JP2002333624A - Liquid crystal display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid crystal display device which is excellent in visibility, by which high resolution display can be performed and wherein both reflection light and transmission light can be utilized for display. SOLUTION: In the liquid crystal display device provided with a liquid crystal display element 100 having a pair of substrates 4 and 5 respectively having alignment layers 2 and 3 formed on the surfaces thereof opposed to each other and a liquid crystal layer 1 interposed between the pair of substrates 4 and 5, an alignment mechanism for simultaneously incorporating at least two alignment states different from each other to optional and different areas utilized for display in the liquid crystal layer 1 are provided, a reflection film 8 is disposed in at least one area of the areas showing the alignment states different from each other in the liquid crystal layer 1 and the areas showing the alignment states different from each other are used for a reflection display part 9 for performing reflection display and a transmission display part 10 for performing transmission display. As the alignment mechanism, for example, alignment layers 2 and 3 alignment treated in the directions different in the reflection display part 9 and the transmission display part 10 and an insulation film 11 formed in the film thicknesses different in the reflection display part 9 and the transmission display part 10 are mentioned.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device used for information devices such as word processors and notebook computers, various video devices and game devices, portable VCRs, digital cameras and the like. In particular, the present invention relates to a liquid crystal display device used both outdoors and indoors, and a liquid crystal display device used in an environment where the lighting environment changes rapidly, such as an automobile, an aircraft, and a ship.

[0002]

2. Description of the Related Art Conventionally, a cathode ray tube (CRT) has been used as a self-luminous display device capable of electrically rewriting display contents.
de Ray Tube) and electroluminescence (EL; E)
Electro-Luminescence elements, plasma display panels (PDPs), and the like have been put to practical use.

However, the self-luminous display device has a problem that power consumption is large because the display light itself is emitted and used for display. Further, since the light emitting surface of the self-luminous display device itself is a display surface having a high reflectance, when the self-luminous display device is used,
In a situation where the ambient light in the use environment is stronger than the light emission luminance, for example, under direct sunlight, a so-called washout phenomenon in which display light cannot be observed is inevitable.

On the other hand, a liquid crystal display device has been put into practical use as a color display for displaying characters and images by adjusting the amount of light transmitted from a specific light source without emitting display light itself. The liquid crystal display (LCD;
Liquid Crystal Display) is a transmissive liquid crystal display,
It can be roughly classified into a reflection type liquid crystal display device.

[0005] Among them, a transmissive liquid crystal display device using a light source called a so-called background illumination (backlight) on the background, that is, the back of the liquid crystal cell, is particularly widely used at present as a color liquid crystal display device. . The transmissive liquid crystal display device has advantages such as thinness and light weight, and its use is expanding in various fields. On the other hand, a large amount of power is consumed to emit background illumination (backlight). However, relatively large power is required, although the power used to modulate the transmittance of the liquid crystal is small.

However, in such a transmission type liquid crystal display device (ie, transmission type color liquid crystal display device),
The washout phenomenon seen in the self-luminous display device is reduced. This is because the reflectance of the display surface of the color filter layer commonly used in the transmission type color liquid crystal display device is reduced by a technique for lowering the reflectance of the color filter layer using a black matrix.

However, even when a transmissive color liquid crystal display device is used, it is difficult to observe the display light when the ambient light is very strong and the display light is relatively weak.
Therefore, if the background illumination light is further increased to solve such a problem, a problem of consuming more power is caused.

[0008] In contrast to the light-emitting display device and the transmissive liquid crystal display device described above, the reflective liquid crystal display device performs display using ambient light, so that display light proportional to the amount of ambient light can be obtained. . For this reason, the reflection type liquid crystal display device has a principle advantage of not causing the above-described washout phenomenon, and can display the display more clearly in a very bright place exposed to direct sunlight. Further, since the reflective liquid crystal display device does not require background lighting (backlight) in its display, it has an advantage that power for emitting background lighting (backlight) can be reduced. ing. Therefore, the reflective liquid crystal display device is particularly suitable for outdoor use such as a portable information terminal device, a digital camera, and a portable video camera.

However, in these conventional reflection type liquid crystal display devices, since ambient light is used for display, the degree of display luminance greatly depends on the surrounding environment, and the display contents are confirmed in an environment with weak ambient light. There is a problem that it is not possible. In particular, when a color filter used to realize color display (color display) is used, the display is further darkened because the color filter absorbs light. Therefore, in such a case, the above problem becomes more remarkable.

Therefore, a lighting device called a front light has been developed as auxiliary lighting so that the reflection type liquid crystal display device can be used even in an environment where ambient light is weak. In a reflection type liquid crystal display device, a reflection plate is provided on a back surface of a liquid crystal layer, and therefore, background illumination (backlight) such as a transmission type liquid crystal display device cannot be used. For this reason,
The illumination device (front light) used in the reflection type liquid crystal display device illuminates the reflection type liquid crystal display device from the front, that is, from the display surface side.

On the other hand, as a liquid crystal display device which makes use of the advantages of the reflection type liquid crystal display device and which can be used in an environment where ambient illumination light is weak, a part of incident light is transmitted and the remaining incident light is transmitted. A liquid crystal display device using a so-called semi-transmissive reflective film that reflects light has been put to practical use. Such a liquid crystal display device using both transmitted light and reflected light is generally called a transflective liquid crystal display device.

For example, Japanese Patent Application Laid-Open No. Sho 59-218483 (corresponding to Japanese Patent Application No. 58-92885) discloses TN
A transflective liquid crystal display device that performs brightness modulation using a liquid crystal display method that modulates transmitted light intensity, such as a (twisted nematic) method or an STN (super twisted nematic) method, is disclosed. Also, Japanese Patent Application Laid-Open No. 7-31
No. 8929 discloses a transflective liquid crystal display device in which a reflective film disposed close to a liquid crystal layer has translucency. Japanese Patent Application Laid-Open No. 6-160878 discloses a transmission type liquid crystal display device using an in-plane switching method as a technique for realizing a wide viewing angle.

[0013]

However, the transflective liquid crystal display device disclosed in Japanese Patent Application Laid-Open No. Sho 59-218483 has a transflective reflective film disposed on the back surface of the liquid crystal cell as viewed from the viewer side. Therefore, it has the following problems (1) and (2).

[0014] That is, (1) it is difficult to set the brightness which affects the visibility of the display. In other words, when the brightness of the transflective liquid crystal display device is set in accordance with the brightness in the case of performing the reflective display, the brightness needs to be set high in preparation for use under conditions where ambient light is insufficient. is there. However, for example, if the transmittance of a polarizing plate used in the TN method is set high in order to increase the brightness, in a transmissive display, the contrast ratio defined by dividing the brightness of the bright display by the brightness of the dark display is insufficient. And deteriorate visibility. On the other hand, when the brightness is set in accordance with the brightness in the case of performing transmissive display, it is preferable to set the brightness so as to increase the contrast ratio. , And deteriorate visibility.

(2) In a reflective display, light passing through a liquid crystal layer sandwiched between substrates is reflected by a reflective film provided on the back surface of the liquid crystal cell to observe the display. (Double image) is observed, causing a decrease in resolution, and making high-resolution display difficult.

In the transflective liquid crystal display device described in Japanese Patent Application Laid-Open No. Hei 7-318929, since the reflective film itself has translucency, an optical device suitable for the reflective display unit and the transmissive display unit is used. There is a problem that design is impossible.

Further, the in-plane switching system disclosed in the above-mentioned Japanese Patent Application Laid-Open No. 6-160878 is used for a transmission type liquid crystal display device, but the liquid crystal alignment on the comb-shaped electrodes does not contribute to display. This is not because the electrode wiring is often made of a metal having no translucency, but because the change in liquid crystal alignment is insufficient for transmissive display.

In order to solve these problems, the present inventors attempted to apply a display method used for a reflective liquid crystal display capable of suppressing parallax to a transflective liquid crystal display device. Was. Specifically, (a) a GH (guest host) method in which a liquid crystal composition in which a dichroic dye (dichroic dye) is mixed in a liquid crystal layer is arranged, and (b) reflection using one polarizing plate. The use of two types of liquid crystal display systems (hereinafter, abbreviated as a single polarizing plate system) for semi-transmissive display has been earnestly studied.

When considering the use of a display method that does not cause parallax, as described in the two methods (a) and (b), a reflective film is arranged so as to be substantially in contact with the liquid crystal layer, and the reflected light is added to the reflected light. In order to allow transmitted light to be used for display, the reflection film was provided with a transmission opening.

As a result, the following problems were further clarified. First, (a) In the GH method, when the concentration of the dichroic dye mixed in the liquid crystal composition is adjusted so as to be suitable for reflective display, the contrast ratio is insufficient in the transmissive display portion, but the display ratio is insufficient. Can not get. On the other hand, when the concentration of the dichroic dye mixed in the liquid crystal composition is adjusted so as to be suitable for transmissive display, a good contrast ratio is obtained in the transmissive display portion, but the brightness is reduced in the reflective display portion, and a good contrast ratio is obtained. No reflective display can be obtained.

(B) When the single-polarizer type is used for transflective display, the liquid crystal orientation and the liquid crystal layer thickness which determine the optical characteristics are determined.
Alternatively, the setting of the voltage or the like applied to the liquid crystal driving them is set according to the reflective display unit, or
It is possible to perform transmission display by further adding a polarizing plate or the like to the back of the display surface (two-polarization plate system), and to set in accordance with the transmission display.

First, the display in the transmissive display unit when the liquid crystal layer thickness is set to a layer thickness suitable for reflective display will be described. When the liquid crystal layer suitable for the reflective display is set, the amount of change in the polarization state due to the change in the alignment due to an external field such as an electric field of the liquid crystal layer is incident through the liquid crystal layer from the front, that is, from the display surface side. The light is emitted to the display surface side again through the liquid crystal layer and reciprocates through the liquid crystal layer to obtain a sufficient contrast ratio. However, in this setting, in the transmissive display section, the amount of change in the polarization state of the light passing through the liquid crystal layer is insufficient. For this reason, in addition to the polarizing plate installed on the viewer side of the liquid crystal cell used for reflective display, that is, in addition to the polarizing plate installed on the display surface side, a polarizing plate used only for transmissive display is installed on the back of the liquid crystal cell as viewed from the viewer side. However, a sufficient display cannot be obtained in the transmissive display section. That is, when the alignment condition of the liquid crystal layer is set to the alignment condition of the liquid crystal layer (liquid crystal layer thickness, liquid crystal alignment, etc.) suitable for the reflective display, the transmissive display portion has insufficient lightness or sufficient lightness. However, the transmittance of dark display does not decrease, and a sufficient contrast ratio for display cannot be obtained.

More specifically, in the case of performing the reflective display, the light passing through the liquid crystal layer only once is approximately １ ／.
The alignment state of the liquid crystal in the liquid crystal layer is controlled by a voltage applied to the liquid crystal layer so that a wavelength phase difference is provided. Using a liquid crystal layer set so as to impart such a phase difference to light passing through the liquid crystal layer, only voltage modulation for giving a quarter-wave phase modulation to light passing through the liquid crystal layer is performed to perform transmissive display. Then, when the transmissive display unit sufficiently reduces the transmittance at the time of dark display, when the transmissive display unit is in the bright display, the light having about half the intensity is absorbed by the polarizing plate on the light emission side, and A bright display cannot be obtained. In addition, when an optical element such as a polarizing plate or a phase difference compensator is arranged to increase the brightness when the transmissive display unit is in bright display, the brightness when the transmissive display unit is in dark display is the same as that in bright display. The brightness becomes about 1/2 of the brightness, and the display contrast ratio becomes insufficient.

Next, display on the reflective display unit when the alignment conditions of the liquid crystal layer are set to conditions suitable for transmissive display will be described. When performing reflective display using a liquid crystal layer suitable for transmissive display, the liquid crystal alignment is controlled by voltage modulation so that the polarization state of light passing through the liquid crystal layer only once is modulated between two orthogonal polarization states. There is a need. Here, the two orthogonal polarization states may be two linearly polarized lights having orthogonal vibration planes, or may be left and right circularly polarized lights, and furthermore, two ellipses having the same ellipticity. The polarization direction may be such that the major axis direction is orthogonal and the rotation direction of the optical electric field is reversed. In order to realize the modulation of the polarization state between the combination of these two orthogonal polarization states, voltage modulation is performed so that a phase difference of 波長 wavelength is given to the transmitted light in the liquid crystal layer. There is a need. When the polarization state of light is modulated between two orthogonal polarization states,
In any case, in the transmissive display, by the action of the polarizing plate and the action of the phase difference compensator used as needed,
Sufficient brightness and contrast ratio can be realized.

