JPH07141086A - Transparent input panel arranged on display part - Google Patents

Abstract

PURPOSE:To improve the brilliancy of a display screen and to reduce parallax shifted depending on an input position and a position where a display position is observed. CONSTITUTION:An input panel is superimposed on glass 6 on the upper plane of which a transparent conductive film 5 is provided via a spacer 4 in which a film 1 on the lower plane of which a large number of transparent conductive film 2 are provided to form a small gap between both conductive films, and it is arranged keeping a fixed interval for the glass on the upper plane of an LCD display part 9. The input panel is constituted in such a way that transparent filling fluid 3 provided with a refractive index almost equal to that of the glass and the film can be filled in space paragraphed by the conductive film 5 on the upper plane of the glass 6 and the spacer 4 on the lower plane of the film 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transparent input panel arranged on a display section. In recent years, LCDs (liquid crystal display devices)
The transparent input panel, which is provided with a transparent panel on the display part such as the touch panel and allows coordinates to be input from the panel surface with a pen or finger, can be operated according to the contents displayed on the display part on the back side of the panel. It is widely used for input personal computers, electronic item keyboards, POS terminals, word processors, etc., and its applications are expected to further develop in the future such as applications for selecting functions from display contents in televisions, facsimiles, etc. .

In such a transparent input panel, an erroneous input is made if the position displayed on the display unit does not correspond to the position desired to be operated. Therefore, the display position on the display unit can be accurately viewed from the surface of the transparent panel. Otherwise, input will be made at the wrong position. Therefore, it is desired to transmit the light output from the display unit to the transparent input panel as much as possible without attenuation (high transmissivity and without reflection) and without refraction.

[0003]

2. Description of the Related Art FIG. 7 is a block diagram of a conventional example.
Shows an example of a transparent input panel including an LCD display section using LC (liquid crystal) as a display section.

In FIG. 7, reference numerals 70 to 74 form an input panel. In this example, a resistance film type structure is shown.
70 is a film having a non-glare treatment on the upper part, 71
Is a conductive film (transparent) of the film, 72 is a plurality of spacers arranged in a matrix on a plane at a constant interval to form a minute gap between the conductive film of the glass and the conductive film of the film, and 73 is a conductive film of the glass The film (transparent), 74 is glass. 75 represents a space. Further, reference numerals 76 to 80 constitute a liquid crystal display section (hereinafter referred to as LCD display section), 76 is glass, 77 is liquid crystal, 78 is glass, 79 is a space, and 80 is a backlight for clarifying the display of the liquid crystal. Or a reflector.

In the conventional transparent input panel, a space 7 is provided above the glass 76 of the LCD display section, which is composed of the sections 76 to 80.
The input panel composed of the respective parts 70 to 74 is placed with a gap shown by 5 between them to be integrated.

This transparent input panel corresponds to the contents displayed on the LCD display section provided at the bottom, and the tip of a pen or a finger is pushed to the position on the film 70 of the input panel where the user wants to input the film 70. Bends below the position of the spacer 72, and the conductive film 7 of the film at that position bends.
1 and the conductive film 73 made of glass are brought into contact with each other and input is performed. Such a resistance film type input panel is conventionally known. For example, the conductive film 71 of the film is arranged as a number of lines parallel to the X axis of the plane coordinate, and the conductive film 73 of the glass is Y.
It is arranged as a number of lines parallel to the axis, and the potential is applied to both ends of each line in advance. When input is performed, the potential corresponding to that position is detected in each of the X and Y directions, and the input coordinate position is identified. To be done.

In the configuration of FIG. 7, an input panel and an LCD
The space 75 is provided between the liquid crystal 77 and the display section when the glass 74 on the lower side of the input panel comes into contact with the glass 76 on the upper side of the LCD due to the pressure (by a finger or a pen) on the input panel. This is to prevent the imprint left on the display surface.

