JPH0895009A - Manufacture of polymer dispersion liquid crystal display element - Google Patents

Abstract

PURPOSE: To provide the manufacturing method of a polymer dispersion liquid crystal display element to form a composite film of good light scattering prop erty without deterioration of dyestuff and liquid crystal. CONSTITUTION: Mixed solution A of polymer material which is polymerized by ultraviolet ray and liquid crystal to which two-color dyestuff is added is filled in between a substrate 1 on which picture element, electrodes 3 and TFTs (active elements) 4 are formed and a substrate 2 on which counter electrodes 10 are formed, so that the ultraviolet ray can be radiated to the layer of the mixed solution A along its thickness while applying voltage to the layer of the mixed solution A along its thickness in the way of applying a more intensive electric field, than an electric field where the average dielectric constant of the liquid crystal is obtained, to the liquid crystal to perform phase dissociation between the liquid crystal and high polymer in the polymer material through photopolymerization and form a composite film.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for manufacturing a polymer dispersed liquid crystal display device.

[0002]

2. Description of the Related Art Recently, as a liquid crystal display element, a polymer dispersion type liquid crystal display element has been attracting attention because it can obtain a very bright display as compared with a commonly used twisted nematic type liquid crystal display element.

This polymer dispersion type liquid crystal display element has a liquid crystal / polymer composite film interposed between opposing electrodes, and a general polymer dispersion type liquid crystal display element is provided with a transparent electrode. A pair of transparent substrates are joined via a frame-shaped sealing material, and the composite film is provided in a region surrounded by the sealing material between the two substrates.

In the above composite film, liquid crystal and polymer are dispersed with each other, and the liquid crystal is confined in each gap of the polymer layer having a cross section like a sponge to form a plurality of liquid crystal domains. It has a structured structure. A nematic liquid crystal having a positive dielectric anisotropy is generally used as the liquid crystal of the composite film, and a dichroic dye is added to the liquid crystal.

This polymer-dispersed liquid crystal display device displays by utilizing the scattering, absorption and transmission of light in the composite film, and the liquid crystal molecules and dye molecules of the liquid crystal domain in the composite film are Since the light is directed in a random direction when no electric field is applied, in this non-electric field state, the light incident on the liquid crystal display element is not allowed to pass through the composite film, and thus at the interface between the polymer layer and the liquid crystal domain. Is scattered by the light refraction and the birefringence effect of liquid crystal molecules, and most of the scattered light is absorbed by the dye molecules, and the display becomes almost black and dark.

Further, when a voltage is applied between the electrodes of both substrates, the liquid crystal molecules of the liquid crystal domains in the composite film are oriented so as to stand up with respect to the substrate surface due to the electric field, and the dye molecules are similarly oriented accordingly. Therefore, the light scattering and absorption in the composite film are reduced, and the display becomes bright.

Therefore, the polymer-dispersed liquid crystal display device does not require a polarizing plate, which is indispensable for a twisted nematic liquid crystal display device, and therefore there is no light amount loss due to light absorption by the polarizing plate. A bright display is obtained.

The polymer dispersion type liquid crystal display device is
Generally, a reflector is arranged on the back surface of the reflector and used as a reflective element. By the way, in the above-mentioned polymer dispersion type liquid crystal display device, conventionally, after a pair of substrates on which electrodes are formed are bonded via a sealing material, a polymer material and a dichroic dye which are polymerized by ultraviolet rays are interposed between the two substrates. The mixed solution with the liquid crystal added with is injected and filled by a vacuum injection method, and the layer of this mixed solution is irradiated with ultraviolet rays from the outer surface side of one of the substrates, whereby the liquid crystal and the polymer by photopolymerization of the polymer material are added. It is manufactured by a method of forming a composite membrane by performing the phase separation of. The method of forming this composite film is called a photopolymerization phase separation method.

