A flexible printed circuit and a manufacture method thereof, an electronic device module and an electronic device are provided. The flexible printed circuit includes a main sub-circuit board and a transfer sub-circuit board. The main sub-circuit board includes a first transfer terminal, a first wiring portion and a second wiring portion; and the transfer sub-circuit board includes a second transfer terminal and a third wiring portion, and the third wiring portion electrically connects a first group of second contact pads with a second group of second contact pads of the second transfer terminal. The transfer sub-circuit board is configured to be mounted on the main sub-circuit board by electrically connecting the first group of second contact pads to the first group of first contact pads and electrically connecting the second group of second contact pads to the second group of first contact pads.

In an electrical connection device in which a adhesive layer is disposed on a flexible base and a conductor pattern is provided on the adhesive layer, an elastomer pattern obtained by curing an ink containing an elastomer composition is formed on the adhesive layer, the conductor pattern obtained by curing an ink containing a conductive particle is formed on the elastomer pattern, and a longitudinal elastic modulus of the elastomer pattern is set to be larger than a longitudinal elastic modulus of the adhesive layer.

In an electrical connection device in which an adhesive layer is disposed on a flexible base and a conductor pattern is provided on the adhesive layer, an elastomer pattern obtained by curing an ink containing an elastomer composition is formed on the adhesive layer, the conductor pattern obtained by curing an ink containing a conductive particle is formed on the elastomer pattern, and a longitudinal elastic modulus of the elastomer pattern is set to be larger than a longitudinal elastic modulus of the adhesive layer.

A patterned article includes a unitary polymeric layer and a plurality of electrically conductive elements embedded at least partially in the unitary polymeric layer. Each electrically conductive element includes a conductive seed layer having a top major surface and an opposite bottom major surface in direct contact with the unitary polymeric layer, and includes a metallic body disposed on the top major surface of the conductive seed layer. The metallic body has a bottom major surface and at least one sidewall. The bottom major surface contacts the conductive seed layer. Each sidewall is in direct contact with the unitary polymeric layer and extends from the bottom major surface of the metallic body toward or to, but not past, a top major surface of the unitary polymeric layer. The conductive elements may be electrically isolated from one another. Processes for making the patterned article are described.

A method for equipping a film material with at least one electrically conductive conductor structure, wherein a dispersion containing metallic nanoparticles in the form of a conductor structure is applied to a thermostable transfer material and the metallic nanoparticles are sintered to form an electrically conductive conductor structure. The electrically conductive conductor structure of sintered metallic nanoparticles is then transferred from the thermostable transfer material to the non-thermostable film material. A method for producing a laminate material using the film material using at least one electrically conductive conductor structure, and to the corresponding film material and laminate material are described.

A method for equipping a film material with at least one electrically conductive conductor structure, wherein a dispersion containing metallic nanoparticles in the form of a conductor structure is applied to a thermostable transfer material and the metallic nanoparticles are sintered to form an electrically conductive conductor structure. The electrically conductive conductor structure of sintered metallic nanoparticles is then transferred from the thermostable transfer material to the non-thermostable film material. A method for producing a laminate material using the film material using at least one electrically conductive conductor structure, and to the corresponding film material and laminate material are described.

In some embodiments, the present invention is directed to an actuator which includes at least the following: a pre-stretched electro-active polymer film being pre-stretched in a single or biaxial planar directions; at least one first semi-stiff conductor attached to a first surface of the pre-stretched electro-active polymer film, wherein the first surface is parallel to the single or biaxial planar stretch directions; at least one second semi-stiff conductor attached to a second surface of the pre-stretched electro-active polymer film, wherein the second surface is opposite to the first surface; where the semi-stiff conductors are configured to: fix the pre-stretched electro-active polymer film in a pre-stretched state and allow the pre-stretched electro-active polymer film to expand; a pair of mechanical connectors coupled to each end of an active region of the pre-stretched electro-active polymer film.

A method for depositing a functional material on a substrate is disclosed. An optically transparent plate having a first surface and a second surface with one or more wells is provided. After coating the second surface with a thin layer of light-absorbing material, the wells are filled with a functional material. The plate is then irradiated with a pulsed light to heat the layer of light-absorbing material in order to generate gas at an interface between the layer of light-absorbing material and the functional material to release the functional material from the wells onto a receiving substrate located adjacent to the plate.

A method is disclosed for applying an electrical conductor to an electrically insulating substrate, which comprises providing a flexible membrane with a pattern of groove formed on a first surface thereof, and loading the grooves with a composition comprising conductive particles. The composition is, or may be made, electrically conductive. Once the membrane is loaded, the grooved first surface of the membrane is brought into contact with a front or/and back of the substrate. A pressure is then applied between the substrate and the membrane(s) so that the composition loaded to the grooves adheres to the substrate. The membrane(s) and the substrate are separated and the composition in the groove is left on the surface of the electrically insulating substrate. The electrically conductive particles in the composition are then sintered to form a pattern of electrical conductors on the substrate, the pattern corresponding to the pattern formed in the membrane(s).

The disclosure relates to methods, kits and compositions for direct printing of double-sided and/or multilayered printed circuit boards. Specifically, the disclosure relates to the printing of conductive leads and insulating portions of printed circuit boards using inkjet printing.