33results about How to "Does not reduce transmittance" patented technology

This invention discloses one LCD device, which comprises color filter base board and relative set film transistor basic board with LCD layer sealed between two basic boards, wherein, the filter slice comprises upper base board, black array, color resin and column pad; the film transistor array basic board comprises down base board, grating scan lie and data scan line; the adjacent electrode scan line and data line define one pixel area composed of film transistor and pixel electrode.

A display device. A transparent display device including an emitting area and a transmitting area is provided. An upper AR structure is disposed on an upper substrate. The upper AR structure includesan upper reflection-preventing layer and an upper color-compensating layer having a blue dye. As a result, the transparency of the transmitting area is increased.

This invention discloses one LCD device, which comprises color filter base board and relative set film transistor basic board with LCD layer sealed between two basic boards, wherein, the filter slice comprises upper base board, black array, color resin and column pad; the film transistor array basic board comprises down base board, grating scan lie and data scan line; the adjacent electrode scan line and data line define one pixel area composed of film transistor and pixel electrode.

The invention provides an ultraviolet resistant finishing application and ultraviolet resistant finishing method of a baffeta of an ionic liquid metal complex, and an ultraviolet resistant baffeta. The finishing method comprises the steps that immersing the baffeta into aqueous solution containing ferrite, then adding imidazolyl ionic liquid salt, and stirring at 20 to 80 DEG C for 2 to 10 hours; afterwards, adding alkali, reacting at 20 to 80 DEG C for 2 to 10 hours, and washing and drying the baffeta. According to the technical scheme, a full-wave band ultraviolet resistant barrier property is achieved, an ultraviolet resistant finishing technique is simple, in-situ generation reaction conditions are mild, and the realization is easy.

The invention discloses a modified sulfonated poly ether ether ketone (SPEEK) membrane applied to a direct methanol fuel cell (DMFC) and a preparation method of the SPEEK membrane. The preparation method comprising the following steps: dissolving a polyether-ether-ketone (PEEK) resin in N, N-dimethylacetylamide or N, N-dimethyl formamide to form an SPEEK resin solution; adding a porphyrin compound to the SPEEK resin solution based on mass ratio of 1-50:1000 of the porphyrin compound to the SPEEK resin solution; and carrying out membrane-forming method such as a tape casting method, a pasting method and a gumming method on the obtained SPEEK resin solution of the porphyrin compound so as to prepare into the modified proton exchange membrane (PEM). In the preparation method, the porphyrin compound which does not penetrate through the methanol and can conduct protons is embedded or bonded to the ion channel of the SPEEK membrane so as to form a hydrogen ion sieve structure, thus maintaining higher proton transmissibility while greatly reducing transmissivity of the methanol, and simultaneously reducing the preparation cost of the proton exchange membrane.

The invention relates to a gallium arsenide solar cell and a preparation method thereof, belonging to the technical field of solar cells. In the gallium arsenide solar cell provided by the present invention, it includes a lower electrode, a substrate layer, a gallium arsenide epitaxial layer, an upper electrode, and an anti-reflection film in order from the backlight surface to the light-receiving surface of the cell; wherein, the anti-reflection film is a double layer structure, including TiO 2 @AZO is the inner anti-reflection layer and SiO made of raw materials 2 The outer anti-reflection layer is made of raw materials, the inner anti-reflection layer is arranged next to the upper electrode grid line, and the outer anti-reflection layer is arranged away from the upper electrode grid line; the TiO 2 @AZO for TiO 2 As the inner core, AZO is the core-shell structure of the outer shell. The battery uses TiO 2 @AZO is used as a raw material to be deposited on the surface of the upper electrode grid line or the surface of the epitaxial layer by vacuum evaporation to form an inner anti-reflection layer, which improves the conductive effect of the upper electrode and the transmittance of sunlight.

The invention provides a method for preparing a dye-sensitized solar cell. The method comprises the following steps of: preparing a photo-anode conductive glass substrate printed with a silver gate electrode and a counter electrode conductive glass substrate; evaporating a transparent LaB6 layer on the silver gate electrode of the photo-anode conductive glass substrate; spraying a silane couplingagent layer on the photo-anode conductive glass substrate again; drying the silane coupling agent layer and printing a titanium dioxide thin film layer in a gap of the photo-anode silver gate electrode; sintering the photo-anode conductive glass substrate; placing the sintered photo-anode conductive glass substrate in prepared dye solution to dye-sensitize the titanium dioxide thin film layer to prepare a photo-anode; preparing an inorganic insulating layer on the counter electrode conductive glass substrate, printing a platinum electrode, and sintering the substrate to prepare a counter electrode; and finally butting the photo-anode and the counter electrode, pouring electrolyte and packaging. The method of the invention can protect the silver gate electrode from being corroded by solution of titanium tetrachloride and solution of electrolyte, so that the stability of a cell module is ensured.

