JPH04116826U - liquid crystal display element - Google Patents

Abstract

(57) [Summary] [Purpose] To eliminate damage to alignment films caused by spacers in liquid crystal display elements. [Structure] Electrode substrates 1 and 2 are fixed with a sealing material 5, and a liquid crystal 6 is sealed therein. The spacer for controlling the cell interval is a mixture of the first resin spheres 3 having a small diameter and the resin spheres 4 having a slightly larger diameter. When the small-diameter spacer is formed of a resin sphere in this way, even if the liquid crystal display element becomes hot and moves freely inside the liquid crystal 6, it will not damage the alignment film 7 like conventional spacers made of glass fiber. do not have.

Description

[Detailed explanation of the idea]

0001

[Industrial application field]

The present invention relates to liquid crystal display elements, particularly spacer materials for controlling cell spacing. It is.

0002

[Conventional technology]

Conventionally, cell spacing control in liquid crystal display elements has been described, for example, in (1) Japanese Patent Application Laid-Open No. 63-65. No. 27, (2) JP-A No. 62-85223 is known. There is. FIG. 8 is a cross-sectional view of the conventional liquid crystal display element described in the above-mentioned document (1) at room temperature. FIG. 9 is a cross-sectional view at high temperature.

0003 As shown in FIG. 8, in a conventional liquid crystal display element, two electrode substrates 11 and 12 are used. is sandwiched between the sealing material 15 and the liquid crystal 16 is sealed between the electrode substrates 11 and 12. There is. The larger diameter spacer is a resin ball 14, and the smaller diameter spacer is a glass fiber 1. It is characterized by the fact that it is 3. At room temperature, the resin sphere 14 is elastic up to the diameter of the glass fiber 13. The electrode substrates 11 and 12 are sealed by applying pressure until they are deformed and shrunk. As a result, the liquid crystal 16 causes volumetric contraction, and the two electrode substrates 1 are separated by the small diameter glass fiber 13. 1 and 12 are supported. Furthermore, at high temperatures as shown in FIG. 9, the liquid crystal 16 undergoes volumetric expansion. As a result, the large-diameter resin sphere 14 supports the electrode substrates 11 and 12 without elastic deformation. , On the other hand, the small diameter glass fiber 13 moves freely in the liquid crystal. .

0004 In this way, the cell spacing can be controlled using either large or small diameter spacers. there was. Next, FIG. 10 is a cross-sectional view of the conventional liquid crystal display element described in the above-mentioned document (2). Ru. As shown in the figure, this liquid crystal display element has resin spheres 14 dispersed in the display area. In addition, the resin spheres 20 are also mixed into the sealing material 15. In addition, In the figure, 17 is an alignment film, 18 is a transparent electrode, and 19 is a base material of an electrode substrate.

[0005] In this liquid crystal display element, the resin spheres 20 in the sealing material 15 are connected to two electrode substrates. When bonding 11 and 12 together, the amount of elastic deformation of the resin ball 20 is controlled by the pressure applied. control and obtain more accurate cell spacing, while the resin spheres 1 dispersed in the display area 4 causes damage to the alignment film 17 due to elastic deformation when pressed from the outside. It was designed to prevent this from happening.

[0006]

[Problem that the idea aims to solve]

However, in the conventional liquid crystal display element described in the above document (1), Glass fibers move freely in the liquid crystal at high temperatures, damaging the alignment film and causing display problems. There was a problem that quality was compromised. Furthermore, in the conventional liquid crystal display element described in the above document (2), two electrodes are used. Cell spacing control in the sealant part when bonding electrode substrates is affected by the pressure applied at that time. Because it is easily subject to fluctuations, reproducibility is poor, and uneven pressure force can cause uneven cell spacing. There was a problem with that. In the display section, the resin balls in the sealing material Since the pressure is applied taking into account the amount of elastic deformation, the resin spheres dispersed in the display area are not necessarily There was a problem in that the cell spacing was not always controlled to a desired value.

