JPH063668A - Color display device - Google Patents

Abstract

PURPOSE:To enhance the light utilizing efficiency by allowing the light from a backlight to serve without wastefulness. CONSTITUTION:A color display device is structured so that the light from a backlight 10 is cast on the area backward of a display panel 20 which is provided with a plurality of picture elements 20C with variable light transmitting quantity, wherein e backlight has a plurality of divisions 10r emitting red, divisions 10g emitting green, and divisions 10b emitting blue so that different beams from backlight divisions are cast correspondingly to the respective picture elements on the display panel. The divisions are constructed by arranging the red, green, and blue emitting phosphors dividedly. The backlight consists of a fluorescent discharge lamp.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a large direct view type color display device for displaying information such as images and characters in full color.

[0002]

2. Description of the Related Art FIG. 6 is a side view showing the basic structure of a conventional direct-view type color display device. As shown in FIG. 6, a conventional direct-view type color display device includes a backlight 1 and a display panel 2. The backlight 1 is the display panel 2
A single white light is radiated substantially uniformly over the entire rear surface of the. The display panel 2 has three types of small pixels 2R, 2
G and 2B are formed in a planar shape by regularly arranging a large number of them.

The pixel 2R is a polarizing filter 2 made of polarizing glass.
x, liquid crystal layer 2y, and red filter 2 of red translucent glass
r and an electrode for liquid crystal (not shown). Pixel 2
G is substantially the same as the pixel 2R, except that the red filter 2r is composed of a green filter 2g of green translucent glass. The pixel 2B is substantially the same as the pixel 2R, except that the red filter 2r is composed of a blue filter 2b made of blue translucent glass.
Each liquid crystal layer 2y of each pixel 2R, 2G, 2B has its own polarization filter 2x and each color filter 2r, 2g, 2b.
It is formed between b.

The liquid crystal layer 2y of each pixel 2R, 2G, 2B is
An electric signal is applied by a driving circuit (not shown) of the color display device via a liquid crystal electrode (not shown) provided for each pixel. Each liquid crystal layer 2y to which an electric signal is applied has a polarization characteristic according to each electric signal.
That is, the polarization filter 2x and the liquid crystal layer 2y, which are paired with each of the pixels 2R, 2G, and 2B, form a light-dark filter whose light transmission amount can be controlled according to an electric signal. Moreover, the pixel 2R has the red filter 2r
G is a green filter 2g and pixel 2B is a blue filter 2b.
It has each.

Therefore, in the pixels 2R, 2G, and 2B of the display panel 2 in which the single white light is illuminated substantially uniformly on the entire rear surface by the backlight 1, the electric signals of the drive circuit (not shown) are provided. Thus, the pixel 2R transmits red light with light and dark (light amount), the pixel 2G transmits green light with light and dark (light amount), and the pixel 2B transmits light and dark (light amount). It transmits the accompanying blue light. Therefore, if the viewing distance of the display panel 2 is set sufficiently larger than the pixel interval, a full color image can be displayed on the display panel 2.

[0006]

However, in the above-described conventional color display device, the efficiency at each stage when the white image with the highest brightness is displayed on the entire surface of the display panel 2 is as follows. Made of That is, the pixel area efficiency (ratio of the effective pixel area to the area of the display panel 2) is about 40%, the light transmittance of the polarizing filter 2x is about 30%, the light transmittance of the liquid crystal layer 2y is about 80%, and the color filter 2r. , 2g, 2
The average light transmittance of b is about 30%. Therefore, the total efficiency of the display panel 2 is about 3% obtained by multiplying them. That is, assuming that the light amount of the single white light emitted to the rear of the display panel 2 is 100%, the light amount that is transmitted through the front and contributes to display white on the entire surface of the display panel 2 is about 3% thereof.
It's just nothing. Therefore, it is 300 cd / m, which is about the same as TV.
^In order to obtain a white light of ^2, a backlight 1 having a brightness of 10,000 cd / m ² was necessary.

Therefore, in order to obtain the same level of visibility (visibility) as that of a television in a conventional color display device, the backlight 1 must have a large capacity, and the color display device is bulky. Therefore, there is a problem that it is difficult to reduce the thickness and heat generation (power loss) becomes large.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an efficient color display device in which light from a backlight is not wasted.

