JPH01108596A - Display device - Google Patents

Abstract

PURPOSE: To inexpensively manufacture a color filter by printing by arraying color filter pixels capable of selectively transmitting light of three primary colors of red, green and blue in the vicinity of the image forming surface of an enlarged projection image corresponding to a display picture on an electro- optical cell. CONSTITUTION: Black-and-white picture light generated by transmitting light through a liquid crystal display cell 40 is colored after successively transmitting the light through a projection lens 50 and a color filter 70. A black-and-white image formed on the cell 40 is enlarged and projected to a screen 80 as a color image. Since a pixel pattern on the cell 40 is enlarged and formed on the screen 80, the filter 70 in contact with the screen 80 can enlarge the array pitch of pixels of three primary colors, i.e., red, green and blue, by the enlargement ratio of the lens 50. Consequently a request for working accuracy at the time of manufacturing the color filter 70 can be sharply relaxed and the color filter 70 can be manufactured by printing.

Description

[Detailed Description of the Invention] <Industrial Application Field> The present invention controls the transmittance of light passing through a mosaic color filter pixel by controlling the transmittance of an electro-optic cell using an electric signal. The present invention relates to an electro-optical display device that performs color display.

<Prior Art> FIG. 4 shows the structure of a color liquid crystal display cell, which is the same in both active matrix driving and multiplex driving. Board 101 on one side
has a mosaic of red, green, and
Blue color filter pixels 500a, 500b, 500c
, . . . are formed on a transparent electrode 201 made of ITo (transparent conductive film) or the like, and further thereon a molecular alignment film 301 made of a polyimide film or the like is formed. The molecular alignment film 301 has been subjected to alignment treatment by rubbing or the like. A liquid crystal layer 400 comes into contact with this molecular alignment film 301 .

On the other substrate 100, transparent electrodes 200a, 20
0b, 200c, . . . , and a molecular alignment film 300 that has been subjected to an alignment process is formed thereon. Molecular alignment film 30
0 is in contact with the liquid crystal layer 400.

Usually, the molecular orientation direction on the two substrates 100 and 101 is
They have a rotation angle of 90° to each other. This cell is sandwiched between two polarizing plates. If the polarization axes of the two polarizing plates are parallel to each other, no light will pass through the portions to which no voltage is applied. For example, in FIG. 4, the electrode 200b and the molecular alignment film 30
1, when a voltage higher than the threshold voltage of the liquid crystal is applied, only green light is transmitted, and a green display is performed. in this way,
Red, green, and blue color filter pixels 500a, 500b.

Color image display is performed by controlling the transmittance of light that passes through 500c, .

<Problems to be Solved by the Invention> In the structure of the color liquid crystal display cell described above, the color filter pixels 500a and 500b are mosaic-shaped.

The display pixel electrodes 200a are used to form the display pixel electrodes 500c, .
.

Almost the same level of processing accuracy as 200b, 200c, . . . is required. Therefore, the color filter 500a.

500b, 500c, etc. are usually produced by covering a substrate such as gelatin with a resist layer with openings formed only in the necessary areas by photolithography, and repeating the process of dyeing this with dye three times. be done. Since color filters are manufactured using such a complicated method, they become very expensive. Also, depending on the heat resistance, chemical resistance, etc. of the substrate such as gelatin, cleaning, formation of transparent electrodes, etc.

There is also the problem that each step of forming the molecular alignment film is subject to significant restrictions.

As shown in FIG. 5, as an application of such a liquid crystal display cell, the liquid crystal display cell 43 having the above-described structure is irradiated with light by the reflecting mirror 13, the light source 23, and the condensing lens 33, and the liquid crystal display cell 43 displays an image. There is a projection type color display device in which an enlarged image is projected onto a screen 76 using a lens 53. However, in this case, since the liquid crystal display cell 43 is close to the light source 23, strong light enters the liquid crystal display cell 43, and as a result, the color filter 500a.

500b, 500c, . . . had a problem of fading.

<Means for Solving the Problems> The present invention provides an electro-optic cell in which the transmittance of a display pixel electrode is controlled by an electric signal to display a monochromatic color, and a light source for enlarging and projecting a display image of the electro-optic cell. In a display device equipped with a projection lens and a screen, a color filter in which red, green, and blue color filter pixels are arranged is provided near an image formation plane for enlarging and projecting a display image of an electro-optic cell.