However, when the above-mentioned liquid crystal layer is set to realize such control, the change of the reflectance in the reflective display during the change from the bright display to the dark display only once in the transmissive display. When the liquid crystal alignment change means is the same, for example, the display changes from a bright display to a dark display, and then becomes a bright display (for example, when the liquid crystal layer has the same layer thickness and the same initial alignment, and is further driven by the same voltage). ), The same light and dark display cannot be realized. Incidentally, the problems that arise in the above cases (a) and (b) are the same as in the transflective liquid crystal display device described in Japanese Patent Application Laid-Open No. Hei 7-318929.

Further, the pressure sensing input device (touch panel) which is used by being superimposed on the liquid crystal display device has a problem that visibility is easily deteriorated because the device itself has reflectivity to light. This tendency is remarkable especially in a reflection type liquid crystal display device.

A front light unit for improving the visibility of a reflection type liquid crystal display device in an environment where ambient light is dark,
Many have a planar light pipe structure, and the display content is observed through the light pipe, which has a problem that visibility is likely to deteriorate.

The present invention has been made in view of the above-mentioned problems, and has as its object to provide excellent visibility and high-resolution display, and utilize both reflected light and transmitted light for display. It is an object of the present invention to provide a liquid crystal display device.
Further, a further object of the present invention is excellent in visibility, and
An object of the present invention is to provide a liquid crystal display device capable of high-resolution color display and capable of utilizing both reflected light and transmitted light for display.

[0029]

Means for Solving the Problems The inventors of the present invention have conducted intensive studies to achieve the above object, and as a result, the cause of the problem of the conventional liquid crystal display device is either the GH method or the polarizing plate method. Also found that the orientation of the liquid crystal layer at the same time was set in the transmissive display portion and the reflective display portion in the same manner, and completed the present invention.

Here, the orientation of the liquid crystal layer means not only the average orientation orientation of liquid crystal molecules at a certain point in the liquid crystal layer but also the average orientation orientation relative to coordinates taken in the normal direction of the layer of the layered liquid crystal layer. It is assumed that the coordinate dependency is also shown.

That is, in order to solve the above-mentioned problems, a liquid crystal display device according to the present invention comprises a pair of substrates having alignment means (for example, alignment films) provided on opposing surfaces, and a pair of substrates sandwiched between the pair of substrates. A liquid crystal display device comprising a liquid crystal display element having a liquid crystal layer having at least two different alignment states in arbitrary and different regions used for display in the liquid crystal layer at the same time. For example, applying different voltages to arbitrary and different regions used for display in the liquid crystal layer, electrodes for generating different electric fields, applied voltage, or arbitrary and different used for display in the liquid crystal layer Provided in each area,
At least two types of alignment films oriented in different directions, or an insulating film or substrate formed to have at least two different thicknesses in a region used for display in the liquid crystal layer, a specific liquid crystal material, A liquid crystal layer structure, a polarizing plate, a retardation compensator, a combination thereof, etc., formed so as to be independently driven, and at least one of regions showing different alignment states in the liquid crystal layer. Reflection means (for example, a reflection film or a reflection electrode) are disposed in one of the two regions, and the regions exhibiting the different alignment states are
It is characterized in that it is used for a reflective display unit for performing a reflective display and a transmissive display unit for performing a transmissive display.

According to the above configuration, since the liquid crystal has different alignment states at the same time, when a dye such as a dichroic dye is used for display, for example, the amount of light absorbed (absorbance) and the optical anisotropic When the property is used, the magnitude of the modulation amount of each optical physical quantity such as the phase difference can be changed for each region where the liquid crystal alignment is different. Therefore, according to the above configuration, it is possible to obtain a transmittance or a reflectance based on the magnitude of the modulation amount of the optical physical quantity according to the alignment state of the liquid crystal layer,
This makes it possible to set optical parameters independently for the transmissive display unit and the reflective display unit. Therefore, according to the above configuration, there is no parallax, a high contrast ratio can be realized, visibility can be improved when the surroundings are dark, and good visibility can be achieved even when ambient light is strong. Can be obtained. For this reason, according to the above configuration, excellent visibility and high resolution display are possible,
A transflective liquid crystal display device that can use both reflected light and transmitted light for display can be provided.

Further, the liquid crystal display device according to the present invention comprises:
In order to solve the above-mentioned problem, in the above-mentioned liquid crystal display device, the above-mentioned alignment mechanism is characterized in that it is display content rewriting means for rewriting the display content over time.

According to the above configuration, the display content rewriting means and the alignment mechanism can be realized by the same means, and the liquid crystal display device can be obtained without adding a new configuration. In this case, the display content rewriting means used for taking a plurality of states having different liquid crystal alignments includes an electric liquid crystal alignment control means which is currently widely used for rewriting display contents with time. That is, it goes without saying that various means used for applying a voltage, such as electrodes, can be used. In this case, for example, by using different electrodes for the transmissive display unit and the reflective display unit, or by changing the voltage itself between the transmissive display unit and the reflective display unit, the alignment state in which the liquid crystal alignment is different in the liquid crystal layer. May be provided.

In order to solve the above-mentioned problems, a liquid crystal display device according to the present invention is arranged such that the liquid crystal display device is disposed so as to be superimposed on a display surface, and detects a coordinate position pressed by being pressed. A pressing coordinate detection type input unit, wherein the orientation mechanism changes an alignment state of a liquid crystal layer in at least one of the reflection display unit and the transmission display unit in conjunction with an output signal of the pressing coordinate detection type input unit. It is characterized by:

According to the above configuration, it is easily detected that the observer is using the display device by the signal of the pressed coordinate detection type input means. Thus, both reduction in power consumption and good visibility can be achieved.

[0037]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The liquid crystal display device according to the present invention is characterized in that the liquid crystal alignment of the reflective display unit and the liquid crystal alignment of the transmissive display unit can take different states at the same time. Here, the liquid crystal orientation refers not only to the average orientation orientation of liquid crystal molecules at a certain point in the liquid crystal layer, but also to the dependence of the average orientation orientation on the coordinates taken in the normal direction of the layer of the layered liquid crystal layer. Shall be. Therefore, in the present invention, a method of realizing different liquid crystal alignments in the reflective display unit and the transmissive display unit and an alignment mechanism used in the method will be roughly classified into three types and described.

The first method uses an alignment mechanism manufactured so that a certain condition of the liquid crystal layer is different between the transmissive display section and the reflective display section, so that the liquid crystal alignment of the reflective display section and the liquid crystal alignment of the transmissive display section can be improved. Is a way to make them different.

As the first method, specifically, for example, (1) a method using an alignment mechanism for performing a twist alignment so that a liquid crystal alignment has completely different twist angles between a transmissive display section and a reflective display section; (2) A method using an alignment mechanism that largely changes the tilt angle of the liquid crystal alignment with respect to the substrate is exemplified. Further, the first method includes (3) a method of arranging different liquid crystal materials in the transmissive display section and the reflective display section, and (4) a method of determining the type and concentration of the dye mixed in the liquid crystal material with the transmissive display section. (In this case, the same liquid crystal material may be used for the transmissive display unit and the reflective display unit), and the like, and the liquid crystal display device according to the present invention includes such a method. The mechanism implemented when implementing the method is provided as the orientation mechanism of the present invention. Further, the first method and the alignment mechanism used in the method may be a combination of these methods (1) to (4), and depending on these methods and the alignment mechanism used in the method, Different liquid crystal alignment can be realized in the reflective display unit and the transmissive display unit.

In the second method, the liquid crystal alignment is made different between the transmissive display section and the reflective display section by the display content rewriting means for rewriting the display contents with the passage of time (that is, the liquid crystal alignment is changed between the transmissive display section and the reflective display section). An orientation mechanism that differs from the display unit is the same as the display content rewriting means). As the display content rewriting means used when adopting this method, an existing display rewriting means can be used.

As the second method, specifically, a method of rewriting the liquid crystal alignment by, for example, (5) a method of using different electrodes for the transmissive display section and the reflective display section as an alignment mechanism, that is, A method can be adopted in which the voltage itself used as the display content rewriting means is changed between the transmissive display unit and the reflective display unit. As the second method, (6) a method of changing the voltage substantially applied to the liquid crystal alignment may be used although the electrodes are the same. In the case of adopting the method (6), for example, an insulator (for example, an insulating film) having a different thickness between the reflective display portion and the transmissive display portion is provided between the liquid crystal layer and the electrode for driving the liquid crystal layer. Accordingly, the liquid crystal alignment of the transmissive display unit and the liquid crystal alignment of the reflective display unit driven by the common electrode may be changed. Also, (7) a method of making the direction of the electric field different between the transmissive display unit and the reflective display unit may be used. For example, when the display is performed by changing the liquid crystal alignment direction in the liquid crystal layer plane by an electrode group which is arranged in parallel with one of the substrates sandwiching the liquid crystal layer and gives a different potential to the liquid crystal layer, the display is performed between the electrodes and on the electrodes. Since the liquid crystal orientations differ greatly in the above, regions having different liquid crystal orientations may be used for reflective display and transmissive display, respectively. Further, a method may be employed in which different potentials are applied to liquid crystal layers which are vertically aligned with respect to the substrate by using a similar electrode group. When the above-mentioned second method is adopted, for example, an electrode, an insulator, or a combination thereof used in realizing the above method corresponds to the alignment mechanism of the present invention, and the obtained liquid crystal display device is And these orientation mechanisms.

The third method is a method in which the liquid crystal alignment itself is not significantly different, but the thickness of the liquid crystal layer, which is a factor for determining the optical characteristics, is different between the reflective display portion and the transmissive display portion. To realize the method, for example, an insulating film formed in different thicknesses in the reflective display portion and the transmissive display portion, a substrate formed in a different layer thickness or shape in the reflective display portion and the transmissive display portion, and the like, It is used as the above alignment mechanism.

In the case of adopting the third method, the liquid crystal alignment may be a uniform twisted liquid crystal alignment such as a TN type used in a liquid crystal display device using two polarizing plates. Good. In this case, the liquid crystal orientation is parallel to the substrate between the substrates sandwiching the liquid crystal layer, and the orientation is twisted while changing the direction within the substrate plane according to the distance from one of the substrates. . If this liquid crystal alignment is used for the reflective display portion and the transmissive display portion by changing the thickness of the liquid crystal layer, good optical display can be realized in both the reflective display portion and the transmissive display portion because the optical characteristics differ depending on the liquid crystal layer thickness.

Also in the GH system, the same effect is obtained as when the dye concentration is substantially changed by changing the thickness of the liquid crystal layer. Therefore, the liquid crystal alignment itself is substantially the same in the reflective display portion and the transmissive display portion. However, good display can be realized in each of the reflective display unit and the transmissive display unit.

As described above, the methods for realizing different liquid crystal alignments in the reflective display portion and the transmissive display portion and the alignment mechanisms used in the methods are roughly classified into three types. The liquid crystal display method used in the realized liquid crystal display device according to the present invention may be appropriately selected from a group of methods using a change in the orientation of liquid crystal for display,
There is no particular limitation. As the above-mentioned liquid crystal display system used in the present invention, specifically, a mode utilizing a nematic phase of a liquid crystal composition for display, for example, a TN mode, an STN mode, a nematic bistable mode, a vertical alignment mode, Hybrid orientation mode, ECB
Various modes such as an (electrically controlled biriefringence) mode can be used. In addition, a mode utilizing scattering, for example, a polymer dispersed liquid crystal mode, a dynamic scattering method, and the like can also be used as the liquid crystal display method used in the present invention. Further, a surface-stabilized ferroelectric liquid crystal display system using a ferroelectric liquid crystal composition and a thresholdless switching antiferroelectric liquid crystal display system using an antiferroelectric liquid crystal also use an orientation change for display. It can be used as the liquid crystal display method used in the above.

