Apparatus and methods are disclosed for transferring solder to a substrate. A substrate belt moves one or more substrates in a belt direction. A decal has one or more through holes in a hole pattern that hold solder. Each of the solder holes can align with respective locations on one of the substrates. An ultrasonic head produces an ultrasonic vibration in the solder in a longitudinal direction perpendicular to the belt direction. The ultrasonic head and substrate can be moved together in the longitudinal direction to maintain the ultrasonic head in contact with the solder while the ultrasonic head applies the ultrasonic vibration. Various methods are disclosed including methods of transferring the solder with or without external heating.

A substrate is manufactured by drilling a chip containing groove in a composite inner layer circuit structure, having a component connecting end of a circuit layer protruding from a mounting side wall in the chip containing groove, mounting a chip component in the chip containing groove, and connecting the surface bonding pad to the component connecting end. The chip component in the present invention penetrates at least two circuit layers, and the surface bonding pad is bonded to the component connecting end of the circuit layer directly, reducing the occupied area of the chip component in each one of the circuit layers, and increasing the area for circuit disposing and the possible amount of chip components that may be mounted in the substrate.

A printed circuit board structure is disclosed for providing reliable solderability for higher density component placement. The printed circuit board structure includes conductive points disposed on the surface of a printed circuit board which are separated by a channel disposed in the surface of the printed circuit board between the conductive points. The conductive points may be surface mount component terminal pads. The printed circuit board structure is particularly useful for overcoming component density limitations related to extremely miniaturized surface mount components known in the art.

A method for applying ink to a printed circuit board to form a pattern, the method may include flooding the printed circuit board with ink, such that the ink advances within edges of the pattern; freezing the ink before the ink exceeds the edges of the pattern; and vibrating the printed circuit board during a vibration period that at least partially overlaps at least one of the flooding and the freezing.

A substrate is manufactured by drilling a chip containing groove in a composite inner layer circuit structure, having a component connecting end of a circuit layer protruding from a mounting side wall in the chip containing groove, mounting a chip component in the chip containing groove, and connecting the surface bonding pad to the component connecting end. The chip component in the present invention penetrates at least two circuit layers, and the surface bonding pad is bonded to the component connecting end of the circuit layer directly, reducing the occupied area of the chip component in each one of the circuit layers, and increasing the area for circuit disposing and the possible amount of chip components that may be mounted in the substrate.

Disclosed herein are an anisotropic conductive film including a polymer layer that restricts a movement of conductive particles and a method of manufacturing the same. An anisotropic conductive film (ACF) including a plurality of conductive particles according to an embodiment includes a polymer layer in which the plurality of conductive particles is dispersed and disposed and which restricts a movement of the plurality of conductive particles by capturing the conductive particles and an adhesive layer configured on the upper and lower parts of the polymer layer to assign adhesiveness.

A display device includes a display module and a circuit board. The display module includes a base substrate, which includes a display area and a non-display area adjacent to the display area, and a first pad positioned on the base substrate and overlapping the non-display area. The circuit board includes a first board and a second pad positioned on the first board and contacting the first pad, wherein the second pad is provided with a first metal layer of a single material.

Provided are a desmearing method and a desmearing device which are able to reliably remove a smear derived from any of an inorganic substance and an organic substance, and eliminate the need to use a chemical that requires a waste liquid treatment. The desmearing method of the present invention is directed to a desmearing method for a wiring substrate material that is a laminated body of insulating layers made from resin containing a filler and a conductive layer, and includes an ultraviolet irradiation treatment step for irradiating the wiring substrate material with ultraviolet beams with a wavelength of 220 nm or less, and a physical vibration treatment step for applying physical vibrations to the wiring substrate material which has undergone the ultraviolet irradiation treatment step.

Apparatus and methods are disclosed for transferring solder to a substrate. A substrate belt moves one or more substrates in a belt direction. A decal has one or more through holes in a hole pattern that hold solder. Each of the solder holes can align with respective locations on one of the substrates. An ultrasonic head produces an ultrasonic vibration in the solder in a longitudinal direction perpendicular to the belt direction. The ultrasonic head and substrate can be moved together in the longitudinal direction to maintain the ultrasonic head in contact with the solder while the ultrasonic head applies the ultrasonic vibration. Various methods are disclosed including methods of transferring the solder with or without external heating.

A display device includes a display module and a circuit board. The display module includes a base substrate, which includes a display area and a non-display area adjacent to the display area, and a first pad positioned on the base substrate and overlapping the non-display area. The circuit board includes a first board and a second pad positioned on the first board and contacting the first pad, wherein the second pad is provided with a first metal layer of a single material.