[0007] This invention solves the above conventional problems and eliminates damage to the alignment film and reduces display quality. The purpose of the present invention is to provide an excellent liquid crystal display element that does not warp. In addition, this invention solves the above conventional problems and allows for more accurate cell spacing control. The purpose of the present invention is to provide a liquid crystal display element that can be used.

[0008]

[Means to solve the problem]

In order to solve the above problems, the present invention provides two electrode substrates and a separate electrode between the electrode substrates. The scattered spacer material, the liquid crystal sealed between the electrode substrates, and the seal that seals the electrode substrates. In a liquid crystal display element comprising a first resin sphere with a small diameter and a first resin sphere with a large diameter, the spacer material is The diameter of the second resin sphere was mixed.

[0009] In addition, in order to solve the above problems, the present invention includes two electrode substrates and an electrode substrate. The spacer material dispersed in between, the liquid crystal sealed between the electrode substrates, and the electrode substrates are sealed. In a liquid crystal display element equipped with a sealing material, a spacer material dispersed between electrode substrates is used. is a mixture of a first resin ball with a small diameter and a second resin ball with a large diameter, and then a seam. A spacer material made of glass fiber was mixed into the material.

0010

[Effect]

According to the present invention, since the liquid crystal display element is configured as described above, the liquid crystal display element is configured as described above. The crystal undergoes volumetric contraction, and as a result, the large-diameter second resin sphere undergoes elastic deformation and becomes smaller-diameter. The diameter of the first resin sphere becomes the cell spacing. At high temperatures, liquid crystals undergo volumetric expansion. As a result, the large-diameter second resin ball hardly undergoes elastic deformation, and the second resin ball The diameter of is the cell spacing. At this time, the small diameter first resin sphere becomes smaller than the cell spacing. Because it is a resin sphere, it moves freely within the liquid crystal, but because it is a resin sphere, it does not damage the alignment film. .

[0011] Further, according to the present invention, since the liquid crystal display element is configured as described above, the above-mentioned effects can be achieved. In addition, the cell spacing in the sealant part should be set to ensure sufficient pressure when bonding the two electrode substrates together. By taking minute steps, the glass fiber diameter can be accurately pressed and controlled. and, At this time, the cell spacing on the display section is determined by the pressure applied to the mixing ratio of large and small diameter resin spheres. It is controlled to have a corresponding desired cell spacing.

0012

【Example】

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. (First example) FIG. 1 is a sectional view of a liquid crystal display device in a low temperature state according to a first embodiment of the present invention. In the liquid crystal display element according to this embodiment, the first electrode substrate 1 and the second electrode substrate 2 are made of a sealing material. 5, and a liquid crystal 6 is sealed between these two substrates. So The spacer for controlling the cell spacing consists of the small-diameter first resin sphere 3 and a slightly smaller diameter spacer. (about 0.2 to 0.3 μm) Two types of spacers for the large diameter second resin sphere 4 It consists of As shown in this figure, the liquid crystal 6 undergoes volumetric contraction in low temperature conditions. As a result, the second resin ball 4 with a large diameter undergoes elastic deformation, and the diameter of the first resin ball 3 with a small diameter decreases. This is the cell spacing. The resin sphere is a crosslinked copolymer whose main component is divinylbenzene. fine particles were used.

[0013] Next, FIG. 2 is a cross-sectional view of the liquid crystal display element according to the first embodiment of the present invention in a high temperature state. Ru. As shown in this figure, the liquid crystal 6 undergoes volumetric expansion under high temperature conditions, and as a result, The large-diameter second resin ball 4 hardly causes elastic deformation, and the diameter of the second resin ball 4 is small. This will be the interval. At this time, the small diameter first resin sphere 3 is smaller than the cell spacing, so Although it moves freely within the liquid crystal 6, the alignment film 7 is not damaged. This is because spacer 3, which has a small diameter, is made of glass fiber as used in the conventional example. This is because it is not a resin ball.

