A method of forming a flexible circuit, including providing a flexible flat cable with a first surface and a second surface. The first surface of the flexible flat cable is diametrically opposed to the second surface. A dispensing apparatus including a nozzle is further provided, and an extruded material is dispensed through the nozzle onto the first surface of the flexible flat cable. The extruded material is shaped into a pattern and cured onto the first surface of the flexible flat cable.

A circuit board includes a main portion and at least one uneven portion. The main portion is obtained by stacking a plurality of base sheets made of a flexible material in a predetermined direction and subjecting the stacked base sheets to compression bonding. The at least one uneven portion is provided on one of the base sheets. The uneven portion includes a concave portion and a convex portion extending in a direction perpendicular or substantially perpendicular to the predetermined direction. The concave portion is sunken in the predetermined direction. The convex portion protrudes in an opposite direction to the predetermined direction.

The present disclosure relates to a printed circuit board and a method of manufacturing the same. The printed circuit board includes: an insulating layer; a plurality of pads disposed on the insulating layer; and a plurality of insulating walls that are disposed on the insulating layer and cover side surfaces of the plurality of pads, respectively, but are not disposed on upper surfaces of the plurality of pads. The plurality of insulating walls are disposed to be spaced apart from each other on the first insulating layer.

A printed circuit board (PCB) comprises two or more PCB layers comprising of a dielectric core and conductive cladding on adjoining surfaces; one or more DC lines embedded in one or more layers of the two or more PCB layers; one or more RF signal lines embedded in one or more layers of the two or more PCB layers; wherein the one or more DC lines crosses over/under at least one of the RF signal lines to form at least one crossover, wherein the at least one crossover is no thicker than the PCB layer in which it is situated. The printed circuit board of claim 1, further comprising two or more generally parallel DC lines which converge to form a stack of superposed parallel DC lines where the two or more DC lines cross over the one or more RF signal lines.

A printed circuit board (PCB) having an improved waterproof structure for preventing corrosion of a substrate is disclosed. A plurality of screen-printed protrusions is provided at the PCB surface. the plurality of protrusions allow water to be formed in waterdrops so that the waterdrops can flow to the outside of the PCB. The PCB is arranged to have a tilted structure for facilitating discharge of the water. The tilted structure discharges waterdrops to a lower side of the PCB. The PCB and a PCB assembly having the same are applicable to electronic appliances such as a washing machine.

A printed circuit board (PCB) includes: a base substrate including a top surface including an electronic device mounting region; chip connection pads that are provided on the electronic device mounting region; a conductive pattern group that is provided on the top surface of the base substrate and includes an extended conductive pattern extending between two adjacent chip connection pads from among the chip connection pads, the extended conductive pattern being spaced apart from each of the two adjacent chip connection pads; and a solder resist layer that covers a part of the extended conductive pattern and is spaced apart from the chip connection pads.

A flexible printed circuit board including: a base film; an electrode pad disposed on one side of the base film; a circuit pattern connected with the electrode pad; a coverlay that overlaps at least a part of the circuit pattern; and a cover resin that overlaps the circuit pattern and at least a part of the coverlay. The coverlay includes a body portion and a protrusion protruded from the body portion.

A circuit board having a high reflectivity includes a wiring board, a first solder resist layer, and a second solder resist layer. The wiring board includes a wiring layer on an outer side, the wiring layer including wiring and a bond pad spaced from the wiring. The first solder resist layer, with opening and groove, covers the wiring layer, the bond pad is exposed from the opening but spaced from the first solder resist layer. The second solder resist layer infills the groove and covers the first solder resist layer but does not make contact with the mounting surface of the bond pad. A method for manufacturing such circuit board is also disclosed.

A wiring structure and a method for manufacturing the same are provided. The wiring structure includes a conductive structure and at least one conductive through via. The conductive structure includes a plurality of dielectric layers, a plurality of circuit layers in contact with the dielectric layers, and a plurality of dam portions in contact with the dielectric layers. The dam portions are substantially arranged in a row and spaced apart from one another. The conductive through via extends through the dam portions.

The present invention provides a printed circuit board assembly including a substrate having a plurality of conductive layers vertically sandwiched between a first cap-insulation layer and a second cap-insulation layer. The substrate has a first part, a second part and a third part. For protecting the conductive layers from moisture, each of the areas of the conductive layers corresponding to the second part is smaller than the area of the first cap-insulation layer corresponding to the second part for at least a first predetermined percentage, and each of the areas of the conductive layers corresponding to the second part is smaller than the area of the second cap-insulation layer corresponding to the second part for at least the first predetermined percentage.