When the third method is adopted, the liquid crystal display method used in the present invention may be a method using optical rotation modulation such as a TN method.
A method using modulation of retardation, such as the CB mode, or a method, in which the light absorption rate (absorbance) is modulated, such as the GH method, may be used. When the third method is adopted, the liquid crystal layer thickness is a major determinant of the optical characteristics including these methods, and the liquid crystal layer thickness is set to be large in the transmissive display section. In addition, it is possible to adopt any method in which setting the thickness of the liquid crystal layer to be thin in the reflective display section has an effect of achieving good display characteristics.

According to the present invention, as described above, the liquid crystal display device comprises a pair of substrates having alignment means provided on opposing surfaces,
What is claimed is: 1. A liquid crystal display device comprising a liquid crystal display element having a liquid crystal layer sandwiched between a pair of substrates, wherein at least two different alignment states are simultaneously provided in arbitrary and different regions used for display in the liquid crystal layer. The liquid crystal layer is provided with a reflection means in at least one of the regions exhibiting different alignment states, and the region exhibiting the different alignment state is a reflective display. By being used for the display unit and the transmissive display unit that performs transmissive display, it is possible to obtain a transmittance or a reflectance based on the magnitude of the modulation amount of the optical physical quantity according to the alignment state of the liquid crystal layer, There is no parallax and a high contrast ratio can be realized. As a result, visibility can be improved when the surroundings are dark, and good visibility can be obtained even when the ambient light is strong.

In the case where the degree of modulation of each optical physical quantity such as the amount of light absorption and the phase difference due to optical anisotropy is changed independently in the reflective display unit and the transmissive display unit, the liquid crystal is not affected by the application of voltage. Even when the orientation direction is substantially the same in the entire region used for display of the liquid crystal layer, in the region where the liquid crystal layer thickness of the liquid crystal layer is different, the orientation direction of the liquid crystal layer is substantially changed in the region. Therefore, the liquid crystal display device according to the present invention has a liquid crystal display device including a pair of substrates having facing surfaces provided with alignment means, and a liquid crystal layer sandwiched between the pair of substrates. Wherein the region used for display in the liquid crystal layer comprises at least two types of regions having different liquid crystal layer thicknesses, and each region having a different liquid crystal layer thickness is a reflective display. Section and the transparent display section Together are needed, at least in the reflective display portion is arranged, reflection means, the liquid crystal layer thickness of the reflective display unit may be configured to be smaller than the transmissive display section.

Also in the above configuration, it is possible to obtain the transmittance or the reflectance based on the magnitude of the modulation amount of the optical physical quantity in the region where the thickness of the liquid crystal layer is different. Optical parameters can be set independently. Therefore, according to the above configuration, there is no parallax, a high contrast ratio can be realized, visibility can be improved when the surroundings are dark, and good visibility can be achieved even when ambient light is strong. Can be obtained.

Hereinafter, a liquid crystal display device which performs good reflective display and good transmissive display by changing the thickness of the liquid crystal layer between the reflective display portion and the transmissive display portion will be described. This will be described with reference to a second embodiment.

[Embodiment 1] In this embodiment, GH
A liquid crystal display device using the method will be described below mainly with reference to FIG.

FIG. 1 is a sectional view of a main part of the liquid crystal display device according to the first embodiment. As shown in FIG. 1, the liquid crystal display device includes a liquid crystal cell 100 (liquid crystal display element) and, if necessary, a backlight 13 (illumination device) as background illumination means. These liquid crystal cells 10
0, the backlight 13 is arranged in the order of the liquid crystal cell 100 and the backlight 13 from the observer (user) side.

As shown in FIG. 1, the liquid crystal cell 100 has an electrode substrate having an alignment film 2 on the side where the liquid crystal layer 1 is in contact with the liquid crystal layer 1 (the interface on the first substrate in contact with the liquid crystal layer 1). 101
(A first substrate) and an electrode substrate 102 (a second substrate) provided with an alignment film 3 on a side in contact with the liquid crystal layer 1 (an interface on the second substrate in contact with the liquid crystal layer 1). have.

The electrode substrate 101 is provided with an electrode 6 (voltage applying means) for applying a voltage to the liquid crystal layer 1 on a substrate 4 made of a translucent glass substrate or the like. Alignment film 2 rubbed to cover
(Orientation mechanism) is formed.

On the other hand, the electrode substrate 10 with the liquid crystal layer 1 interposed therebetween
In order to apply a voltage to the liquid crystal layer 1, the electrode substrate 102 provided opposite to
An electrode 7 (voltage applying means) is formed as a counter electrode facing the electrode 6 with the insulating film 11 interposed therebetween.

The insulating film 11 is used for displaying on the liquid crystal layer 1 so that a region used for display on the liquid crystal layer 1 has at least two (in this embodiment, two) different liquid crystal layer thicknesses. In a region corresponding to a region to be used, the film is formed to have a partially different film thickness. More specifically, the insulating film 11 is formed to have a smaller thickness in a region corresponding to the transmissive display unit 10 than in a region corresponding to the reflective display unit 9.

The reflective display section 9 on the electrode substrate 102
A reflection film 8 (reflection means) covering the electrode 7 is formed in a region corresponding to the above, and the alignment film 3 (alignment mechanism) subjected to the rubbing treatment covers the electrode 7 and the reflection film 8. Is formed.

The electrodes 6 and 7 are made of, for example, ITO
It is a transparent electrode formed of (indium tin oxide). Also, a voltage for generating an electric field in the liquid crystal layer 1 is applied to the electrodes 6 and 7, and the display is controlled by applying a voltage according to the display content. ing.

The reflection film 8 has light reflectivity, and is made of, for example, a metal such as aluminum or silver, or a dielectric multilayer mirror. When the reflective film 8 is made of a conductor, the reflective film 8 may also serve as an electrode instead of the electrode 7. That is, the reflective film 8 may be a reflective pixel electrode which also serves as a liquid crystal drive electrode for driving the liquid crystal layer 1 and a reflective means. Further, the reflection film 8 may be a color reflection film that reflects light in a wavelength band appropriately selected from visible light.

The materials and forming methods of the members constituting the electrode substrates 101 and 102 are not necessarily limited to those described above, and conventionally known materials and conventional methods can be used. Further, the configuration of the liquid crystal display device is not limited to the above configuration, for example,
In response to a signal from a touch panel (pressed coordinate detection type input means) or the like described in an embodiment described later, the liquid crystal cell 10
0, the reflective display unit 9 and the transmissive display unit 10
May be configured to apply a voltage to the electrodes 6 and 7 corresponding to. Further, a configuration in which an active element such as a TFT element or an MIM is provided as a switching element may be employed.

As shown in FIG. 1, the electrode substrates 101 and 102 are opposed to each other so that the alignment films 2 and 3 are opposed to each other, are adhered to each other by using a sealing agent or the like, and a liquid crystal composition is introduced into the gap. As a result, the liquid crystal layer 1 is formed.

The backlight 13 is disposed on the back side of the liquid crystal cell 100 as viewed from the observer (user), that is, on the back side of the electrode substrate 102. The backlight 13
Is mainly composed of a light source 13a and a light guide 13b. The light source 13a is disposed, for example, along the side surface of the light guide 13b, whereby the light guide 13b is
For example, the side surface on the side where the light source 13a is provided is the incident surface,
The light incident from a is emitted to the liquid crystal cell 100 as an object to be illuminated. Note that an existing lighting device can be used as the backlight 13.

In the liquid crystal display device having the above configuration, in the reflective display section 9 on which the reflective film 8 is formed, the substrate 4
The reflection intensity of the ambient light incident on the display surface from the side, that is, the observer side, is controlled by a change in the liquid crystal orientation to perform display. Further, in the transmissive display section 10 on which the reflective film 8 is not formed, the transmitted light intensity of the light incident on the display surface from the substrate 5 side is controlled by a change in the liquid crystal alignment to perform display. In this case, the illumination light from the backlight 13 installed on the back of the liquid crystal cell 100 may be used as needed.

In the liquid crystal display device shown in FIG. 1, as described above, the reflective display section 9 and the transmissive display section 10 have different liquid crystal layer thicknesses. Thus, the liquid crystal display device has substantially different liquid crystal orientations in the reflective display unit 9 and the transmissive display unit 10.

Here, the configuration of the liquid crystal display device for obtaining different liquid crystal film thicknesses in the reflective display section 9 and the transmissive display section 10 will be described below.

In order to obtain different liquid crystal film thicknesses in the reflective display section 9 and the transmissive display section 10, for example, as shown in FIG.
The insulating film 11 may be formed so that the reflective display portion 9 and the transmissive display portion 10 have different thicknesses.

The structure for changing the thickness of the liquid crystal layer between the reflective display portion 9 and the transmissive display portion 10 is such that at least one of the substrates holding the liquid crystal (ie, the electrode substrates 101 and 102) is used. You only need to have it.

Therefore, the insulating film 11 may be provided not on the substrate 5 but on the substrate 4. However, even in such a case, the reflection film 8 is formed on the substrate 5 on the electrode substrate 102 side (that is, the display surface side (the electrode substrate 101 side) opposite to the liquid crystal layer 1). Is done.

In the liquid crystal display device shown in FIG. 1, the thickness of the insulating film 11 is changed between the area corresponding to the reflective display section 9 and the area corresponding to the transmissive display section 10 in the insulating film 11. Although the liquid crystal layer thickness is changed between the reflective display section 9 and the transmissive display section 10, the reflective display section is formed by forming the substrate 4 or the substrate 5 itself in the same shape as the insulating film 11 shown in FIG. A configuration in which the liquid crystal layer thickness is changed between 9 and the transmissive display unit 10 may be adopted.

The reflective display section 9 in the insulating film 11
And the region corresponding to the transmissive display unit 10,
When the film thickness is changed, as shown in FIG. 1, the thickness of the insulating film 11 in the region corresponding to the transmissive display unit 10 is made smaller than the film thickness of the insulating film 11 in the region corresponding to the reflective display unit 9. Alternatively, an insulating film 11 may be formed in a region corresponding to the reflective display portion 9, and the transmissive display portion 10 may be formed.
May be configured such that the insulating film 11 is not formed in a region corresponding to the above.

Further, the reflective display section 9 and the transmissive display section 1
In order to keep the liquid crystal layer thickness of the liquid crystal layer 1 at 0 at a predetermined value, a spacer (not shown) may be arranged on the liquid crystal layer 1, and the liquid crystal layer thickness is kept at a predetermined value by another method. You may be dripping. For example, when a spherical spacer is provided in the liquid crystal layer 1, the thickness of the liquid crystal layer in the reflective display section 9 having a small liquid crystal layer thickness is substantially equal to the diameter of the spacer.

The substrate pair prepared as described above, that is, the liquid crystal layer 1 sandwiched between the electrode substrates 101 and 102 is made of the liquid crystal composition as described above.
As a liquid crystal display system using the liquid crystal layer 1, for example, FIG.
As shown in (2), using a liquid crystal composition in which dichroic dye 12 is mixed into liquid crystal, an electric field is generated in liquid crystal layer 1 to control the liquid crystal alignment and simultaneously change the alignment direction of dichroic dye 12. In addition, a GH method for performing display using a change in absorption coefficient due to dichroism can be used.

Next, the operation of the liquid crystal layer 1 in the GH mode, the liquid crystal film thickness in the reflective display section 9 and the transmission display section 10
Display principle when the liquid crystal layer thickness is different in
This will be described below with reference to FIG.

When a display is performed using the liquid crystal display device shown in FIG. 1, the transmissive display section 10 emits light from the back of the liquid crystal layer 1 such as the backlight 13 only once, as indicated by an arrow. The light is emitted from the display surface after passing through the display surface, and is displayed as display light. At this time, the liquid crystal layer 1
Dichroic Dye 12 Mixed in Liquid Crystal Composition
Changes the light absorption rate depending on the liquid crystal alignment. For this reason, when the liquid crystal is oriented parallel to the display surface (electrode substrate 101) (hereinafter, referred to as parallel orientation), as shown in the transmissive display section 10a, the transmissive display section 10 causes the liquid crystal in this section. Since the chromatic dye 12 strongly absorbs light passing through the liquid crystal layer 1, dark display is obtained, and the transmissive display portion 10b
As shown in (2), when the liquid crystal is vertically oriented with respect to the display surface (electrode substrate 101) (hereinafter, referred to as vertical orientation), the light is weakly absorbed by the dichroic dye 12, so that a bright display is obtained. Display.

