An electronic device is provided. The electronic device includes a hinge structure, a first housing structure, a second housing structure that is foldable with the first housing structure, a foldable housing, a flexible display, a first mid-plate disposed on one side of the first housing structure, a second mid-plate disposed on one side of the second housing structure, a flexible printed circuit board (FPCB) extending between the first mid-plate and the second mid-plate, a first sealing member that seals a first opening formed in the first mid-plate, and a second sealing member that seals a second opening formed in the second mid-plate.

A mini smart card and a method of manufacturing the mini smart card are introduced. The method includes disposing bilayered print layers on a top side and a bottom side of a circuit layer, respectively; performing a heat-compression treatment and then a printing treatment on the circuit layer and the bilayered print layers; removing surface layers from the bilayered print layers; and disposing transparent protective layers on the bilayered print layers, respectively. The bilayered print layers are prevented from deforming under the heat generated during the printing treatment. Removal of the surface layers from the bilayered print layers effectively reduces the thickness of the mini smart card.

A bending apparatus including a stage on which a bending object is positioned, a bending bar, a drive unit connected to the bending bar and configured to move the bending bar according to a standard route to bend the bending object by coming into contact with the bending object, and a measuring unit that measures a movement route of the bending bar.

A circuit module (100) includes: a substrate (10) including a plurality of inner conductors (2); a first electronic component arranged on one main surface (S1) of the substrate (10); a first resin layer (40) provided on the one main surface (S1) and configured to seal the first electronic component; a plurality of outer electrodes (B1) provided on another main surface (S2) of the substrate (10) and including a ground electrode; a conductor film (50) provided at least on an outer surface of the first resin layer (40) and a side surface (S3) of the substrate (10) and connected to the ground electrode with at least one of the plurality of inner conductors (2) interposed therebetween; and a resin film (60).

A circuit module (100) includes: a substrate (10) including a plurality of inner conductors (2); a first electronic component arranged on one main surface (S1) of the substrate (10); a first resin layer (40) provided on the one main surface (S1) and configured to seal the first electronic component; a plurality of outer electrodes (B1) provided on another main surface (S2) of the substrate (10) and including a ground electrode; a conductor film (50) provided at least on an outer surface of the first resin layer (40) and a side surface (S3) of the substrate (10) and connected to the ground electrode with at least one of the plurality of inner conductors (2) interposed therebetween; and a resin film (60).

According to an aspect of the present disclosures, a method of making a flexible printed circuit board, which includes a base film having an insulating property, a conductive pattern disposed on either one or both surfaces of the base film, and a cover layer covering a conductive-pattern side of a laminated structure inclusive of the base film and the conductive pattern, includes a superimposing step of superimposing a cover film on the conductive-pattern side of the laminated structure, the cover film having a first resin layer and a second resin layer that is laminated to an inner side of the first resin layer and that softens at a lower temperature than does the first resin layer, and a pressure bonding step of vacuum bagging the laminated structure and the cover film at a temperature higher than a softening temperature of the second resin layer.

A component carrier assembly includes a first component carrier having a first electrically insulating layer structure and a via in the first electrically insulating layer structure, where the via is at least partially filled with electrically conductive material and where an upper part of the via extends beyond an outer main surface of the first component carrier; and a second component carrier having a second electrically insulating layer structure, and an electrically conductive adhesive material that is at least partially embedded in the second electrically insulating layer structure. The first component carrier and the second component carrier are interconnected and the upper part of the via at least partially penetrates into the electrically conductive adhesive material.

An electronic device includes a display panel having first pads, a circuit board that includes second pads corresponding to the first pads, and a conductive adhesive member disposed between the display panel and the circuit board to connect the first pads and the second pads, in which the conductive adhesive member includes a first resin layer adjacent to the display panel, a second resin layer disposed between the first resin layer and the circuit board and having a curing agent different from that of the first resin layer, and conductive particles disposed in the first resin layer wherein at least one of the second pads protrudes through the second resin layer and is in contact with the conductive particles.

A display device and a chip-on-film structure thereof are provided. The chip-on-film structure includes a substrate, multiple first output pads, multiple second output pads, multiple first lead wires, and multiple second lead wires. The substrate has a surface including a bonding zone. The first and output pads are located in the bonding zone. The first lead wires and the first output pads are located on the same surface of the substrate. The first lead wires and the second lead wires are located on two opposite surfaces of the substrate. Each of the first lead wires is connected to one of the first output pads. Each of the second lead wires is connected to one of the second output pads. The second lead wires each have a portion corresponding to the bonding zone and having the terminal sections that are respectively opposite to the first and second output pads.

Disclosed is a printed circuit board (PCB) module including a first PCB comprising a base PCB, a sidewall disposed on a periphery of the base PCB, and conductive vias penetrating the sidewall, a second PCB disposed on the sidewall to cover a cavity formed by the sidewall of the first PCB, and at least one electronic component disposed inside the cavity and located on the first PCB and/or the second PCB, wherein the sidewall comprises a first layer disposed on an upper face of the base PCB and constructed of an insulating member, a second layer disposed on the first layer and comprising a polyimide, a third layer disposed on the second layer and constructed of an insulating member, and a fourth layer disposed on the third layer and comprising a conductive member conductive with respect to the conductive vias.