Abstract: A method forming a grating device includes: providing a substrate; entering the substrate into a process chamber; and depositing a grating material on the substrate to form a grating material layer on the substrate. A refractive index of the grating material gradually changes during depositing the grating material in the process chamber. The grating material layer includes a varying refractive index.

Abstract: A touch panel including a first insulation substrate, a first conductive film, a first insulation film, first conductive wires, a second insulation substrate, a second conductive film, and second conductive wires is provided. The first conductive film is disposed on the first insulation substrate and the first insulation layer covers a portion of a periphery of the first conductive film so that the first conductive film has an exposed region. The first conductive wires are disposed on the periphery of the first conductive film and each of the first conductive wires includes an electrode segment and an extending segment. The electrode segment is electrically connected with the first conductive film and the extending segment is electrically isolated from the first conductive film. The second conductive film is disposed on the second insulation substrate. The second conductive wires are disposed on the periphery of the second conductive film.

Abstract: A touch panel including a first insulation substrate, a first conductive film, a first insulation film, first conductive wires, a second insulation substrate, a second conductive film, and second conductive wires is provided. The first conductive film is disposed on the first insulation substrate and the first insulation layer covers a portion of a periphery of the first conductive film so that the first conductive film has an exposed region. The first conductive wires are disposed on the periphery of the first conductive film and each of the first conductive wires includes an electrode segment and an extending segment. The electrode segment is electrically connected with the first conductive film and the extending segment is electrically isolated from the first conductive film. The second conductive film is disposed on the second insulation substrate. The second conductive wires are disposed on the periphery of the second conductive film.

Abstract: The present disclosure relates to a method for making touch panel. A substrate having a surface is provided. The substrate defines two areas: a touch-view area and a trace area. An adhesive layer is formed on the surface of the substrate. The adhesive layer on the trace area is solidified. A carbon nanotube layer is formed on the adhesive layer. The adhesive layer on the touch-view area is solidified. The carbon nanotube layer on the trace area is removed. At least one electrode and a conductive trace is formed.

Abstract: A patterned conductive element includes a substrate having a surface, an adhesive layer located on the surface, and a patterned carbon nanotube layer located on the adhesive layer. Part of the patterned carbon nanotube layer is embedded in the adhesive layer, and the other part of the patterned carbon nanotube layer is exposed from the adhesive layer.

Abstract: The present disclosure relates to a method for making pattern conductive element. The method includes steps. A substrate having a surface is provide. An adhesive layer is formed on the surface of the substrate. Part of the adhesive layer is solidified to form a solidified adhesive layer and a non-solidified adhesive layer. A carbon nanotube layer is applied on the adhesive layer. The non-solidified adhesive layer is solidified so that the carbon nanotube layer on the non-solidified adhesive layer forms a fixed carbon nanotube layer and the carbon nanotube layer on the solidified adhesive layer forms a non-fixed carbon nanotube layer. The non-fixed carbon nanotube layer is removed and the fixed carbon nanotube layer is remained to form a pattern carbon nanotube layer.

Abstract: A method for making a plurality of touch panels one time which includes the following steps. A substrate is provided. The substrate has a surface defining a plurality of target areas with each including a touch-view area and a trace area. An adhesive layer is formed on the surface of the substrate. The adhesive layer on the trace areas is solidified. A carbon nanotube layer is formed on the adhesive layer. The adhesive layer on the touch-view area is solidified. The carbon nanotube layer on the trace areas is removed to obtain a plurality of transparent conductive layers spaced from each other. An electrode and a conductive trace are formed on each target area. A plurality of touch panels is obtained by cutting the substrate.

Abstract: The present disclosure relates to a method for making pattern conductive element. The method includes steps. A substrate having a surface is provide. An adhesive layer is formed on the surface of the substrate. Part of the adhesive layer is solidified to form a solidified adhesive layer and a non-solidified adhesive layer. A carbon nanotube layer is applied on the adhesive layer. The non-solidified adhesive layer is solidified so that the carbon nanotube layer on the non-solidified adhesive layer forms a fixed carbon nanotube layer and the carbon nanotube layer on the solidified adhesive layer forms a non-fixed carbon nanotube layer. The non-fixed carbon nanotube layer is removed and the fixed carbon nanotube layer is remained to form a pattern carbon nanotube layer.