[0009]

However, the above-mentioned conventional method for manufacturing a polymer-dispersed liquid crystal display device has a problem that a composite film having a good light-scattering property cannot be obtained. This is because the molecules of the liquid crystal and the dichroic dye in the mixed solution are oriented in random directions, and when the composite film is formed by the photopolymerization phase separation method described above, the ultraviolet rays irradiated on the layer of the mixed solution are mixed. This is because it is absorbed by the molecules of the dichroic dye added to the liquid crystal in the solution, and the ultraviolet light applied to the mixed solution is absorbed by the dye molecules as it passes through the mixed solution, resulting in a decrease in its intensity. Therefore, the polymerization reaction of the polymer material does not proceed, and therefore the size of the liquid crystal domain formed by the phase separation between the liquid crystal and the polymer becomes large, and the formed composite film has a low light scattering property. It becomes a film.

By increasing the intensity of the ultraviolet rays applied to the mixed solution, the polymerization reaction of the polymer material can be promoted to form a composite film having a small liquid crystal domain size and good light scattering properties. When the intensity of ultraviolet rays is increased in this way, the amount of ultraviolet rays absorbed by the dye molecules increases, and the dye deteriorates, and the liquid crystal also deteriorates due to the absorption of ultraviolet rays.

The present invention provides a method for producing a polymer-dispersed liquid crystal display device comprising a composite film in which a liquid crystal containing a dichroic dye and a polymer are dispersed between opposing electrodes. It is an object of the present invention to provide a manufacturing method capable of forming a composite film having a good light scattering property without deteriorating a dye and a liquid crystal.

[0012]

Means for Solving the Problems The method for producing a polymer dispersed liquid crystal display device according to the present invention is directed to the layer thickness of a mixed solution of a polymer material which undergoes a polymerization reaction by ultraviolet rays and a liquid crystal to which a dichroic dye is added. Direction is applied to the layer of the mixed solution with ultraviolet rays in the thickness direction thereof, and a liquid crystal produced by photopolymerization of the polymer material is applied. And the polymer is subjected to phase separation to form the composite film.

In the production method of the present invention, the photopolymerization of the polymer material is performed, for example, by interposing a layer of the mixed solution between the electrodes facing each other and allowing the liquid crystal in the mixed solution to have an average dielectric constant between the electrodes. This is performed by irradiating the layer of the mixed solution with ultraviolet rays from the thickness direction thereof while applying a voltage to which an electric field stronger than the electric field with which the rate is obtained is applied. in this case,
The voltage V _ext applied between the electrodes is

[0014]

[Equation 2] To satisfy the voltage.

When one of the opposing electrodes is the pixel electrode connected to the active element and the other electrode is the opposing electrode facing the pixel electrode, the voltage V _ext applied between these electrodes is applied. , A voltage lower than the breakdown voltage of the active element.

[0016]

In other words, the production method of the present invention is one in which the polymer material is photopolymerized while an electric field is applied to the layer of the mixed solution of the polymer material and the liquid crystal to which the dichroic dye is added. If, in the thickness direction of the layer of the mixed solution, an electric field stronger than the electric field at which the average dielectric constant of the liquid crystal is obtained is applied, liquid crystal molecules in the mixed solution rise in the thickness direction of the mixed solution layer. The dye molecules are oriented, and the dye molecules are also oriented accordingly.

The molecules of the dichroic dye have a high light absorption property in the direction of the long axis of the molecule and a small light absorption in the direction orthogonal to the long axis of the molecule. Therefore, the dye molecules are oriented as described above. By irradiating the layer of the mixed solution with ultraviolet rays in the thickness direction in this state, the amount of ultraviolet rays absorbed by the dye molecules can be reduced.

Therefore, according to the manufacturing method of the present invention, the polymer material in the mixed solution is irradiated with ultraviolet rays of sufficient intensity to accelerate the polymerization reaction, and the liquid crystal domain size is small and the light scattering property is good. It is possible to form a composite film, and since the amount of UV absorption of the dye molecules is small, the intensity of the UV light that irradiates the layer of the mixed solution does not need to be very strong. It is not deteriorated by absorption.