[0008]

In the above-mentioned conventional example,
A space (air) is kept between the film 70 on the upper part of the input panel and the lower glass by a spacer so that a constant space is maintained. However, when viewing the display contents of the LCD display unit through the input panel, the light rays (representing the display contents) generated from the LCD display unit enter the film 70 through the space separated by the spacer 72 through the glass 74, Further, when the light passes through the film 70 and goes out of the panel, the amount of light is reduced by about 30% as compared with the case of displaying only on the surface (glass 76) of the LCD display section. Therefore, there is a problem that the display screen becomes dark and the vividness of the display decreases.

Further, even if the actual display position on the LCD display unit coincides with the input position, the position shift occurs depending on the viewing angle of the person. That is, the position where the display position of the same LCD display section is observed from the front and the position where a person who observes it from an oblique direction recognizes it due to the refraction of light between the surface of the LCD display and the film 70 of the panel. I will end up. Therefore, when a plurality of people view the same screen, there is a problem that parallax occurs depending on the viewing position and the input position and the display position do not match.

The present invention improves the saturation of the display screen of a transparent input panel including a display unit, and can reduce the parallax which shifts between the input position and the display position depending on the viewing position. The purpose is to provide.

[0011]

The first solution of the present invention is to provide a transparent input panel in which a panel is arranged on the display unit, and a glass or a film having a refractive index between the lower glass and the upper film of the input panel is The light transmittance is improved by filling almost the same liquid.

Another solution of the present invention is to insert a liquid or lens between the display section and the input panel so that the information on the display screen can be clearly seen through the input panel. . Further, as another solution, a prism plate is provided on the lower surface of the glass of the panel.

FIG. 1 shows a first embodiment according to the first principle of the present invention.
1 is a film, 2 is a film conductive film, 3 is a filling liquid, 4 is a spacer, 5 is a glass conductive film, 6 is glass, 7 is an antireflection film, and 8 is a reflection film. And LCD
A space between the display units, and 9 is an LCD display unit. In the example of FIG. 1, an LCD display unit using liquid crystal as a display unit is shown, but it goes without saying that the present invention can be applied to other display media such as other CRT displays and plasma displays.

[0014]

In the structure of the first embodiment according to the first principle of the present invention, as shown in FIG. 1, the spacer 4 is provided between the conductive film 5 on the upper surface of the glass 6 of the input panel and the conductive film 2 on the lower surface of the film 1.
The filling liquid 3 is filled in the space partitioned by. The filling liquid 3 has a refractive index that is substantially the same as that of the glass 6 and the film 1. As a result, the light representing the display content generated from the LCD display unit 9 is not refracted in the gap portion partitioned by the spacers 4, and therefore the amount of light attenuated by reflection is reduced, so that the transmittance is improved and the input panel is improved. The saturation of the display on the LCD display unit 9 can be increased.

[0015]

EXAMPLE FIG. 1 is a configuration diagram of Example 1, and FIG. 2 is a diagram showing characteristics of incident angle and reflectance at boundaries of different media.
In FIG. 2, Rs represents the energy reflectance in the vertical direction and Rp represents the energy reflectance in the parallel direction.

The first embodiment shown in FIG.
9 to 9 and an input panel is composed of 1 to 7, and the input panel is placed on the LCD display 9 via the space 8. The LCD display unit 9 has the same structure as the conventional example (FIG. 7).

In the structure of the conventional example (see FIG. 7), air (n = 1.0, where n is the refractive index) is contained in the gap defined by the spacer 72 between the film 71 and the glass 73. As long as it is a gas, it has almost the same refractive index.

If air is contained in this portion as shown in FIG. 7, glass (n = 1.5) or film (n = 1.4 to
Since 1.5) has a high refractive index, if the light source (LCD display section) is behind the glass 74 below the input panel, the glass 7
Reflection is repeated between each layer while light reaches the outside of the panel from the layer 4 through the air layer and the layer of the film 70. At this time, the light output from the glass layer to the air layer is A. As shown in, the total reflection occurs at an incident angle of 40 ° or more.

