JPH04122910A - Liquid crystal display device - Google Patents

Abstract

PURPOSE:To make a field angle large, to eliminate the need for a polarizing plate, and to realize a large bright screen and high picture quality by using guest-host liquid crystal which contains dichroic coloring matter and dispersing the liquid crystal in a high polymer in three-dimensional network structure. CONSTITUTION:The display device which is provided with the liquid crystal 24 between a lower transparent substrate 10, where the active matrix element 13 of a varister element consisting principally of zinc oxide is provided, and an upper transparent substrate 17 and drives the liquid crystal by the element 13 uses the guest-host liquid crystal containing the dichroic coloring matter as the liquid crystal, which is dispersed in the high polymer in the three- dimensional mesh structure. Then the substrate 17 is provided with a black matrix 25 consisting of a metallic thin film so as to realize a sharp color image and a color filter part 16 is provided on the matrix 25 across an insulating layer 26; and a counter electrode 15 is provided on it and an upper insulating layer 18 for prevention against a short circuit with the element 13 is further provided thereupon.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a liquid crystal display device using a polymer dispersed liquid crystal in which liquid crystal is dispersed in a polymer having a three-dimensional network structure. .

(Prior Art) Currently, image display devices such as liquid crystal televisions are broadly classified into simple matrix type and active matrix type.

The simple matrix method is a method in which two groups of band-shaped electrodes (row electrodes and column electrodes) are orthogonally crossed, and a display pixel is formed at the intersection point, and a predetermined voltage is applied between these band-shaped electrodes by a drive circuit to generate a display pixel. Activate. This method is
Since the structure is simple, the system can be realized at a low cost. However, since crosstalk occurs in each liquid crystal pixel, the contrast ratio of the pixels cannot be maintained, and when displaying a high-definition image such as a television image, a reduction in image quality is unavoidable.

On the other hand, in the active matrix method, a switching element is provided for each liquid crystal pixel to maintain the voltage.
Since the voltage applied to the liquid crystal can be maintained even when the liquid crystal display device is time-divisionally driven, it is possible to increase the display capacity, and it has good image quality characteristics such as high contrast ratio, making it possible to realize high-quality image display on liquid crystal televisions. It is something.

A conventional active matrix type liquid crystal display device using a varistor as an active matrix element is shown in FIGS. 4 and 5. As shown in the figure, row electrodes 11 and pixel electrodes 12 are provided on a lower glass substrate 10 at a predetermined interval, and these row electrodes 11 and pixel electrodes 12 are formed by a sintered Harrisque element 13 made of zinc oxide. It is connected.

A liquid crystal 14 is injected and filled between the counter electrodes 12 connected to the column electrodes and the upper glass substrate 17 provided with the color filters 16 at a predetermined distance d above these. The liquid crystal 14 used here is usually TN
A (twisted spear matic) type liquid crystal is common, and the liquid crystal is used as a light shutter. In this case, a deflection plate 1 is placed on the outside of the lower glass substrate 10 and the upper glass substrate 17.
9 will be installed. Sintered varistor element 1 that switches the liquid crystal 14 based on the voltage applied to the row electrode 11
No. 3 is a varistor particle in which ZnO particles are coated with a metal insulating film such as a thin Mn or Co oxide film, and is sintered with glass flint. A threshold voltage is obtained. Therefore, the row electrode 11
If the distance between the pixel electrode 12 and the pixel electrode 12 is set to 30 μml, substantially six varistor grains 1 existing in series within this distance
The row electrode 11 and the pixel electrode 12 are connected via 3a,
A threshold voltage of 3V x 6 = 18V is obtained between these electrodes 11 and 12. That is, when a voltage exceeding this threshold voltage is applied, the liquid crystal 14 becomes driven, eliminating the influence of the applied voltage on other liquid crystal elements, and preventing the occurrence of crosstalk. can do.

[Problem to be solved by the invention]

Among conventional liquid crystal display devices, active matrix type ones have good image quality characteristics such as contrast ratio as mentioned above, and can realize the image display of an LCD TV, but with the recent trend toward larger screens, There are the following problems.

A conventional liquid crystal display device has a structure in which liquid crystal 14 is filled between the lower glass substrate 1o and the upper glass substrate 17, but since the liquid crystal used in this case is a TN type liquid crystal, there is no liquid crystal on the outside of the upper and lower glass substrates. A total of two polarizing plates are required. Normally, the light transmittance of a polarizing plate is only about 30% (because two polarizing plates are used in a stacked manner, the intensity of transmitted light is less than 10% of the incident light in a transmissive liquid crystal display device, resulting in high brightness). It is difficult to obtain a large transmission type liquid crystal display device due to the light source.Furthermore, since TN type liquid crystal uses optical rotation due to twisting of liquid crystal molecules, it is dependent on viewing angle, and it is difficult to obtain a large screen. This was a major problem at the time.

