JPH03187592A - Color picture display device - Google Patents

Abstract

PURPOSE:To improve the lightness of a displayed picture by making the color selection member of a translucent substrate face to each picture element of a display means, and filling up a space between them with translucent material. CONSTITUTION:Light from a light source 2 is transmitted from one of the translucent substrate 11 formed by embedding plural microlenses 22 in it or the color selection member 9 to the other of them, and the light of a color determined beforehand at every picture element is selected, and simultaneously, the rays of light of these elements are converged by the micro-lenses 22 at every picture element of the display means 6. Even in the case the non- translucent area of the light other than the picture element is present on the display means 6, the light incident on the non-translucent area is converged to the picture element by the micro-lenses 22. Thus, a light color picture can be obtained.

Description

Detailed Description of the Invention <Industrial Application Field> The present invention relates to a color image display realized as a device that uses a transmissive color liquid crystal display device and projects a color image on a screen using light from a light source. Regarding equipment.

<Conventional technology> In order to realize a relatively large screen using a small and lightweight device, a projection type that uses a transmissive liquid crystal display element and projects a color image onto the screen by irradiating light from a light source on the back side. Color image display devices (hereinafter abbreviated as image display devices) are used. The structure of the liquid crystal display element used is that three liquid crystal display elements are used to form images in these colors based on the red, green, and blue color signals in the image signal, and the transmitted light from these elements is superimposed on the screen. configuration has been adopted. However, with this configuration, three liquid crystal display elements are required, and separate optical systems are required to align the light of each color on the screen, which limits the ability to reduce size and weight. This will also increase costs.

As a second conventional example to solve this problem, a technique is adopted in which a matrix-driven liquid crystal display device is used and a color filter is formed for each picture element to obtain transmitted light of red, green, and blue, for example.

However, in such a conventional example, in particular, a switching element such as a thin film transistor or an MIM (metal-insulated 1#-metal) T: element, and an individual display electrode connected to the switching element, and a drive signal is supplied to the display electrode. In the case of an active matrix drive type liquid crystal display device that uses a drive signal line and a scanning signal line that supplies a control signal to scan the switching elements, display electrodes in a unit area and various types other than the display Ratio of area occupied by signal lines, switching elements, etc.
The aperture ratio (hereinafter referred to as the aperture ratio) is reduced compared to other cases of full precepts. When displaying a color image, it is necessary to downsize the display electrode and increase the pixel density, which increases the area of the light-shielding region that is not suitable for display, and reduces the aperture ratio. decreases further.

This reduction in the aperture ratio causes a problem in that the amount of light that passes through the liquid crystal display device decreases, resulting in a dark displayed image.

As a third conventional example that solves the problems of the second conventional example, a technique is adopted in which a microlens array corresponding to each picture element is formed on the light source side of a single liquid crystal display device. The microlens array condenses incident light to the highest degree possible for display, and prevents the above-mentioned decrease in the amount of transmitted light.

The following method has been proposed as a method for forming the microlens array.

■A method of molding synthetic resin material or glass using a mold.

■Using the phenomenon that when a specific type of photosensitive resin is exposed to light in a pattern corresponding to a microlens array, unreacted monomers of the photosensitive resin move from the exposed area to the exposed area, causing the exposed area to bulge. , how to shape a convex lens.

■Thermoplastic resin is made using well-known photography technology, etc.
A method in which a convex lens is formed by forming a pattern into a flat plate shape that corresponds to a microlens array, and then heating it to a temperature above its softening point to give it fluidity and causing edge blur.

■A method in which a photosensitive resin is subjected to proximity exposure, and the amount of photoreactant is distributed according to the blur of the transferred image on the photosensitive resin at the edge of the mask used for exposure, thereby forming a convex lens.

■A method in which a photosensitive resin is irradiated with light with an intensity distribution to form a refractive index distribution according to the intensity of the light to obtain a structure equivalent to a lens.

■A method of forming a refractive index distribution on a transparent substrate such as glass using selective ion diffusion to obtain a structure equivalent to a lens.

■A method of forming convex lenses by utilizing the shrinkage caused by crystallization that occurs when photosensitive glass is irradiated with light.

Furthermore, a method has been proposed in which this microlens array is selectively colored using pigments or dyes in the same manner as the color filter, thereby displaying color.