[0009]

SUMMARY OF THE INVENTION In order to solve the above problems, the present invention provides a back panel behind a display panel having a plurality of pixels whose light transmission amount can be varied. In a color display device formed by illuminating with a light, a backlight is provided with a plurality of sections for emitting red light, a section for emitting green light, and a section for emitting blue light, and a predetermined pixel of a display panel is provided in a predetermined section of the backlight. Is irradiated correspondingly. Further, the invention according to claim 2 is characterized in that the red fluorescent material, the green fluorescent material, and the blue fluorescent material are separately provided to configure the partition.
Further, the invention according to claim 3 is characterized in that the backlight is constituted by a fluorescent discharge lamp.

[0010]

With the above-described structure, the invention according to claim 1 can display a full-color image without providing a color filter unlike the conventional color display device. It is possible to eliminate the attenuation of the light quantity. Even if a colored filter is provided, the red light section irradiates the red filter and the red corresponding pixel, the green light section irradiates the green filter and the green corresponding pixel, and the blue light section irradiates the blue filter and the blue corresponding pixel. By irradiating, the light transmission efficiency of each color filter can be improved.

According to the second aspect of the invention, the red phosphor, the green phosphor, and the blue phosphor are provided separately to form a backlight that constitutes each of the sections. Pixels are illuminated with high brightness red light from the red phosphor, green pixels are illuminated with high brightness green light from the green phosphor, and blue pixels are illuminated with high brightness blue light from the blue phosphor. You can receive each.

Further, in the invention according to claim 3, the backlight constituting each of the sections by separately providing the red phosphor, the green phosphor and the blue phosphor is a fluorescent discharge lamp. Since it is configured, the configuration of the backlight can be simplified.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A basic structure of a color display device according to the present invention will be described with reference to FIG. 1, an embodiment of the color display device according to the present invention will be described with reference to FIG. 5 will be described in detail.

FIG. 1 is a sectional view showing the arrangement of a backlight and a display panel of a color display device. In FIG. 1, 10 is a backlight and 20 is a display panel. The backlight 10 is arranged behind the display panel 20. The backlight 10 does not irradiate a single white light like a conventional backlight, but includes a plurality of red light sections 10r, a plurality of green light sections 10g, and a plurality of blue light sections 10b. Each of these compartments 10
The r, 10g, and 10b are arranged alternately vertically and horizontally or vertically or horizontally.

The display panel 20 differs from the conventional one in that
Only a plurality of types of pixels 20C are provided. The respective pixels 20C are arranged at positions facing the respective partitions 10r, 10g, 10b, and the partition 10r is the partition 10r.
Only the pixel 20C facing the
Only the pixel 20C facing 0g and the section 10b are configured to irradiate only the pixel 20C facing the section 10b as much as possible.

The pixel 20C includes a polarizing filter 20x made of polarizing glass, a liquid crystal layer 20y, and a colorless transparent glass 20z.
And a liquid crystal electrode (not shown). Liquid crystal layer 2
0y is a polarizing filter 20x and colorless transparent glass 20z
It is formed between and.

Therefore, an electric signal from a driving circuit (not shown) of the color display device is applied to a liquid crystal electrode (not shown) for each pixel 20C to form a pair of polarization filters 20x for each pixel 20C. When a bright / dark filter whose light transmission amount is controllable is controlled according to an electric signal composed of the liquid crystal layer 20y and the liquid crystal layer 20y, an electric signal from a drive circuit (not shown) causes
The pixel 20C facing the red light section 10r transmits red light with light and darkness (size of light), and the pixel 20C facing the green light section 10g transmits green light with brightness (size of light). The pixel 20C facing the blue light section 10b transmits blue light accompanied by light and dark (amount of light).

Therefore, if the viewing distance of the display panel 20 is set sufficiently larger than the pixel interval, a full-color image can be displayed on the display panel 20, as in the conventional color display device. Moreover, the pixel 20C of the display panel 20 does not have a colored filter like the conventional pixels. Therefore, the light emitted from the backlight 10 effectively contributes to the display of a full-color image on the display panel 20 because there is no colored filter.

