An ultrasonic welding system is provided. The ultrasonic welding system includes a support structure for supporting a workpiece. The ultrasonic welding system also includes a weld head assembly including an ultrasonic converter carrying a sonotrode. The ultrasonic welding system also includes a conductive pin supply configured to provide a plurality of conductive pins for welding using the sonotrode.

A method for assembling components implementing includes a pre-treatment of the solder bumps allowing an assembly by fluxless and residue-free soldering. A first component carrying solder bumps is assembled with a second component carrying connectors. Beforehand, a pre-treatment of the components carrying solder bumps is carried out by contacting them with a pre-treatment liquid which makes their subsequent fluxless and residue-free soldering possible.

An adhesive member is between an electronic component and an electronic panel that are connected to each other through the adhesive member. The adhesive member has a second surface and a first surface. The adhesive member includes a first recess pattern recessed from the first surface and a second recess pattern recessed from the first surface. The second recess pattern is spaced apart in a first direction from the first recess pattern. A sum of a planar area of the first recess pattern and a planar area of the second recess pattern ranges from about 20 percent (%) to about 70% of a planar area of the first surface.

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 light radiation emitting device including at least one LED-type device capable of generating a light radiation in a predefined wavelength range and having two electrical contact pads, and a support delimited by first and second opposite sides defining together a thickness of the support, the support supporting at least one LED luminous device and at least one conductive electric track. The electric track is formed of conductive wires. All or part of the conductive wires are bonded to the support along all or part of their length. All or part of the conductive wires have at least one contact portion exposed towards at least one of the first and second sides of the support. Each of the contact pads of the LED-type device is positioned opposite a contact portion of one of the conductive wires and is electrically connected to the contact portion.

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 printed wiring board includes an insulating layer and a conductor part. The insulating layer includes a cavity perpendicular to a first surface of the insulating layer. The conductor part includes a connection conductor fitted in at least part of the cavity. The cavity includes a first recess provided in an inner wall surface of the cavity. The connection conductor is partially fitted in the first recess. The first recess includes a second recess provided in an inner wall surface of the first recess. The connection conductor is partially fitted in the second recess.

A method of fabricating a display device may include disposing a display panel on a stage to be parallel to an XZ-plane defined by a horizontal X-axis and a vertical Z-axis, measuring a height of a first side surface of the display panel in a direction of the Z-axis, rotating the stage such that the first side surface is parallel to a reference horizontal line in case that a result of the measured height indicates that the first side surface includes an inclined surface, moving the display panel in a direction of the Z-axis such that a first pad disposed on the first side surface overlaps the reference horizontal line, and bonding a second pad of a printed circuit board with the first pad.

A flexible circuit comprises a laminated substrate, a layer of a protective coating, and first and second components. The laminated substrate comprises a support layer and a conductive layer arranged on the support layer. The conductive layer includes conductive traces. Edges of the conductive traces taper outwardly and towards the support layer. The layer of the protective coating is deposited on the conductive traces. The first component is soldered at a first connection point on one of the conductive traces. The soldering sublimates the protective coating. The second component is connected to the conductive layer at a second connection point. The second connection point is free of the protective coating.

A present invention provides a method for manufacturing a printed wiring board having excellent plating adhesion to a resin substrate having low surface roughness such as having surface roughness Ra of 0.2 μm or less, having excellent treating solution stability, and having high penetrability into the resin substrate. The method for manufacturing a resin substrate includes a step 1A or a step 1B; and a step 2 after the step 1A or the step 1B; and the steps are conducted before conducting electroless plating.