Further, the light entering the film layer from the air layer is B.I. As shown in Fig. 3, total reflection does not occur, but the reflectance increases as the angle of incidence increases. This reflectance (R)
Is represented by the following equation. In the formula, a represents the incident side and b represents the transmission side.

R = [(n _a −n _b ) / (n _a + n _b )] ² According to this, the greater the difference between the refractive index on the incident side and the refractive index on the transmission side, the greater the reflectance, and the opposite. If the refractive index on the incident side and the refractive index on the transmission side are equal to each other, theoretically no reflection occurs.

Therefore, in the first embodiment, reflection of light emitted from the glass 6 of the input panel to the gap formed by the spacer 4 and reflection of light entering the film 1 from the gap formed by the spacer 4 are eliminated. In order to transmit all the incident light, the gap 3 was filled with the filling liquid 3 having a refractive index similar to that of glass or film.

The filling liquid 3 is methyl alcohol (n = 1.
33) and methylene iodide (n = 1.74) are used. For this filling liquid, put methyl alcohol in a beaker, put glass (conductive film, with spacers) and film (with conductive film and non-glare treatment on the surface) cut pieces, and completely soak it in the liquid. Then add methylene iodide dropwise. Then, a concentration (n = about 1.5) at which the boundary between the cut piece and the liquid is considerably hard to see is obtained. A liquid having this concentration is used as a filling liquid to fill the gap between the glass 6 and the film 1 in FIG. In the above example, methylene iodide was used as the high refractive index liquid, but methylene bromide (n = 1.74) and benzene iodide (n = 1.62) were used.
Etc. may be used.

Further, in the conventional structure, it is necessary to narrow the spacing between the spacers in order to ensure the insulation between the conductive film 2 under the film and the conductive film 5 made of glass. Therefore, the number of spacers is large and the area of the input panel is large. The ratio of the spacers was about 4%. On the other hand, according to the present invention, the space in which the spacers are provided is filled with the insulative filling liquid 3, so that the spacing between the spacers can be widened and the number of the spacers can be reduced (about 0.1% in area). I was able to.

Further, by providing the antireflection film 7 under the glass 6, the light incident on the input panel from the LCD display section 9 can enter the panel without reflection. As a specific example of the antireflection film 7, a silicon oxide (SiO ₂ ) film having a thickness of 140 nm is formed on the surface of the glass 6 opposite to the conductive film 5 by a sputter deposition method.

With the structure of the first embodiment described above, the transmittance of the input panel was 70% in the conventional example, while it was 8%.
It could be improved to 0%. Next, FIG. 3 is a configuration diagram of a second embodiment of the present invention.

In the second embodiment, the same liquid as the liquid filled in the gap defined by the spacer 4 between the film 1 and the glass 6 in the first embodiment is used.
It is characterized by filling the space of the display unit.

In FIG. 3, the respective parts denoted by the reference numerals 1, 2, 4 to 6 and 9 are the same as the respective parts having the same reference numerals in FIG. 1, 1 is a film, 2 is a conductive film of the film, and 4 is Spacers, 5 is a conductive film of glass, 6 is glass, and 9 is an LCD display section, which is a characteristic configuration of the second embodiment.
Is a filling liquid filled in the space between the lower surface of the glass 6 of the input panel and the upper surface of the LCD display unit 9. This filling liquid 10
Can be obtained by preparing a liquid whose refractive index is almost the same as that of glass by the same method as the filling liquid 3 of the above-mentioned Example 1.

According to the structure of the second embodiment, when the light from the LCD display unit 9 enters the filling liquid 10 and the filling liquid 1
When entering from 0 into the glass 6 of the input panel, the light enters without refracting at each incident, and the reflection of the glass between the glass on the surface of the LCD display unit 9 and the glass 6 of the input panel is prevented. It is possible to make the display image of the LCD display unit 9 appear to be floating, and to reduce parallax depending on the viewing angle.