Next, an embodiment of the color display device will be described with reference to FIG. FIG. 2 is a front view showing the arrangement relationship between the backlight and the display panel of the color display device. Figure 2
In the figure, 10 is a backlight and 20 is a display panel. The backlight 10 is arranged behind the display panel 20.

The backlight 10 includes three types of rod-shaped light sources 10r, 10g and 10b having the same shape. The rod-shaped light sources 10r, 10g, 10b may be arranged in any direction, but in the present embodiment, a large number of rod-shaped light sources are alternately arranged at equal intervals. The rod-shaped light source 10r corresponds to a red light section that emits red light, the rod-shaped light source 10g corresponds to a green light section that emits green light, and the rod-shaped light source 10b corresponds to a blue light section that emits blue light.

The display panel 20 is a planar one formed by arranging a number of substantially square pixels 20C in the vertical and horizontal directions at equal intervals, and one side of the pixel 20C is made slightly larger than the width of the rod-shaped light source 10r. . The configuration of the pixel 20C is the same as that described above, and the pixel 20C is controlled by an electric signal from a drive circuit (not shown) of the color display device. Further, the intervals between the vertical columns of the pixels 20C arranged in the vertical and horizontal directions are set to the respective bar-shaped light sources 10r, 10g, 10
The pixel 20C is arranged so as to be equal to the interval b, and to face any of the rod-shaped light sources 10r, 10g, and 10b. Further, although not shown, the rod-shaped light source 1
The rod-shaped light sources 10r, 10g, and 10b themselves have a reflecting surface (not shown) or the rod-shaped light sources 10r and 10g in order to prevent the light from mixing with each other.
A rod-shaped light source 10r, 10b is provided by providing a mirror light-shielding plate (not shown) as a separator between g and 10b.
The lights from g and 10b are radiated only to the front without being mixed.

Here, the rod-shaped light source 10r is a fluorescent discharge lamp in which a red single-wavelength phosphor is applied to an arc tube, and the rod-shaped light source 10g is a fluorescent discharge lamp in which a green single-wavelength phosphor is applied to an arc tube, a rod-shaped light source. If 10b is a fluorescent discharge lamp in which a blue single-wavelength phosphor is applied to the arc tube, the luminous flux from the backlight 10 is
The luminous flux is about 85% compared to the case where the same number of fluorescent discharge lamps in which white phosphors are applied to the arc tubes of the same shape are used. However, the pixel 20C does not have a colored filter like the conventional pixel.

Therefore, as compared with a color display device in which only a fluorescent discharge lamp in which a white phosphor is applied to the backlight is provided and a color filter is provided, a red single-wavelength type light emitting tube is used for the backlight as described above. A fluorescent discharge lamp coated with a phosphor, a fluorescent discharge lamp coated with a green single-wavelength fluorescent material on an arc tube, and a fluorescent discharge lamp coated with a blue single-wavelength fluorescent material on an arc tube are arranged and a colored filter In the color display device that does not need the above, the total luminous flux from the backlight is reduced to about 0.85 times, but the colored filter (average light transmittance for a single white light is about 30%) is not necessary, so the light transmittance is reduced. Is improved about 3 times. In other words, the overall efficiency improvement is about 2.5 times.

Since the three primary color lights obtained by the fluorescent discharge lamp coated with the red, green, and blue single-wavelength phosphors have a bright line spectrum due to mercury at the time of discharge and the color purity deteriorates, a colored filter is provided as in the conventional case. In some cases, the color purity is improved, but even if the red filter that transmits only red light transmits almost all red light, that light is transmitted without being attenuated. In this case, the light transmittance of the colored filter is improved to about 75%.

Next, another embodiment of the color display device will be described with reference to FIGS. FIG. 3 is a front view showing a fluorescent discharge lamp used for a backlight, FIG. 4 is a side view showing an arrangement relationship between the backlight and a display panel, and FIG. 5 is a front view showing the display panel.

In FIG. 4, 10 is a backlight, 20 is a display panel, and 30 is a color filter. The backlight 10 is arranged behind the display panel 20, and the colored filter 30 is arranged between the backlight 10 and the display panel 20.

