Abstract: A touch display device is provided in some embodiments of the present disclosure, including a transparent cover, a patterned touch sensing film layer, a light-shielding layer, and a UV-blocking layer. The patterned touch sensing film layer covers a first surface of the transparent cover. The light-shielding layer is located between the transparent cover and the patterned touch sensing film layer. The UV-blocking layer prevents UV from irradiating the light-shielding layer. The UV-blocking layer is located between the light-shielding layer and the patterned touch sensing film layer and covers the light-shielding layer. A method of forming a touch display device is also provided. The touch display device and formation method thereof provided in some embodiments avoid the injury of the light-shielding layer caused by the laser by disposing of the UV-blocking layer in the single-side electrode structure, which replaces the wet etching steps and decreases the cost of the etching steps.

Abstract: A touch panel includes a thin-film substrate, a first conductive layer, and a second conductive layer. The thin-film substrate has a display region and a peripheral region defined thereon, has a first surface and a second surface opposite to each other, and has a thickness. The first conductive layer is disposed on the first surface and includes a plurality of first traces disposed in the peripheral region. The second conductive layer is disposed on the second surface and includes a plurality of second traces disposed in the peripheral region. The thin-film substrate has at least one groove at an interlaced region between one of the first traces and one of the second traces. The groove is in one of the first surface or the second surface and has a depth. The depth is between about 2.5 ?m and about one-half of the thickness.

Abstract: A touch display device is provided in some embodiments of the present disclosure, including a transparent cover, a patterned touch sensing film layer, a light-shielding layer, and a UV-blocking layer. The patterned touch sensing film layer covers a first surface of the transparent cover. The light-shielding layer is located between the transparent cover and the patterned touch sensing film layer. The UV-blocking layer prevents UV from irradiating the light-shielding layer. The UV-blocking layer is located between the light-shielding layer and the patterned touch sensing film layer and covers the light-shielding layer. A method of forming a touch display device is also provided. The touch display device and formation method thereof provided in some embodiments avoid the injury of the light-shielding layer caused by the laser by disposing of the UV-blocking layer in the single-side electrode structure, which replaces the wet etching steps and decreases the cost of the etching steps.

Abstract: An electronic device includes a flexible substrate and a plurality of metal wires. The flexible substrate includes a touch area and a peripheral area. The touch area includes a plurality of first electrodes, a plurality of insulating layers, and a plurality of second silver electrodes. The plurality of first electrodes include a first silver nanowires (SNW) conductive layer and a first conductive thin layer. The first conductive thin layer is located on the first silver nanowires (SNW) conductive layer. The insulating layers are located on the first electrodes. The plurality of second electrodes are located on the insulating layers and include a second silver nanowires (SNW) conductive layer and a second conductive thin layer. The insulating layers are configured to isolate the first electrodes from the second electrodes. The first electrodes, the second electrodes, or a combination thereof are coupled to the metal wires in the peripheral area.

Abstract: A mounting device for quick and easy mounting of an electronic device includes a mounting rack, a locking mechanism, and a support rack. The locking mechanism includes a movable locking rack, a shaft connected to the locking rack, and a locking ring on the shaft. The support rack includes an engaging element and groove, and when the support rack is moved toward the mounting rack during mounting, the free end of the engaging element passes through the lower side of the locking rack, and pushes against the locking ring. When mounted on the mounting rack, the bottom of the locking ring is in the engaging groove. When the support rack is raised up, the engaging element raises the locking rack to the magnetic part, and the locking rack is magnetically held to the magnetic part.

Abstract: A mounting device for quick and easy mounting of an electronic device includes a mounting rack, a locking mechanism, and a support rack. The locking mechanism includes a movable locking rack, a shaft connected to the locking rack, and a locking ring on the shaft. The support rack includes an engaging element and groove, and when the support rack is moved toward the mounting rack during mounting, the free end of the engaging element passes through the lower side of the locking rack, and pushes against the locking ring. When mounted on the mounting rack, the bottom of the locking ring is in the engaging groove. When the support rack is raised up, the engaging element raises the locking rack to the magnetic part, and the locking rack is magnetically held to the magnetic part.

Abstract: An electronic device includes a flexible substrate and a plurality of metal wires. The flexible substrate includes a touch area and a peripheral area. The touch area includes a plurality of first electrodes, a plurality of insulating layers, and a plurality of second silver electrodes. The plurality of first electrodes include a first silver nanowires (SNW) conductive layer and a first conductive thin layer. The first conductive thin layer is located on the first silver nanowires (SNW) conductive layer. The insulating layers are located on the first electrodes. The plurality of second electrodes are located on the insulating layers and include a second silver nanowires (SNW) conductive layer and a second conductive thin layer. The insulating layers are configured to isolate the first electrodes from the second electrodes. The first electrodes, the second electrodes, or a combination thereof are coupled to the metal wires in the peripheral area.