On the other hand, in the reflective display section 9, light incident on the display surface from the observer side is used for display. That is, the light incident on the display surface passes through the liquid crystal layer 1 and is reflected by the reflection film 8 as shown by the arrow, passes through the liquid crystal layer 1 again, and exits from the display surface to become display light. At this time,
As shown in the reflective display section 9a, when the liquid crystal is parallel-aligned, the dichroic dye 12 in the reflective display section 9a strongly absorbs light, resulting in dark display. As described above, when the liquid crystal is vertically aligned, light is weakly absorbed by the dichroic dye 12, so that bright display is possible and display is possible.

Therefore, by giving a potential difference between the electrode 6 and the electrode 7 and controlling the liquid crystal alignment, a bright display and a dark display can be realized. In this case, the initial alignment state of the liquid crystal is not particularly limited. For example, the liquid crystal may be aligned in parallel when no voltage is applied, may be further twisted, or conversely, the voltage may be changed. Vertical alignment may be performed when no voltage is applied. In the former case (that is, when the liquid crystal alignment when no voltage is applied is parallel alignment or when the liquid crystal is further twisted), a liquid crystal having a positive dielectric anisotropy can be used as the liquid crystal. . On the other hand, in the latter case (ie,
In the case where the liquid crystal alignment when no voltage is applied is vertical alignment), a liquid crystal having a negative dielectric anisotropy can be used as the liquid crystal. Thus, the initial alignment state of the liquid crystal is
Although not particularly limited, it is necessary to adjust the thickness of the insulating film 11 so as to obtain a liquid crystal layer thickness suitable for the type of liquid crystal alignment to be used.

Further, as shown in FIG. 1, in order to easily manufacture the liquid crystal layer 1, as in the case of a normal liquid crystal display device, the liquid crystal layer 1 includes the reflective display section 9 and the transmissive display section 10, or a plurality of display sections. It is preferable to have a structure in which the display pixels communicate with each other.

As described above, even when the liquid crystal layer 1 is in communication between the reflective display section 9 and the transmissive display section 10, the liquid crystal layer thickness is different between the transmissive display section 10 and the reflective display section 9. ,
The distance during which the light that ultimately becomes the display light passes through the liquid crystal layer 1 is determined by the distance that the light passes through the liquid crystal layer 1 only once in the transmissive display unit 10 and the distance that the light passes through the reflective display unit 9. It is possible to set substantially the same as the reciprocating distance of the liquid crystal layer 1.

For this reason, the reflection brightness of the reflection display section 9 and the transmission brightness of the transmission display section 10 can be set to substantially the same level, and the contrast ratio in the reflection display section 9 and the contrast ratio in the transmission display section 10 can be set. Can be set to approximately the same level. In other words, dichroic dye 1
In the GH system utilizing the absorption of light by 2, changing the thickness of the liquid crystal layer between the reflective display unit 9 and the transmissive display unit 10 has substantially the same effect as changing the dye density. By changing the thickness of the liquid crystal layer between the transmissive display unit 10 and the reflective display unit 9, the concentration of the dichroic dye 12 suitable for the reflective display unit 9 in the liquid crystal composition and the transmissive display unit 1
It is possible to make the mixed concentration of the dichroic dye 12 suitable for 0 substantially equal. Therefore, the reflective display unit 9 and the transmissive display unit 1
By the liquid crystal layer 1 communicating with 0, the reflective display unit 9 and the transmissive display unit 10 can simultaneously realize good display. That is, the reflective display unit 9 and the transmissive display unit 10
The display contrast ratio is almost the same, and the brightness of bright display is also about the same.

The brightness in this case indicates the proportion of the light incident on the liquid crystal layer 1 in the reflective display section 9 or the transmissive display section 10 which is observed by the observer as display light, and the contrast ratio is It shall be defined by dividing the brightness of the display by the brightness of the dark display.

In general, when a contrast ratio suitable for reflective display and a contrast ratio suitable for transmissive display are compared, it is found that the contrast ratio suitable for transmissive display is higher than the contrast ratio suitable for reflective display. Required.
Therefore, in order to satisfy this requirement, the liquid crystal layer thickness in the transmissive display unit 10 is made larger than the liquid crystal layer thickness in the reflective display unit 9 rather than setting the contrast ratio in the reflective display unit 9 and the contrast ratio in the transmissive display unit 10 equal. It is effective to set the thickness to be thicker so that the contrast ratio in the transmissive display unit 10 exceeds the contrast ratio in the reflective display unit 9 in order to perform good display.

Hereinafter, the liquid crystal display device according to the present embodiment will be described based on the above-described display principle with reference to FIGS. 1 to 3 and specific examples and comparative examples. The liquid crystal display device according to the embodiment is not limited at all by the following examples.

[Embodiment 1] In this embodiment, when no voltage is applied to the liquid crystal layer 1, the liquid crystal is oriented almost perpendicular to the normal to the display surface, and the voltage is applied to the liquid crystal layer 1. A liquid crystal display device using a GH type liquid crystal layer 1 using a liquid crystal having a negative dielectric anisotropy, in which the liquid crystal is inclined with respect to the display surface and which has negative dielectric anisotropy, will be described. First, a method for manufacturing the liquid crystal display device will be described below.

First, 140 nm of ITO was formed on a transparent substrate 4 by sputtering, and an etching process was performed using photolithography to form an electrode 6 (transparent electrode) having a predetermined pattern. Note that a glass substrate was used as the substrate 4.

Next, on the surface of the substrate 4 on which the electrodes 6 were formed, a vertical alignment film was further arranged by offset printing, and this was baked in an oven at 200 ° C. to form an alignment film 2. After that, the alignment film 2 was subjected to an alignment process by rubbing, and an electrode substrate 101 as an observer-side substrate was manufactured.

Here, the vertical alignment film has the property of aligning the liquid crystal in the normal direction of the film surface, and the property of tilting the liquid crystal alignment by several degrees from the normal direction by an alignment treatment such as rubbing. Having. Due to this tilt, the liquid crystal alignment after voltage application is further tilted toward the alignment processing direction.

On the other hand, a photosensitive resin having an insulating property is applied on the substrate 5 by spin coating, and furthermore, the photosensitive resin is not left in the transmissive display section 10 by mask irradiation with ultraviolet light. The insulating film 11 was patterned so that the photosensitive resin was formed to have a thickness of 3 μm. At this time, the pattern edge portion of the insulating film 11 was formed in a sufficiently gentle step shape so that the electrode 7 formed in a later step would not be broken by the step of the insulating film 11. Note that a transparent glass substrate similar to the substrate 4 was used as the substrate 5.

Further, 140 nm of ITO was sputtered on the surface of the substrate 5 on which the insulating film 11 was formed.
A film was formed thereon, and further, aluminum functioning as a light-reflecting electrode was further sputtered to a thickness of 200 nm.
A film was formed. Next, the obtained aluminum film is photo-etched so that the aluminum film remains only in the reflective display portion 9 (that is, the portion where the photosensitive resin is left when the photosensitive resin is patterned to form the insulating film 11). The reflective film 8 was formed by patterning by lithography and dry etching. Further, an electrode 7 (transparent electrode) having a predetermined pattern was formed by etching the ITO film under the reflective film 8 using photolithography.

Next, on the surface of the substrate 5 on which the electrodes 7 and the reflective film 8 are formed, the electrode substrate 1 serving as a viewer-side substrate is provided.
An alignment film 3 was formed in the same manner as the alignment film 2 of No. 01. After that, the alignment film 3 was subjected to an alignment treatment by rubbing, and the electrode substrate 102 was manufactured.

The electrode substrate 10 manufactured as described above
A seal resin (not shown) as an encapsulating sealant is disposed around one of the electrode substrates 1 and 102, and a spherical plastic having a diameter of 4.5 μm is formed on the alignment film forming surface of the other electrode substrate. As shown in FIG. 1, spacers were scattered, and the sealing resin was cured under pressure with the electrode surfaces facing each other to produce a liquid crystal cell for liquid crystal injection. When the thickness of the gap for injecting liquid crystal (that is, the thickness of the liquid crystal layer 1) in the reflective display portion 9 and the transmissive display portion 10 of the liquid crystal cell for liquid crystal injection was measured by measuring the reflected light spectrum, the reflective display portion 9 showed 4.5 μm, 7.5 μm in transmissive display section 10
Met.

Further, when a liquid crystal composition comprising a liquid crystal having a negative dielectric anisotropy and a dichroic dye 12 mixed therein is introduced into the above-mentioned liquid crystal cell for injecting liquid crystal, the concentration of the dichroic dye 12 is: The density was adjusted so that a sufficient contrast ratio could be obtained between the reflective display section 9 and the transmissive display section 10. Further, a chiral additive for imparting a twist to the alignment of the liquid crystal is added to the liquid crystal composition, and the alignment treatment performed on the alignment films 2 and 3 and the liquid crystal between the upper and lower electrode substrates 101 and 102 of the liquid crystal layer 1 are formed. The orientation twist was set to be the same between the reflective display unit 9 and the transmissive display unit 10 in a voltage application state used for dark display. Further, the liquid crystal composition was introduced into the liquid crystal cell for liquid crystal injection by a vacuum injection method, thereby producing a liquid crystal display device.

When a voltage was applied to the liquid crystal layer 1 while measuring the reflectance of the reflective display section 9 and the transmittance of the transmissive display section 10 of the obtained liquid crystal display device with a microscope, the display characteristics shown in FIG. 2 were obtained. Was. The voltage applied to the liquid crystal layer 1 is a rectangular wave whose polarity is inverted every 17 msec. In FIG. 2, the horizontal axis indicates the effective value of the applied voltage, and the vertical axis indicates the brightness (reflectance or transmittance). . Also, in the same figure, a curve 111 indicates the voltage dependency of the reflectance of the reflective display unit 9, and a curve 112 indicates the voltage dependency of the transmittance of the transmissive display unit 10.

As shown by the curves 111 and 112, in the liquid crystal display device described above, the brightness (reflectance or transmittance) of the reflective display unit 9 and the transmissive display unit 10 both decreases with the application of a voltage. ing. When the applied voltage is 1.
When the voltage is 8V, the reflectance of the reflective display unit 9 is 55%, the transmittance of the transmissive display unit 10 is 52%, and when the applied voltage is 5V, the reflectance of the reflective display unit 9 is 11%. The transmittance of the transmissive display section 10 was 10%.

That is, according to the liquid crystal display device described above, both the reflective display unit 9 and the transmissive display unit 10
Brightness of bright display showed a high value exceeding 50%, and the contrast ratio was about 5. As a result, a display with excellent visibility was realized.

[Comparative Example 1] Here, a comparative example of the above-mentioned Example 1 will be described. In Comparative Example 1, in the liquid crystal display device using the GH method shown in Example 1, except that the liquid crystal layer thickness in the reflective display unit 9 and the liquid crystal layer thickness in the transmissive display unit 10 were designed to be the same. A comparative liquid crystal display device was manufactured according to the method for manufacturing a liquid crystal display device shown in Example 1.

More specifically, in this comparative example, Example 1 was used.
A liquid crystal display device in which the thickness of the liquid crystal layer in the reflective display unit 9 and the thickness of the liquid crystal layer in the transmissive display unit 10 were both 4.5 μm without producing the insulating film 11 as produced on the substrate 5 was produced. That is, the upper and lower electrode substrates opposed to each other with the liquid crystal layer 1 interposed therebetween produce a smooth liquid crystal cell for liquid crystal injection in the reflective display section 9 and the transmissive display section 10, and the liquid crystal cell for liquid crystal injection is implemented. A liquid crystal display device was manufactured by introducing a liquid crystal composition containing the same dichroic dye 12 and chiral additive as in Example 1.

