TH10219A - A method for manufacturing a light-emitting monitor assembly for use with cathode ray tubes. - Google Patents

Abstract

The methods for manufacturing the display on the support by electro-impregnation for use within the CRT, as defined in this invention, include the sequential processing of the conductive backing and the top coat. Optical conductors Electrostatic charge on the conductive layer by light and the exposure of a selected region of the optical conductive layer by using visible light to have an effect on the charge at This enhanced process uses a dry powder screen structural material with a surface charge regulator. It is present at least one type to control the triboelectric capacitance of the screen's structural material.

Claims (9)

1. In the manufacturing method of a panel emitting light on a support by an electrolytic process for use in CRTs, including the procedure of (a) the aforementioned coating of the screen part with a volatile conductive layer. (b) a coating over such a conductive layer with a photoconductive layer, including a visible light-sensitive dye (c) a uniform electrostatic charge on the substance layer. (D) illumination of a selected region of the photoconductor layer by using visible light to affect the charge present on that layer. (e) Applying a first type of triboelectric charge-emitting phosphor to the selected and exposed area of the photoconductive layer (f) Fix the first chromatic phosphor to adhere to the photoconductive layer (g). Repeat steps c, d, e and f respectively so that the phosphor emits light. The second and third types of colors that carry a bitriboelectric charge have created a light-emitting display made up of small parts. (H) Aluminum impregnation to the radiant panel and (i) baking the faceplate to eliminate elements. That evaporates from the light-emitting screen to form a set of such light-emitting monitors. Improvements in which the luminescent material consists of A dry powder particle with at least a surface charge regulator on the particle to control the particle's triboelectric charge holding. 2. Procedure for claim 1 where, after the first step (d), there is a method that includes an additional Shaping the underexposed regions of the photoconductive stage by means of a screen material that absorbs light as a dry powder that holds triboelectric charge. Including polymers and charge regulators The fixation of the structural material of the screen that absorbs the light is fixed and the conductive, uniform electrostatic charge is repeated on the photoconductive layer and on the structural material of the monitor that absorbs the light. 3. Claim Method 1 where, prior to the (a) procedure, the method includes the preliminary steps of forming a light-absorbing matrix commonly applied to the aforementioned inner surface of the section. The screen that is the face. 4. Method of claim 1, where the fixation step (f) consists of bonding the phosphor to the photoconductive layer by heat. 5. Method of claim 4, where the process of thermal bonding is performed by irradiating the phosphor with infrared radiation. 6. Method of claim 2 where the aforementioned fixing procedure includes lighting the screen material that absorbs the light using infrared radiation to bond the material to the conductive layer. Such light 7. Method for manufacturing a panel light-emitting panel on the inner surface of the colored CRT faceplate panel by an electro-imaging process consisting of the procedure of (a) the aforementioned coating of the said panel part with a Volatile Conductors (b) The coating over the conductors with volatile photovoltaic layers, including visible light-sensitive dyes. The dyes are selected from a group containing crystals, violet, chloridine, blue, and rhodamine, EG (c), a uniform electrostatic charge on the photoconductive layer (d). The light passes through a selected area of the photovoltaic layer. By using visible light from a xenon lamp to have an effect on the charges on the photoconductive layer (e), the image is formed at the underexposed region of the photoconductive layer. Light-absorbing screen materials in a dry powder-carrying triboelectric charge include polymers. And charge regulator The charge on the substrate material of such a monitor is of a state opposite to the charge on the exposed region of the photoconductive layer (f). Fixing the screen material by bonding the frame material of the screen. The photovoltaic layer is attached by heat (g) to a uniform electrostatic charge on the photoconductive layer and on the structural material of the screen (h). The light passes through the aforementioned part of the aforementioned areas of the photoconductive layer, using the visible light from the lamp to influence the present charge. (I) Reversal of a part of the aforementioned region of the photoconductive layer using the phosphor-based screen material It emits color I light as a tribo-electrically charged dry powder. Such a first color-emitting phosphor contains at least one surface charge regulator on it to produce a charge having the same polarity as that of the underexposed region of the conductive layer. The light power and the structural material of the screen that absorbs the light to push the chromatic phosphor out of the section (j). The first one is to be firmly attached to one part of the aforementioned region of the photoconductive layer (k). Repeat steps g, h, i and j in order to obtain the structural material. Of a screen that is a second and third color-emitting phosphor in dry powder form with triboelectric charge, each has at least one surface charge regulator on it to Create a light-emitting display made up of small parts. (L) Aluminum is applied to the emitting screen, and (m) the annealing of the faceplate to eliminate elements. That evaporates from the monitor to form a set of such light-emitting monitors. 8. In the manufacturing method, a panel emits light on the inner surface of the colored CRT faceplate portion by an electro-impregnation process, which consists of the steps of a) the aforementioned coating of the said screen portion with a layer. Volatile conductive material (b) The coating over the conductive layer with volatile photovoltaic layers, including visible light sensitive dyes (c) uniform electrostatic charge. On the photoconductive layer (d) the light passes through a selected region of the photoconductor layer by using visible light to affect the charges on it (e). Imaging at the underexposed regions of the photovoltaic layer by the light-absorbing screen structural material in dry powder-carrying tri-ion charge (f) fixing material. The monitor is attached to the aforementioned photovoltaic layer (g) repeated electrostatic charge on the photoconductive layer and on the substrate of the monitor that absorbs the light (h). ) To pass light to a part of the selected region of the photoconductor using visible light from (I) Reforming part of the selected region of the photoconductive layer. The screen material was a first color light-emitting phosphor in the form of a tri-charged dry powder with a surface charge regulator (j). The first colored phosphor material is firmly attached to one part of the aforementioned area of the photoconductive layer (k). Perform steps g, h, i and j It is repeated sequentially so that the screen's structural material is a second and third colored fluorescent phosphor in the form of triboelectric dry powder, each containing at least a charge regulator. Where a kind of surface is on it to create a light-emitting display made up of small parts (L) Aluminum is applied to the emitting screen, and (m) the annealing of the faceplate to eliminate elements. That evaporates from the monitor to form a set of such light-emitting monitors. 9. Method of claim 8, where the fixing steps (f) and (j) consist of bonding the material to such photoconductive layer by heat 1. 0. Method of claim 9, where thermal bonding is performed by irradiating the material with infrared radiation.