Also in the configuration of the second embodiment shown in FIG. 3, the space defined by the spacer 4 between the film 1 and the glass 6 of the input panel is filled with the same filling liquid as that shown in FIG. can do.

FIG. 4 is a block diagram of the third embodiment of the present invention.
In FIG. 4, each part represented by each reference numeral 1, 2, 4 to 6 and 9 corresponds to each part having the same reference numeral in FIG. 1 and FIG. 3, and 11 which is a feature of this embodiment is an input panel. It is a prism plate provided on the lower surface of the glass 6.

In the third embodiment, the prism plate 11 is provided on the lower surface of the glass 6 of the input panel so that the display light output from the LCD display unit 9 is reflected on the lower surface of the glass 6 which is the rear surface of the input panel. To prevent.

FIG. 5 is an explanatory view of the function of the prism plate.
As shown in FIG. 5, when light in an oblique direction such as or is incident as light input from the LCD display side, the prism plate 11 refracts light as shown in FIG. The lower surface of the glass 6 is prevented from reflecting. As a result, the LCD display unit 9
Therefore, the light transmittance can be improved.

As the prism plate 11, specifically, an apex angle of 70 ° and a prism pit of 200 μm was used. As a result, the image display on the surface of the input panel becomes brighter and the contrast can be improved.

The structure of the third embodiment is combined with the structure of the first embodiment, and the same space as that shown in FIG. 1 is formed in the space defined by the spacer 4 between the film 1 and the glass 6 of the input panel. It can be configured to be filled with a filling liquid.

FIG. 6 is a block diagram of a fourth embodiment of the present invention.
In FIG. 6, reference numeral 20 denotes an input panel, which is used in the second embodiment.
Similar to (FIG. 3) and the third embodiment (FIG. 4), it is formed by the components represented by the reference numerals 1, 2, 4 to 6. Also, 9 is L
The CD display unit 12 is a SELFOC lens array (SLA) which is a characteristic configuration of the fourth embodiment.

In the fourth embodiment, a SELFOC lens (gradient distribution lens) array (SLA) 12 is provided in a space between the glass of the LCD display section 9 and the lower surface of the glass of the input panel 20 which is conventionally a space. In addition, it improves the light transmittance of the LCD display unit and prevents parallax.

This SELFOC lens array (SLA)
Reference numeral 12 is also used in a facsimile, a printer, a copying machine, etc. In the embodiment of the transparent input panel of the present invention, a lens opening angle of 20 ° was used in order to prevent a decrease in transmittance. This SELFOC lens array (SLA) has a lens thickness of 8 mm, the optical distance between the LCD display unit 9 and the input surface is 15 mm, and if the SELFOC lens array (SLA) 12 is placed in the middle, the LCD display unit 9 displays An erect image of 1 is displayed on the surface of the input panel, and parallax due to the height of the screen and human eyes can be prevented.

FIG. 6 shows an example in which the image of "A" on the LCD display portion 9 is displayed on the input panel 20 as an erecting equal-magnification image by one SELFOC lens. Moreover, parallax and contrast can be further improved by adjusting the optical length of this SELFOC lens array.

Further, as described in the above-mentioned conventional example, conventionally, when the input panel is pressed with a pen or a finger, the LCD display section is pressed and display disorder occurs. Therefore, in order to prevent this, the input panel and the LCD are prevented. Since a space is provided between the display unit and the display unit, the space can be effectively used by placing the SELFOC lens array 12 in the space.

The above-described first embodiment can be combined with the configuration of the fourth embodiment. That is, by filling the space defined by the spacer 4 with the filling liquid 3 between the conductive film 5 on the upper surface of the glass 6 and the conductive film 2 on the lower surface of the film 1 in the input panel 20, It is possible to increase the transmittance and eliminate parallax.