FIG. 3 shows the display characteristics obtained by measuring the reflectance of the reflective display section 9 and the transmittance of the transmissive display section 10 in the same manner as in Example 1 in the obtained liquid crystal display device.

Comparative Example 2 In Comparative Example 2, a liquid crystal composition having a higher concentration of dichroic dye 12 than in Comparative Example 1 was introduced into the same liquid crystal cell as Comparative Example 1, and A liquid crystal display device in which the brightness and the contrast ratio were set to be optimal was manufactured.

The display characteristics obtained by measuring the reflectance of the reflective display unit 9 and the transmittance of the transmissive display unit 10 in the obtained liquid crystal display device in the same manner as in Example 1 were compared with Comparative Example 1.
The results are shown in FIG.

In FIG. 3, the horizontal axis represents the effective value of the applied voltage, and the vertical axis represents the brightness (reflectance or transmittance). Also, in the same figure, a curve 121 indicates the voltage dependency of the reflectance of the reflective display unit 9 of Comparative Example 1, and a curve 122 indicates the voltage dependency of the transmittance of the transmissive display unit 10 of Comparative Example 1. A curve 123 indicates the voltage dependence of the reflectance of the reflective display unit 9 of Comparative Example 2, and a curve 124 indicates the transmissive display unit 1 of Comparative Example 2.
The voltage dependence of the transmittance of 0 is shown.

As shown by the curves 121 and 122, in the liquid crystal display device obtained in Comparative Example 1, the lightness (reflectance or transmittance) in the reflective display unit 9 and the transmissive display unit 10 is shown.
Both decrease with the application of the voltage, whereas the reflectance of the reflective display unit 9 when the applied voltage is 1.8 V is 51%, whereas the transmittance of the transmissive display unit 10 is When the applied voltage was 5 V, the reflectance of the reflective display unit 9 was 11%, and the transmittance of the transmissive display unit 10 was 22%.

That is, according to the liquid crystal display device obtained in Comparative Example 1, although the reflective display section 9 provided high brightness exceeding 50% and a contrast ratio of about 5, the transmissive display section 10 provided the same. Since the liquid crystal layer thickness in the transmissive display section 10 is the same as the liquid crystal layer thickness in the reflective display section 9,
Although the brightness of the liquid crystal layer 1 was high, the contrast ratio was as low as about 3 and the display quality was low.

Further, as shown by the curves 123 and 124, in the liquid crystal display device obtained in Comparative Example 2, the lightness (reflectance or transmittance) in the reflective display unit 9 and the transmissive display unit 10 is both voltage Is decreasing with the decrease of
When the applied voltage is 1.8 V, the reflectance of the reflective display unit 9 is 2
9%, the transmittance of the transmissive display unit 10 is 51%.
% When the applied voltage is 5 V.
Was 3%, and the transmittance of the transmissive display section 10 was 10%.

That is, according to the liquid crystal display device obtained in Comparative Example 2, although the transmissive display section 10 provided high brightness exceeding 50% and a contrast ratio of about 5, the reflective display section 9 provided the same. Since the liquid crystal layer thickness in the reflective display section 9 is the same as the liquid crystal layer thickness in the transmissive display section 10,
The contrast ratio is as high as about 10, but the brightness is 30%
And the display became dark.

As is clear from the comparison between Example 1 and Comparative Examples 1 and 2, in the GH type liquid crystal display device, the contrast ratio of the transmissive display section 10 is equal to or smaller than that of the reflective display section 9. It has been found that it is effective to set the layer thickness of the liquid crystal layer 1 of the transmissive display section 10 larger than the layer thickness of the liquid crystal layer 1 of the reflective display section 9 in order to achieve a higher height.

[Second Embodiment] In the first embodiment,
Although the liquid crystal display device using the GH method has been described, as the liquid crystal display method according to the present invention, in addition to the GH method, as shown in FIG.
And a method of using the retardation and the optical rotation of the liquid crystal layer 1 (hereinafter, collectively abbreviated as a polarization conversion effect) for display may be adopted.

Thus, in the present embodiment, a liquid crystal display device utilizing the above-mentioned polarization conversion effect for display is mainly shown in FIG.
This will be described below with reference to FIG. Note that, for convenience of explanation, components having the same functions as those in the first embodiment are given the same reference numerals, and descriptions thereof are omitted.

FIG. 4 is a cross-sectional view of a main part of the liquid crystal display device according to the present embodiment. The liquid crystal display device shown in FIG. 4 includes a liquid crystal cell 200 (liquid crystal display element) and, if necessary, the backlight 13 (illumination device). The liquid crystal cell 200 and the backlight 13 are viewed from the observer (user) side.
3 are arranged in order.

As shown in FIG. 4, the liquid crystal cell 200 has an electrode substrate in which the liquid crystal layer 1 has an alignment film 2 on the side in contact with the liquid crystal layer 1 (the interface on the first substrate in contact with the liquid crystal layer 1). 201
(A first substrate) and an electrode substrate 202 (a second substrate) provided with an alignment film 3 on a side in contact with the liquid crystal layer 1 (an interface on the second substrate in contact with the liquid crystal layer 1). The phase difference compensating plate 16 and the polarizing plate 14 are provided outside the electrode substrate 201 (that is, on the side opposite to the surface facing the electrode substrate 202), and outside the electrode substrate 202 (that is, the electrode substrate 2).
(A side opposite to the surface opposite to the surface 01) is provided with a phase difference compensating plate 17 and a polarizing plate 15. The phase difference compensators 16 and 17 are provided and used as needed.

Various retardation compensators such as stretched polymer films, liquid crystal alignment fixed polymer films, liquid crystalline polymer films, etc. may be used as the retardation compensators 16 and 17 used as required in the present invention. Can be used. The optical action is to prevent coloring, which is often seen when the phase difference compensators 16 and 17 are not used, to change the dependence of brightness on the potential difference between the electrodes 6 and 7, and to change the display viewing angle. Used for

The electrode substrate 201 is provided with an electrode 6 for applying a voltage to the liquid crystal layer 1 on a substrate 4 made of a light-transmitting glass substrate or the like. The rubbing-processed alignment film 2 is formed.

On the other hand, the electrode substrate 20 with the liquid crystal layer 1 interposed therebetween
In order to apply a voltage to the liquid crystal layer 1, the electrode substrate 202 provided opposite to
An electrode 7 is formed as a counter electrode facing the electrode 6 with the insulating film 11 interposed therebetween. However, in the liquid crystal display device shown in FIG.
The electrode 7 is electrically insulated from the electrode 7 so that a voltage is separately applied from outside the liquid crystal cell. Then, the reflective display section 9 on the electrode substrate 202
Is formed in a region corresponding to the above, and an alignment film 3 subjected to a rubbing process is formed so as to cover these electrodes 7 and the reflection film 8. Further, the insulating film 11 is formed such that the film thickness of the region corresponding to the transmissive display unit 10 in the insulating film 11 is smaller than the film thickness of the region corresponding to the reflective display unit 9.

As shown in FIG. 4, the electrode substrates 201 and 202 are arranged so that the alignment film 2 and the alignment film 3 are opposed to each other, bonded together using an encapsulating sealant or the like. The liquid crystal layer 1 is formed by introducing a substance.

In the above liquid crystal display device, in bright display,
The liquid crystal layer 1 made of the liquid crystal composition described above
And a transparent display unit 10.
The liquid crystal of the liquid crystal layer 1 is shown in FIG.
When the liquid crystal layer 1 is parallel-aligned as shown in the transmissive display section 10b, the light passing through the liquid crystal layer 1 has a polarization conversion effect, resulting in a dark display. On the other hand, as shown in the reflective display section 9a and the transmissive display section 10a, when the liquid crystal of the liquid crystal layer 1 is vertically aligned, the polarization conversion effect is weak and a bright display is obtained.

Therefore, the orientation change in the reflective display portions 9a and 9b and the transmissive display portions 10a and 10b is controlled by the polarizing plate 14 on the display surface side and the polarizing plate 15 on the backlight 13 side which sandwich the liquid crystal layer 1 therebetween. By utilizing the linearly polarized light selective transmission effect of the above for display as a change in the intensity of display light, a bright display and a dark display can be achieved. As described above, in this case, in order to compensate the wavelength dependence of the refractive index difference of the liquid crystal layer 1, or to change the voltage dependence of the brightness modulated by the liquid crystal layer 1 as necessary, or In order to change the viewing angle of the display, a phase difference compensating plate 16 as shown in FIG.
・ 17 may be used.

In the case where the optical anisotropy is used for display as described above, the initial alignment state of the liquid crystal is not particularly limited. For example, the liquid crystal layer 1 in a state where no voltage is applied is applied to the display surface. It may be in a state of being oriented parallel to the substrate, or in a state of being oriented vertically. In the former case (that is, when the liquid crystal alignment under no voltage application is parallel alignment), a liquid crystal having a positive dielectric anisotropy can be used as the liquid crystal. On the other hand, in the latter case (that is, when the liquid crystal alignment under no voltage application is vertical alignment), a liquid crystal having a negative dielectric anisotropy can be used as the liquid crystal.

As described above, even when the optical anisotropy is used for display, the initial alignment state of the liquid crystal is not particularly limited, but a liquid crystal layer thickness suitable for the type of liquid crystal alignment to be used is obtained. It is effective to adjust the thickness of the insulating film 11 so that it can be performed.

In order to realize dark display in the reflective display section 9, first, light that has been linearly polarized by the polarizing plate 14 is prepared. Then, if necessary, the polarization state is changed by the phase difference compensator 16, and the polarization state is further changed in the liquid crystal layer 1 of the reflective display unit 9, which is set to be thinner than the transmissive display unit 10. At this time, a condition necessary for an ideal dark display is that the polarization state on the reflection film 8 is circularly polarized light which may be turned to the left or right. Further, a condition necessary for realizing ideal bright display in the same reflective display section 9 is that the polarization state on the reflective film 8 be linearly polarized light. If the liquid crystal alignment can be electrically controlled between the dark display and the bright display, the display can be switched.

That is, when dark display is realized, the liquid crystal layer 1
The phase difference given to the light by the liquid crystal layer 1 before the light incident on the liquid crystal reaches the reflection film 8 (the phase difference of the display light on the reflection film 8) and the liquid crystal layer 1 when a bright display is realized. The phase difference between the liquid crystal layer 1 and the phase difference of the display light on the reflection film 8 before the incident light reaches the reflection film 8
There is a difference of substantially 1/4 wavelength (approximately 90 degrees), and the liquid crystal alignment to achieve it is, for example, electrically controllable, that is, controlled between circularly polarized light in dark display and linearly polarized light in bright display. If possible. At this time, the polarization direction of the linearly polarized light on the reflective film 8 for realizing a bright display may be any direction.

In the transmissive display section 10, the light that has been linearly polarized by the polarizing plate 15 is changed in polarization state by the phase difference compensating plate 17 as necessary, and then the layer thickness is made larger than that of the reflective display section 9. The display is performed by changing the thickness of the liquid crystal layer 1 which is set to be thick, and further changing the phase by the phase difference compensator 16 as necessary, and emitting the light from the polarizing plate 14.

In this case, the polarizing plate 1 is used for display.
4 shows a change in the state of polarization immediately before the light enters No. 4. Therefore,
In the case of performing a bright display, the polarization state immediately before the light enters the polarizing plate 14 may be adjusted so as to be linearly polarized light having a vibration direction of the transmission axis direction of the polarizing plate 14. Represents the polarization state immediately before the light enters the polarizing plate 14,
What is necessary is just to adjust so that it may become linearly polarized light having a vibration plane of the absorption axis direction of the polarizing plate 14.

That is, when performing bright display, the transparent display unit 1
0 to the light passing through the liquid crystal layer 1 (the phase difference of the display light emitted from the liquid crystal layer 1), and the phase difference to be applied to the light passing through the liquid crystal layer 1 of the transmissive display unit 10 when performing dark display. The change in the orientation of the liquid crystal layer 1 is electrically controlled by applying a voltage such that the difference from the phase difference (the phase difference of the display light emitted from the liquid crystal layer 1) becomes substantially 波長 wavelength (approximately 180 degrees). Then, the display can be switched.