[0014] (Second example) FIG. 3 is a sectional view of a liquid crystal display device showing a second embodiment of the present invention. In the liquid crystal display element according to this embodiment, two electrode substrates 1 and 2 having an alignment film 7 are The liquid crystal 6 is sealed between the two electrode substrates 1 and 2. It is. Here, the spacer in the sealing material 5 is glass fiber 8, and The spacers are a mixture of small-diameter first resin spheres 3 and large-diameter second resin spheres 4. It is something. By configuring the spacer in this way, the sealing material 5 can be separated. The gap between the two electrode substrates 1 and 2 can be adjusted by applying sufficient pressure when bonding the two electrode substrates 1 and 2 together. It is possible to accurately press and control down to the fiber diameter, while the display part is Mixing ratio of resin spheres that cause elastic deformation of large and small diameters to have the desired cell spacing All you need to do is set the .

[0015] Control of cell spacing in this embodiment will be explained below. First, FIG. 4 is a characteristic diagram showing the change in cell spacing due to elastic deformation of the resin sphere when two electrode substrates are pressurized. From the figure, it can be seen that when the pressing force exceeds approximately 160 g/cm ² , the cell spacing becomes narrower as the pressing force increases. As an example, the cells with diameters of 5.25 μm and 5 μm are shown, but it can be understood that the cell spacing changes slightly due to a slight difference in the pressing force, and that the unevenness in the pressing force directly causes unevenness in the cell spacing. Therefore, it is clear that the cell spacing reproducibility strongly depends on the pressing force and is unstable.

Next, FIG. 5 is a characteristic diagram showing changes in cell spacing with respect to pressing force when resin spheres having a diameter of 5.25 μm and resin spheres having a diameter of 5 μm are mixed at a particle number ratio of 1:1. Since the total number of spacer particles is kept constant, the dispersion density for the 5.25 μm diameter resin spheres is small. As shown in the figure, the cell spacing begins to decrease more quickly with pressure than in the case of Fig. 4, but when the pressure reaches about 250 g/cm ² , the 5 μm diameter resin sphere becomes a stopper, so the cell spacing is approximately 5 μm. An area where there is no change is created. Therefore, for example, if two electrode substrates are bonded together with a pressure of 250 g/cm ² , it can be seen that a cell spacing of 5.05 μm can be achieved without being influenced by the pressure. In other words, there is a margin for the cell spacing relative to the pressing force.

[0017] By doing this, delicate cell spacing can be adjusted without changing the total number of spacer particles. This can be achieved with high precision and good reproducibility. This means that the resin sphere diameter has a diameter distribution. This is caused by variations in the diameter of the resin sphere, and There is no strong constraint that the particle size distribution must be kept below a certain level as in the past. In fact, the particle size distribution is used in reverse. Also, set the pressure force to a certain value. If there is a process request for cell spacing, fine-grained cell spacing control is available. Simply set the mixing ratio of large and small diameter resin spheres without changing the dispersion density of the resin spheres. It is easy because it can be done. Furthermore, the desired cell spacing is adjusted to an accuracy of 0.01 μm. This can be achieved in degrees.

Next, FIG. 6 is a characteristic diagram showing the change in cell spacing with respect to the pressing force when the mixing ratio of resin spheres with a diameter of 5.25 μm and resin spheres with a diameter of 5 μm was set to 1:3 in terms of particle number ratio. From this figure, it can be seen that the cell spacing begins to decrease more quickly than in the case of FIG. 4 with respect to pressurization, and that the reproducibility of the 5.05 μm diameter at 250 g/cm ² becomes even better. In addition, the change in cell spacing with respect to the pressing force is more dominated by the diameter distribution of the small-diameter 5 μm resin spheres, so it can be seen that it is effective in finely controlling the cell thickness closer to 5 μm than 5.25 μm. It can also be seen that if a cell thickness close to 5.25 μm is desired, the mixing ratio should be increased to 5.25 μm.