In the manufacturing method of the present invention, the photopolymerization of the polymer material is carried out, for example, by interposing a layer of the mixed solution between opposing electrodes, and making the average dielectric constant of the liquid crystal in the mixed solution between the electrodes. In the case where the layer of the mixed solution is irradiated with ultraviolet rays from the thickness direction in the state where a voltage applied with an electric field stronger than the electric field with which the rate is obtained is applied, the voltage V _ext applied between the electrodes is

[0020]

[Equation 3] Is satisfied, and by applying such a voltage between the electrodes, the liquid crystal molecules and the dye molecules in the mixed solution can be aligned in the above-described alignment state.

If one of the facing electrodes is a pixel electrode connected to the active element and the other electrode is a facing electrode facing the pixel electrode, the voltage V _{ext is set.}
Is a voltage lower than the withstand voltage V _{H of the} active element, that is,

[0022]

[Equation 4] The voltage V that is applied between the electrodes
_{If ext} is in this range, the active element will not be dielectrically broken down.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing a state where a mixed solution is irradiated with ultraviolet rays showing a method for producing a polymer dispersed liquid crystal display element, and FIG. 2 is a sectional view of the produced polymer dispersed liquid crystal display element.

First, the structure of the polymer dispersed liquid crystal display element manufactured will be described. The polymer dispersed liquid crystal display element shown in FIG. 2 is a thin film transistor (hereinafter referred to as TFT).
Of a pair of substrates 1 and 2 facing each other, a plurality of pixel electrodes 3 are provided on the inner surface of the back substrate 1 (lower substrate in the figure). TFTs 4 corresponding to the respective pixel electrodes 3 are arranged in a matrix in the row direction and the column direction.

The backside substrate 1 is, for example, a glass substrate, and the TFT 4 includes the gate electrode 5 formed on the substrate 1, a gate insulating film 6 covering the gate electrode 5, and the gate insulating film 6. An i-type semiconductor film 7 made of a-Si (amorphous silicon) or the like formed above, and an n-type semiconductor film made of a-Si or the like doped with impurities on the i-type semiconductor film 7 (not shown) It is composed of a source electrode 8 and a drain electrode 9 formed via

The gate electrode 5 of the TFT 4 is integrally formed with a gate line (not shown) wired on the substrate 1, and the drain electrode 9 is connected to a data line (not shown). The data lines are wired on an interlayer insulating film (not shown) formed on the gate insulating film 6 so as to correspond to the data line wiring region,
The drain electrode 9 is connected through a contact hole formed in the interlayer insulating film.

Further, the gate insulating film 6 of the TFT 4 is used.
Is provided over almost the entire surface of the substrate 1, and the terminal portion of the gate line is exposed by providing an opening in the gate insulating film 6.

The pixel electrode 3 is formed on the gate insulating film 6 and is connected to the source electrode 8 of the corresponding TFT 4 at the edge thereof. This pixel electrode also serves as a light reflecting film, and is formed of a metal film such as Al (aluminum) or Al alloy.

On the other hand, the front side substrate (upper side substrate in the figure) 2 is a transparent substrate made of glass or a resin film, and all the pixel electrodes of the back side substrate 1 are provided on the inner surface of the front side substrate 2. A transparent counter electrode 10 is provided so as to face the counter electrode 3.

The pair of substrates 1 and 2 are bonded to each other with their electrode forming surfaces facing each other through a frame-shaped sealing material (not shown).
A liquid crystal / polymer composite film 11 is provided in a region surrounded by the sealing material between the two.

The composite film 11 is composed of a dichroic dye-added liquid crystal and a polymer dispersed in each other, and the liquid crystal is confined in each gap of the polymer layer 12 having a cross section like a sponge. As a result, a plurality of minute liquid crystal domains 13 are formed. In FIG. 2, a indicates a liquid crystal molecule and b indicates a dichroic dye molecule. The liquid crystal is a nematic liquid crystal having a positive dielectric anisotropy.

This polymer-dispersed liquid crystal display device is a device for displaying by utilizing external light such as natural light or indoor illumination light and utilizing the scattering, absorption and transmission of light in the composite film 11. Light incident on the display element from the front side thereof is scattered and absorbed by the composite film 11, or transmitted through the composite film 11 and reflected by the pixel electrode 3 which also serves as a reflective film on the inner surface of the rear substrate 1. Emit to the front side.