Abstract: Disclosed is an adjustable internal support restraint device for roundness control of a cabin component. The present disclosure solves the problem that the existing cabin components are prone to roundness distortion in a heat treatment process. The adjustable internal support restraint device includes a central limiting column and at least two circumferential ejecting correcting assemblies that are coaxially mounted on the central limiting column in a sleeving manner. Each circumferential ejecting correcting assembly includes a mounting piece and a plurality of ejector blocks. The mounting piece is mounted on the central limiting column in a sleeving manner. The plurality of the ejector blocks are annularly arranged outside the mounting piece and are in threaded connection with the mounting piece. One side surface, close to the inner cavity profile of a cabin, of each ejector block and the inner cavity profile of the cabin are arranged according to the shapes.

Abstract: Disclosed is an adjustable internal support restraint device for roundness control of a cabin component. The present disclosure solves the problem that the existing cabin components are prone to roundness distortion in a heat treatment process. The adjustable internal support restraint device includes a central limiting column and at least two circumferential ejecting correcting assemblies that are coaxially mounted on the central limiting column in a sleeving manner. Each circumferential ejecting correcting assembly includes a mounting piece and a plurality of ejector blocks. The mounting piece is mounted on the central limiting column in a sleeving manner. The plurality of the ejector blocks are annularly arranged outside the mounting piece and are in threaded connection with the mounting piece. One side surface, close to the inner cavity profile of a cabin, of each ejector block and the inner cavity profile of the cabin are arranged according to the shapes.

Abstract: A touch panel having a visible area and a peripheral area includes a first substrate, a first metal nanowires layer, a first wiring component, and a first conductive adhesive layer. The first metal nanowires layer is formed on the surface of the first substrate and patterned to include a first sensing part corresponding to the visible area and a first connecting part corresponding to the peripheral area. The first wiring component includes a first carrier plate and a first peripheral trace. The first carrier plate is located corresponding to the peripheral area and has a hollow design corresponding to the visible area. The first peripheral trace is disposed on the surface of the first carrier plate adjacent to the side of the first metal nanowires layer. The first conductive adhesive layer, located corresponding to the peripheral area, is disposed between the first metal nanowires layer and the first wiring component.

Abstract: The present invention relates to a method for preparing ferrite/reducing metal composite particles and a method for preparing a high temperature resistant stealth coating based on 3D laser printing, belonging to the technical field of preparation of absorbing coatings. The present invention aims to solve the problems that an existing high-temperature absorbing coating has insufficient coating/matrix bonding force, the microstructure of the coating is difficult to control, and electromagnetic properties cannot be ensured. In the present invention, nano ferrite powder and nano reducing metal powder are prepared into composite particles by a mixing granulation process. In a sealed preparation chamber of a 3D printing device, composite particles are subjected to laser-induced in-situ reaction on the surface of a substrate to prepare a high temperature resistant stealth coating.

Abstract: A coiled battery cell, comprises: a first electrode plate, the first electrode plate comprising a first active material layer, the first active material layer completely covering two surfaces of the first electrode plate; an outermost circle of the coiled battery cell is a separator, the separator in the outermost circle is adjacent to the first electrode plate. A battery comprising the coiled battery cell is further disclosed. The purpose is to at least reduce the risk of short circuit as a result of tearing or breaking of the aluminum foil in the outer layer when the cell is dropped.

Abstract: A touch panel having a visible area and a peripheral area includes a first substrate, a first metal nanowires layer, a first wiring component, and a first conductive adhesive layer. The first metal nanowires layer is formed on the surface of the first substrate and patterned to include a first sensing part corresponding to the visible area and a first connecting part corresponding to the peripheral area. The first wiring component includes a first carrier plate and a first peripheral trace. The first carrier plate is located corresponding to the peripheral area and has a hollow design corresponding to the visible area. The first peripheral trace is disposed on the surface of the first carrier plate adjacent to the side of the first metal nanowires layer. The first conductive adhesive layer, located corresponding to the peripheral area, is disposed between the first metal nanowires layer and the first wiring component.

Abstract: A fingerprint identification apparatus includes a cover plate, an optic fingerprint identification device, and an adhesive. The optic fingerprint identification device has a light-transmitting window. The adhesive is disposed between the cover plate and the optic fingerprint identification device, and a projection of the adhesive on the cover plate surrounds a projection of the light-transmitting window on the cover plate.