A stretchable cable 1 includes a sheet-shaped stretchable base material 2 exhibiting elasticity and elongated in one direction, and a stretchable wiring 3 formed on one surface of the stretchable substrate 2 and exhibiting elasticity. The stretchable base material 2 is made of a material exhibiting elasticity. The stretchable wiring 3 is made of a conductive composition including elastomer and a conductive filler filling the elastomer.

A method of manufacturing a resin multilayer substrate with a cavity, includes stacking insulation substrates including thermoplastic resins and thermocompression-bonding the insulation substrates. At least one of the insulation substrates is formed by affixing a peelable carrier film to one main surface of the insulation substrate, making a cut in the insulation substrate having the carrier film affixed thereto, the cut being designed to form the cavity, penetrating the insulation substrate in a thickness direction and not penetrating the carrier film in a thickness direction, and removing the carrier film and a portion of the insulation substrate that is cut out by the cut.

An object of the invention is to provide a method for more easily manufacturing a touch-panel conductive sheet in which end portions of lead-out wires are collected on one surface side of a substrate with high productivity, and a touch-panel conductive sheet. The method for manufacturing a touch-panel conductive sheet of the invention includes: forming, on a rear surface of a substrate, first detection electrodes and rear surface-side wires of which one ends are electrically connected to the first detection electrodes and the other ends have first pad portions, and on a front surface of the substrate, second detection electrodes, second lead-out wires which are electrically connected to the second detection electrodes, and second pad portions which are arranged at positions opposed to the first pad portions via the substrate; forming through holes penetrating the first pad portions, the substrate, and the second pad portions; and producing through wires which electrically connect the first pad portions and the second pad portions by filling the through holes with a conductive material to form first lead-out wires which include the rear surface-side wires and the through wires and are electrically connected to the first detection electrodes.

An electronic-device having an intermediate connection layer interposed between a wiring substrate and an electronic component. The intermediate connection layer has a laminated structure including a rigid substrate and a flexible substrate. A first conductor part is formed on one principal surface of the flexible substrate, and second and third conductor parts are formed on both principal surfaces of the rigid substrate, respectively. The rigid substrate includes an opening, and the first conductor part of the flexible substrate includes a narrowed fuse part at a position opposite the opening. Windows are formed near the fuse part. The flexible substrate and the rigid substrate are electrically connected with each other via solder.

The present invention provides a circuit board structure and manufacturing method thereof. Select a processing area for electronic components on a circuit board containing a copper foil layer, and calculate marking points without setting the electronic components. Spray water-based environmentally friendly paint on the circuit board to form a first insulating layer. Cut the circuit board outside the marking points to form through holes, and spray water-based environmentally friendly conductive paint on the first insulating layer to form a conductive layer that forms an electrical connection with the copper foil layer. Finally, spray water-based environmentally friendly paint on the conductive layer to form a second insulating layer, so that electromagnetic waves and other interference of the electronic components are guided to the internal ground plane of the circuit board through the conductive layer for elimination, and heat is dispersed on the first and second insulating layers.

A circuitized substrate which includes a conductive paste for providing electrical connections. The paste, in one embodiment, includes a metallic component including nano-particles and may include additional elements such as solder or other metal micro-particles, as well as a conducting polymer and organic. The particles of the paste composition sinter and, depending on what additional elements are added, melt as a result of lamination to thereby form effective contiguous circuit paths through the paste. A method of making such a substrate is also provided, as is an electrical assembly utilizing the substrate and including an electronic component such as a semiconductor chip coupled thereto.

A multilayer printed circuit as well as printed passive and active electronic components using additive printing technology is provided. The fabrication process includes a substrate and a first conductive layer that is printed with conductive ink on the substrate. An insulation layer that has uniform thickness is printed on the first conductive layer and the substrate, less via cavities, test point cavities, and a surface mount component contact point and mounting cavities. The insulation layer is replaceable with resistive layer or semi-conductive layer to fabricate electronic components. The vias are printed with conductive ink inside of the via cavities. Additionally, a second conductive layer is printed on the vias and over the insulation layer. The insulation, resistive, or semi-conducting layer, the vias, and the conductive layers are repeatedly printed in sequence to thus form the multilayer printed circuit.

A component built-in board mounting body has a component built-in board mounted on a mounting board, the component built-in board being configured having stacked therein a plurality of printed wiring bases that each have a wiring pattern and a via formed on/in a resin base thereof, and having an electronic component built in thereto, wherein the component built-in board has at least a portion of the plurality of printed wiring bases including thermal wiring in the wiring pattern and including a thermal via in the via, and is mounted on the mounting board via a bump formed on a surface layer of the component built-in board, and a surface on an opposite side to an electrode formation surface of the built in electronic component is connected to the bump via the thermal via and the thermal wiring, and is thermally connected to the mounting board via the bump.

The invention relates to an electronic device having an electrically isolating support structure, an electrically conducting conductor path on a surface of the support structure, and an electrically conducting contact structure which extends from the surface into the support structure and is electrically connected to the conductor path at a connection point, thereby forming a common conductor track. The conductor path and the contact structure transition into each other in an enlargement-free manner at the connection point.

Methods of forming microelectronic device structures are described. Those methods may include forming at least one opening through a build up structure and a photo sensitive material disposed on the build up structure, wherein the build up structure comprises a portion of a package substrate, filling the at least one opening with a metal containing nanopaste, and sintering the metal containing nanopaste to form a bulk property metal structure in the at least one opening.