That is, the liquid crystal molecules a and the dye molecules b of the liquid crystal domain 13 of the composite film 11 are oriented in random directions when no electric field is applied. When the light incident from the surface side passes through the composite film 11, it is scattered by the photorefraction at the interface between the polymer layer 12 and the liquid crystal domain 13 and the birefringence effect of the liquid crystal molecules a. Most of the light is absorbed by the dye molecule b, and the display becomes almost black and dark.

In this case, some light passes through the composite film 11 without being absorbed by the dye molecule b, and is reflected by the pixel electrode 3 on the inner surface of the rear substrate 1, but the reflected light passes through the composite film 11 again. Since the light is scattered and absorbed in the process, the amount of light emitted to the surface side is extremely small, and therefore the display in the non-electric field state becomes a dark display closer to black.

When a voltage is applied between the electrodes 3 and 10 of the substrates 1 and 2, an electric field having a strength corresponding to the voltage is applied to the composite film 11, and the electric field causes the liquid crystal domain 13 in the composite film 11. The liquid crystal molecules a are oriented so as to stand upright with respect to the surfaces of the substrates 1 and 2, and the dye molecules b are also oriented accordingly.

Therefore, when an electric field is applied, the scattering and absorption of light in the composite film 11 is reduced, and the incident light is absorbed by the composite film 11.
Is reflected by the pixel electrode 3 on the inner surface of the back-side substrate 1, and the reflected light again passes through the composite film 11 and is emitted to the front surface side, and the display becomes a bright state.

In this case, liquid crystal molecule a and dye molecule b
Is vertically aligned at a rising angle according to the strength of the electric field applied to the composite film 11, and the composite film 1 is aligned according to the alignment state.
Since the degree of light scattering and absorption at 1 changes, the intensity of emitted light can be changed by controlling the voltage applied between the electrodes 3 and 10, and bright display with gradation can be obtained. .

In the active matrix type liquid crystal display device, a gate signal is sequentially supplied to each gate line, and a data signal having a potential corresponding to image data is supplied to each data line at the timing to drive the display. When a gate signal is supplied to the selected gate line, the TFT 4 connected to the gate line is turned on, and the pixel electrode 3 connected to this TFT 4 is turned on.
A voltage corresponding to the potential of the gate signal from the gate line is applied between the pixel electrode 3 and the counter electrode 10, and the charge corresponding to the voltage is composed of the pixel electrode 3, the counter electrode 10 and the composite film 11 therebetween. Is charged to the capacity.

When the selection period elapses and the supply of the gate signal to the gate line is cut off, the TFT 4 is turned off and the charge is held in the capacitance, and the voltage is kept in the non-selection period during the composite film. 11 is applied.

Next, a method for manufacturing the above polymer dispersion type liquid crystal display device will be described with reference to FIG. First, the pixel electrode 3
The back side substrate 1 on which the TFTs 4 and the like are formed and the front side substrate 2 on which the counter electrode 10 is formed are bonded to each other with their electrode forming surfaces facing each other through a frame-shaped sealing material (not shown).

Next, in the region surrounded by the frame-shaped sealing material between the two substrates 1 and 2, from the injection port formed by removing a part of the sealing material, a polymer polymerized by ultraviolet rays is introduced. A mixed solution A of the material and the liquid crystal added with the dichroic dye is injected and filled by the vacuum injection method. When the mixed solution A is filled between the substrates 1 and 2, the liquid crystal molecules a and the dye molecules b in the mixed solution A are oriented in random directions.

Next, all the data lines of the back side substrate 1 and the counter electrode 10 of the front side substrate 2 are supplied with power (for example, with a frequency of An AC power source of about 10 Hz) 20 is connected, and in that state, gate signals are simultaneously supplied to all gate lines of the backside substrate 1.