<Function> In the display device according to the present invention, the monochromatic image light of the image displayed on the electro-optic cell passes through a color filter consisting of red, green, and blue pixels arranged near the image forming plane for enlarged projection. By transmitting the light, the displayed image of the electro-optic cell is enlarged and projected as a color image.

<Example> FIG. 1 shows the optical arrangement of a display device of this example. In the figure, 10 is a reflecting mirror, 20 is a light source, 30 is a condenser lens, 40 is a liquid crystal display cell, 50 is a projection lens, 70 is a color filter, and 80 is a screen.

The reflecting mirror 10, the light source 20, the condenser lens 30, and the projection lens 50 are an optical system that enlarges and projects the image formed on the liquid crystal display cell 40 onto the screen 80.

5- The liquid crystal display cell 40 displays a monochromatic image by controlling the transmittance of light passing through the display pixel electrode by an electric signal. This liquid crystal display cell 40 is T F T Cm
The voltage applied between the display pixel electrodes arranged in a matrix on one substrate and the counter electrode formed over the entire surface on the other substrate is controlled by active matrix drive using membrane transistors. Polarizing plate and 2
The electro-optical characteristics of the liquid crystal layer between the two substrates display a black and white gradation pattern.This liquid crystal display cell 40 forms a monochromatic image, and the color liquid crystal display shown in FIG. The liquid crystal display cell 40 does not have a color filter in the cell.This liquid crystal display cell 40 may display a black and white gradation pattern by multiplex driving.

The color filter 70 is disposed in contact with a screen 80 that is an image formation surface for enlarged projection. The color filter 70 has color filter pixels arranged in a mosaic pattern that selectively transmit light of the three primary colors of red, green, and blue.

To explain the operation, the light emitted from the light source 20 and the light reflected by the reflecting mirror 10 are condensed by the condenser lens 30 and enter the liquid crystal display cell 40. The black and white image light generated by the light passing through the liquid crystal display cell 40 is transmitted through the projection lens 50 and further transmitted through the color filter 70 to be colored. Then, on the screen 80, a liquid crystal display cell 40
The black and white image formed is enlarged and projected as a color image.

In this configuration, the pixel pattern of the liquid crystal display cell 40 is enlarged and imaged on the screen 80, so that the color filter 70 in contact with the screen 80 has the arrangement pitch of the pixels of the three primary colors red, green, and blue projected. It can be increased by the magnification rate provided by the lens 50. Therefore, the requirements for processing accuracy in manufacturing the color filter 70 are significantly relaxed, and the color filter 70 can be manufactured by a printing method. For example, the color filter 70 can be produced by printing color filter pixels at a pitch of 111 in the vertical and horizontal directions on the surface of a polyester sheet by offset printing.

The color filter 70 produced by the above method was pasted on the screen 80, and the display image of the liquid crystal display cell 40 having display pixel electrodes with a vertical and horizontal pitch of 200 μm was enlarged five times and projected onto the screen 80. Color reproducibility and display contrast equivalent to those of a projection type color display device (FIG. 5) using a liquid crystal display cell having a built-in color filter were obtained.

FIG. 2 shows another embodiment. In the figure, 11 is a reflecting mirror, 21
31 is a light source, 31 is a condenser lens, 41 is a liquid crystal display cell, 51 is a projection lens, 61 is a reflecting mirror, 71 is a color filter, and 81 is a transmission screen.

The liquid crystal display cell 41 is the liquid crystal display cell 40 of the above-mentioned embodiment.
It has a similar structure. The reflecting mirror 61 reflects the image light that has passed through the projection lens 51 and guides it to the transmission screen 81 .

The transmissive screen 81 has a color filter 71 formed of mosaic color filter pixels of three primary colors of red, green, and blue printed on its light incident surface.

Light from the light source 21 and the reflecting mirror 11 is condensed by a condenser lens 31 and irradiated onto a liquid crystal display cell 41 . The black and white image light generated by passing through the liquid crystal display cell 41 passes through the projection lens 51 and is further reflected by the reflecting mirror 61.
The light is guided to a color filter 71 on a transmission screen 81. The black and white image light is colored by the color filter 71, and the color image is enlarged and projected onto the transmission screen 81. A person visually recognizes the image from the right side of the screen 81 in the figure. In this case, the order of the color filter 71 and the screen 81 is not necessarily as shown in FIG.
It can be the other way around. Further, the color filter 71 is connected to the screen 8
In addition to being placed on the reflective surface of the reflective mirror 61, it may be configured to be attached to the reflective surface of the reflective mirror 61.

