EA026935B1 - Display sensor glass, coating of an opaque mask, and method for application of such coating - Google Patents

Abstract

The invention relates to sensor displays with a window and a mask over the contour, the mask serving as a dielectric substrate and covering the printed circuit that controls the sensor layer, and to a method of manufacturing said mask. The objective of the invention is provision of a sensor display glass with a coating - black or colour mask - that has a high resistance, and the coating itself provides electric connections to the sensor layer. If necessary, the mask can be made of any predetermined colour. The objective is attained by making the mask in the form of printed circuit tracks of electric conductors and output contacts of the sensor with gaps between tracks throughout the thickness of the mask, the gaps are filled with a dielectric material, the colour of the dielectric material coinciding or being as close as possible to the visible colour of the main mask, and a sensor film is applied over the conductive layer of the mask. Making the sensor glass and the mask in accordance with the invention permits production of an opaque, dense, temperature-resistant coating with a high electric resistance factor and predetermined colour in commercial conditions. The technological documentation and methodology have been developed for forming a set of nano layers of predetermined colour characteristics.

Description

The invention relates to touch screens with a mask on the contour, while the mask serves as a dielectric substrate and closes the printed circuit for controlling the sensor layer, as well as methods for manufacturing such a mask.

A black mask device [1] is known having a first, second and third layers in a sequence, a first layer with a first optical absorption coefficient to reduce the refractive index, a second layer with a second absorption coefficient to reduce the refractive index, a third layer with a third absorption coefficient to reduce the coefficient refraction, in which the first absorption coefficient to reduce the refractive index is made smaller than the second absorption coefficient, and the second absorption coefficient made smaller than the third absorption coefficient, and in which the first layer is in contact with the second layer and the second layer is in contact with the third.

The same source describes a method of manufacturing a black mask, which includes placing a dielectric layer on a substrate, placing an absorbing layer on a dielectric layer, placing a reflective layer on an absorbing layer, and applying a pattern of a scattering and absorbing layer in a single process.

Also known are liquid crystal displays [2], including a color filter located on the opposite side of the liquid crystal layer. The color filter is made of colored resin, separated by a black mask having many holes, and the visibility of the liquid crystal display depends on the characteristics of the black mask.

In color filters for use in liquid crystal displays, it is necessary to reduce the optical reflection of the surface of the black mask in the wavelength region in the visible range in order to improve the visibility of the panel so that it is always black.

The black mask described in Japanese application [3] is designed so that all layers contain the same kind of metal. This means that the first antireflection film consists of a chromium compound, the second antireflection film consists of a chromium compound and the screen film consists of chromium, all films must be successfully formed. In particular, the first antireflection film consists of a chromium compound containing Cr, O, N, and C. The second antireflection film consists of a chromium compound containing Cr, Ν, O, and C, and the screen film containing chromium contains only metal. However, the wavelength depends on the reflectivity of the surface of the black mask to remain large enough and the reflectivity does not significantly decrease. The known device in this case requires a separate application of electrical installation on the mask for the electrical connection of the touch display.

A device with a black mask and a method for its manufacture [4]. A thin black mask is created in one process. The dielectric layer is placed on the substrate. An absorbent layer is placed above the dielectric layer and the reflective layer. The absorbing and reflecting layers are applied in a single mask process. In this case, the dielectric layer has an attenuation coefficient in the range from 0 to 0.1, and the refractive index is from 1 to 3. The absorbing layer has an attenuation coefficient in the range from 1 to 4, and the refractive index is from 1 to 5. The black mask device includes the first, the second and third layers in a row, the first layer with a first ratio of absorption coefficient to refractive index in the wavelength range less than the ratio of absorption coefficient to refractive index in the wavelength range in the second layer, and less than about the ratio of the absorption coefficient to the refractive index in the wavelength range in the third layer.

A display sensor glass [5] is adopted as a prototype. It contains a window for the display zone with a thin sensor film applied and located along the glass contour in the zone of electrical conductors of an opaque dielectric mask, in which the mask is laminated from a dielectric opaque light-absorbing layer and transparent nanolayers in contact with it with different refractive indices of metal oxides and nitrides and semiconductors.

The disadvantage of the prototype is the need to perform on top of the mask printed wiring to control the touch layer of the display glass. In known devices and methods for applying a printed circuit for controlling a sensor layer, the operation of applying a topography of a printed circuit is performed in a separate operation and accordingly imposes restrictions on the design of previous layers. Moreover, the manufacturing technology of thin-film layers imposes restrictions on the technology of applying printed wiring.

