Abstract: An insert-storage intravenous drip moving seat includes a main body, two extension support arms, an inverted V-shaped support arm and plural moving wheels. The two extension support arms form a V-shaped structure, and each is bent and connected to a fixed bar, so that a storage space is formed under the main body and the two extension support arms; the bottom of both ends of each fixed bar has a moving wheel; the inverted V-shaped support arm is connected to the two extension support arms; the bottom of the other ends of the inverted V-shaped support arm has one of the moving wheels; both moving wheels are disposed on the same radius distance; and a guide entrance is formed between the two fixed bars and corresponsive to the inverted V-shaped support arm to provide an insert-storage design of the inverted V-shaped arm by the guide entrance.

Abstract: An insert-storage intravenous drip moving seat includes a main body, two extension support arms, an inverted V-shaped support arm and plural moving wheels. The two extension support arms form a V-shaped structure, and each is bent and connected to a fixed bar, so that a storage space is formed under the main body and the two extension support arms; the bottom of both ends of each fixed bar has a moving wheel; the inverted V-shaped support arm is connected to the two extension support arms; the bottom of the other ends of the inverted V-shaped support arm has one of the moving wheels; both moving wheels are disposed on the same radius distance; and a guide entrance is formed between the two fixed bars and corresponsive to the inverted V-shaped support arm to provide an insert-storage design of the inverted V-shaped arm by the guide entrance.

Abstract: A solar power sunroof device having a low reflectance is for receiving and reflecting a solar ray and a visible ray. A substrate is illuminated by the solar ray. A front contact layer has a first upper connecting surface and a first lower connecting surface. The first upper connecting surface is connected to the substrate. A photoelectric conversion layer is connected between the first lower connecting surface and a back contact layer. A low reflective layer has a third upper connecting surface and a third lower connecting surface. The third upper connecting surface is connected to the back contact layer, and the third lower connecting surface has a visible light reflectance. The visible ray illuminates the third lower connecting surface of the low reflective layer, and the third lower connecting surface scatters or absorbs the visible ray so as to decrease the visible light reflectance.

Abstract: A touch panel includes a cover glass, a flexible substrate, and a touch-sensing electrode structure. The flexible substrate is connected to the cover glass via a bonding layer, and the touch-sensing electrode structure is formed on the flexible substrate. The cover glass, the bonding layer, the flexible substrate and the touch-sensing electrode structure are arranged in order, with the flexible substrate being located between the touch-sensing electrode structure and the bonding layer.

Abstract: A touch panel includes a cover glass, a flexible substrate, and a touch-sensing electrode structure. The flexible substrate is connected to the cover glass via a bonding layer, and the touch-sensing electrode structure is formed on the flexible substrate. The cover glass, the bonding layer, the flexible substrate and the touch-sensing electrode structure are arranged in order, with the flexible substrate being located between the touch-sensing electrode structure and the bonding layer.

Abstract: A touch panel structure and the manufacturing method thereof are disclosed, in which the manufacturing method includes the steps of: providing a bonding layer; and forming a conductive pattern layer on the bonding layer; wherein the conductive pattern layer is composed of at least one first and at least one second major conductors with an insulation layer interposed between the first and the second major conductors. Comparing with the prior art for manufacturing touch panels, the disclosure is advantageous in material cost, production cost, and production yield; moreover, the panel lamination process can be simplified and the touch panel structure can be joined to a planar or curvy panel and facilitate the design of a thinner product.

Abstract: A capacitive touch panel includes at least one first conductive series extending along a first direction and at least one second conductive series extending along a second direction on a substrate. The first conductive series includes a plurality of first electrodes disposed along the first direction and a plurality of first connecting electrodes respectively disposed between two adjacent first electrodes. The second conductive series includes a plurality of second electrodes disposed along the second direction and a plurality of second connecting electrodes respectively disposed between two adjacent second electrodes. The first direction intersects the second direction. At least one kind of elements of the first electrodes, the first connecting electrodes, the second electrodes, and the second connecting electrodes are formed from a metal mash layer, and the first conductive series and the second conductive series are electrically isolated from each other.