The present invention has been made in view of the above-mentioned drawbacks of the conventional method, and it is an object of the present invention to provide a large, bright liquid crystal display device that has no viewing angle dependence as a liquid crystal, does not require a polarizing plate, and is bright.

[Means for Solving the Problems] A liquid crystal display device according to the present invention has a liquid crystal disposed between a lower transparent substrate and an upper transparent substrate, each having an active matrix element formed of a varistor element containing zinc oxide as a main component. , a liquid crystal display device in which a liquid crystal is driven by an active matrix element, which uses a guest host liquid crystal containing a dichroic dye as the liquid crystal, and is characterized by a structure in which the liquid crystal is dispersed in a polymer having a three-dimensional network structure. be.

Further, in the liquid crystal display device according to the present invention, in the above invention, the upper substrate is provided with a black matrix made of a metal thin film, and an insulating layer and a color filter are provided thereon,
Furthermore, it is characterized by having a counter electrode provided thereon, thereby realizing clear color display.

[Function] In the liquid crystal display device of the present invention, a guest host liquid crystal containing a dichroic dye is used as the liquid crystal, and a polymer having a three-dimensional network structure is dispersed in the liquid crystal, thereby widening the viewing angle. , it becomes possible to make the display screen even brighter,
The objective is to realize a clear, high-brightness, large-screen liquid crystal display device.

[Example] A liquid crystal display device according to the present invention will be specifically described based on an example.

First, a polymer dispersed liquid crystal used in a liquid crystal display device will be explained based on FIG. 2 and Part 3.

As shown in Fig. 2, the polymer dispersed liquid crystal is made by dispersing a three-dimensional network structure 24 (b) obtained by ultraviolet polymerization in a continuous layer of Hachimatic liquid crystal 24 (a). It exhibits a light scattering mechanism due to the random orientation of liquid crystals due to the three-dimensional polymeric structure of molecules. Such polymer-dispersed liquid crystals are produced by adding a photopolymerization initiator to a polymer precursor (such as MMA) and applying liquid 78 mixed with nematic liquid crystal to both sides.
It is manufactured by filling a liquid crystal cell with a transparent electrode such as TO, irradiating it with light such as ultraviolet rays, forming a three-dimensional network structure through a photopolymerization reaction, and simultaneously separating the liquid crystal. At this time, the average network size of the three-dimensional network structure obtained varies depending on the polymerization conditions, but is controlled to be around 1 μm. As shown in FIG. 2(a), when no voltage is applied to the polymer dispersed liquid crystal 24, the liquid crystal 24 (a
) are oriented along the interface of the three-dimensional mesh structure 24 (b) and scatter light, making the polymer dispersed liquid crystal 24 milky white and opaque. On the other hand, the 211iI
(When a voltage is applied to the polymer dispersed liquid crystal 24 as shown in (b), the molecular direction of the liquid crystal 24 (a) is aligned in the direction of the electric field, so light is transmitted and the polymer dispersed liquid crystal 24
4 becomes transparent. However, since such an opaque state due to light scattering does not block light, it is difficult to use it as a light shutter for a transmissive liquid crystal display device. Adding a dichroic dye to the liquid crystal is effective for imparting light-shielding properties to the photomolecularly dispersed liquid crystal.

As shown in FIG. 3, dichroic dye 2 is added to liquid crystal 24 (a).
4 Add (c).

Dichroic dyes are rod-shaped like liquid crystal molecules, so they move by following the liquid crystal molecules. Therefore, Fig. 3(a)
As shown in , when no voltage is applied, the dichroic dye 24 (c) assumes a random arrangement similar to the liquid crystal 24 (a), and the incident light is scattered by the liquid crystal 24 (a). At the same time, it is absorbed by dichroic dye 24(c). On the other hand, as shown in the third [D(b), when a voltage is applied,
The molecular direction of the liquid crystal 24 (a) is aligned in the direction of the electric field, and the dichroic dye 24 (c) is also aligned along the optical axis, so the incident light passes through the liquid crystal layer without being absorbed much, making it brighter. It becomes transparent. In this way, by using a polymer dispersed liquid crystal as a guest host, a light blocking effect can be imparted, and it becomes possible to use it as a light shutter of a transmissive liquid crystal display device.