As described above, when the gate signals are supplied to all the gate lines, all the TFTs 4 are turned on, and the power source 20 is provided between all the pixel electrodes 3 and the counter electrodes 10.
Voltage is applied from.

The power source 20 is connected between the electrodes 3 and 10,
It is a power supply that applies a voltage having a value to which a stronger electric field is applied to the liquid crystal in the mixed solution A than the electric field at which the average dielectric constant is obtained. When a voltage having such a value is applied between the electrodes 3 and 10, the voltage causes Mixed solution A interposed between electrodes 3 and 10
The above-mentioned strong electric field is applied in the thickness direction of the layer of the mixed solution A
Most of the liquid crystal molecules a therein are oriented so as to rise in the thickness direction of the mixed solution layer as shown in FIG. 1, and accordingly, most of the dye molecules b are similarly oriented. The rising directions of the liquid crystal molecules a and the dye molecules b are random, but the rising angles with respect to the surfaces of the substrates 1 and 2 are almost the same.

Next, while the voltage application between the electrodes 3 and 10 is continued and the liquid crystal molecules a and the dye molecules b are maintained in the above-described alignment state, ultraviolet rays are applied to the layer of the mixed solution A from the thickness direction thereof. Irradiate. The ultraviolet irradiation is performed from the outer surface side of the transparent front surface side substrate 2.

When the mixed solution A is irradiated with ultraviolet rays in this way, the polymer material in the state of a monomer or an oligomer is radicalized by the dissolution of its double bond, and radicals of adjacent molecules are bound to each other. The reaction produces a polymer, and the polymerization of the polymer material causes the liquid crystal and the polymer to undergo phase separation, whereby the composite film 11 shown in FIG. 2 is formed.

The voltage applied between the electrodes 3 and 10 is
The photopolymerization phase separation between the liquid crystal and the polymer may be continued for a time (which is grasped in advance), and when the voltage application is stopped, the liquid crystal of the liquid crystal domain 13 in the formed composite film 11 is stopped. The molecules a and the dye molecules b are in a random alignment state in the non-electric field state.

In the above manufacturing method, the liquid crystal molecules a and the dye molecules b in the mixed solution A are oriented so as to rise in the thickness direction of the mixed solution layer A, and the mixed solution A is
Since the layer is irradiated with ultraviolet rays from the thickness direction, the amount of ultraviolet rays absorbed by the dye molecule b is small.

Therefore, according to this manufacturing method, the polymer material in the mixed solution A is supplied with ultraviolet rays of sufficient intensity to accelerate its polymerization reaction, and the size of the liquid crystal domain 13 is small and the light scattering property is good. Since the composite film 11 can be formed and the amount of UV absorption of the dye molecule B is small,
The intensity of the ultraviolet light with which the layer of the mixed solution A is irradiated does not have to be so strong that the dichroic dye and the liquid crystal are not deteriorated by the absorption of the ultraviolet light.

A voltage applied between the electrodes 3 and 10 in the above manufacturing method, that is, a voltage applied to the liquid crystal in the mixed solution A by applying an electric field stronger than the electric field for obtaining the average dielectric constant will be described. Voltage V _LC applied to liquid crystal in mixed solution A
, When the voltage applied between the electrodes 3, 10 and V _ext,
It is expressed by the following equation (1).

[0051]

[Equation 5]

By the way, the dielectric constant ε _LC of the liquid crystal changes according to the change of the alignment state of the liquid crystal molecules due to the application of the electric field.
This will be described with respect to a liquid crystal element in which liquid crystal molecules are homogeneously aligned. FIG. 3 shows a dielectric constant-voltage characteristic (ε-V characteristic) of the homogeneously aligned liquid crystal element, and the dielectric constant of the liquid crystal is equal to that of electrodes facing each other. It changes as shown in the figure according to the strength of the electric field due to the voltage applied between them.

On the other hand, the average permittivity of the liquid crystal is the permittivity when the liquid crystal is randomly oriented, and the orientation state of the liquid crystal when the permittivity is higher than this average permittivity indicates that the molecular long axis is on the substrate surface. Liquid crystal molecules standing upright, that is, liquid crystal molecules oriented so as to rise in the thickness direction of the liquid crystal layer,
This is a state in which there are more liquid crystal molecules in other alignment states.