Here, the phase control of 波長 wavelength corresponds to controlling the polarization direction of linearly polarized light incident on the polarizing plate 14 from the liquid crystal layer 1 side, and the main axes of the refractive index are uniformly oriented in parallel. In addition to controlling the phase difference by the retardation, the principal axis of the refractive index of the liquid crystal layer 1 is twisted with the torsion of the liquid crystal alignment, and the optical rotation phenomenon in which the polarization direction of the linearly polarized light changes with the change of the torsion of the alignment with the voltage. This is a polarization conversion action that also includes The polarization conversion effect of the liquid crystal layer 1 for realizing this is a polarization conversion effect between ordinary orthogonal polarization states when the application of the phase difference compensator 16 or 17 is also considered.

The liquid crystal alignment that enables the polarization conversion effect for realizing the above-mentioned polarization state control (light phase control) is as follows.
The alignment may be parallel to the substrates 4 and 5 (parallel to the display surface) and uniform parallel alignment (homogeneous alignment).
5 (parallel to the display surface) and twisted (twisted) between the substrates 4.5 (the upper and lower substrates opposed to each other with the liquid crystal layer 1 interposed therebetween). Vertical orientation (homeotropic orientation) perpendicular to the display surface (perpendicular to the display surface). Further, a hybrid alignment or the like in which one interface of the liquid crystal layer 1 is in parallel alignment and the other is in vertical alignment can be used.

In this case, the twist orientation is specifically set at 60 ° or more and 100 ° or less between the substrates 4 and 5, or at 0 ° or more and 40 ° or less. Is desirable. The reason is that, without changing the rubbing direction between the transmissive display unit 10 and the reflective display unit 9, it is possible to satisfy both the conditions suitable for the reflective display unit 9 and the conditions suitable for the transmissive display unit 10. It is because it becomes.

When mass-producing a liquid crystal display device, the most preferable optical design of the liquid crystal layer 1 is to set the display brightness (reflectance or transmittance) between the upper and lower limits of the range of the driving voltage applied to the liquid crystal layer 1. Is designed to change monotonically to increase or decrease monotonically.

In consideration of the driving conditions described above, the simplest optical design of the liquid crystal layer 1 is based on a liquid crystal oriented substantially perpendicular to the display surface and a liquid crystal oriented substantially parallel to the display surface. The design is such that electro-optical characteristics are achieved in which the display is controlled so that the display brightness monotonically increases or monotonically decreases.

In this case, in particular, using a parallel alignment film,
When a liquid crystal alignment parallel to the display surface is realized as a liquid crystal alignment without application of a voltage, conditions suitable for reflective display and conditions suitable for transmissive display clearly exist. Therefore, this condition was obtained by calculation by the so-called Jones matrix method, and an appropriate range of the twist angle was obtained.

As a result, it has been clarified that the twist angle needs to be set to 0 ° or more and 100 ° or less in order to obtain a good display in the reflective display.

That is, first, the present inventors have found that, in the liquid crystal layer 1 for realizing good display in reflection display, liquid crystal alignment having a polarization conversion effect (when a parallel alignment film is used, substantially no voltage is applied. (Equivalent to the liquid crystal alignment in the case of (1)), it is found that an action of efficiently converting circularly polarized light into linearly polarized light is necessary.
The reflectance when circularly polarized light was incident on the sample was determined by the above calculation method. In the calculation, light is incident on the liquid crystal cell 200 in the order of the polarizing plate 14, the phase difference compensating plate 16 for providing a phase difference of 90 degrees, the liquid crystal layer 1, and the reflecting film 8, and the light is conversely polarized from the reflecting film 8. The reflectance of the light propagating to the plate 14 and emitted was determined.

As a result, by adjusting the product (Δn · d) of the refractive index difference (Δn) of the liquid crystal of the liquid crystal layer 1 and the thickness (d) of the liquid crystal layer for each twist angle of the liquid crystal layer 1, the twist angle can be reduced. It has been clarified that circularly polarized light can be converted into perfect linearly polarized light within a range of 0 ° to 70 °.
Further, it has been found that in the range from more than 70 degrees to 100 degrees, circularly polarized light cannot be converted to perfect linearly polarized light, but good display is possible. The maximum value at a visible wavelength of the reflectance up to a twist angle of 70 degrees is 1
00%, Δn of the liquid crystal layer 1 for each twist angle
By adjusting d, the reflectivity at a specific wavelength at a twist angle of 80 degrees is 97% and the twist angle is 90%.
The reflectance at a degree of 83%, and the reflectance at a twist angle of 100 ° is 72%, so that a good reflectance can be obtained.
However, when the twist angle exceeds 100 degrees, for example, the reflectance at a twist angle of 110 degrees is 54%, and the reflectance at a twist angle of 120 degrees is 37%, so that circularly polarized light can be efficiently polarized into linearly polarized light. Becomes impossible. That is,
In the liquid crystal layer 1 in the reflective display section 9, the twist angle is set to 0.
It is necessary to set within the range of not less than 100 degrees and not more than 100 degrees.

In the above description, the circularly polarized light was used for the calculation in order to evaluate the polarization conversion effect of the liquid crystal layer 1 in the reflective display section 9. However, in actual display, the liquid crystal layer 1 in the reflective display section 9 was used. It is not always necessary to make circularly polarized light incident on the liquid crystal layer 1. Even if the liquid crystal layer 1 is designed as described above and linearly polarized light is made incident on the liquid crystal layer 1, a favorable display can be obtained in the reflective display section 9.

On the other hand, in order to obtain a good display in the transmissive display section 10, the liquid crystal is oriented with a small twist angle (0 to 40 degrees) or a large twist angle (60 degrees). (Up to 110 degrees).

The polarization conversion function necessary for obtaining good display in the transmissive display section 10 includes a basic optical function (first condition), a basic optical function (first condition), and reflection display. Realistic optical action determined by the association with the part 9 (second
Condition) must be satisfied.

The reason is that, for example, under the first condition, in a liquid crystal alignment having a polarization conversion effect (when a parallel alignment film is used, the alignment is substantially equal to the alignment when no voltage is applied). In the liquid crystal layer 1 in the transmissive display section 10,
Efficiently converts a certain polarized light (linearly polarized light, circularly polarized light, or elliptically polarized light, and a polarized light having a designated polarization state) orthogonally to the polarized light (in the case of linearly polarized light, the plane including the oscillating electric field of the light is orthogonal) In the case of linearly polarized light and circularly polarized light, it is necessary to have the function of converting to circularly polarized light whose rotation direction is inverted, and to be elliptically polarized light, it is elliptically polarized light with the same ellipticity whose elliptical principal axis directions are orthogonal and the rotation direction is inverted. To do that.

Therefore, the present inventors have proposed that the transparent display unit 10
The polarization conversion effect was calculated by the above calculation method (Jones matrix method) in order to evaluate the above-mentioned effect as a property required for the above, but there is no particular limitation contrary to the range of the twist angle required for this. Became clear.

In the present invention, the second condition is that the optical film (the polarizing plate 14 and the phase difference compensating plate 16) on the display surface side common to the reflective display portion 9 and the transmissive display portion 10 is used.
Is a constraint that arises from the use of The optical films in the reflective display section 9 and the transmissive display section 10 are set so as to perform good reflective display. On the surface opposite to the display surface of the liquid crystal display device, a different optical film can be set. This optical film displays the transmissive display section 10 by using the polarizing plate, which is an optical film on the display surface side. 14
In addition, it is preferable to set the arrangement such that the phase difference compensating plate 16 cooperates with the liquid crystal layer 1 on the transmission display section 10 to make the arrangement good. In order to make such settings, the transparent display unit 1
0, the polarization conversion effect of the liquid crystal layer 1 is simply the first
It is important not only to satisfy the condition (1) but also to be able to satisfactorily convert circularly polarized light into circularly polarized light in the opposite direction, or to satisfactorily convert linearly polarized light into orthogonally polarized light.

The liquid crystal layer 1 in the transmissive display section 10
In order to evaluate a specific condition satisfying the above second condition, the intensity of light that becomes reverse circularly polarized light when circularly polarized light is incident on the liquid crystal layer 1 was obtained by the above calculation method. The calculation is based on the assumption that the light is the polarizing plate 1 as the first polarizing plate.
A phase difference compensator 17 as a first phase difference compensator for providing a phase difference of 5, 90 degrees, the liquid crystal layer 1 has a slow axis orthogonal to the first phase difference compensator for providing a phase difference of 90 degrees. The transmittance when the light propagated in the order of the phase difference compensating plate 16 as the second phase difference compensating plate and the polarizing plate 14 as the second polarizing plate orthogonal to the first polarizing plate was obtained.

As a result, the present inventors adjusted the Δn · d of the liquid crystal layer 1 for each twist angle, and when the twist angle was in the range of 0 ° to 40 °, the circularly polarized light was reversed. They have been found to be well converted to circularly polarized light. Specifically, when the transmittance of light at a visible wavelength at a twist angle of 0 degree is 100%, the transmittance of light at a twist angle of 30 degrees is 88.6%, and the twist angle is 40 degrees. The light transmittance at the time is 80.8%, the light transmittance at a twist angle of 50 degrees is 72.0%, and the light transmittance at a twist angle of 60 degrees is 62.4%. When the polarization conversion effect of converting polarized light into reverse circularly polarized light is evaluated by transmittance, the transmittance decreases as the twist angle increases. For this reason, it was concluded from the above results that it is appropriate to set the upper limit of the twist angle to about 40 degrees.

On the other hand, the setting of the twist angle of the transmissive display section 10 for efficiently converting the linearly polarized light into the orthogonal linearly polarized light is limited to the case where the twist angle is 0 degree or more when the wavelength of light is limited to one wavelength. With this twist angle, a sufficiently efficient transmittance can be realized. However, in order to obtain high transmittance in a wide visible wavelength region, there is an optimum value for the twist angle. Specifically, the twist angle is changed so that the liquid crystal layer 1 has a maximum transmittance at 550 nm, which is the center wavelength of the visible wavelength range.
Was adjusted, and when the transmittance at 550 nm was taken as 100%, the wavelength width excluding the upper and lower limits of the wavelength at which a transmittance of 90% or more was obtained was determined. The transmittance is calculated as follows: when light passes through the polarizing plate 15 as the first polarizing plate, the liquid crystal layer 1, and the polarizing plate 14 as a second polarizing plate orthogonal to the first polarizing plate, The liquid crystal alignment in the center of the liquid crystal layer 1 in the thickness direction is arranged so that the transmission axes of the polarizing plates 14 and 15 form an angle of 45 degrees, and the transmittance at that time is obtained.

As a result, the wavelength width (wavelength range) when the twist angle is 0 degree is 230 nm, the wavelength width when the twist angle is 10 degrees is 235 nm, and when the twist angle is 20 degrees, the wavelength width is 240 nm. The wavelength width when the angle is 30 degrees is 245 nm, the wavelength width when the twist angle is 40 degrees is 250 nm, and the wavelength width when the twist angle is 50 degrees is 25.
5 nm, the wavelength width when the twist angle is 60 degrees is 265n
m, the wavelength width when the twist angle is 70 degrees is 280 nm,
The wavelength width when the twist angle is 80 degrees is 310 nm, the wavelength width when the twist angle is 90 degrees is 330 nm, the wavelength width when the twist angle is 100 degrees is 305 nm, and the wavelength width when the twist angle is 110 degrees is The wavelength width at 255 nm and a twist angle of 120 degrees was 210 nm.

From the above examination, it is found that the twist angle is 60
It was found that a high transmittance was realized in a wide wavelength range (wavelength range) within a range of not less than 110 ° and not more than 110 °, a good polarization conversion action was realized, and a good display was possible. Accordingly, from the above-described polarization conversion effect on circularly polarized light and polarization conversion effect on linearly polarized light, the twist angle of the liquid crystal of the transmissive display unit 10 that satisfies the second condition is in the range of 0 ° or more and 40 ° or less, or It is limited within the range of 60 degrees or more and 110 degrees or less.