An object of the present invention is to provide a touch screen glass coated with a black or color mask, which has high electrical resistance and printed electrical wiring, while the mask itself provides electrical connections to the sensor layer. If necessary, the mask can be performed with any specified color.

The problem is solved in that in the known display sensor glass containing a window for the display area with a thin sensor film deposited on it and a light-tight mask located along the glass contour in the area of the electrical conductors, the mask is multilayer, the first layer being dielectric and the last layer from the glass is electrically conductive, according to the invention, the mask is made in the form of tracks for printed wiring of electrical conductors

- 1 026935 and the output contacts of the sensor with gaps between the tracks throughout the thickness of the mask, the gaps are filled with dielectric material, while the color of the dielectric material matches or is as close as possible to the visible color of the main mask, and the sensor film is applied over the electrically conductive layer of the mask.

The problem is also solved by the fact that the color of the dielectric material is chosen to coincide with the color of the mask at the border with the glass, and the degree of coincidence is selected depending on the width of the gap between the tracks.

The problem is also solved by the fact that the gaps between the conductive paths are made with a width of not more than 50 microns.

The problem is also solved by the fact that pastes and photoresists based on organic compounds with a surface resistance of at least 10 ¹² Ohm / sq are used as the dielectric material.

The problem is also solved by the fact that the dielectric material additionally covers the entire surface of the mask and is made in the form of a protective layer of the mask.

The problem is also solved by the fact that on the surface of the display sensor glass opposite the surface on which the mask is formed, a transparent coating is applied with a refractive index lower than that of the base glass, for example, from a number of oxides and fluorides of silicon or magnesium.

The problem is also solved by the fact that on the surface of the glass, opposite the surface on which the mask is formed, a transparent coating is applied that has the properties of hydro and oleophobicity, for example, low and high molecular weight organosilicon and organofluorine compounds.

The problem is solved in that in the known coating of a lightproof mask for a display sensor glass containing several nanolayers providing its color at the interface with the glass and a layer of electrical conductor, according to the invention, the last layer of the mask from glass is made of metal or alloy, which provides reliable connection of external flexible conductor loops, while the entire coating is made in the form of tracks for printed wiring of electrical conductors and output contacts of the sensor with gaps throughout t lschine coating gaps between the tracks are filled with dielectric material, the color or the same dielectric material as close to the visible color of the primary coating from the glass side.

The problem is also solved by the fact that in the coating the gaps between the conductive paths are made with a width of not more than 50 microns.

The problem is solved in that in the known method for coating a lightproof mask by the method of layer-by-layer vacuum deposition according to the invention, it is applied in the form of electrically conductive tracks, while the topology is performed by photolithography.

The problem is also solved by the fact that the mask is applied in a continuous layer, and the topology is performed after applying all the layers, including the sensor layer by laser removal of coating materials to the glass surface.

The problem is also solved by the fact that before the process of applying the first layer of the mask conduct ion cleaning of the surface of the substrate.

The invention is illustrated by drawings.

In FIG. 1 schematically shows a touch display glass with a black mask.

In FIG. 2 shows a portion of a mask in the form of a printed circuit of electrical conductors with a thin sensor layer (I) applied and with a portion for connecting a control loop II.

In FIG. 3 shows an enlarged portion I of FIG. 2 topographies with gaps between tracks.

In FIG. 4 shows a section AA of a mask consisting of optical dielectric nanolayers and an electrically conductive layer, with gaps between the tracks.

In FIG. 5 shows a section AA of a mask consisting of optical dielectric nanolayers and an electrically conductive layer, with gaps between the tracks filled with an opaque dielectric material.

In FIG. 6 shows an enlarged section II of FIG. 2 topographies with gaps between tracks made at the loop connection point. Before filling with dielectric material, these gaps are transparent. After filling with dielectric material, the gaps become invisible and indistinguishable in color with the main mask.

The display sensor glass consists of a substrate made of chemically tempered glass 1, a protective mask 2, made in the form of a combination of nanolayers 3 with predetermined optical properties and high electrical resistance, a thin sensor film 4 and metal tracks 5 for electrical connection of the sensor film. The gaps between the metal tracks 6 are filled with dielectric material 7. An additional antireflective and / or oleophobic coating (not shown) can be applied to the front of the glass 1 opposite to the mask. For a better understanding of the picture, the touch thin film is indicated in gray, although in reality it is invisible.