In the above-mentioned method for producing a polymer dispersion type liquid crystal display device, since the dye molecules b are oriented in the same manner as the liquid crystal molecules a, the liquid crystal molecules oriented so as to rise in the thickness direction of the mixed solution A. Is a state in which there are many dye molecules b oriented so as to rise in the thickness direction of the mixed solution A.

The molecule b of the dichroic dye has light absorption characteristics such that the absorption coefficient in the direction of the long axis of the molecule is large and the absorption coefficient in the direction orthogonal to the long axis of the molecule is small. By irradiating the layer of the mixed solution A with ultraviolet rays from the thickness direction in a state where there are many dye molecules b oriented so as to stand upright, the amount of ultraviolet rays absorbed by the dye molecules b can be reduced. it can.

Therefore, the liquid crystal in the mixed solution A is
By irradiating with ultraviolet rays while applying an electric field to which an electric field stronger than the electric field from which the average dielectric constant is obtained, the absorption of ultraviolet rays by the dye molecules b can be reduced.

The voltage _{Vext at} which an electric field stronger than that for obtaining the average dielectric constant is applied to the liquid crystal in the mixed solution A is
It is a voltage that satisfies the following formula (2).
By applying _ext between the electrodes 3 and 10, the liquid crystal molecules a and the dye molecules b in the mixed solution A can be aligned in the alignment state as described above.

[0058]

[Equation 6]

In this case, the applied voltage V between the electrodes 3 and 10
_The higher the value of _ext , the liquid crystal molecule a and the dye molecule b
Is further orientated in the thickness direction of the mixed solution A,
Although it is possible to reduce the amount of ultraviolet rays absorbed by the dye molecule b, if the applied voltage V _ext between the electrodes 3 and 10 is too high, the source and drain electrodes 8 and 9 and the gate of the TFT 4 which is an active element are gated. A high voltage is applied between the electrode 5 and the other conductive film, and the TFT 4 is dielectrically broken down.

Therefore, in this embodiment, the voltage V _ext applied between the electrodes 3 and 10 is set to a voltage lower than the withstand voltage V _H of the TFT 4 to prevent the dielectric breakdown of the TFT 4. That is, in the manufacturing method of the above-described embodiment, the liquid crystal in which the dichroic dye is added between the pixel electrode 3 connected to the active element (TFT 4 in the embodiment) and the counter electrode 10 facing the pixel electrode 3. In manufacturing an active matrix type polymer dispersed liquid crystal display device in which a liquid crystal / polymer composite film 11 in which a polymer and a polymer are dispersed is interposed, a pixel electrode 3 connected to the active element (TFT 4) ,
A layer of a mixed solution A of a polymer material which undergoes a polymerization reaction by ultraviolet rays and a liquid crystal to which a dichroic dye is added is interposed between the pixel electrode 3 and a counter electrode 10 which faces the pixel electrode 3.
Between ten,

[0061]

[Equation 7] By applying a voltage V _ext having a value satisfying the above condition to the layer of the mixed solution A, the layer of the mixed solution A is irradiated with ultraviolet rays from the thickness direction of the layer so that the phase separation between the liquid crystal and the polymer by photopolymerization of the polymer material is performed. By doing so, the liquid crystal / polymer composite film 11 is formed.

That is, in this manufacturing method, the polymer material is photopolymerized while a voltage is applied to the layer of the mixed solution A of the polymer material and the liquid crystal to which the dichroic dye is added. When a voltage V _ext is applied between the electrodes 3 and 10, that is, in the thickness direction of the layer of the mixed solution A, an electric field stronger than that for obtaining the average dielectric constant of the liquid crystal is applied to the liquid crystal,
The liquid crystal molecules a in this mixed solution are oriented so as to rise in the thickness direction of the mixed solution layer A, and the dye molecules b are similarly oriented accordingly.

