Full-automatic microelectronic printer comprising a printing platform, a control component, a feeding component, a camera component, a machine vision device, an ink droplet observation device, and a CAD/CAM system. The printing platform comprises a four-axis linkage system, a printing worktable, a base, a protective housing, an automatic ink cartridge turning device, and an automatic cleaning device; the feeding component comprises a switching control device, an ink cartridge, and an auxiliary processing component; the control component comprises a core control integrated circuit board, a plurality of drive control circuit boards, and a control module interface. The feeding component switches the ink cartridges and the auxiliary processing components to the printing platform in response to the control component which drives the ink cartridges and auxiliary processing components to print, and the protective housing removes fine particles and gas odors. CAD/CAM system assists in designing, generating, and sending instruction to the control component, printing platform, and feeding component to operate and realize full-automatic multi-layer printing.

Graphene ink compositions comprising nitrocellulose and related methods of use comprising either thermal or photonic annealing.

A circuit forming method, comprising: a coating step of applying a metal-containing liquid and a metal paste in an overlapping manner on a base, the metal-containing liquid containing fine metal particles and the metal paste containing a resin binder and metal particles larger than the fine metal particles in the metal-containing liquid; and a heating step of making the metal-containing liquid and the metal paste coated in the coating step conductive by heating the metal-containing liquid and the metal paste.

A component mounting method includes an application step of applying a specific solder paste including Sn and a metal other than Sn to a board; a disposition step of positioning and disposing an upper surface reference type component having a positioning reference on an upper surface with respect to one or more reference points on the board; and a reflow step of reflow-soldering the component by heating the board, in which in the specific solder paste, at least a part of the Sn is melted, and molten Sn and the metal other than Sn form an intermetallic compound in the reflow step, thereby fixing the upper surface reference type component to the board.

An application mechanism according to one embodiment of the present invention serves as an application mechanism that applies an application material onto a substrate using an application needle. The application mechanism according to one embodiment of the present invention includes: a holder base; a slide mechanism attached to an inside of the holder base; an application needle fixing member, to which the application needle is attached, the application needle fixing member being supported by the slide mechanism so as to be slidable in an extending direction of the application needle; and a position holding mechanism that holds a relative position of the application needle fixing member with respect to the slide mechanism.

An apparatus for producing a printed circuit board on a substrate, has a table for supporting the substrate, a function head configured to effect printing conductive and non-conductive materials on the substrate, a positioner configured to effect movement of the function head relative to the table, and a controller configured to operate the function head and the positioner to effect the printing of conductive and non-conductive materials on the substrate. The apparatus optionally has a layout translation module configured to convert PCB files or multilayer PCB files to printing data for controlling the function head to print conductive material and nonconductive material onto the substrate. The apparatus has a testing head to verify conductors which operates automatically. The translation module also prints nonconductive material component alignment areas and nonconductive material substrate stiffeners.

A method of forming a structure upon a substrate is disclosed. The method comprises: providing a substrate upon a surface of which a plurality of electrically conductive pads are disposed; depositing fluid containing a dispersion of electrically polarizable nanoparticles onto the substrate such that at least a portion of a first one of the plurality of pads is in contact with the fluid; applying an alternating electric field to the fluid using a first electrode and a second electrode, the first electrode being positioned so as to provide an effective first electrode end position from which the electric field is applied, coincident with the deposited fluid, and spaced apart from the first pad by a distance, and the second electrode being in contact with the first pad, such that a plurality of the nanoparticles are assembled to form a first elongate structure extending along at least part of the distance between the effective first electrode end position and the portion of the first pad.

A component carrier includes a carrier body formed of a plurality of electrically conductive layer structures and/or electrically insulating layer structures, a metal surface structure coupled to the layer structures and a metal body directly on the metal surface structure formed by additive manufacturing.

A manufacturing apparatus that includes a conveyance device that moves a stage, where an electronic device shaped by multiple layers is placed, in X-axis and Y-axis directions. A first shaping unit, a second shaping unit, and a component mounting unit are arranged within a range in which the stage can move. The manufacturing apparatus performs additive manufacturing of the electronic device on the stage by performing a sequential movement of the stage to respective working positions of different units. As a result, in this manufacturing apparatus, a workpiece on the stage does not have to be removed and repositioned during each work process such as shaping by a first shaping unit, shaping by a second shaping unit, and electronic component mounting by a component mounting unit.

To provide a wiring formation method that can increase the wiring density in a case where wiring is formed on an inclined surface by three-dimensional additive manufacturing. The wiring formation method of the present disclosure includes a metal member forming step of forming multiple metal members with a first fluid containing metal particles, a resin layer forming step of forming a resin layer including an upper surface and an inclined surface inclined downward from the upper surface, and a connection wiring forming step of forming multiple connection wirings on the inclined surface and the upper surface of the resin layer with a second fluid containing metal particles, and the connection wirings being formed to individually connect the multiple connection wirings to the multiple metal members on a lower surface of the inclined surface.