As described above, the reflective display section 9 has a range of 0 ° to 100 °, the transmissive display section 10 has a range of 0 ° to 40 °, or 60 ° to 11 °.
It has been found that a twist angle within the range of 0 degrees or less gives a good display. That is, as an example of the embodiment of the present invention, the twist angle for obtaining good display in both the reflective display unit 9 and the transmissive display unit 10 is 0 degree or more and 4 degrees or more.
It is appropriate that the angle is in the range of 0 degrees or less, or in the range of 60 degrees or more and 100 degrees or less.

In the following examples, the twist angles of the liquid crystal layer 1 in the reflective display section 9 and the transmissive display section 10 are equal (Examples 2 to 9 and Example 11).
In Example 2, a typical example of using circularly polarized light with a twist angle of 0 degree is Example 11 (the liquid crystal alignment is vertical alignment),
A typical example of using a linearly polarized light with a twist angle of 0 degree is Example 3 (adjusted by a phase difference compensator so as to obtain a good bright display). A typical example in which linearly polarized light is used when the twist angle is around 70 degrees is Example 5 (adjustment is performed by a phase difference compensator so as to obtain a better bright display).
It is.

According to the above-mentioned study, the twist angle of the liquid crystal layer 1 for obtaining good display in the reflective display section 9 and the transmissive display section 10 is within the range of 0 to 40 degrees.
Alternatively, it is in the range of 60 degrees or more and 100 degrees or less.

In the above description, the magnitude of the twist angle has been described only with respect to the positive sign. However, the same discussion can be applied to the case where the absolute value is the same and the negative sign (the twist direction is twisted in the opposite direction). Needless to say, it is effective.

When the twist angle is set small, in any case, the change in the polarization state becomes a function of the product (Δn · d) of the refractive index difference (Δn) and the liquid crystal layer thickness (d). Since the incident light reciprocates through the liquid crystal layer 1 in the reflective display section 9 and the incident light passes through the liquid crystal layer 1 only once in the transmissive display section 10, the thickness of the liquid crystal layer in the transmissive display section 10 is reduced. It is desirable that the thickness is set to be thicker than the thickness.

In a TN liquid crystal display device using ordinary optical rotation, when the liquid crystal layer thickness is small, the optical rotation and the change in the polarization state due to the retardation cannot be distinguished. It is needless to say that the optical rotation used in the TN liquid crystal display device can be used for the bright display and the dark display using the above-mentioned polarization conversion function for use in the display. The polarization conversion function in the present invention includes the modulation of the transmitted light intensity by the optical rotation.

Further, in the above-mentioned polarization conversion operation, in order to change the liquid crystal orientation that can change the polarization state, as described above, it is controlled whether the orientation state of the liquid crystal is parallel or perpendicular to the substrates 4 and 5. Not only liquid crystal, but also liquid crystal in which only the alignment direction changes while maintaining the alignment direction almost parallel to substrates 4 and 5, such as surface-stabilized ferroelectric liquid crystal and antiferroelectric liquid crystal, and nematic liquid crystal In addition, there is also a method in which the alignment direction is changed while maintaining the alignment direction of the liquid crystal in a plane parallel to the display surface by changing the electrode structure using the method described above.

In the liquid crystal display device described above, the installation orientation (sticking orientation) of the polarizing plates 14 and 15 can be appropriately set. For example, if the installation direction of the polarizing plate 14 is set in accordance with the reflection display unit 9, the transmission display unit 1 is inevitably set.
Since the same polarizing plate 14 also acts on the display light passing through the polarizing plate 14, the polarizing plate 15
What is necessary is just to determine the installation direction of.

As described above, when the liquid crystal alignment having no twist is used for display, when the reflective display unit 9 displays, for example, a dark display, the transmissive display unit 10 similarly displays, for example, a dark display. However, for example, if the installation direction of the polarizing plate 15 is changed by 90 degrees while the installation direction of the polarizing plate 14 is kept as it is, the display is inverted between the reflective display unit 9 and the transmissive display unit 10. That is, good display cannot be obtained as it is. Therefore, in order to prevent such inversion of the display, the installation orientation of the polarizing plate 15 may be returned to the original one, or the reflective display unit 9 and the transmissive display unit 10 may be provided with independent electrodes, respectively. The driving itself may be inverted by only one of the reflective display unit 9 and the transmissive display unit 10 so that the brightness of the display matches.

Next, the display principle of the reflective display unit 9 and the transmissive display unit 10 in the liquid crystal display device shown in FIG. 4 will be described in more detail.

First, the display principle of the reflective display section 9 will be described below. For simplicity, in the following description, the phase difference compensators 16 and 17 are not used, and the liquid crystal alignment of the liquid crystal layer 1 has a twist in the reflective display portion 9b and the transmissive display portion 10b. Make it not exist. Further, when light having a wavelength of 550 nm is transmitted through the liquid crystal layer 1 only once, the reflective display unit 9b and the transmissive display unit 10b
It is assumed that the thicknesses of the reflective display unit 9 and the transmissive display unit 10 are adjusted so as to have a phase difference of ４ wavelength and 波長 wavelength, and the liquid crystal composition has a positive dielectric anisotropy. When no voltage is applied, the orientation of the liquid crystal is substantially parallel to the substrates 4 and 5, and the orientation of the liquid crystal is relative to the absorption axis of the polarizing plate 14.
It is assumed that the angle is 45 degrees.

In this case, the liquid crystal alignment in the reflective display section 9 and the transmissive display section 10 when no voltage is applied is the liquid crystal alignment shown in the reflective display section 9b and the transmissive display section 10b.
The liquid crystal alignment in the reflective display unit 9 and the transmissive display unit 10 changed by the application of the voltage becomes the liquid crystal alignment shown in the reflective display unit 9a and the transmissive display unit 10a.

In the reflective display section 9b, the product (Δn · d) of the refractive index difference (Δn) of the liquid crystal composition and the thickness (d) of the liquid crystal layer.
Satisfies the ４ wavelength condition. Therefore, the ambient light becomes linearly polarized light by the polarizing plate 14 at the time of incidence, and becomes circularly polarized light when it reaches the reflection film 8 due to the retardation of the liquid crystal layer 1. At this time, the traveling direction of the incident light is reversed by the reflective film 8, and the circularly polarized light preserves the rotation direction of the oscillating electric field and only the traveling direction is reversed. In other words, it becomes circularly polarized light whose right and left are reversed. The circularly polarized light again passes through the liquid crystal layer 1 of the reflective display section 9b, becomes linearly polarized light parallel to the absorption axis direction of the polarizing plate 14, is absorbed by the polarizing plate 14, and provides a dark display.

At this time, in the transmissive display section 10b,
The product (Δn · d) of the refractive index difference (Δn) of the liquid crystal composition and the thickness (d) of the liquid crystal layer satisfies the 波長 wavelength condition. For this reason, the liquid crystal layer 1 has the function of converting the azimuth of the plane of vibration of the incident linearly polarized light into line symmetry with respect to the liquid crystal alignment direction. Therefore, the absorption axis azimuth of the polarizing plate 15 on the light incident side of the light to the transmissive display unit 10b is adjusted by the above-described action of the liquid crystal layer 1 so that the light passing through the polarizing plate 14 is absorbed by the polarizing plate 14 and dark display is performed. The polarizing plate 14 and the polarizing plate 1
5 is determined to be parallel to the transmission axis direction.

As described above, the polarizing plates 14 and 15
However, when their transmission axis directions are parallel and arranged so that the liquid crystal alignment forms an angle of 45 degrees from the transmission axis direction,
It was found that both the reflective display section 9b and the transmissive display section 10b displayed dark.

Next, no voltage application state (initial alignment state of liquid crystal) shown in the reflective display section 9b and the transmissive display section 10b.
From the following, the operation when the potential difference is applied to the electrodes 6 and 7 to change the alignment state of the liquid crystal almost perpendicularly to the display surface as shown in the reflective display portion 9a and the transmissive display portion 10a will be described below. Will be described.

In this case, in the reflective display section 9a, the surrounding light is linearly polarized by the polarizing plate 14, and the liquid crystal layer 1 has no retardation with respect to the linearly polarized light. After the light reaches the reflective film 8 and the traveling direction is further reversed, the light passes through the liquid crystal layer 1 again, and is emitted from the polarizing plate 14 while maintaining the direction of linearly polarized light orthogonal to the absorption axis direction of the polarizing plate 14.

In the transmissive display section 10a, similarly to the reflective display section 9a, the incident light becomes linearly polarized light by the polarizing plate 15, and passes through the polarizing plate 14 while maintaining the direction of the linearly polarized light substantially.

When the above-described polarization conversion effect due to optical anisotropy is used for display, the amount of this polarization conversion effect is determined, for example, when the liquid crystal is aligned in parallel and no voltage is applied to the liquid crystal layer 1. Has a twist angle of the orientation of the liquid crystal layer 1,
It is determined by the product (Δnd) of the liquid crystal layer thickness (d) and the refractive index difference (Δn) of the liquid crystal composition. For this reason, the fact that the transmissive display section 10 has a liquid crystal layer thickness greater than that of the reflective display section 9 as in the present invention can reduce the brightness and contrast ratio of the display in a liquid crystal display device using transmitted light and reflected light for display. , The reflection display unit 9 and the transmission display unit 10. Note that the twist angle is determined by the reflection display unit 9.
And the transmissive display unit 10 may be different from each other.

When the liquid crystal display device has the phase difference compensating plates 16 and 17, sufficient lightness and contrast ratio can be secured for light of a plurality of wavelengths in the visible light region. As a result, better display can be realized.

Further, even if the liquid crystal composition and the orientation of the liquid crystal layer 1 are the same as those described above, the above-mentioned change in display can be reversed by the action of the phase difference compensators 16 and 17. That is, for example, if a quarter-wave plate is used as the phase difference compensating plates 16 and 17, in the reflective display section 9b, the ambient light becomes circularly polarized by the phase difference compensating plate 16 when entering the liquid crystal layer 1, Further, due to the polarization conversion effect due to the optical anisotropy of the liquid crystal layer 1, when the light reaches the reflection film 8, the light becomes linearly polarized light.
4 is again converted into a transmission component and is emitted from the polarizing plate 14, so that a bright display is obtained, and the liquid crystal alignment is changed to the reflection display section 9.
In the case where the ambient light changes as shown in a, the ambient light reaches the reflective film 8 as circularly polarized light, so that a dark display is performed.

In the above description, the case where the display changes from dark display to bright display as the potential difference between the electrode 6 and the electrode 7 increases, but the change in display is not limited to this. However, for example, as described above, the liquid crystal composition used for the liquid crystal layer 1 can be inverted by making the dielectric anisotropy of the liquid crystal negative and setting the initial alignment state of the liquid crystal to vertical alignment.

Here, when the initial alignment state of the liquid crystal is set to the vertical alignment, there is provided a technical feature that the polarization conversion effect of the initial alignment is not greatly affected by the manufacturing accuracy of the liquid crystal layer thickness. . Therefore, to take advantage of this feature,
Assigning the initial alignment state to black display so as to stabilize black display, which greatly affects display quality, can be a means of high mass productivity. In particular, in order to realize this, it is necessary to make the display black in a state where the polarization conversion effect of the vertically aligned liquid crystal layer 1 has almost disappeared, and the phase difference compensator 16 needs to have a good circular polarization effect. It is. That is, the phase difference compensating plate 16
It is important to have a configuration in which circularly polarized light is emitted over as wide a wavelength as possible.

Further, the transmissive display section 10 is arranged, for example, so that the phase difference compensating plate 17 and the phase difference compensating plate 16 have a slow axis direction orthogonal to each other, and the polarizing plate 14 and the polarizing plate 1 are arranged.
5 are arranged so as to have absorption axis directions orthogonal to each other, a bright display is obtained with the liquid crystal orientation shown in the transmissive display section 10b, and a dark display is made with the liquid crystal orientation shown in the transmissive display section 10a.

Regardless of whether the orientation of the liquid crystal layer 1 is parallel orientation or vertical orientation, in the liquid crystal display device according to the present invention, the thickness of the liquid crystal layer is changed between the reflective display portion 9 and the transmissive display portion 10. In this case, the reflective display unit 9 and the transmissive display unit 10
In order to make the brightness and the contrast ratio compatible, as described above, in the reflective display unit 9, the light incident through the liquid crystal layer 1 from the display surface side exits again through the liquid crystal layer 1 to the display surface side. In the transmissive display section 10, light incident from the back side (backlight 13 side) is reflected by the liquid crystal layer 1.
When the display is performed by emitting light to the display surface side after passing through only once, the thickness of the liquid crystal layer in the transmissive display unit 10 is set to be larger than the thickness of the liquid crystal layer in the reflective display unit 9. It is effective to satisfy the conditions.