[0041]

EFFECTS OF THE INVENTION According to the present invention, when the input panel is installed on the LCD display unit, the problems of the display on the LCD display unit being difficult to see and the parallax being generated to make it difficult to write are solved. It became possible to display a clear image and prevent parallax.

Specifically, according to the first embodiment of the present invention, the gap between the glass and the film of the input panel is filled with the filling liquid to eliminate the reflection between the layers and increase the light transmittance. The saturation of the display can be improved, and the spacer density can be reduced to further improve the transmittance.

Further, according to the second embodiment, it is possible to prevent reflection between the LCD display section and the glass of the input panel to improve the transmittance and prevent parallax. And the third
According to this embodiment, the image display on the surface of the input panel can be made bright and the contrast can be improved. Furthermore, according to the fourth embodiment, it is possible to display a clear image on the surface of the input panel and eliminate parallax.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a first embodiment of the present invention.

FIG. 2 is a diagram showing characteristics of incident angle / reflectance at boundaries of different media.

FIG. 3 is a configuration diagram of a second embodiment of the present invention.

FIG. 4 is a configuration diagram of a third embodiment of the present invention.

FIG. 5 is an explanatory diagram of a function of a prism plate.

FIG. 6 is a configuration diagram of a fourth embodiment of the present invention.

FIG. 7 is a configuration diagram of a conventional example.

[Explanation of symbols]

 1 Film 2 Conductive Film of Film 3 Filling Liquid 4 Spacer 5 Conductive Film of Glass 6 Glass 7 Antireflection Film 8 Space 9 LCD Display

Claims (6)

[Claims] 1. A film having a transparent conductive film on a lower surface thereof is laminated on a glass having a transparent conductive film on an upper surface thereof through spacers arranged to form a minute gap between the conductive films. In a transparent input panel in which the input panel is placed at a fixed distance from the glass on the upper surface of the display,
The space defined by the spacer of the conductive film on the upper surface of the glass of the panel and the conductive film on the lower surface of the film is filled with a transparent filling liquid having a refractive index similar to that of the glass and the film. A transparent input panel placed on the display. 2. The transparent input panel according to claim 1, further comprising an antireflection film formed on a lower surface of the glass of the input panel to prevent reflection of light from the display section. 3. A film having a transparent conductive film on a lower surface thereof is laminated on a glass having a transparent conductive film on an upper surface thereof through spacers arranged to form a minute gap between the conductive films. In a transparent input panel in which the input panel is placed at a fixed distance from the glass on the upper surface of the display,
Arranged on a display unit characterized in that a space having a constant interval between the glass on the upper surface of the display unit and the glass on the lower surface of the input panel is filled with a filling liquid having a refractive index similar to that of the glass. Transparent input panel. 4. A film having a transparent conductive film on a lower surface thereof is laminated on a glass having a transparent conductive film on an upper surface thereof via spacers arranged to form a minute gap between the conductive films. In a transparent input panel in which the input panel is placed at a fixed distance from the glass on the upper surface of the display,
A transparent input panel arranged on a display unit, wherein a prism plate for preventing reflection of light from the display unit is arranged on a lower surface of the glass facing the display unit of the input panel. 5. A film having a transparent conductive film on a lower surface thereof is laminated on a glass having a transparent conductive film on an upper surface thereof with a plurality of spacers arranged to form a minute gap between the conductive films. In a transparent input panel in which the input panel is placed at a fixed distance from the glass on the upper surface of the display,
A transparent input panel arranged on the display unit, wherein a self-occ lens array is arranged between the glass on the upper surface of the display unit and the glass on the lower surface of the input panel. 6. The transparent input panel arranged on the display unit according to claim 1, wherein a self-occ lens array is arranged between the glass on the upper surface of the display unit and the glass on the lower surface of the input panel. .