Provided is a method of producing a wiring board capable of easily producing a wiring board, and a conductive ink. A method of producing a wiring board according to the present invention is a method of producing a wiring board using a transfer film including a support, a protective layer that is formed on one surface of the support and is peelable from the support, and a receiving layer that is formed on a surface of the protective layer and receives a solvent of a conductive ink including a conductive substance and the solvent, and the method has a wiring pattern forming step of forming a wiring pattern to the transfer film by performing printing using the conductive ink from a surface of the transfer film opposite to a surface on which the support is formed, an adhering step of, after the wiring pattern forming step, causing the surface of the transfer film on which the wiring pattern is formed opposite to the surface on which the support is formed to abut onto a substrate and causing the transfer film to adhere to the substrate, and a peeling step of, after the adhering step, peeling off the support from the transfer film caused to adhere to the substrate to obtain a wiring board.

A high density region for a low density circuit. At least a first liquid dielectric layer is deposited on the first surface of a first circuitry layer. The dielectric layer is imaged to create plurality of first recesses. Surfaces of the first recesses are plated electro-lessly with a conductive material to form first conductive structures electrically coupled to, and extending generally perpendicular to, the first circuitry layer. A plating resist is applied. A conductive material is electro-plated to the first conductive structure to substantially fill the first recesses, and the plating resist is removed.

A flexible conductive film and its manufacturing method are provided. A flexible touch screen and a flexible touch display panel including the flexible conductive film are also provided. The manufacturing method of a flexible conductive film includes: providing a first substrate; applying a first conductive metal ink on the first substrate and forming a first conductive metal pattern; applying a polyimide varnish on a surface of the first substrate having the first conductive metal pattern; soaking the first substrate in deionized water after the polyimide varnish has been solidified; and detaching the solidified polyimide varnish and the first conductive metal pattern from the first substrate to obtain the flexible conductive film. The flexible conductive film prepared can be used in a flexible touch screen and a flexible display panel to improve the adhesion of nanosilver material to a flexible substrate, and to improve its stability of mechanical strength.

A method for forming on a substrate (108; 214) a pattern of a material, the method comprising: providing (S100) a material layer (104); providing (S104, S106) an adhesive layer (106), wherein at least one of the material layer (104) or the adhesive layer (106) comprises a pattern corresponding to the pattern to be formed on the substrate (108; 214); and transferring (S108) the material to the substrate (108; 214) with the adhesive fixing the material to a surface (110; 216) of the substrate (108; 214). This solves the problem of forming on a substrate a pattern of a material that, in general, cannot be applied to the substrate directly due to the fact that the material cannot be printed and/or has no or reduced adherence properties with respect to the substrate.

For the purpose of simple integration of conductor circuits into composite material components, a method and an apparatus for producing composite material components of this kind are proposed, wherein a conductor circuit is printed onto or applied in some other way to a support, is provided with a thermally activatable adhesive and then the support is applied to a blank of the composite material component for joint curing. The curing at high pressure and high temperature creates a strong connection between the conductor circuit and the composite material component.

Electronic modules having complex contact structures may be formed by encapsulating panels containing pluralities of electronic modules delineated by cut lines and having conductive interconnects buried within the panel along the cut lines. Holes defining contact regions along the electronic module sidewall may be cut into the panel along the cut lines to expose the buried interconnects. The panel may be metallized, e.g. by a series or processes including plating, on selected surfaces including in the holes to form the contacts and other metal structures followed by cutting the panel along the cut lines to singulate the individual electronic models. The contacts may be located in a conductive grove providing a castellated module.

The present invention relates to a method for producing a flexible substrate. According to the method of the present invention, a flexible substrate layer can be easily separated from a carrier substrate even without the need for laser or light irradiation so that a device can be prevented from deterioration of reliability and occurrence of defects caused by laser or light irradiation. In addition, according to the method of the present invention, a flexible substrate can be continuously produced in an easier manner based on a roll-to-roll process.

An economical, efficient, and effective formation of a high resolution pattern of conductive material on a variety of films by polymer casting. This allows, for example, quite small-scale patterns with sufficient resolution for such things as effective microelectronics without complex systems or steps and with substantial control over the characteristics of the film. A final end product that includes that high resolution functional pattern on any of a variety of substrates, including flexible, stretchable, porous, biodegradable, and/or biocompatible. This allows, for example, highly beneficial options in design of high resolution conductive patterns for a wide variety of applications.

The disclosure relates to systems, methods and compositions for direct printing of printed circuit boards with embedded integrated chips. Specifically, the disclosure relates to systems methods and compositions for the direct, top-down inkjet printing of printed circuit board with embedded chip and/or chip packages using a combination of print heads with conductive and dielectric ink compositions, creating predetermined dedicated compartments for locating the chips and/or chip packages and covering these with an encapsulating layer while maintaining interconnectedness among the embedded chips. Placing of the chips can be done automatically using robotic arms.

System with at least two layers as a mean or system for transferring electrically conductive ink adapted to receive and transfer said ink on a textile substrate by a thermal transfer.