FIG. 3 shows yet another embodiment. In the figure, 12 is a reflecting mirror, 22 is a light source, 32 is a condenser lens, 42 is a liquid crystal display cell, 52 is a projection lens, 72 is a color filter, 8
2 is a transmission screen, 92 is a projection lens, and 75 is a screen.

The structure of the 9-1 liquid crystal display cell 42 is similar to the liquid crystal display cell 40 described above. A color filter 72 consisting of mosaic color filter pixels of three primary colors of red, green, and blue is formed on the surface of the transmission screen 82 by printing. Here, the order of the color filter 72 and the screen 82 is not necessarily as shown in FIG. 3, and may be reversed. A projection lens 92 is disposed close to the transmission screen 82.

A screen 75 is disposed on the right side of the projection lens 92 in the figure. The configuration consisting of the reflecting mirror 12, light source 22, condenser lens 32, liquid crystal display cell 42, and projection lens 52 is composed of the reflecting mirror 10, light source 20, condenser lens 30, liquid crystal display cell 40, and projection lens 50 of the above-mentioned embodiment. It is similar to the configuration.

The display image of the liquid crystal display cell 42 is enlarged and projected onto the transmission screen 82 by the projection lens 52.

The black and white image light that has passed through the projection lens 52 passes through the color filter 72 and is colored, and a color image is formed on the screen 82. The color image formed on the transmission screen 82 is further transmitted to the projection lens 92 and the screen 7.
5 will be enlarged and projected. In this example, a projection lens 92 projects the color image on the screen 82 onto the screen 75.
By providing this, enlarged projection to any size is possible. Of course, a color filter may be provided on the screen 75, but in this case, the magnification ratio during projection cannot be changed. However, the contrast degradation due to ambient light is reduced.

In any of the above three embodiments, the light source 20.2
As 1.22, a halogen lamp, a fluorescent lamp, a xenon arc lamp, a metal halide lamp, a fluorescent mercury lamp, etc. can be used. Furthermore, the electro-optical cell that forms an image is not limited to a liquid crystal display cell;
It may also be one using an LZT display panel (translucent ceramic display panel) or a light valve with a mechanical shutter.

<Effects of the Invention> As described above, according to the present invention, color filters conventionally formed by photolithography can be manufactured at low cost by printing.

In addition, when bonding two substrates together in the production of a liquid crystal display cell, which is one type of electro-optical display cell, it is necessary to align the color filter pixels on one substrate with the display electrodes on the other substrate. This method has the advantage of eliminating the need for the conventional process, and greatly improving the yield when manufacturing liquid crystal display cells. Furthermore, cleaning the color filter layer,
Complicated steps such as forming an alignment film on a color filter or forming a transparent electrode are also eliminated. Furthermore, since the light incident on the color filter is the enlarged image of the display image formed on the electro-optic display cell, its intensity is low, and therefore the problem of color fading of the color filter can be solved.

[Brief explanation of the drawing]

1, 2, and 3 are diagrams showing the structure of an embodiment of the present invention. FIG. 4 is a diagram showing the structure of a conventional color liquid crystal display cell. FIG. 5 is a diagram showing a conventional projection type display device. FIG. 10.11.12...Reflector 20.21.22...Light source 30.31.32...Condenser lens 40.41.
42...Liquid crystal display cell 50.51, 52.92...Projection lens 61...Reflector? 0,71.72...Color filter 75.80...
・Screen 81.82... Transparent screen patent applicant Sharp Corporation Representative Patent attorney Nishi 1) Shin

Claims (1)

[Claims] An electro-optic cell whose transmittance of light transmitted through a display pixel electrode is controlled by an electric signal to display a monochromatic color; at least one set of light sources for enlarging and projecting a display image of the electro-optic cell; a projection lens; In a display device equipped with a screen, color filter pixels that selectively transmit light of three primary colors of red, green, and blue are arranged in the vicinity of an image formation plane of an enlarged projected image of a display image of the electro-optic cell. A display device characterized by: