JPH04263244A - Image display device - Google Patents

Abstract

PURPOSE:To obtain the inexpensive image display device which facilitates enlargement to large area and has a bright display screen. CONSTITUTION:An He-Ne laser which has a peak nearly at 633nm wavelength is used as a red light source 1, an Ar laser which has a peak almost at 515nm wavelength is used as a green light source 2, and an Ar laser which has a peak nearly at 477nm wavelength is used as a blue light source 3; and their laser light beam have their outward shapes and density controlled under necessary light conditions to irradiate liquid crystal panels 5, 6, and 7, whose images are put together by an optical system 8 and further enlarged and displayed on the display screen 9.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the structure of an image display device. In particular, the present invention relates to an image display device suitable for displaying enlarged images using a liquid crystal electro-optical device.

0002

[Prior Art] Conventionally, terrestrial television stations, satellite television stations, cable television stations, or individual television video recording devices (video decks, laser discs,
A device for specifically displaying video signals sent from a magneto-optical disk (such as a magneto-optical disk) used a method in which electron beams were emitted in a vacuum tube called a cathode ray tube or CRT to cause a phosphor screen to emit light.

[0003] Initially, the diagonal of the display screen was 12 to 14 inches, but in recent years, due to the demands of society,
Sizes exceeding 20 inches and even well over 30 inches have now appeared.

[0004] In the case of a diagonal of 30 inches, the depth is also approximately 30 inches, and the thickness of the glass forming it has also come to exceed 1 cm in order to maintain strength. If the display surface exceeds 30 inches, the weight of the entire device is 100K.
It ended up being well over g. 10 in an ordinary household
It is difficult to place heavy items over 0 kg unless you have a very specific location. In addition, its weight makes it difficult to move it manually when the layout needs to be changed, which has been an obstacle to its widespread use in general households.

[0005] Therefore, in order to solve the problem of weight, a projection type image display device has been proposed. This is a method in which the display from a high-brightness cathode ray tube is enlarged using an optical system and displayed on a screen, and is used for objects with large display areas.

[0006] In recent years, in this projection type,
In place of cathode ray tubes, it has been proposed to put into practical use a thin film transistor type liquid crystal panel using amorphous silicon as its base display. The weight is 30% compared to the projection type cathode ray tube system.
This was one of the factors that helped spread the word to ordinary households.

[0007] A projection display device using this liquid crystal panel usually uses three liquid crystal panels dedicated to red (R), green (G), and blue (B), which are combined into one screen by an optical system. to enlarge the display. For this reason, these three LCD panels require high alignment accuracy, specifically 1μ
An accuracy of m is required.

[0008] Such a projection type display device enlarges and displays a liquid crystal panel of about 3 inches to a screen of about 100 inches on a screen 4 to 5 meters away. For this reason, it is necessary to make the display liquid crystal panel high-definition before enlarging so that the 100-inch display screen does not become rough and blurry.

[0009]

[Problems to be Solved by the Invention] In such a high-definition liquid crystal panel, the distance between adjacent pixels naturally becomes short. Therefore, in order to prevent blurring of the displayed image on the screen projected by the projection, even higher accuracy is required for the alignment of the images of the three R, G, and B panels by the optical system.

[0010]Furthermore, the irradiated light is scattered after passing through the liquid crystal panel, and as the distance between the pixels becomes narrower, the effect of this wraparound light comes into play, making it extremely difficult to realize a clear display image.

[0011] Furthermore, in both rear type and front type image display apparatuses, the liquid crystal panel is irradiated with light from a strong light source, and an optical system is used to enlarge and display the image. This situation is schematically shown in FIG.

The light L from the light source 20 passes through the optical system 21 and is split into three lights for R, G, and B, and is further processed into the required light source state, and then sent to each liquid crystal panel 22, 23, 24.
It passes through and is irradiated. Color filters 25, 26, and 27 are installed before or after the liquid crystal panel, and by passing through these filters, R, G,
Although the color is B, the attenuation of light in this area is large, and in order to obtain a bright display screen, it was necessary to use a more powerful light source. When the light source 20 is made more powerful, various problems occur such as increased power consumption, heat generation within the projection device, temperature inside the projection device increases due to heat generation, changes in driving conditions of the liquid crystal panel, and decreased reliability. . Furthermore, a common problem with these devices was the need for low prices.

[0013]

[Means for Solving the Problems] The present invention prevents the reduction in contrast due to stray light as described above, and as shown in FIG. This is a device that synthesizes the light that has passed through the liquid crystal panel and displays it in color, and is characterized by using a laser beam that has an emission peak in a specific wavelength range as the light source for the light that passes through the liquid crystal panel. .

[0014] That is, this is a device that uses laser light as the irradiation light source of a projection-type image display device and performs color display without the need for a color filter. For example, in FIG. 1, the red light source 1 for this laser beam is a He-Ne laser that has a peak around a wavelength of 633 nm.
The green light source 2 is an Ar laser with a peak wavelength of around 515 nm, and the blue light source 3 is an Ar laser with a peak wavelength of around 477 nm. is processed into the necessary light conditions and irradiated onto the liquid crystal panels 5, 6, and 7. The light passing through this liquid crystal panel is controlled by the shutter function of the liquid crystal panel.
After the amount of transmitted light is limited as ON, OFF or gray scale, they are combined by the optical system 8 and further enlarged and displayed on the display screen 9.

[0015] Since the conventional device used a color filter, the rate of light attenuation at this filter portion was high, but with the configuration of the present invention, the rate of light attenuation is considerably higher than that of the conventional device. became. Furthermore, since the light source has a single wavelength, it is possible to match the optical conditions for each liquid crystal panel when it passes through the panel, so there is less scattered light after passing through the panel, and the blurring of the magnified and projected display screen is reduced. This eliminates the need for a sharp display.

Laser beams used in the present invention include, in addition to the gas laser mentioned above, laser beams using metal vapors such as cadmium and zinc, solid-state lasers using ruby, etc., and other types of laser beams within the visible light range. It is possible to use one having a peak wavelength of . Furthermore, even wavelengths other than the normal emission wavelength could be used to emit light in the visible light range by passing through a special optical system, such as the second harmonic of a YAG laser.

Normally, three laser beams with emission wavelengths close to the red, blue, and green wavelengths are used, but four or more laser beams with different wavelengths are used to synthesize colors and display colors. It was also possible to do so.

[0018]

Embodiment Embodiment 1 In this embodiment, the present invention was applied to a projection type image display device 30 as shown in FIG. In the figure, as the light source 31, the wavelength 63
3nm He-Ne laser, 442nm wavelength He-C
d laser and a He-Cd laser with a wavelength of 534 nm. In the figure, only one laser light source is shown to simplify the explanation. In addition, a dispersion type liquid crystal electro-optical device was used as the three liquid crystal panels for displaying images, and a projection type image display device was realized without using a polarizing plate or a color filter.

FIG. 4 shows a process diagram of a method for manufacturing a dispersion type liquid crystal electro-optical device used in this example. In Figure 4,
Since this is a schematic diagram for explanation, the dimensions are different from the actual dimensions. The substrate used is ordinary blue plate glass 40
On top is an IT layer with a thickness of 2000 Å as a translucent pixel electrode 41.
A material in which O was formed into a predetermined pattern was used. This electrode 41 is etched into a predetermined pattern,
The terminal portion 42 of the second electrode is formed simultaneously with the pixel electrode 41. (Figure 4(A))

However, this terminal portion is particularly effective when formed of metal, and serves to reduce the resistance of the lead-out portion of the second electrode.

Next, a uniform mixed solution of prepolymer and nematic liquid crystal was formed to a thickness of about 15 μm by screen printing. Trimethylolpropane triacrylate was used as the prepolymer, and a homogeneous solution was used in which it was mixed with a polymerization initiator at a ratio of about 25% to a normal nematic liquid crystal material. After this, the printed mixed solution is left for a while to sufficiently level the substrate, and then the entire surface of the substrate is irradiated with ultraviolet light to harden the monomer formed between the substrates.
polymerization) to form a light control layer 43 with a thickness of 25 μm. (Figure 4(B))

In the case of this example, there is no need to remove the solvent after applying the light control layer, and the solvent evaporates during leveling, so that the light control layer surface is not disturbed and the light control layer surface is flat. This was convenient for realizing uniform liquid crystal electro-optical properties.

Furthermore, a second electrode 4 is provided on this light control layer 43.
Step 4: ITO is formed to a thickness of 2000 Å and removed by etching into a predetermined pattern. At this time, there is a high possibility of damaging the light control layer, so when forming the ITO film by sputtering, the heating temperature is lowered than usual, and the ITO film in the lower oxide state is lowered in oxygen atmosphere concentration. form. Then, using a predetermined mask pattern, a mask is formed with photoresist, dry etching is performed with an etching gas containing carbon tetrachloride, the ITO film is patterned, and then oxidized in an oxidizing atmosphere at a temperature of about 250°C. A second electrode can be formed by processing to oxidize the ITO film to improve transmittance and lower electrical resistance.

Of course, ITO can be patterned by wet etching using a normal acid solution, but in this case, a light control layer that is resistant to the acid solution used must be selected.

Next, a transparent protective film and silicone resin are formed on this second electrode by a coating method to complete the protective film 45, and a liquid crystal electro-optical device can be manufactured using only one substrate. I was able to complete it. (FIG. 4(C)) The three liquid crystal panels thus created are installed in the light source and optical system part in the positional relationship shown in FIGS. 1 and 3 to form an image display device 3 of the present invention.
Completed 0.

In this device, light from a laser beam 31 passes through an optical system 34, is processed into a required shape, and is irradiated onto a liquid crystal panel 32 as parallel light beams. This liquid crystal panel controls the degree of transmission of laser light according to image information displayed by a control device 33, and then the three colors are combined in an optical system 35, enlarged, and projected onto a screen 36 to display an image. be.

In the case of this embodiment, since a color filter is not required and a dispersion type liquid crystal panel is used, a polarizing plate is not required, and a bright display screen with a small degree of attenuation of light at the liquid crystal panel 32 portion can be realized. was completed.

Furthermore, since the light source has a single wavelength, it is possible to match the optical conditions for each liquid crystal panel when it passes through the panel, so there is less scattered light after passing through the panel, and enlarged and projected images can be displayed. The blurring of the screen is eliminated, a sharp display can be achieved, and when images are combined in the optical system 35, a margin can be obtained in the alignment accuracy of each liquid crystal panel.

Embodiment 2 In this embodiment, the present invention was applied to a projection type image display device that displays an image on a distant wall. In this example, the light sources used are a He-Ne laser with a wavelength of 633 nm and a He-Ne laser with a wavelength of 534 nm.
Four light sources were used as light sources: a He-Cd laser with a wavelength of 442 nm, and an Ar laser with a wavelength of 488 nm. This example uses two types of laser light that have emission peaks in the blue region, which is particularly difficult to see, so it is possible to increase the blue light intensity and at the same time display color display by mixing light of four wavelengths. Therefore, it is possible to display images with more color tones.

Furthermore, as the four liquid crystal panels for displaying images, liquid crystal panels using ferroelectric liquid crystal are used in this embodiment, and the high-speed response of ferroelectric liquid crystal is utilized to display moving images, for example. A projection-type image display device with a very light screen was realized by realizing TV screen display without the use of color filters.

Furthermore, a thin film with a specific refractive index that can serve as an anti-reflection film is provided on the substrate of the liquid crystal panel, between the substrate and the electrodes, or between the electrodes and the liquid crystal, depending on the wavelength of the laser light to be transmitted. By suppressing reflected light at these interfaces and suppressing the generation of stray light due to wraparound, the liquid crystal panels could be aligned with higher precision, resulting in high-definition display.

[0032]

According to the structure of the present invention, a projection type display device having a brighter display screen can be realized, and it is possible to perform good display even in the daytime, outdoors, or in a bright room.

Furthermore, a projection-type image display device that does not require a color filter, has a small number of parts, is inexpensive, and allows for easy positioning of each liquid crystal panel and provides high-definition display has been realized.

[Brief explanation of the drawing]

FIG. 1 shows a schematic diagram of the optical relationship of an image display device of the present invention.

FIG. 2 shows an example of an optical system of a conventional projection type display device.

FIG. 3 shows a schematic diagram of an image display device of the present invention.

FIG. 4 shows a manufacturing process diagram of a liquid crystal panel.

[Explanation of symbols]

1, 2, 3... Laser light 4...Optical system 5, 6, 7...LCD panel

Claims (2)

[Claims] 1. A projection type image display device that displays colored light by passing colored light through a plurality of liquid crystal panels and synthesizing the light that has passed through these liquid crystal panels, wherein the light passing through the plurality of liquid crystal panels is An image display device characterized in that a laser beam having an emission peak in a different wavelength range is provided as a light source corresponding to the number of liquid crystal panels, and a color filter is not required. 2. The method according to claim 1, wherein each of the laser beams used has a different emission wavelength peak, and color display is performed by combining the lights that have passed through a liquid crystal panel using four or more types of laser beams as light sources. [Claim 3] A projection-type image display device that displays color by passing colored light through a plurality of liquid crystal panels and synthesizing the light that has passed through the liquid crystal panels, wherein the plurality of liquid crystal panels As a light source for the light passing through the panel, a laser beam having an emission peak in a different wavelength range is provided as a light source, corresponding to the number of liquid crystal panels, and a laser beam having an emission peak in a different wavelength range is provided as a light source. An image display device characterized in that a liquid crystal panel is provided with a thin film having a specific refractive index that can serve as an antireflection film.