As shown in FIG. 3, the backlight 10 has a substantially square shape in a front view, and a light emitting component 11 having a substantially square shape in a front view and a cathode formed by projecting a rear center of the light emitting component 11. The component 12 is integrally formed. The light emitting component 11 is a long and narrow transparent glass tube in which substantially rectangular bulges are formed at predetermined intervals, and is formed in a bead shape, and is formed in a spiral shape in a plane along four sides of the light emitting component 11. A tube 13 is provided. A hot cathode 10M is provided in the space inside the cathode constituent portion 12.

The spiral arc tube 13 has 64 bulges in total. The red single-wavelength phosphor R, the green single-wavelength phosphor G, or the blue single-wavelength phosphor B is applied to the inner surface of the bulge portion for each bulge portion, and the red light section 13r is applied. , Green light section 13g, blue light section 13b
Are formed respectively. In the arc tube 13 of the embodiment, 64 bulges are arranged in an orthogonal array of 8 rows and 8 columns as a whole. In addition, the red light section 13r and the blue light section 13b are used in an orthogonal arrangement in which the green light section 13g is used twice, and the backlight 10 is additionally installed in the vertical and horizontal directions so as to be compatible with a large screen. Care is taken not to break the relationship. This relationship is established in order to balance the color of the image due to the different luminous efficiencies of the phosphors R, G, B. Therefore, the arrangement of the sections 13r, 13g, 13b may be changed as appropriate, and the arc tube 13 may not necessarily have a spiral shape but may have a zigzag shape or the like.

A positive electrode 10P is provided at one end of the arc tube 13.
And the communication opening 13a communicating with the hot cathode 10M is provided at the other end of the arc tube 13. Also, arc tube 1
The inner space of 3 is made airtight, and is filled with an inert gas such as argon or mercury. In addition, a reflective film (not shown) is formed on the rear surface of each bulge of the arc tube 13 so that the light emitted from each of the phosphors R, G, and B can be efficiently emitted only forward. Is preferred. Further, it is also preferable to provide a mirror light-shielding plate (not shown) as a separator between the respective bulging portions (red light section 13r, green light section 13g, blue light section 13b) of the arc tube 13 to avoid mixing of light. .

As shown in FIG. 5, the display panel 20 has pixels 20C having the same structure as that described in the previous embodiment arranged in a grid pattern, and each pixel 20C drives a color display device. Each is controlled by an electric signal of a circuit (not shown). Further, each pixel 20C has a red light section 13r, a green light section 13g, and a blue light section 13b.
And face each other one to one. The display panel 20 may be expanded in the vertical and horizontal directions so as to be compatible with a large screen.

The color filter 30 is a film-like member having the same size as the display panel 20.
Red filter section 30 in a grid pattern in accordance with the pixels 20C of
r, a green filter portion 30g, and a blue filter portion 30b are provided. The colored filter 30 is for improving the color purity, and the red filter unit 30
r, the green filter portion 30g, and the blue filter portion 30b face the red light section 13r, the green light section 13g, and the blue light section 13b of the backlight 10 in a one-to-one manner. The colored filter 30 may be added in the vertical and horizontal directions so as to be compatible with a large screen.

In the color display device described above with reference to FIGS. 3 to 5, a full-color image can be displayed on the display panel 20 as follows. That is, when a voltage is applied across the hot cathode 10M of the backlight 10 to heat the hot cathode 10M, and a sufficient voltage is applied between the hot cathode 10M and the positive electrode 10P via an appropriate impedance, the discharge is generated. Then, the red light section 13r emits red light and is opposed to the pixel 2 through the red filter section 30r.
0C, the green light section 13g emits green light and illuminates the opposite pixel 20C via the green filter portion 30g,
The blue light section 13b emits blue light and the blue filter portion 30b.
The pixel 20C which opposes is irradiated via.

Therefore, an electric signal of a driving circuit (not shown) of the color display device is applied to a liquid crystal electrode (not shown) of each pixel 20C to form a pair of polarization filters for each pixel 20C. When a bright / dark filter whose light transmission amount is controllable is controlled according to an electric signal composed of a liquid crystal layer, the red light section 13 is driven by an electric signal of a drive circuit (not shown).
The pixel 20C facing the r transmits the red light accompanied by the light and darkness (the amount of light is large and small), and the pixel 20C facing the green light section 10g.
Light-transmits green light accompanied by light and darkness (large and small amount of light), and the pixel 20C facing the blue light section 10b transmits blue light accompanied by light-darkness (large and small amount of light).