Abstract: The present disclosure relates to a method for making touch panel. A substrate having a surface is provided. The substrate defines two areas: a touch-view area and a trace area. An adhesive layer is formed on the surface of the substrate. The adhesive layer on the trace area is solidified. A carbon nanotube layer is formed on the adhesive layer. The adhesive layer on the touch-view area is solidified. The carbon nanotube layer on the trace area is removed. At least one electrode and a conductive trace is formed.

Abstract: The present disclosure relates to a touch panel. The touch panel includes a substrate having a surface, a transparent conductive layer, at least one electrode, and a conductive trace. The substrate defines a touch-view area and a trace area. The transparent conductive layer is located on the surface of the substrate and on only the touch-view area. The transparent conductive layer includes a carbon nanotube film. The at least one electrode is electrically connected with the transparent conductive layer. The conductive trace is located on only the trace area and electrically connected with the at least one electrode.

Abstract: A patterned conductive element includes a substrate having a surface, an adhesive layer located on the surface, and a patterned carbon nanotube layer located on the adhesive layer. Part of the patterned carbon nanotube layer is embedded in the adhesive layer, and the other part of the patterned carbon nanotube layer is exposed from the adhesive layer.

Abstract: A soldering system includes a circuit board having first soldering terminals, a soldering object having second soldering terminals, soldering blocks disposed between the circuit board and the soldering object for electrically interconnecting the first soldering terminals and the second soldering terminals respectively, and a supporting structure supporting the soldering object and having a height that determines the height of the solder blocks. A related soldering method is also provided.

Abstract: A touch panel including a first insulation substrate, a first conductive film, a first insulation film, first conductive wires, a second insulation substrate, a second conductive film, and second conductive wires is provided. The first conductive film is disposed on the first insulation substrate and the first insulation layer covers a portion of a periphery of the first conductive film so that the first conductive film has an exposed region. The first conductive wires are disposed on the periphery of the first conductive film and each of the first conductive wires includes an electrode segment and an extending segment. The electrode segment is electrically connected with the first conductive film and the extending segment is electrically isolated from the first conductive film. The second conductive film is disposed on the second insulation substrate. The second conductive wires are disposed on the periphery of the second conductive film.

Abstract: A display device includes a circuit board connecting structure. The circuit board connecting structure includes a first circuit board, a soldering layer, and a second circuit board. The first circuit board includes a baseboard and a plurality of parallel elongate first electrodes defined at a predetermined area. The second circuit board includes a plurality of parallel elongate second electrodes positioned at the predetermined area. The second electrodes are electrically connected to the corresponding first electrodes via the soldering layer. A space defined by the projection of the second electrodes to the baseboard of the first circuit board is filled in by the soldering layer.

Abstract: A soldering system includes a circuit board having first soldering terminals, a soldering object having second soldering terminals, soldering blocks disposed between the circuit board and the soldering object for electrically interconnecting the first soldering terminals and the second soldering terminals respectively, and a supporting structure supporting the soldering object and having a height that determines the height of the solder blocks. A related soldering method is also provided.

Abstract: A backlight module (3) includes a light guide plate (31) having an incident surface (311), and a plurality of light sources (32) disposed opposite to the incident surface. Each of the light sources defines an encapsulation portion (321) to cover and protect core parts of the light source. A filler portion (33) is provided between the light source and the incident surface. A refractive index of the filler portion is the same as refractive indexes of the encapsulation portions and the light guide plate. Therefore a transmission rate of light beams from each light source to the light guide plate approaches or even is 1. Thus the transmission rate of the backlight module is correspondingly high. The arrangement of the filler portion between the light guide plate and the light sources decreases or even eliminates loss of light beams. Therefore the utilization of light beams and the brightness of the backlight module are improved.

Abstract: A device (1) for bonding two components (31, 32) includes a heating unit (11) and a lifting device (13) used to drive the heating unit to move. The heating unit includes a pressing device (17) including a pressing plate (171). The pressing plate can conduct heat, and the pressing plate is adapted to press the components. The bonding device can prevent protuberances from forming in a connecting part between the bonding components and can achieve reliable hot pressing result.