A method and device for realizing a vacuum high-precision window belong to the technical field of optical-mechanical-electrical engineering, aiming at solving the problem of low surface precision of the vacuum window in the prior art. The present invention constructs a method for realizing a stepped pressure differential vacuum window. The mounting seat is fixed to the mounting interface by screws, and the window glass A is mounted on the mirror seat A through the pressure ring and the sealing ring A, the sealing ring B and the sealing ring C. , a plurality of flexible adjustment knobs A are evenly distributed on the circumference between the mirror base A and the mounting base; Sealing rings are used between the seats A for sealing installation, and a plurality of flexible adjustment knobs B are evenly distributed on the circumference between the mirror seat A and the mounting seat B; n pieces of window glass A or window glass B are used for continuous installation. The realization method and device of the high-precision vacuum window of the present invention are simple in operation, high in surface shape precision, simple in structure, and convenient for disassembly and maintenance.

The invention provides a display device, which relates to the field of display technology, and is used for realizing the antistatic protection function under the premise of not reducing light transmittance and meeting the requirement of a narrow frame display device. Wherein the display device includes: a display panel, a cover plate superimposed on the display panel, an antistatic layer arranged on the side of the cover plate facing the display panel, and the antistatic layer surrounds the display device display area, and the antistatic layer is grounded. The aforementioned display device is used for screen display.

The invention relates to an ultra-low density silica airgel with adjustable transparency, a preparation method and application thereof. The method comprises the following steps: forming a thin layer of long-chain alkane on the inner surface of a mold; adding sol for preparing ultra-low-density silica airgel to the mold to obtain a transparent wet gel; raising the temperature to restrict the diffusion of long-chain alkane on the surface of the mold Enter the interior of the gel, and obtain an opaque wet gel after cooling; put the opaque wet gel into an ethanol solution containing long-chain alkanes for solvent replacement to obtain an alcohol gel; dry the alcohol gel with supercritical carbon dioxide to obtain a transparent tuned ultra-low density silica airgel. The light transmittance of the airgel prepared by the present invention has obvious temperature responsiveness. When the ambient temperature is lower than the long-chain alkane phase transition temperature, the aerogel is completely opaque under visible light. When the ambient temperature is higher than the long-chain alkane phase transition temperature At high temperature, airgel is completely transparent under visible light, and has great application value in smart home, high-end display, personal privacy and other fields.

The present invention provides an array substrate, including a first area corresponding to a display area of ​​a display panel, a second area located outside the first area corresponding to a non-display area, and a third area located outside the second area. area; the first area and the second area are provided with at least two data lines parallel to each other and at least two scan lines perpendicular to the data lines; the third area is provided with fan-out lines, and at least one adapter line intersecting with the fan-out line on a different plane; the fan-out line is correspondingly connected to the data line or the scan line in the first area; one end of the adapter line is connected to the first For the data line or the scan line in the second area, the other end of the adapter line forms a break point; beneficial effect: the present invention neither reduces the transmittance nor reduces the transmittance of the pixel area by designing multiple data lines and scan lines By increasing the size of the panel, any disconnection in the panel can be repaired.

The invention discloses a metal nanowire network coated with graphene or metal oxide and a preparation method thereof. The preparation method comprises the following steps that a metal nanowire grid is prepared on a substrate, and then the following 1) or 2) is carried out; 1), graphene oxide is deposited on the surface of the metal nanowire grid by utilizing an electrochemical deposition method, the graphene oxide is reduced to the graphene, and then the metal nanowire grid coated with the graphene is obtained; and 2), the metal oxide is deposited on the surface of the metal nanowire grid by utilizing the electrochemical deposition method, and then the metal nanowire grid coated with the metal oxide is obtained. According to the preparation method, the graphene or the metal oxide is selectively deposited on the surface of the metal nanowire network by utilizing electrochemical deposition, and thus the stability of the metal nanowire network is improved without influencing the photoelectric property of the metal nanowire network; and the thickness of the shell layer of the graphene or the metal oxide can be controlled by controlling reaction conditions of the electrochemical deposition, and the transmittance of the metal nanowire network is hardly reduced.

The invention provides a color-film substrate and a display panel. The color-film substrate comprises a substrate body, a black matrix arranged on the substrate body and a color-film layer and further comprises a light processing unit, wherein the light processing unit is arranged on the side, away from the substrate body, of the black matrix, and the light processing unit can make backlight irradiated to the light processing unit and forming an included angle with the substrate body in a set range refract and then irradiated into the black matrix. The color-film substrate can make the backlight forming the included angle with the substrate body in the set range refract and then irradiated into the black matrix so as to avoid backlight and a display picture color-crossing phenomenon caused by penetration of a color film with more than two colors by arranging the light processing unit, and accordingly the color-crossing problem during display of the display panel is improved. In addition, the light processing unit does not reduce the aperture opening ratio of the display panel while improving the color-crossing phenomenon and also does not reduce the transmittance rate of the backlight.