Next, FIG. 7 is a characteristic diagram showing the change in cell spacing with respect to the ratio of the number of particles of 5.25 μm and 5 μm when the pressing force is 200 g/cm ² . The figure shows that by controlling the mixing ratio of resin spheres with a diameter of 5.25 μm and resin spheres with a diameter of 5 μm, the cell spacing can be realized with fine precision. In this way, by controlling only the mixing ratio of large-diameter resin spheres and small-diameter resin spheres, it is possible to realize cell spacing with fine precision, and also to have a margin for pressurizing force, with good reproducibility. A liquid crystal display element having a uniform desired cell spacing can be obtained.

[0020] Note that the present invention is not limited to the above embodiments, but based on the spirit of the present invention. Various modifications are possible and are not excluded from the scope of the invention.

[0021]

[Effect of the idea]

As explained in detail above, according to the present invention, even small diameter spacers can be used as resin balls. Therefore, the alignment film will not be damaged even at high temperatures. Therefore, display quality An excellent liquid crystal display element without any damage can be obtained. Furthermore, according to the present invention, the spacer mixed in the sealing material is made of glass fiber. , since the spacers dispersed in the display area are a mixture of large and small diameter resin spheres, By pressing and controlling the cell spacing of the sealing material to almost the diameter of the glass fiber. , stable and reproducible cell spacing without uneven cell spacing due to uneven pressure, etc. can be controlled. Furthermore, by setting the mixing ratio of large and small diameter resin spheres, The cell spacing on the display section can be controlled to the desired spacing, and the cell spacing can be controlled to the desired spacing. The spacing margin will be better. Therefore, the liquid crystal table with uniform desired cell spacing A display element can be obtained.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view of a liquid crystal display device in a low temperature state according to a first embodiment of the present invention.

FIG. 2 is a cross-sectional view of a liquid crystal display device in a high temperature state according to a first embodiment of the present invention.

FIG. 3 is a cross-sectional view of a liquid crystal display device showing a second embodiment of the present invention.

FIG. 4 is a characteristic diagram showing the change in cell spacing with respect to the pressure applied to the resin sphere.

FIG. 5 is a characteristic diagram showing changes in cell spacing with respect to pressing force when resin spheres with a diameter of 5.25 μm and a resin sphere with a diameter of 5 μm are mixed at a particle number ratio of 1:1.

FIG. 6 is a characteristic diagram showing the change in cell spacing with respect to pressing force when resin spheres with a diameter of 5.25 μm and a resin sphere with a diameter of 5 μm are mixed at a particle number ratio of 1:3.

FIG. 7: 5. when the pressing force is 200 g/cm ² .
It is a characteristic diagram showing the change in cell spacing with respect to the ratio of the number of particles of 25 μm and 5 μm.

FIG. 8 is a cross-sectional view of a conventional liquid crystal display element in a low temperature state.

FIG. 9 is a cross-sectional view of a conventional liquid crystal display element in a high temperature state.

FIG. 10 is a cross-sectional view of another conventional liquid crystal display element.

[Explanation of symbols]

1 First electrode substrate 2 Second electrode substrate 3 First resin ball 4 Second resin ball 5 Sealing material 6 LCD 7 Alignment film 8 Glass fiber

Claims (4)

[Scope of utility model registration request] 1. Two electrode substrates, a spacer material dispersed between the electrode substrates, and a liquid crystal sealed between the electrode substrates,
A liquid crystal display element comprising a sealing material for sealing the electrode substrate, wherein the spacer material is a mixture of small-diameter first resin spheres and large-diameter second resin spheres. element. 2. The liquid crystal display element according to claim 1, wherein the sealing material contains a spacer material made of glass fiber. 3. The liquid crystal according to claim 2, wherein the cell spacing in the sealing material region is made approximately equal to the diameter of the spacer material mixed in the sealing material by applying pressure when the two electrode substrates are bonded together. display element. 4. The liquid crystal display element according to claim 1, wherein the cell spacing in the display area is controlled to a desired value by adjusting the mixing ratio of the first resin spheres and the second resin spheres.