<Problems to be Solved by the Invention> In the third conventional example, since the microlens array is dyed to realize the function of a color filter, the following problems occur. Even if an attempt is made to control the spectral characteristics, which is the function of a color filter, by its shape, since this color filter is also a microlens, it is difficult to change the shape determined based on the required lens characteristics. In addition, when constructing a microlens, there is a relatively small range of materials to choose from in terms of refractive index, molecular structure, melting point, etc., and restrictions are imposed on the material of the lens, so the range of pigments and dyes that can be used is also limited. The problem is that there are significant restrictions.

The main objective of the present invention is to provide a color image display device that solves the above-mentioned technical problems, has a smaller and lighter configuration, and can significantly improve the brightness of displayed images.

Means for Solving the Problems The present invention provides: a light source; a display means in which display pixels that selectively transmit light from the light source are arranged in a matrix; and a display device provided on the light source side of the display means, A translucent substrate in which a plurality of microlenses are embedded and formed, wherein transmitted light is selected in a predetermined color at a position corresponding to each microlens in the thickness direction of the translucent substrate. and a light-transmitting substrate on which color selection members are respectively formed, the color selection members of the light-transmitting substrate facing each pixel of the display means, and the space between them being filled with a light-transmitting material. This is a color image display device characterized by:

<Function> According to the present invention, light from a light source is transmitted from either the transparent substrate or the color selection member, in which a plurality of microlenses are embedded, through the other, and the light is transmitted through the other. Light of a predetermined color is selected for each pixel, and these lights are focused by a microlens on each pixel of the display means.6 In addition to the pixel, there is a non-transmissive area of light in the display means. Even in this case, the light incident on the non-transparent region is focused on the picture element by the microlens. Therefore, a color il image is displayed by light selectively transmitted for each picture element through the 0 display means capable of obtaining a bright color image.

<Example> FIG. 1 is a sectional view showing the configuration of a color image display device 1 according to an example of the present invention.1 The image display device 1 includes a white light source 2 and a reflecting mirror 3. The light source light from the reflection M3 enters the display means 6 through, for example, a pair of condenser lenses 4.5.The display means 6 has a color selection member 9 and a liquid crystal display element 10 stacked in this order from the light source 2 side. The light from the 0 display means 6 is projected onto the screen 8 by the projection lens 7 to form a color image.

FIG. 2 is a sectional view showing the structure of the display means 6, and FIG. 3 is a picture element electrode 1 as a display picture element of the liquid crystal display element 10.
The one color selection member 9 shown in the enlarged plan view around 3 is arranged on the light source 2 side of the liquid crystal display element 10. This liquid crystal display element 1
0 is, for example, an active matrix driven type,
As shown in FIG. 3, picture element electrodes 13 made of a transparent conductive material such as ITO (indium tin oxide) are arranged in rows and columns on a glass substrate 19.
A drive signal to 3 is transmitted from a drive signal line 14 to a switching element 15 such as a thin film transistor (TPT).
Supplied via. This switching element 15 is turned on/off by inputting a scanning signal from a scanning signal line 16, and turns on/off the drive signal.

Referring again to FIG. 2, the ellipses of the picture element electrodes 13 and the like are provided on the glass substrate 19 of the light source 2 (1) of the liquid crystal display element 10, and facing the picture element corner 13 on the opposing glass substrate 20. I
Opposed $4iIk2 made of transparent conductive material f4 such as TO
1 is formed over the entire surface of the glass substrate 20.

In such a liquid crystal display element 10, the picture element type [i
13 forms a transmissive region 17, and a drive signal line 14, a scanning signal line 16, a switching element 15, and the like form a light-shielding region 18 that does not transmit light.

FIG. 4 is a sectional view illustrating the manufacturing process of the display means 6, and FIG. 5 is a plan view illustrating the manufacturing process. In the glass substrate 11 of FIGS. 4(1) and 5(1) disposed on the light source 2 side of the liquid crystal display element 10, ions have an intensity distribution by the well-known selective ion diffusion method, and are distributed over the glass substrate 1.
1 is injected into the glass substrate 11 to form a region having a refractive index larger than that of the glass substrate 11 in the shape of a convex lens, and microlenses 22 individually corresponding to the picture element electrodes 13 of the liquid crystal display element 10 are formed. A microlens array arranged in a matrix as shown in FIG. 4(2) and FIG. 5(2) is formed.