Therefore, if the viewing distance of the display panel 20 is set sufficiently larger than the pixel interval, a full-color image can be displayed on the display panel 20 as in the conventional color display device. Moreover, although the colored filter 30 for improving the color purity due to the mixing of the emission line spectrum of mercury at the time of discharge is interposed, the light transmittance of the colored filter 30 is improved to about 75% for the reason described above.

Here, in the color display device described with reference to FIGS. 3 to 5, the efficiency at each step when a white image of the highest brightness is displayed on the entire surface of the display panel 20 is calculated as follows. Becomes That is, the pixel area efficiency (ratio of the effective pixel area to the area of the display panel 20) is approximately 40% as in the conventional case (actually, the light sections 13r, 13g, 13).
The thin part of the arc tube 13 connecting b is not coated with a phosphor, and all the light from each of the light sections 13r, 13g, and 13b is incident on the pixel 20C, so it may be 40% or more. The light transmittance is about 30% as before, the light transmittance of the liquid crystal layer is about 80% as before, and the color filter 30 is used.
The average light transmittance of is about 75%. Therefore, the display panel 2
The total efficiency of 0 is about 7% by multiplying these.

That is, assuming that the amount of light applied to the rear of the display panel 20 is 100%, the light is transmitted to the front and the display panel 2 is transmitted.
The amount of light that contributes to displaying a white image on the entire surface of 0 is
That is about 7%. That is, it is possible to obtain a brightness twice as high as that of the conventional case of 3%. Therefore, as much as 30
It is a backlight 10 of 5000 cd / m ² about brightness in order to obtain white light 0 cd / m ^2.

The present invention is not limited to the above embodiment, and the backlight may be a cathode ray tube in which each phosphor is separately coated. Further, the pixel is not limited to the one using the polarization filter and the liquid crystal layer, and may be any one as long as the light transmission amount can be controlled by an electric signal.

[0038]

Since the color display device of the present invention is configured as described above, the invention according to claim 1 can improve the utilization efficiency of the light from the backlight, and thus the backlight is conventionally used. According to the invention of claim 2, in addition to the above effect, each of red, green and blue can be made small in size and heat generation (power loss) can be reduced and visibility can be reduced. Since each light is directly radiated from each section where the phosphors are sectioned and provided, the efficiency can be further improved. In addition to the above effects, the backlight is a fluorescent discharge lamp. Therefore, it is possible to provide a color display device having a simple backlight configuration.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing an arrangement relationship between a backlight and a display panel for explaining a basic configuration of a color display device according to the present invention.

FIG. 2 is a front view showing an arrangement relationship between a backlight and a display panel of an embodiment of the color display device according to the present invention.

FIG. 3 is a front view showing a backlight of another embodiment of the color display device according to the present invention.

FIG. 4 is a side view showing an arrangement relationship between a backlight and a display panel of another embodiment of the color display device according to the present invention.

FIG. 5 is a front view showing a display panel of another embodiment of the color display device according to the present invention.

FIG. 6 is a side view showing a basic configuration of a conventional color display device.

[Explanation of symbols]

 10 backlight 10r red light section 10g green light section 10b blue light section 13r red light section 13g green light section 13b blue light section 20 display panel 20C pixel R red phosphor G green phosphor B blue phosphor

Claims (3)

[Claims] 1. A color display device in which a back surface of a display panel, in which a plurality of pixels each having a variable light transmission amount are arranged, is illuminated by a backlight, and the backlight includes a section for emitting red light and a section for emitting green light. A color display device characterized in that a plurality of sections for emitting blue light are provided respectively, and predetermined pixels of a display panel are correspondingly irradiated with predetermined sections of a backlight. 2. The partition is formed by separately providing a red phosphor, a green phosphor, and a blue phosphor.
The described color display device. 3. The color display device according to claim 2, wherein the backlight is a fluorescent discharge lamp.