The molecule b of the dichroic dye has a light absorption characteristic in which the absorptance in the direction of the major axis of the molecule is large and the absorptance in the direction orthogonal to the major axis of the molecule is small. By irradiating the layer of the mixed solution A with ultraviolet rays from the thickness direction in the state of being orientated in the direction, the amount of ultraviolet rays absorbed by the dye molecule b can be reduced.

Therefore, according to the above manufacturing method, the polymer material in the mixed solution A is supplied with ultraviolet rays of sufficient intensity to accelerate its polymerization reaction, and the liquid crystal domain 13 is small in size and has a good light scattering property. Since the composite film 11 can be formed and the amount of UV absorption of the dye molecule b is small,
The intensity of the ultraviolet light with which the layer of the mixed solution A is irradiated does not have to be so strong that the dichroic dye and the liquid crystal are not deteriorated by the absorption of the ultraviolet light.

Moreover, in this manufacturing method, the electrodes 3,
The voltage V _ext applied between 10 is higher than the voltage at which the average dielectric constant of the liquid crystal is obtained, and the active element (TFT
Since the voltage is lower than the withstand voltage V _{H of} 4), there is no possibility of dielectric breakdown of the active element.

In the above embodiment, the electric field for vertically aligning the liquid crystal molecules 8a is applied by utilizing the display pixel electrode 3 and the counter electrode 10 formed on the inner surfaces of the pair of substrates 1 and 2, respectively. However, this electric field may be applied by providing external electrodes on the outer surfaces of both substrates 1 and 2.

Further, in the above-mentioned polymer dispersion type liquid crystal display element, the pixel electrode 3 on the inner surface of the rear substrate 1 is used as an electrode which also serves as a reflection film, but the pixel electrode 3 may be a transparent electrode. Well, in that case, the ultraviolet irradiation to the mixed solution A may be performed from the back side substrate 1 side or both substrates 1 and 2 side, and ultraviolet rays may be emitted from both the substrate 1 and 2 sides. When irradiated, the polymer material can be efficiently photopolymerized.

Further, in the above-mentioned embodiment, the mixed solution A is filled between the pair of substrates 1 and 2 which are bonded to each other through the frame-shaped sealing material, and the layer of the mixed solution A is irradiated with ultraviolet rays while an electric field is applied. The composite film 11 is formed by
1 is the mixed solution A on one substrate, for example, the back substrate 1 on which the pixel electrode 3 and the active element (TFT 4) are formed.
To a desired thickness, an external electrode is arranged on the upper surface side of the mixed solution layer, and the external electrode and the pixel electrode 3 on the rear surface side substrate 1 or the external electrode arranged on the outer surface of the rear surface side substrate 1. It may be formed by irradiating the layer of the mixed solution with ultraviolet rays from the thickness direction of the mixed solution in a state in which a voltage applied to the liquid crystal is stronger than the electric field for obtaining the average dielectric constant of the liquid crystal. In that case, after forming the composite film 11, the counter electrode 10 facing the pixel electrode 3 may be formed thereon.

The liquid crystal used for the composite film 11 may be a nematic liquid crystal added with a chiral agent such as cholesteric liquid crystal so as to have twist orientation, and a nematic liquid crystal having such twist orientation is used. By doing so, when the mixed solution A is irradiated with ultraviolet rays in a state in which an electric field is applied to form the composite film 11 and then in a non-electric field state,
The liquid crystal molecules a and the dye molecules b are in a better random alignment state, and the liquid crystal molecules a and the dye molecules b are randomly aligned when the electric field is applied to the liquid crystal display device when the display is driven. It is possible to return to the oriented state satisfactorily and with good operability.

