An electronic device and a manufacturing method thereof are provided. The electronic device includes a circuit substrate, a plurality of electronic components, a plurality of carriers, and a bonding layer. The circuit substrate includes a circuit layer. The plurality of electronic components are disposed on the circuit substrate. The circuit layer is electrically connected to at least one of the plurality of electronic components. The plurality of carriers are disposed on the circuit substrate. The bonding layer bonds the plurality of carriers to the circuit substrate. At least one gap is between the plurality of carriers. A width of the gap is Wg. An average width of the plurality of carriers is Wa. A width of the circuit substrate is Wc. The electronic device satisfies: Wa*2*10.sup.?4<Wg<(Wc?Wa*2).

An electronic device includes: a first circuit board on which a first circuit is mounted; a second circuit board on which a second circuit is mounted; a supporter; a flexible flat cable disposed on the supporter and connecting the first circuit board and the second circuit board to each other, the flexible flat cable transmitting signals between the first circuit and the second circuit. The flexible flat cable is provided with a crease. The flexible flat cable is disposed such that the crease is in contact with the supporter.

One aspect of the present invention relates to a method for manufacturing a substrate with a conductive pattern, the method including: a base forming step of forming a plating base in a desired pattern on at least a portion of one surface of a stretchable substrate, wherein the stretchable substrate has a tensile modulus at 20? C. of 0.1 MPa or more and 500 MPa or less, an elongation at break of 100% or more and 1000% or less, and a storage modulus at 250? C. of 0.1 MPa or more; a bending step of bending the stretchable substrate; and a conductive pattern forming step of plating the plating base after performing the bending step to form a conductive pattern on the stretchable substrate.

A method for manufacturing a stretchable circuit board includes preparing a laminate in which a metal layer and a first stretchable insulating layer are in contact with each other and a peel strength between the metal layer and the first stretchable insulating layer is 0.5 N/mm or more and 3.0 N/mm or less, a second stretchable insulating layer, and a fluid; forming a via leading from a first surface, in contact with the metal layer, of the first stretchable insulating layer to a second surface opposite to the first surface; filling the fluid in the via; laminating the second stretchable insulating layer on the second surface to seal the via; and patterning the metal layer.

According to an embodiment of the present disclosure, a structure constructed by a sheet includes a sheet body. The sheet body has a plurality of enclosed paths. A plurality of slits and connection portions are arranged along each enclosed path. Each connection portion is located between two adjacent slits. The sheet body is flexible. In an extended state, the slits form extended openings. At least one extended opening is a symmetric opening, so that the sheet body is extended to form a structure constructed by sheet. The structure constructed by sheet forms a stereoscopic curved surface, and the plurality of connection portions is located on a plurality of contours of the stereoscopic curved surface.

An object of the present invention relates to a thermosetting adhesive sheet that, without the use of a metal reinforcement sheet, which is regarded as a major factor responsible for an increase in thickness of electronic devices and other devices, reinforces a flexible printed circuit to such a level that detachment of mounted components, for example, is prevented, prevents warping, and has good electrical conductivity. The present invention relates to a thermosetting adhesive sheet configured to be used to reinforce a flexible printed circuit. The thermosetting adhesive sheet includes a woven fabric, a nonwoven fabric, or a metal base of 50 m or less thickness and a thermosetting adhesive layer adjacent to at least one surface of the woven fabric, the nonwoven fabric, or the metal base of 50 m or less thickness.

A wearable item comprising a conductive transfer applied to a surface of the wearable item is described. The conductive transfer comprises first and second non-conductive ink layers and an electrically conductive layer positioned between the two non-conductive ink layers. The transfer also has an adhesive layer which adheres the conductive transfer to the surface of the wearable item. The conductive transfer is configured to withstand elongation such that the resistance of the electrically conductive layer provides a resistance within a pre-specified range.

A package substrate includes a dielectric layer, a first circuit layer, a second circuit layer and at least one electrically conductive pole. The dielectric layer includes a first side and a second side opposite to the first side. The first circuit layer is located at the first side of the dielectric layer, and includes a plurality of spaced first circuit patterns embedded into the dielectric layer. The second circuit layer is located at the second side of the dielectric layer, and includes a plurality of spaced second circuit patterns located on the second side the dielectric layer. The electrically conductive pole electrically couples the first circuit layer to the second circuit layer. Each of the first circuit patterns has an extension direction from the first side toward the second side, and has widths gradually decreasing along the extension direction.

According to an aspect of the present inventive concept there is provided a system comprising: a conductive textile including conductive fibers, an electronic circuit unit arranged on a first main surface of the conductive textile and including circuitry and a carrier supporting the circuitry, the carrier having a first main surface and a second main surface facing the first main surface of the textile and including a through-hole extending from the first main surface to the second main surface, a conductive pin including an leg segment arranged at least partly in the through-hole, and a grip segment arranged to grip about at least one fiber of the conductive textile. There is also provided a method for mounting an electronic circuit unit on a conductive textile.

A device for attachment of double-sided adhesive and a method for attachment of the double-sided adhesive are provided. The device includes a driver, a platform and a robot arm provided above the platform. The robot arm is connected with the driver and configured to, under the driving of the driver, place the double-sided adhesive onto a preset position of the platform, strip off the first protective film of the double-sided adhesive at the preset position, press the printed circuit board assembly (PCBA) at the preset position against the double-sided adhesive without the first protective film, and unload the PCBA attached with the double-sided adhesive from the preset position. A positioning structure is provided at the preset position and configured to secure the adhesive layer and the second protective film when the robot arm strips off the first protective film, and release the securing of the adhesive layer and the second protective film when the double-sided adhesive is attached to the PCBA.