A color selection member is provided for each microlens 22 in the liquid crystal display element 10 [11 of this glass substrate 11, and the transmitted light is red,
Color filter 23R selected for green and blue respectively
, 23G, and 23B (collectively referred to by reference numeral 23 if necessary) are formed as shown in FIG. 4 (3) and FIG. The shape is selected so that the light that enters through the color filters 23 enters the picture element electrodes 13 of the liquid crystal display device 10.In other words, if the microlenses 22 were not present, the light that would enter the light shielding area 18 would also be , the picture element is focused on the pole 13 by the microlens 22.

In addition, in order to form the color filter 23, red, green,
A synthetic resin material in which a blue pigment is dispersed may be formed in a predetermined pattern for each color, and multiple layers of inorganic oxide films having different optical refractive indexes may be selectively formed on the liquid crystal display element IO side of the glass substrate 11 by sputtering. IF! IL, there are multiple lights from light source 2! Each interference color of red, green, and blue may be realized by an oxide film.

The glass substrate 11 on which the color filters 23 are formed in this way is attached to the glass substrate 19 by aligning the microlenses 22, each color filter 23, and the pixel electrodes 13 using a transparent adhesive 24. Fixed. In this way, the display means 6 is integrally constructed.

At this time, the light that enters the display means 6 from the light source 2 via the condenser lens 4.5 is focused by the microlens 22 on each picture element electrode 13 of the liquid crystal display element 10, and when passing through the liquid crystal layer. , undergoes intensity modulation in response to the drive signal.

After this light passes through the liquid crystal display element 10, it is diffused into a cone corresponding to the solid angle determined by the numerical aperture (NA) defined for the microlens 22. The aperture D1 of the projection lens 7 is selected so that the light beam can also be received. This makes it possible to prevent the light passing through the liquid crystal display element 10, that is, the displayed image, from being restricted by the projection lens 7.

In this way, the light from the light source 2 passes only through the transmission area 17 of the liquid crystal display element 10, so the brightness of the image formed on the screen 8 can be increased without unnecessarily increasing the illuminance of the light source 2. can do. Further, compared to the configuration using three liquid crystal display devices corresponding to red, blue, and green as described in the conventional example, the configuration can be made smaller and lighter.

The light source 2 is a white light source, and a halogen lamp, a metal baride lamp, a xenon lamp, etc. are used.

<Effects of the Invention> As described above, according to the present invention, light from a light source is transmitted from either the transparent substrate or the color selection member in which a plurality of microlenses are embedded, to the other. Light of a predetermined color is selected for each display pixel, and these lights are focused by a microlens on each display pixel of the display means. A color image is displayed by the light that is selectively transmitted through each image. This eliminates the need for a configuration in which display means and light sources are used individually for each of the colors, and the configuration can be made smaller and lighter. 0 When a non-light transmitting area exists in the display means other than the picture element, Even if the light is incident on the non-transparent region, it is focused on the picture element by the microlens. Therefore, it is possible to prevent a situation in which the transmitted light intensity of the entire display means is attenuated.

Therefore, the brightness of the displayed image can be significantly improved.

[Brief explanation of drawings]

FIG. 1 shows an image display device according to an embodiment of the present invention. &1, FIG. 2 is a cross-sectional view showing an example of the structure of the display means 6, FIG. 3 is an enlarged plan view of a part of the liquid crystal display element 10, and FIG. 4 shows the M manufacturing process of the display means 6. FIG. 5 is a cross-sectional view to explain the manufacturing process, and FIG. 5 is a plan view to explain the manufacturing process. DESCRIPTION OF SYMBOLS 1... Image display device, 2... White light source, 6... Display means, 9... Color selection member, 10... Liquid crystal display element, 11.19.20... Glass substrate, 13 ... Pixel as pole, 17... Transmissive area, 18... Light blocking area, 2
2...Micro lens, 23R, 23G, 23B...
・Color filter

Claims (1)

[Scope of Claims] A light source, a display means in which display pixels that selectively transmit light from the light source are arranged in a matrix, and a plurality of microlenses provided on the light source side of the display means and embedded therein. A light-transmitting substrate is formed of a light-transmitting substrate, and a color selection member for selecting a predetermined color of transmitted light is formed on one side in the thickness direction of the light-transmitting substrate at a position corresponding to each microlens. and a color selection member of the transparent substrate faces each picture element of the display means, and the space between them is filled with a transparent material. Device.