers. The inner circuit substrate is divided into a flexible area, a first and second rigid area. Each shielding structure includes a copper layer, a metal seed layer formed on the copper layer, a flexible dielectric layer formed on the metal seed layer, and a backing adhesive sheet layer formed on the flexible medium layer. The backing adhesive sheet layer is pressed on the adhesive sheet layer and the inner circuit substrate located in the flexible area. Each outer circuit layer is formed on the copper layer, located in the first rigid area and the second rigid area and electrically connected to the inner circuit substrate.

The present invention provides a multilayer transformer PCB structure for an electric car and manufacturing method for the same, which includes first and second connecting copper tabs horizontally formed in plural on both surfaces of a base substrate, thereby forming inner layer circuits coupled to battery cells, and third and fourth connecting copper tabs stacked on a top surface of the first connecting copper tab and a top surface of the second connecting copper tab by patterning process a copper material several times as a predetermined thickness, thereby forming outer layer circuits coupled to the battery cells. According to the present invention configured thus, the transformer PCB for an electric car has a structure in which a conductive material having a predetermined thickness is stacked in a multilayer form, and thus an increased quantity of charges to be treated is highly distributed, thereby maximizing current efficiency.

The first present invention is a graphite sheet having a thickness of not more than 9.6 μm and more than 50 nm and a thermal conductivity along the a-b plane direction at 25° C. of 1950 W/mK or more. The second present invention is a graphite sheet having a thickness in a range of less than 9.6 μm and 20 nm or more, an area of 9 mm2 or more, and a carrier mobility along the a-b plane direction at 25° C. of 8000 cm2/V.Math.sec or more.

A flexible printed circuit board with multiple layers includes an inner wiring substrate and at least one outer wiring plate. Each outer wiring plate is connected to one surface of the inner wiring substrate, and defines at least one through hole which passes through the outer wiring plate to expose the inner wiring substrate. Each outer wiring plate further includes an adhesive plate connected to the inner wiring substrate. The adhesive plate includes a stepped portion extending towards a center of the through hole.

An object of the present invention is to provide: a heat-curable composition capable of yielding a cured article in which crack generation during a heating-cooling cycle can be inhibited; a dry film thereof; and a printed wiring board comprising the cured article. The heat-curable composition is characterized by comprising a semisolid or a solid epoxy compound and a curing accelerator that is made miscible with the epoxy compound when heated at 130 to 220° C. The dry film comprises a resin layer formed from this heat-curable composition, and the printed wiring board comprises a cured article obtained from the heat-curable composition or the dry film.

The present invention is to provide a microstructure capable of improving the withstand voltage of an insulating substrate while securing fine conductive paths, a multilayer wiring board, a semiconductor package, and a microstructure manufacturing method. The microstructure of the present invention has an insulating substrate having a plurality of through holes, and conductive paths consisting of a conductive material containing metal filling the plurality of through holes, in which an average opening diameter of the plurality of through holes is 5 nm to 500 nm, an average value of the shortest distances connecting the through holes adjacent to each other is 10 nm to 300 nm, and a moisture content is 0.005% or less with respect to the total mass of the microstructure.

A high-CTI and halogen-free epoxy resin composition for copper-clad plates and uses thereof is provided. The formula of the high-CTI and halogen-free epoxy resin composition for copper-clad plates comprises 100˜140 parts of halogen-free phosphorous epoxy resin, 10˜35 parts of dicyclopentadiene phenolic epoxy resin, 32˜60 parts of benzoxazine, 1˜5 parts of phenolic resin, 0.05˜0.5 parts of accelerants; and 25˜70 parts of fillers, by weight. The copper-clad plates, prepared according to embodiments of the present invention, can reach the requirements of high CTI (CTI≧500V), high heat resistance(Tg≧150 ° C., PCT, 2 h>6 min) and the level of flame retardance of UL-94 V0, and they are widely used in the electronic materials of electric machines, electric appliances, white goods and so on.

A method of manufacturing a component carrier, includes providing a base structure having a main surface that is at least partially covered by a component fixation structure; providing a component, the component intrinsically comprising warpage; mounting the component on a surface provided on a plate structure and/or on the base structure to remove the warpage of the component at least partially; and fixating the component to the component carrier through the component fixation structure.

In a semi-finished product for the production of a printed circuit board, the semi-finished product comprising a plurality of having multiple insulating layers of a prepreg material and conductive layers (2, 2′) of a conductive material and further comprising having at least one electronic component embedded in at least one insulating layer the at least one electronic component is attached to a corresponding conductive layer by the aid of an Anisotropic Conductive Film and the Anisotropic Conductive Film as well as the prepreg material are in an unprocessed state. The method for producing a printed circuit board comprises the following steps: Providing at least one conductive layer (2), Applying an Anisotropic Conductive Film on the conductive layer, Affixing at least one electronic component on the Anisotropic Conductive Film, Embedding the electronic component in at least one insulating layer of prepreg material to obtain a semi-finished product, Laminating the semi-finished product to process the prepreg material and the Anisotropic Conductive Film.

A method for producing a printed circuit board (13, 15, 16) with multilayer subareas in sections, characterized by the following steps: a) providing at least one conducting foil (1, 1′) and application of a dielectric insulating foil (3, 3′) to at least one subarea of the conducting foil; b) applying a structure of conducting paths (4, 4′) to the insulating layer (3, 3′); c) providing one further printed circuit board structure; d) joining of the further printed circuit board structure with the conducting foil (1, 1′) plus insulating layer (3, 3′) and conducting paths (4, 4′) by interposing a prepreg layer (5, 85; 18, 18′), and e) laminating the parts joined in step d) under pressing pressure and heat; and a printed circuit board produced according to this method.