A manufacturing method for flexible printed circuit board is provided, in which a flexible insulating material and a metal material are liquefied and the liquefied materials are coated and solidified to form a flexible insulating layer and an anti-EMI layer of an anti-EMI structure, respectively. As such, an adhesive layer can be eliminated and the thickness of the flexible insulating layer and the anti-EMI layer can be reduced and an amount of materials consumed is also reduced, resulting in reduction of production cost, reduction of thickness of the flexible printed circuit board with anti-EMI structure, and improved quality.

The invention provides a manufacturing method for flexible printed circuit board, by liquefying the flexible insulating material and the metal material, coating the liquefied materials and solidifying the coated layers to form respectively the flexible insulating layer and the anti-EMI layer of the anti-EMI structure. As such, an adhesive layer is eliminated to achieve reducing the thickness of the flexible insulating layer and the anti-EMI layer and the material consumption, resulting in reduced production cost, reduced thickness of the flexible printed circuit board with anti-EMI structure, and improved quality.

In one aspect, a liquid-based encapsulation system includes an electronic material having a plurality of exposed surfaces; and an encapsulating liquid disposed over an entirety of the exposed surfaces of the electronic material to prevent diffusion of water past the encapsulating liquid and to protect the electronic material from water. In one aspect, a method of making a liquid-based encapsulation system includes providing an electronic material having a plurality of exposed surfaces; and encapsulating the electronic material with an encapsulating liquid over an entirety of the exposed surfaces of the electronic material to prevent diffusion of water past the encapsulating liquid and to protect the electronic material from water.

A method for manufacturing traces of a printed circuit board (PCB) comprises an application of the periodic pulse reverse (PPR) pattern plating process. In the first stage, walls and bottoms in drilled holes of the PCB are modified with reduced graphene oxide (rGO) so that the vias can be formed by filling with copper and a very thin copper layer can be formed on the substrate through the electroplating process. In the second stage, a pattern of very fine traces with width/space less than 30/30 m is formed on the thin copper layer and then the traces are formed through the PPR pattern plating process. After removing unwanted copper layer, the traces with even thicknesses and square profiles are achieved and thus conform to requirements of the high density interconnection (HDI) technology.

To provide a liquid composition whereby a resin powder can be uniformly dispersed in a resin or the like without being scattered, and a method for producing a film, a laminate or the like by using the liquid composition. The liquid composition comprises a liquid medium and a resin powder dispersed in the liquid medium, and characterized in that the average particle size of the resin powder is from 0.3 to 6 m, the volume-based cumulative 90% diameter of the resin powder is at most 8 m, and the resin powder is a resin containing a fluorinated copolymer having a specific functional group. And, the method is a method for producing a film, a laminate or the like by using the liquid composition.

Various embodiments are directed to a method of forming an apparatus including placing a first electronic circuit in contact with a second electronic circuit, wherein each of the first and second electronic circuits have connector circuits configured and arranged to provide an electrical connection between the first and second electronic circuits and are formed with a polymer film that is configured to adhere, via self-healing, to another polymer film. The method further includes, in response to the contact, causing or facilitating the self-healing of the respective polymer films of the first and second electronic circuits, thereby creating the electrical connection therebetween.

A manufacturing method of a composite substrate is provided. A first conductive layer is formed on a first liquid crystal polymer layer. The first conductive layer is patterned to form a patterned first conductive layer. A second liquid crystal polymer layer including a soluble liquid crystal polymer is formed to cover the patterned first conductive layer. The second liquid crystal polymer layer which is on the patterned first conductive layer is removed.

The curved-type rigid board includes: a main sheet layer capable of maintaining a curved state with a certain curvature; a first adhesive layer formed on the main sheet layer; a sub sheet layer bonded onto the main sheet layer by the first adhesive layer while the sub sheet layer forms a line structure having diagonal lines, which do not match directions of horizontal and vertical lines of the mesh structure of the thermosetting resin of which the main sheet layer is made, in order for the main sheet layer to have rigidity to maintain the curved state; a second adhesive layer formed on the sub sheet layer; and a pattern forming layer bonded onto the sub sheet layer by the second adhesive layer.

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 method for manufacturing traces of a printed circuit board (PCB) comprises an application of the periodic pulse reverse (PPR) pattern plating process. In the first stage, walls and bottoms in drilled holes of the PCB are modified with reduced graphene oxide (rGO) so that the vias can be formed by filling with copper and a very thin copper layer can be formed on the substrate through the electroplating process. In the second stage, a pattern of very fine traces with width/space less than 30/30 m is formed on the thin copper layer and then the traces are formed through the PPR pattern plating process. After removing unwanted copper layer, the traces with even thicknesses and square profiles are achieved and thus conform to requirements of the high density interconnection (HDI) technology.