LT7133B - DISPLAY MODULE WITH ELECTRONIC INK - Google Patents

Abstract

A display module based on electronic ink technology, such as "e-ink", comprising a TFT matrix with an electronic ink layer (1) with an active area (2) and an inactive area (2'), a fiber optic plate (3), light sources (4) located on one side of the fiber optic plate (3), and an upper protective layer (5). The dimensions of the fiber optic plate (3) of the display module are sufficient for partial or complete or excessive overlap of the inactive area (2'). The fiber optic plate (3) is located between a masking layer (6) and an upper protective layer (5). The arrangement of the layers of the display module is as follows (from bottom to top): TFT matrix with an electronic ink layer (1), masking layer (6), fiber optic plate (3), light sources (4), upper protective layer (5).

Description

TECHNICAL FIELD

The invention relates to screens of individual electronic devices, implemented on the basis of electronic ink technology, intended for visually reproducing electronic text and graphic information.

STATE OF THE ART

The technology of "electronic ink" or "electronic paper" is known from the state of the art - it is a technology for displaying information that imitates conventional ink on paper.

The most common ways to implement this technology are:

The use of Janus particles - spherical elements consisting of negatively charged black plastic on one side and positively charged white plastic on the other. All the spheres are placed in a transparent silicone rubber sheet, and each sphere is suspended in a bubble of grease so that it can rotate freely. The polarity of the voltage applied to each pair of electrodes determines whether the white or black side of the sphere is oriented towards the user, thus determining the white or black color of a conventional pixel [1].

An electrophoretic display is one in which an image is created by changing the position of charged pigment particles using an electric field. Simply, titanium dioxide particles about one micrometer in diameter are dispersed in mineral oil, to which black dye and other impurities are added. The mixture is placed between two conductive plates separated by a gap of 10-100 microns. When a voltage is applied to one of the plates, the particles move towards the plate with the opposite charge. When the particles are closer to the front of the screen plate, it appears white because light is reflected from the titanium particles, which have a high refractive index. When the particles are closer to the back of the screen, it appears dark because of the color of the mineral oil [2].

Unlike traditional LCDs, which use dot-matrix backlighting to form an image, e-paper reflects light like regular paper. It can display text and images for as long as you want without using electricity, and the image can be changed later. These properties of "electronic ink" technology are successfully used in e-books.

There are several technologies for creating electronic devices based on electronic ink technology, some of which use a plastic substrate and electronics to produce a flexible screen. Potentially, an electronic ink screen should be more comfortable to read than conventional screens. This is achieved due to the stable image that does not need to be constantly updated, a wide viewing angle, as well as the fact that an electronic ink screen reflects external light instead of emitting its own. An electronic ink screen can be read in direct sunlight without any loss of image quality.

The main disadvantage of these devices is that they cannot be used in low light conditions, which is also typical for regular paper books. Constant use of such screens causes eye fatigue and strain.

US Patent No. US7777954B2 claims a display based on electronic ink technology, which implements the usual "top-illumination" technology, which allows devices with such a display to be used in poor lighting conditions. This device consists of the following main layers (from bottom to top): TFT matrix with an electronic ink layer; including the active area - the area of the electronic ink layer where visual information is displayed; fiber optic plate - a thin optical plastic plate with a microcapsule texture, evenly emitting light from the light source over its entire plane; light sources - "warm" and "cold" light-emitting diodes soldered in parallel on a flexible printed circuit FPC. The main disadvantage is that only the active area of the display is illuminated and it is impossible to overlap other parts of the display, which leads to significant design limitations of the device, i.e. the need to cover inactive parts of the screen with a casing, decorative glass, etc., which, in turn, determines a significant percentage of the device's ineffective area (taking into account the significant size of the technical parts of the screen on which it is impossible to display information).

ESSENCE OF THE INVENTION

The task of the presented invention is to create a display module based on electronic ink technology, such as "E-Ink", which will allow more efficient use of the active area without causing inconvenience to the user, will bring the external image of the screen closer to the image of a paper page and will allow efficient use of various devices according to the specified invention in low light conditions without excessive strain on the user's eyes.

The display module based on electronic ink technology includes a TFT matrix with an electronic ink layer with an active area where the image is displayed and an inactive area - the part of the display module where the image is not reproduced; a fiber optic plate; a light source located on one side of the fiber optic plate and the upper protective layer.

The fiber optic plate is placed between the masking layer and the upper protective layer. The surface of the fiber optic plate has dimensions sufficient to partially, completely or excessively cover the surface of the inactive area. The arrangement of the display layers is as follows (from bottom to top): TFT matrix with electronic ink layer; masking layer, fiber optic plate; light sources, upper protective layer.