Next, a liquid crystal display device using the polymer dispersed liquid crystal 24 will be explained with reference to FIG. Note that the same parts as in the conventional example described earlier based on FIGS. 4 and 5 are given the same reference numerals, and redundant explanation will be omitted. As shown in Figure 1,
The liquid crystal display device of this embodiment has a structure in which a polymer dispersed liquid crystal 24 is sandwiched between a lower glass substrate 10 and an upper glass substrate 17.
, a pixel electrode 12 and a sintered varistor element 13 as an active matrix element are provided, and an upper glass substrate 17 has an upper insulating film 18 made of polyimide, a transparent counter electrode 15, and red, green, and blue color filters. 16R
・Insulating layer 26 made of 16G/16B, SiO□, Cr
A thin metal film black matrix 25 is provided. Here, a black matrix 25 made of a metal thin film is provided in order to realize a clear color image display, and in order to prevent short circuit between this black matrix 25 and the counter electrode 15, a black matrix 25 provided on the upper glass substrate 17 is provided. Color filters 16R, 16G, and 16B are provided on the matrix 25 via an insulating layer 26, a counter electrode 15 is provided on top of the color filters 16R, and an upper insulating layer 18 is provided on top of the counter electrode 15 to prevent short circuit with the varistor element 13. It is. The liquid crystal display device having the above structure is manufactured through the following steps. First, an ITO film (indium oxide-tin oxide film) is deposited on the lower glass substrate 10 to a thickness of 11
A resist pattern is formed thereon by a photo process, and row electrodes 11 and pixel electrodes 12 are formed using an etching solution of ferric oxide:hydrochloric acid (1:3). Furthermore, after sintering the raw material Zn0 powder at 1200°C for 1 hour, it was ground in a ball mill and air classified to give a powder of 5μ1.
A ZnO single crystal particle powder of 1 to 10 μ- was obtained, and CO□
0.5 mol% of 03 and 0.5 mol% of MnCo3 were added and fired again at 1200°C for 1 hour to obtain varistor powder having varistor properties, and 25% by weight of glass flint and Ethyl cellulose (viscosity 50c
PS) was added to form a paste using calpitol as a solvent, and this paste was printed in the pattern of the sintered body element on the lower glass substrate 10 by silk screen printing,
This is fired at 480°C for 30 minutes to form a sintered varistor element 13. At this time, the sintered varistor element 13
is printed to a predetermined thickness, usually in the range of 10 to 20 μm, because it also serves as a gap spacer when bonding the lower glass substrate 10 and the upper glass substrate 17 together.

Next, a few percent of glass beads are placed around the upper glass substrate on which the upper insulating layer 18, the transparent counter electrode 15 made of ITO film, the color filters 16R, 16G, 16B, the insulating layer 26, and the blank matrix 25 are provided. Print the mixed adhesive epoxy resin by silk screen printing, align and bond with the lower glass substrate 10,
Apply pressure and heat to bond. Next, this panel is filled with a polymer-dispersed liquid crystal precursor through an inlet provided in a part of the adhesive section. Specifically, the precursors of this polymer-dispersed liquid crystal include 33 parts by weight of MMA (methyl methacrylate), 2 parts by weight of a photopolymerization initiator (Darocur-935 manufactured by Merck & Co., Ltd.), and a guest-hosted nematic liquid crystal (Merck & Co., Ltd.). Company-made E
7) in a proportion of 65 parts by weight. Also,
The dichroic dye added to make the nematic liquid crystal a guest host was a black dye, and specifically, 4% by weight of LCD471 manufactured by Nippon Kawara was added to the nematic liquid crystal. Finally, ultraviolet rays are irradiated from the lower glass substrate side of the liquid crystal baffle filled with this polymer dispersed liquid crystal precursor to cause a photopolymerization reaction, forming a three-dimensional network structure and completing the liquid crystal display device. did.

[Effect] According to the liquid crystal display device of the present invention, a guest host liquid crystal containing a dichroic dye is used as the liquid crystal, and the liquid crystal is dispersed in a polymer having a three-dimensional network structure, thereby improving the viewing angle. In addition, the screen becomes brighter without the need for a polarizing plate for image display, and high-quality image display can be realized even on a larger screen.

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional view of a liquid crystal display device according to an embodiment of the present invention, FIGS. An explanatory diagram of the operation of a hosted polymer-dispersed liquid crystal, FIG. 4 is a plan view of a conventional liquid crystal display device, and FIG. 5 is a cross-sectional view taken along line AA' in FIG. 4. It is. 11...Row electrode 12...Pixel electrode 13...Sintered varistor element 15...
・Counter electrode, 16R, 16G, 16B... Color filter I
8... Upper insulating layer 19... Polarizing plate 24... Polymer dispersed liquid crystal 24a... Liquid crystal 24b... Three-dimensional network structure Body 24c...Dichroic dye 25...Blank matrix 26...Insulating layer patent Applicant Toppan Printing Co., Ltd. Representative Kazuo Suzuki +6R 6G 6B Figure Figure Figure figure

Claims (2)

[Claims] (1) In a liquid crystal display device in which a liquid crystal is provided between a lower transparent substrate and an upper transparent substrate using a varistor element mainly composed of zinc oxide as an active matrix element, and is driven via the active matrix element, A liquid crystal display device characterized in that the liquid crystal is a guest host liquid crystal containing a dichroic dye, and the liquid crystal is dispersed in a polymer having a three-dimensional network structure. (2) Claim (1) characterized in that the upper transparent substrate is provided with a black matrix made of a metal thin film, an insulating layer and a color filter are provided on the black matrix, and a counter electrode is further provided on the black matrix. The liquid crystal display device described.