The present invention is not limited to the active matrix type in which the TFT is an active element, but is not limited to the M type.
It can also be applied to the production of active matrix type polymer dispersed liquid crystal display elements using a two-terminal non-linear resistance element such as IM as active elements, and polymer dispersed type liquid crystal display elements of simple matrix type or segment display type. You can

[0071]

The method for producing a polymer-dispersed liquid crystal display device according to the present invention has an average dielectric constant of the liquid crystal in the thickness direction of the layer of the mixed solution of the polymer material and the liquid crystal to which the dichroic dye is added. By applying an electric field stronger than the electric field from which the liquid crystal is obtained, and irradiating the layer of the mixed solution with ultraviolet rays in the thickness direction in that state, phase separation between the liquid crystal and the polymer is performed by photopolymerization of the polymer material. Since the composite film is formed in this manner, it is possible to form the composite film having a good light scattering property without deteriorating the dye and the liquid crystal.

In the production method of the present invention, the photopolymerization of the polymer material is carried out, for example, by interposing a layer of the mixed solution between the electrodes facing each other and making the average dielectric constant of the liquid crystal in the mixed solution between the electrodes. In the case where the layer of the mixed solution is irradiated with ultraviolet rays from the thickness direction in the state where a voltage applied with an electric field stronger than the electric field with which the rate is obtained is applied, the voltage V _ext applied between the electrodes is

[0073]

[Equation 8] Is satisfied, and by applying such a voltage between the electrodes, the liquid crystal molecules and the dye molecules in the mixed solution can be aligned in the above-described alignment state.

When one of the opposing electrodes is the pixel electrode connected to the active element and the other electrode is the opposing electrode facing the pixel electrode, the voltage V _{ext is set.}
May be set to a voltage lower than the withstand voltage V _{H of the} active element. If the voltage V _ext applied between the electrodes is within this range, the active element will not be dielectrically broken down.

[Brief description of drawings]

FIG. 1 is an ultraviolet irradiation state diagram of a mixed solution showing a method for manufacturing a polymer dispersed liquid crystal display device according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of the manufactured polymer dispersion type liquid crystal display device.

FIG. 3 is a diagram showing dielectric constant-voltage characteristics of a homogeneous alignment liquid crystal element.

[Explanation of symbols]

 1, 2 ... Substrate 3 ... Pixel electrode 4 ... TFT (active element) 10 ... Counter electrode A ... Mixed solution a ... Liquid crystal molecule b ... Dye molecule

Claims (4)

[Claims] 1. A method for producing a polymer-dispersed liquid crystal display device, comprising a composite film in which a liquid crystal to which a dichroic dye is added and a polymer are dispersed between opposing electrodes, which comprises: By applying an electric field stronger than the electric field that gives the average dielectric constant of the liquid crystal in the thickness direction of the layer of the mixed solution of the polymer material that polymerizes by the reaction and the liquid crystal to which the dichroic dye is added, the mixture is mixed in that state. A polymer dispersion characterized in that the composite layer is formed by irradiating the layer of the solution with ultraviolet rays from the thickness direction to cause phase separation of the liquid crystal and the polymer by photopolymerization of the polymer material. Type liquid crystal display element manufacturing method. 2. A method for producing a polymer-dispersed liquid crystal display element, comprising a composite film in which a liquid crystal to which a dichroic dye is added and a polymer are dispersed between opposing electrodes, A layer of a mixed solution of a polymer material that undergoes a polymerization reaction by ultraviolet rays and liquid crystal to which a dichroic dye is added is interposed between electrodes, and the average dielectric constant of the liquid crystal in the mixed solution is obtained between the electrodes. By irradiating the layer of the mixed solution with ultraviolet rays from the thickness direction while applying a voltage applied with an electric field stronger than the electric field, phase separation between the liquid crystal and the polymer is performed by photopolymerization of the polymer material. A method of manufacturing a polymer dispersed liquid crystal display device, which comprises forming the composite film by using the above method. 3. The voltage V _ext applied between the electrodes is expressed by the following formula: The method for producing a polymer-dispersed liquid crystal display device according to claim 2, wherein the voltage satisfies the above condition. 4. One of the opposing electrodes is a pixel electrode connected to the active element, and the other electrode is an opposing electrode facing the pixel electrode, and a voltage V applied between these electrodes.
_The method for manufacturing a polymer-dispersed liquid crystal display device according to claim 3, wherein _ext is a voltage lower than the withstand voltage of the active device.