Provided are a stretchable wire tape for a textile that can maintain high levels in all of stretchability, electrical conductivity, durability, an insulating property, and design and can also have a reduced production cost, wearable devices, and a method for producing textiles having wires. The stretchable wire tape for the textile includes a stretchable electrically conductive wire, and stretchable insulating films each including a first face and a second face opposite to the first face, the stretchable insulating films being bonded to opposite sides of the stretchable electrically conductive wire on their first faces. Since the stretchable insulating films are bonded to the opposite sides of the stretchable electrically conductive wire via bonding layers, durability and an insulating property can be secured while stretchability and electrical conductivity of the electrically conductive wire can be maintained, and design can also be improved.

A planarized core material manufacturing method includes: a core material forming step of forming a core material having a first surface and a second surface opposed to the first surface by impregnating glass cloth with a synthetic resin, and drying the glass cloth; and a core material planarizing step of planarizing the first surface or the second surface of the core material by grinding processing or polishing processing. Preferably, a plurality of pieces of the glass cloth are laminated in the core material.

Provided is a method of manufacturing a circuit board involves: preparing a composite laminate including a support, a release layer, and a multilayered circuit board; disposing the composite laminate on a stage such that one face of the composite laminate is put into tight contact with the stage; and releasing the support or the multilayered circuit board from the release layer such that the support or the multilayered circuit board forms a convex face with a curvature radius of 200 to 5000 mm while the face of the composite laminate is kept in tight contact with the stage. The method according to the present invention can prevent the occurrences of defects, for example, breaking in the support and cracking and wire disconnections in the multilayered circuit board in manufacturing of circuit boards, such as coreless circuit boards, and ensure stable release of the support or the multilayered circuit board.

A method of manufacturing a circuit substrate including forming, in an insulating substrate and circuit patterns that are provided on a first surface and a second surface of the insulating substrate, a through-hole penetrating the insulating substrate and the circuit patterns, where the circuit patterns contain Cu as a main component. The method including filling, in the through-hole, an electrically conductive paste that is a melting-point shift electrically conductive paste including SnBi solder powder, Cu powder, and resin, and forming a protrusion obtained by causing the electrically conductive paste to protrude from the through-hole. The method further including performing pressure treatment on the protrusion near the through-hole; and performing heat treatment on the insulating substrate whose protrusion is subjected to the pressure treatment and causing the circuit patterns and the electrically conductive paste to be electrically connected with each other.

The present invention refers to a new type of transport roller providing a modified surface to provide improved transport properties for new substrates. Furthermore, it refers to horizontal transport systems beneficially utilizing such transport rollers, especially for providing retaining roller pairs. Additionally, the present invention refers to a treatment device containing such transport roller or horizontal transport system. Furthermore, it refers to a method for treating a substrate and the use of such transport roller.

A transparent conductor is provided, including a visible light transparent substrate and metal traces disposed on the substrate, and a layer of a second metal deposited on at least a portion of the metal traces. The transparent conductor further includes a layer of a second metal, which conforms to the surface structure of the metal traces on which it is deposited. Optionally, the transparent conductor also includes a coating layer disposed on a portion of the metal traces and the substrate surface. The coating layer includes a polymer prepared from a polymerizable composition containing at least one ionic liquid monomer. A method of forming a transparent conductor is also provided, including obtaining a visible light transparent substrate having metal traces disposed on the substrate and applying a coating composition on a portion of the metal traces and substrate. The coating composition contains at least one noble metal salt and at least one polymerizable ionic liquid monomer.

Systems and methods are disclosed by which patterns of various materials can be formed on flexible substrates by a continuous roll-to-roll manufacturing process. The patterns may include metallic, transparent conductive, or non-metallic elements with lateral dimensions including in the range from below 100 nanometers to millimeters and with thickness dimensions including the range from tens of Angstroms to greater than 10,000 Angstroms. The substrate may be any material capable of sufficient flexibility for compatibility with roll-based processing equipment, including polymeric films, metallic foils, and thin glass, with polymeric films representing a particularly broad field of application. Methods may include the continuous roll-to-roll formation of a temporary polymeric structure with selected areas open to the underlying substrate, the continuous addition or subtraction of constituent materials, and the continuous removal, where necessary, of the polymeric structure and any excess material.

A method for manufacturing a printed wiring board includes forming a seed layer on a surface of a resin insulating layer, applying a dry film onto the seed layer using a laminating roll device, cutting the dry film applied onto the seed layer to a predetermined size, applying pressure and heat to the dry film, forming a plating resist on the seed layer from the dry film using photographic technology, forming an electrolytic plating film on part of the seed layer exposed from the resist, removing the resist from the seed layer, and removing the part of the seed layer exposed from the electrolytic plating film. The applying of the pressure and heat includes applying the pressure and heat to the dry film applied onto the seed layer such that the pressure and heat are applied to the entire surface of the dry film cut to the predetermined size simultaneously.

In a method for filling through-holes of a substrate with a metal paste, an upper lamination foil is secured to the top surface of the substrate and a lower lamination foil is secured to the bottom surface of the substrate. A laser beam is used to generate a first plurality of holes in the upper lamination foil, and a second plurality of holes in the lower lamination foil. Respective locations of the first and second plurality of holes are aligned with the through-holes of the substrate. Metal paste is applied into the through-holes through the first plurality of holes using a squeegee or a knife. Any metal paste that is pressed out from the second plurality of holes may be scraped off by the squeegee or the knife and recycled. Finally, the upper and lower lamination foils may be removed from the substrate.

A wiring board includes: a support body including at least one woven fabric woven from weaving yarns that are each formed by bundling insulating fibers; and a conductive body supported by the support body. The conductive body includes a first conductive path disposed on a first main face of the support body and that extends in a planar direction of the first main face. The first conductive path includes at least one of a first conductor portion disposed in a basket hole of the woven fabric and a first intervening portion disposed in a gap between the insulating fibers.