Abstract: A touch panel includes a substrate, at least one first axis electrode, and at least one second axis electrode. The first axis electrode is disposed on the substrate and extends along a first direction. The first axis electrode includes at least one first mesh. The second axis electrode is disposed on the substrate and extends along a second direction. The second axis electrode includes at least one second mesh. The first axis electrode at least partially overlaps the second axis electrode along a direction perpendicular to the substrate. An aperture ratio of a region where the first axis electrode overlaps the second axis electrode is substantially equal to an aperture ratio of a region where the first axis electrode does not overlap the second axis electrode.

Abstract: A touch panel includes a first substrate and a first composite material conductive layer. The first composite material conductive layer has a first multilayer structure. The first multilayer structure includes a first refraction index compensating layer, a second refraction index compensating layer, and a first metal conductive layer. The first refraction index compensating layer, the first metal conductive layer, and the second compensation layer are stacked on the first substrate, and an equivalent refraction index of the first composite material conductive layer is substantially between a refraction index of the first substrate and 1.1 times the refraction index of the first substrate.

Abstract: An electrowetting display device includes a lower substrate, an upper substrate, a medium layer, a lower electrode, an upper electrode, and a molecular chain layer. The medium layer is disposed between the lower substrate and the upper substrate. The medium layer includes a first medium and a second medium separated from each other. The first medium is a light transmission medium, and the second medium is a light-shielding medium. The lower electrode is disposed between the medium layer and the lower substrate. The molecular chain layer is disposed between the medium layer and the lower electrode. The molecular chain layer includes molecular chains. Each molecular chain has a first section and a second section. The first section is used to attract the first medium or repel the second medium. The second section is used to attract the second medium or repel the first medium.

Abstract: A touch panel including a first substrate, a second substrate, a first sensing layer, a second sensing layer, and a plurality of spacers is provided. The second substrate is parallel to and opposite to the first substrate in a top-bottom manner. The first sensing layer is disposed on the first substrate and located between the first substrate and the second substrate. The second sensing layer is disposed on the second substrate. The spacers are located between the first sensing layer and the second sensing layer, and the spacers includes a plurality of movable first spacers and a plurality of second spacers fixed on the second substrate, wherein each of the first spacers is surrounded by a portion of the second spacers.

Abstract: A touch panel structure and the manufacturing method thereof are disclosed, in which the manufacturing method includes the steps of: providing a bonding layer; and forming a conductive pattern layer on the bonding layer; wherein the conductive pattern layer is composed of at least one first and at least one second major conductors with an insulation layer interposed between the first and the second major conductors. Comparing with the prior art for manufacturing touch panels, the disclosure is advantageous in material cost, production cost, and production yield; moreover, the panel lamination process can be simplified and the touch panel structure can be joined to a planar or curvy panel and facilitate the design of a thinner product.

Abstract: A touch-sensitive device includes a first and a second substrate and a first and a second touch-sensing electrode structure. The first touch-sensing electrode structure is disposed on the first substrate, and at least one touch position of a conductor is detected by sensing the capacitance variation of the first touch-sensing electrode structure. The second touch-sensing electrode structure is disposed on one side of the second substrate back to the first touch-sensing electrode structure. At least one touch position of an insulator is detected by sensing a variation of the interval between the first touch-sensing electrode structure and the second touch-sensing electrode structure.

Abstract: A method of driving an electronic paper solving an image sticking problem is provided. First, a frame writing process is executed, wherein a turn-on voltage is supplied to scan lines to enable transistors, and a frame data voltage is supplied to display units through data lines to write a frame. Then, a frame holding process is executed, wherein a turn-off voltage and an auxiliary data voltage are respectively supplied to the scan lines and the data lines to disable the transistors, and a first common voltage is provided by a common electrode layer. During the frame holding process, the first common voltage and the frame data voltage are applied to hold the frame, the turn-off voltage, the auxiliary data voltage, and the first common voltage are fixed voltages, and the auxiliary data voltage is substantially equal to the first common voltage and greater than the turn-off voltage.

Abstract: A touch panel includes a first and a second transparent substrates, a first and a second signal lines, a first polymeric conductive film, and a first and a second non-polymeric conductive films. The first signal line is formed on the first transparent substrate, the first polymeric conductive film is formed on the first transparent substrate, and the first non-polymeric conductive film is formed on the first polymeric conductive film. The second signal line is provided on the second transparent substrate, and the second non-polymeric conductive film is provided on the second transparent substrate.