A method of making printed circuit board vias using a double drilling and plating method is disclosed. A first hole is drilled in a core, the first hole having a first diameter. The first hole is filled and/or plated with an electrically conductive material. A circuit pattern may be formed on one or two conductive layers of the core. A multilayer structure may then be formed including a plurality of cores that also include pre-drilled and plated via holes, wherein at least some of the pre-drilled and plated via holes are aligned with the first hole. A second hole is then drilled within the first hole and the aligned pre-drilled and plated holes, the second hole having a second diameter where the second diameter is smaller than the first diameter. A conductive material is then plated to an inner surface of the second hole.

A device-embedded board includes a board main body, conductor wiring layers formed inside or on a surface of the board main body, and device formation layers formed inside the board main body so as to be in contact with a portion of the conductor wiring layers. The device formation layer is configured in an insulating region in which functional filler for forming a devices is dispersed.

Described herein is a multilayer flex circuit having a first dual flex circuit and a second dual flex circuit where each one comprises an outer metal layer, a base insulation layer, and an inner metal layer. The base insulation layer is disposed between the outer metal layer and the inner metal layer. The inner metal layer of the first dual flex circuit is configured to face toward the inner metal layer of the second dual flex circuit. The multilayer flex circuit also includes a coupling layer that adhesively couples the inner metal layer of the first dual flex circuit to the inner metal layer of the second dual flex circuit. The multilayer flex circuit also comprises an electrically conductive material that electrically connects the inner metal layer of the second dual flex circuit to the inner metal layer of the first dual flex circuit.

A semi-finished product for the production of connection systems for electronic components including two groups (A, B) of alternately applied conductive layers and insulating layers, wherein first layers (2, 2) of the two groups (A, B) are facing each other to form a separation area for the groups (A, B) to be separated from each other to yield connection systems and the separation area is overlapped and sealed on all sides thereof at least by the two insulating layers (4, 4) following the separation area.

A printed circuit board comprises an epoxy-containing member, a first copper pattern disposed adjacent to the epoxy-containing member, and a first adhesion promoter layer interposed between the epoxy-containing member and the first copper pattern.

A method of manufacturing a multilayer substrate includes preparing a plurality of substrates, stacking the substrates with bonding sheets interposed, and a first bonding process of bonding the substrates to each other by partially heating the stacked substrates by a heater and partially melting the bonding sheet. Each of the substrates is provided with a through-hole and a metal film covering an inner peripheral surface of the through-hole. In the first bonding process, the metal film is heated by the heater and heat is transferred from the heater to the bonding sheet via the metal film.

A multi-layer circuit board is formed by positioning a top sub having traces on at least one side to one or more pairs of composite layers, each composite layer comprising an interposer layer and a sub layer. Each sub layer which is adjacent to an interposer layer having an interconnection aperture, the interconnection aperture positioned adjacent to interconnections having a plated through via or pad on each corresponding sub layer. Each interposer aperture is filled with a conductive paste, and the stack of top sub and one or more pairs of composite layers are placed into a lamination press, the enclosure evacuated, and an elevated temperature and laminated pressure is applied until the conductive paste has melted, connecting the adjacent interconnections, and the boards are laminated together into completed laminated multi-layer circuit board.

A multilayer circuit board structure includes a first multilayer circuit board and a second multilayer circuit board. The first multilayer circuit board includes a first patterned circuit layer and a first dummy circuit layer. The first dummy circuit layer surrounds the first patterned circuit layer. The second multilayer circuit board is disposed on the first multilayer circuit board, and includes a second patterned circuit layer and a second dummy circuit layer surrounding the second patterned circuit layer. The first patterned circuit layer is bonded to the second patterned circuit layer and the first dummy circuit layer is bonded to the second dummy circuit layer. A hollow space is defined between the first multilayer circuit board and the second multilayer circuit board.

The present disclosure discloses a printed circuit board, a method for manufacturing the same and an electronic device. The PCB includes: a core board assembly including a first core board and a second core board which are stacked together, wherein the second core board includes a metal layer formed on a side of the second core board oriented towards the first core board, and the first core board defines a through slot extending through the first core board; a radiator, disposed in the through slot; and a conductive adhering layer, disposed between the metal layer of the second core board and the radiator, wherein the conductive adhering layer is configured to electrically connect the radiator and the metal layer. The present disclosure connects the radiator directly with the metal layer. The implementation of the present disclosure may help cooling the metal layer to improve the cooling performance of the PCB.

A method for manufacturing a circuit board comprises steps of providing a single-sided board comprising a first insulating base, a copper layer, and at least one first conductive structure; providing a laminated board comprising a metal layer, a third insulating base, a metal shielding layer, and a second insulating base; forming a wiring layer by the metal layer comprising at least one signal wire and at least one connecting pad; defining at least one second through hole each passing through the second insulating base, the metal shielding layer, and the third insulating base; forming a second conductive structure in each second through hole; providing a double-sided board comprising a wiring layer, a fourth insulating base, a first copper foil; and at least one third conductive structure; pressing the single-sided board, at least one middle structure, and the double-sided board in that sequence to form the circuit board.