The masking layer is covered with light-blocking elements and/or light-reflecting elements whose color is close to the color of the TFT matrix with the electronic ink layer.

The display module contains an additional light source or sources located on the other sides or edges of the fiber optic panel.

The display module additionally includes a touch panel located between the TFT matrix and the masking layer.

The active area surface dimensions of the touch panel are larger than the active area surface dimensions of the TFT matrix.

The top protective layer contains a masking element made in the form of a silkscreen frame.

With the help of the specified invention, the increase in the useful area of the active area of the screen is achieved by placing a fiber optic plate between the masking layer and the upper protective layer. At the same time, the dimensions of the fiber optic plate are sufficient for partial or complete, or excessive, overlap of the inactive area, and on the masking layer are placed light-blocking elements and/or light-reflecting elements, the color of which is close to the color of the TFT matrix with an electronic ink layer, in addition, the upper protective layer may contain a masking element made in the form of a silk-screen frame.

The specified reflective elements reflect light and illuminate the fields according to the tone of the screen, and the upper masking layer, in turn, is designed to mask the area of the arrangement of the LEDs. Depending on the design of the device, the area of the arrangement of the LEDs may be at the expense of the housing.

Since the reflective elements are at the level of the active area of the screen, this allows the user to change the visual perception of the screen size in the direction of increase. Due to this effect, the visual boundary between the text on the screen and the edge of the active area is minimized and, depending on the screen size, the amount of text that can be displayed on the screen without changing the width of the frame increases by approximately 10-20%. These features also allow for the implementation of a frameless product design that will be more similar to the page of a paper book and will improve the user's visual perception of the text.

The presented invention allows to reduce the user's eye fatigue when using the device in low light conditions, which is achieved by using an additional light source or sources located on the other sides of the fiber optic panel.

The presented invention allows the use of an improved software product interface (IP) created for devices with a display module based on electronic ink technology, which improves interaction with the user, for example, allows tracking the device's holding position, using additional gesture control elements, touch control scenarios using a combination of sensors in the active and inactive areas, additional touch buttons, etc. The specified technical result is achieved when the specified invention includes an active area of the touch panel, the surface dimensions of which are larger than the dimensions of the active area of the TFT matrix.

BRIEF DESCRIPTION OF THE DRAWINGS

The features of the invention, which are new and non-obvious, are set forth in the claims. However, the invention may best be understood from the following detailed description of the invention, in which, without limiting the scope of the invention, exemplary embodiments of the invention are described together with the accompanying drawings, in which:

Fig. shows a multilayer structure (section) of a display module according to the invention;

Fig. Comparative visualization of devices with a) a typical display module and b) a display module according to the invention.

Preferred embodiments of the invention are described below with reference to the drawings. In each figure, the same numbering is given for the same or equivalent element.

DETAILED DESCRIPTION OF THE IMPLEMENTATION OF THE INVENTION

It should be understood that numerous specific details are set forth in order to provide a complete and understandable description of the exemplary embodiments of the invention. However, it will be apparent to one skilled in the art that the detail of the exemplary embodiments of the invention is not intended to limit the scope of the invention, which may be practiced without such specific instructions. Well-known techniques, procedures, and components have not been described in detail so that the exemplary embodiments of the invention are not misleading. Furthermore, this description should not be construed as limiting the exemplary embodiments set forth, but rather as an implementation thereof.

Electronic ink or digital paper display technology, such as "e-ink" developed by E Ink Corporation, is well known and will not be discussed in detail here.

The display module based on electronic ink technology includes a TFT matrix with an electronic ink layer (1) with an active area (2) and an inactive area (not shown in the drawings), a fiber optic plate (3), light sources (4) located on one side of the fiber optic plate (3), an edge, a top protective layer (5), a masking layer (6), light-tight elements (7), reflective elements (8), a touch panel (9), a masking element (10) made on the basis of a silk-screen printing frame.

The dimensions of the said fiber optic plate (3) are such that the surface of the fiber optic plate (3) covers the surface of the inactive area partially, i.e. 1-99%, completely, i.e. 100%, or redundantly, i.e. 101%. The useful area of the active area of the display module is increased by placing the fiber optic plate (3) between the masking layer (6) and the upper protective layer (5), and the arrangement of the display layers is as follows (from bottom to top): TFT matrix with electronic ink layer (1), masking layer (6), fiber optic plate (3), light sources (4), upper protective layer (5). The masking layer (6) is covered with light-tight elements (7) and/or reflective elements (8), the color of which is close to the color of the TFT matrix with electronic ink layer (1). The light-reflecting elements (8) reflect light and illuminate the fields according to the screen tone, and the upper masking layer (6) in turn is intended to mask the area of arrangement of the light-emitting diodes (4). Depending on the design of the device, the area of arrangement of the light-emitting diodes (4) may be at the expense of the housing.