- 2 026935

The method is as follows. In the case of choosing photolithography technology by known methods, a predetermined pattern of gaps between conductors (tracks) is applied by photoresist. It should be noted that the gaps 6 between tracks 5 in this technology are very small (maximum width 50 μm, nominal no more than 20 μm), materials and photolithography technology must be carefully selected to ensure a given line thickness. The surface of the glass before spraying is cleaned in a known manner, including ion cleaning. After that, layer-by-layer deposition of dielectric optical layers, an electrically conductive layer and the last sensor layer is carried out. After applying all the layers by known methods, the photoresist with the layers deposited on it and the formation of gaps between the tracks are removed. Given that the total thickness of the deposited nanolayers does not exceed 0.2-0.3 microns, and the lack of mounting parts, the gaps between the tracks can be made up to 50 microns wide.

If you choose a different technology for making tracks, you can spray the entire mask layer by layer, and after spraying the last conductive layer, cut out the topology pattern with a laser beam to a glass substrate.

Then, the gaps between the tracks are filled with dielectric material, for example, pastes and photoresists based on organic compounds with a surface resistance of at least 10 ¹² Ohm / sq.

Contacts for connecting a control loop.

All these layers and layer complexes have a very high electrical resistance - more than 200 MΩ. This allows them to be used as a substrate for performing printed wiring for connecting a touch display. In addition, the combination of nanolayers is optically opaque and completely hides the printed circuit, and due to the reflected light gives the desired color cast.

The implementation of the touch glass and mask according to the invention allows to obtain an opaque dense heat-resistant coating with a high coefficient of electrical resistance and a predetermined color in an industrial environment. At the same time, an electrical wiring of the contacts of the sensor coating is obtained. Technological documentation has been developed and a technique has been developed for the formation of a complex of nanolayers with specified color characteristics.

Sources of information taken into account during the examination.

1. US patent I87969638, IPC С02Р 1/1335, С06Р 1/041, publ. 10/15/2009.

2. US patent I86285424, IPC S02P 1/1335, publ. September 4, 2009

3. Application of Japan ΙΡ8-179301 IPC С06Р 1/041.

4. US patent I87969638, IPC С02В27 / 00; С02Р1 / 03, publ. 06/06/2011.

5. Eurasian application 201200613, IPC С02Р 1/00, ВВВ 17/06 - prototype for glass, coating and method.

Claims (9)

1. Display touch glass containing chemically tempered glass (1), on which a black or color opaque mask (2) is formed, on which a sensor film (4) is applied, while the opaque mask (2) is located along the contour of chemically tempered glass (1) ) with the formation of a window for the display zone and is made in the form of a multilayer coating, characterized in that the multilayer coating consists of a set of nanolayers (3), including nanolayers with desired optical properties and high electrical resistance, and nano in the form of tracks (5) for the electrical connection of the sensor film (4) located with gaps (6) over the entire thickness of the nanolayers (3) of the multilayer coating, while the gaps (6) are filled with dielectric material (7), the color of which matches or maximally close to the color of the multilayer coating. 2. The display touch glass according to claim 1, characterized in that a protective layer of dielectric material is applied to the multilayer coating with the sensor film and to the gaps between the tracks filled with dielectric material. 3. The display touch glass according to claims 1, 2, characterized in that a transparent antireflective and / or oleophobic coating is applied to the surface of the chemically tempered glass opposite to the surface on which the opaque mask is formed. 4. The display touch glass according to claim 3, characterized in that the transparent antireflection coating has a refractive index lower than that of chemically tempered glass, and is selected, for example, from a number of oxides and fluorides of silicon or magnesium. 5. The display touch glass according to claim 3, characterized in that the transparent oleophobic coating is selected, for example, from a number of low and high molecular weight organosilicon and organofluorine compounds. 6. The display touch glass according to claims 1 to 3, characterized in that the gaps between the tracks are made with a width of not more than 50 microns. 7. The display touch glass according to claims 1-3, characterized in that a paste or photoresist based on organic compounds with a surface resistance of at least 10 ¹² Ohm / sq is used as the dielectric material. 8. The display touch glass according to claims 1 to 3, characterized in that the electrically conductive layer of the multilayer coating is made of metal or alloy. 9. The display touch glass according to claims 1 to 3, characterized in that the degree of coincidence of the color of the dielectric material and the color of the multilayer coating is selected depending on the width of the gap.