Since the reflective elements (8) are located at the level of the active screen area, this allows the user to change the visual perception of the screen size in an increasing direction. Due to this effect, the visual boundary between the text on the screen and the edge of the active area is minimized and, depending on the screen size, the amount of text that can be displayed on the screen without changing the width of the frame increases by approximately 10-20%. These features also allow for the implementation of a frameless product design that will be more similar to the page of a paper book and will improve the user's visual perception of the text.

The electronic ink display module may additionally include one or more additional light sources (4) on the other sides, edges of the optical fiber plate (3). Thus, the light sources (4) may be arranged on all edges of the optical fiber plate (3). This allows to reduce the user's eye fatigue when the device is used in low light conditions.

The presented display module works as follows. After the device is powered and the light sources (4) are turned on, the light flux formed by the light-emitting diodes enters the fiber-optic plate (3), which distributes and directs the light flux to the side of the active area (2), which is part of the TFT matrix with an electronic ink layer (1) and a masking layer (6) with a complex structure that performs the function of blocking and reflecting light. Due to the light-blocking elements (7) located under the layer (6), the structural elements are masked, and due to the reflective elements (8), the masking area is perceived as a continuation of the active area (2). At the same time, the light temperature and the intensity of the light flux of the light sources (4) are determined by the control module, which is not a component of the display module. The upper protective layer (5) is considered the upper layer of the display module.

Optionally, a touch panel (9) can be used to control the device in which the display module is used. It is desirable that the dimensions of the active area of the touch panel (9) are such that the surface of the active area of the touch panel (9) overlaps the surface of the active area (2) of the TFT matrix (1) by more than 100%. In this way, it is possible to use an improved software product interface (interface) created for devices with a display module based on electronic ink technology, which improves interaction with the user, for example, allows tracking the position of the device, using additional gesture control elements, touch control scenarios using a combination of sensors in the active and inactive areas, additional touch buttons, etc.

Optionally, a masking frame (10) can be placed on the surface of the protective layer (5), for example by silkscreen printing, which allows the light sources (4) and the opaque areas of the touch panel (9) to be hidden from the user.

Citation sources:

Crowley, J.M.; Sheridon, N.K.; Romano, L. Dipole moments of gyricon balls Journal of Electrostatics 2002, 55, (3-4), 247.

Srikanth, G; Kariyappa, B (2016). Parametric analysis of amorphous silicon thin film transistors. IEEE International: 1642-1646.

Claims (9)

DEFINITION OF THE INVENTION 1. A display module with electronic ink, comprising a TFT matrix with an electronic ink layer (1) with an active area (2) and an inactive area (2'), a fiber optic plate (3), light sources (4) located on one side of the fiber optic plate (3), and an upper protective layer (5), characterized in that the fiber optic plate (3) overlaps the inactive area (2'), the fiber optic plate (3) is located between a masking layer (6) and an upper protective layer (5), and the arrangement of the display layers is as follows (from bottom to top): TFT matrix with an electronic ink layer (1), masking layer (6), fiber optic plate (3), light sources (4), upper protective layer (5). 2. Display module with electronic ink according to claim 1, characterized in that the masking layer (6) is covered with light-blocking elements (7) and/or reflective elements (8), the color of which is close to the color of the TFT matrix with the electronic ink layer (1). 3. An electronic ink display module according to claim 1 or 2, characterized in that it comprises one or more additional light sources (4) on the other sides of the fiber optic plate (3). 4. An electronic ink display module according to one of claims 1 to 3, characterized in that it additionally comprises a touch panel (9) located between the TFT matrix (1) and the masking layer (6). 5. The electronic ink display module according to claim 4, characterized in that the surface of the active area of the touch panel (9) overlaps the surface of the active area (2) of the TFT matrix (1) by more than 100%. 6. An electronic ink display module according to any one of claims 1-5, characterized in that the upper protective layer (5) includes a masking element (10) made in the form of a silkscreen frame. 7. The electronic ink display module according to any one of claims 1 to 6, wherein the surface of the optical fiber plate (3) overlaps the surface of the inactive area by 1 to 99%. 8. The electronic ink display module according to any one of claims 1-6, wherein the surface of the optical fiber plate (3) covers the surface of the inactive area by 100%. 9. The electronic ink display module according to any one of claims 1 to 6, wherein the surface of the optical fiber plate (3) covers the surface of the inactive area by more than 101%.