Hereinafter, among the liquid crystal display devices according to the present embodiment, a liquid crystal display device that uses a change in the polarization state due to the polarization conversion action of the liquid crystal layer 1 using the polarizing plates 14 and 15 for display will be described with reference to FIG. 8 to describe specific examples and comparative examples, the liquid crystal display device according to the present embodiment is not limited to the following examples.

[Embodiments 2 to 4] In Embodiments 2 to 4, the transmissive display section 10 is made to be 7.5 μm and reflective by the same method as that of the liquid crystal cell for injecting liquid crystal of Embodiment 1. A liquid crystal cell for liquid crystal injection in which the display section 9 had a liquid crystal layer thickness (d) of 4.5 μm was produced. That is, also in the second to fourth embodiments, the insulating film 11 is patterned so that the photosensitive resin does not remain in the transmissive display unit 10 and the photosensitive resin is formed to have a layer thickness of 3 μm in the reflective display unit 9. By setting, the thickness of the liquid crystal layer was set to be larger in the transmissive display unit 10 than in the reflective display unit 9. However, in Examples 2 to 4, as shown in FIG. 4, the electrode 7 of the reflective display unit 9 and the electrode 7 of the transmissive display unit 10 are electrically insulated, and the electrode 7 of the reflective display unit 9 is electrically insulated. An electrode pattern was prepared so that a voltage was separately applied to the electrode 7 of the transmissive display unit 10 from the outside.

Further, in Examples 2 to 4, in the liquid crystal cell for injecting liquid crystal, the difference in refractive index (Δn) between the liquid crystal composition containing no chiral agent and the positive dielectric constant was 0.065. The liquid crystal layer 1 was formed by introducing a liquid crystal composition having an isotropic property by a vacuum injection method.

The phase difference compensators 16 and 17 are provided outside the respective electrode substrates in the liquid crystal cell thus obtained.
Then, the polarizing plates 14 and 15 were attached to produce a liquid crystal display device. At this time, in the second to fourth embodiments, the phase difference compensating plate 17
Is composed of two phase difference compensating plates, and the phase difference compensating plate 16 is
In the third embodiment, one phase difference compensating plate is used.
In No. 4, two phase difference compensating plates were used. The sticking directions of the phase difference compensating plates 16 and 17 and the polarizing plates 14 and 15 are as follows.
It was determined according to the orientation direction (orientation direction) of the liquid crystal.

Further, in Example 2, the liquid crystal alignment was a homogeneous alignment, and the display was NB (normally black).
Mode was used. In Example 3, the liquid crystal alignment was a homogeneous alignment, and an NW (normally white) mode was used for display. In the fourth embodiment, a mixture of these (the NB mode is used for the reflective display and the NW mode is used for the transmissive display) is used.

However, in Examples 2 to 4, parallel alignment films are used for the alignment films 2 and 3 so that the liquid crystal is aligned parallel to the display surface when no voltage is applied. The rubbing intersection angle of the alignment films 2 and 3 was set to 180 degrees to perform the alignment processing.

Here, as shown in FIG. 5, the rubbing crossing angle refers to the orientation in the electrode substrate which is the observer side substrate among the pair of electrode substrates sandwiching the liquid crystal layer 1 in the liquid crystal cell for liquid crystal injection. With reference to the rubbing direction X, which is the orientation direction of the film 2 (ie, the orientation film 2 on the substrate 4 side), the orientation direction of the orientation film 3 on the other electrode substrate (ie, the orientation film 3 on the substrate 5 side). Is defined as an angle measured counterclockwise.

The alignment state of the liquid crystal molecules in the liquid crystal layer 1 sandwiched between the alignment films 2 and 3 that have been subjected to the alignment treatment is determined by the alignment property of the alignment films 2 and 3 and the characteristic of the liquid crystal when no electric field or magnetic field is present. And the rubbing crossing angle.

When the rubbing intersection angle is, for example, 180 degrees,
The liquid crystal composition in which the chiral additive is not mixed is aligned without twisting. Further, when the chiral additive induces a twist of left twist in the liquid crystal, for example, the liquid crystal layer 1 is oriented without twisting until the amount of the chiral additive reaches a certain amount, and the certain amount is adjusted. If it exceeds, twist alignment is performed 180 degrees left-handed (180 degrees left twisted). When the amount of the chiral additive is further increased, 1
Twisting by an integral multiple of 80 degrees is realized.

Therefore, in the present embodiment, the alignment film 3 realized by the rubbing intersection angle (180 degrees) described above.
When the rubbing direction X of the alignment film 2 disposed on the electrode substrate on the upper side of the liquid crystal layer 1 is x degrees, the alignment direction of the upper liquid crystal is x degrees when the chiral additive is not added. When the amount of the agent is increased and twisted 180 degrees to the left between the upper and lower electrode substrates, it is expressed as (180 + x) degrees.

In such an alignment treatment, the alignment films 2 and 3 are so-called parallel alignment films for aligning the liquid crystal in parallel to the alignment film surface. When a nematic liquid crystal having a positive anisotropy is used, the liquid crystal molecules are oriented substantially parallel to the upper and lower electrode substrates sandwiching the liquid crystal layer 1 and have no twist (that is, homogeneous alignment) when no voltage is applied. In addition, with the application of the voltage, the liquid crystal at the center in the thickness direction of the liquid crystal layer 1 undergoes a change in the alignment according to the voltage.

Table 1 shows the optical arrangement of the polarizing plates 14 and 15, the phase difference compensating plates 16 and 17, and the liquid crystal layer 1 (that is, the polarizing plates) in each of the liquid crystal display devices obtained in Examples 2 to 4. 14 and 15 and the orientations of the phase difference compensators 16 and 17 and the orientation of the liquid crystal) are shown using a common orientation standard in each example.

The optical arrangement shown in Table 1 is the arrangement of each optical element on the display surface when the observer observes the display surface, and the phase difference compensating plate 16 or 17 has a plurality of phase difference compensating plates 17. In the case of being constituted by a phase difference compensating plate, the respective phase difference compensating plates constituting the phase difference compensating plates 16 and 17 are described in the order of actual arrangement from the observer side.

Since the liquid crystal layer 1 is not twisted, the orientation of the entire liquid crystal layer 1 when no voltage is applied (the orientation of the long axis of the liquid crystal molecules) is described. And the orientation of the alignment treatment performed on the alignment film 2 on the substrate 4 side.

Each azimuth represents an azimuth from a reference azimuth arbitrarily taken on the display surface in units of degrees, and the retardation of each phase difference compensator (ie, the in-plane refractive index difference of the phase difference compensator). And the product of the thickness) are values in nm for monochromatic light having a wavelength of 550 nm.

[0183]

[Table 1] The display characteristics of each of the liquid crystal display devices obtained in Examples 2, 3, and 4 are shown in FIGS. 6, 7, and 8, respectively. These display characteristics were measured by the same method as in Example 1. In each of the figures, the horizontal axis represents the effective value of the applied voltage, and the vertical axis represents the brightness (reflectance or transmittance). Rate). Further, the transmittance of the transmissive display unit 10 to which both the polarizing plates 14 and 15 are not attached is set to a transmittance of 1
00%, and the reflectance of the reflective display unit 9 before attaching the polarizing plate 14 is 100%.

In FIG. 6, a curve 211 shows the voltage dependence of the reflectance of the reflective display section 9 with respect to the voltage between the electrodes 6 and 7 in the liquid crystal display device obtained in Example 2, and the curve 212 shows 7 shows the voltage dependence of the transmittance of the transmissive display unit 10 with respect to the voltage between the electrodes 6 and 7 in the liquid crystal display device obtained in Example 2.

As shown in FIG. 6, in the second embodiment, in a section where the applied voltage is 1 V to 2 V, both the reflectance and the transmittance increase with an increase in the applied voltage. When the applied voltage is 1
When V, the reflectance of the reflective display unit 9 is 3%, and the transmissive display unit 1
When the applied voltage was 2 V, the transmittance of the reflective display unit 9 and the transmittance of the transmissive display unit 10 were both 40%.

In FIG. 7, a curve 221 indicates the voltage dependency of the reflectance of the reflective display section 9 with respect to the voltage between the electrodes 6 and 7 in the liquid crystal display device obtained in the third embodiment. Reference numeral 222 denotes the voltage dependency of the transmittance of the transmissive display unit 10 with respect to the voltage between the electrodes 6 and 7 in the liquid crystal display device obtained in Example 3.

As shown in FIG. 7, in the third embodiment, in the section where the applied voltage is between 1 V and 2 V, both the reflectance and the transmittance decrease as the applied voltage increases. When the applied voltage is 1
V and the reflectance of the reflective display unit 9 and the transmissive display unit 10
Were 40%, the reflectance of the reflective display unit 9 was 3%, and the transmittance of the transmissive display unit 10 was 2% when the applied voltage was 2V.

In FIG. 8, a curve 231 indicates the voltage dependency of the reflectance of the reflective display section 9 with respect to the voltage between the electrodes 6 and 7 in the liquid crystal display device obtained in Example 4. Reference numeral 232 indicates the voltage dependency of the transmittance of the transmissive display unit 10 with respect to the voltage between the electrodes 6 and 7 in the liquid crystal display device obtained in Example 4.

As shown in FIG. 8, in the fourth embodiment, in the section where the applied voltage is 1 V to 2 V, the reflectance increases as the applied voltage increases, while the transmittance decreases. When the applied voltage is 1 V, the reflectance of the reflective display unit 9 is 3%, the transmittance of the transmissive display unit 10 is 40%, and the applied voltage is 2 V.
, The reflectance of the reflective display unit 9 is 40%, and the transmissive display unit 1
The transmittance of 0 was 2%.

As described above, in each of the liquid crystal display devices obtained in Examples 2 to 4, the transmittance and the reflectance change as the voltage applied to the liquid crystal display device changes. Thus, both reflective display and transmissive display were possible.

Further, visual observation was carried out. In Examples 2 and 3, the same voltage was applied to the electrode 7 in the reflective display section 9 and the electrode 7 in the transmissive display section 10, and Since the display is performed while maintaining the voltage applied to the liquid crystal layer 1 by the electrodes 6 and 7 in the reflective display unit 9 and the transmissive display unit 10 in the same manner, the reflective display unit 9 and the transmissive display unit 10 are bright and dark. Was the same, and it was confirmed that the inversion of light and dark of the display did not occur. In this display, even if the intensity of the ambient light was changed during the observation, no change was observed in the display contents. That is, when the reflective display unit 9 performs dark display, the transmissive display unit 10 also performs dark display, and when the reflective display unit 9 performs bright display, the transmissive display unit 10 also performs bright display. Therefore, even when the reflective display unit 9 and the transmissive display unit 10 are driven by using the same electrode 7 as shown in FIG. 1, the display is not inverted.

On the other hand, in the fourth embodiment, when a voltage is applied in the same manner as in the second and third embodiments, that is, when a voltage of 1 V is applied, the transmissive display section 10 becomes a bright display, and the reflective display is made. The part 9 is in a dark display. Also, 2V
, The transmissive display section 10 displayed dark, and the reflective display section 9 displayed bright. For this reason, in the transmissive display unit 10 and the reflective display unit 9, the display brightness was reversed. Due to this inversion, display is performed in an environment with low ambient light,
When the reflective display is performed by intensifying the ambient light mainly when observing the transmissive display unit 10, the contrast of the display is reversed, and it is difficult to confirm the display contents. From this, as shown in Example 4, the electrode 7 in the reflective display unit 9 and the transmissive display unit 10
When the same voltage is applied to the electrode 7 at
In the case of the mixed mode of NB and NW, it was confirmed that the inversion of the display of the reflective display unit 9 and the transmissive display unit 10 was large, and the visibility was deteriorated.

On the other hand, in the fourth embodiment, when the reflective display section 9 performs bright display, the transmissive display section 10 simultaneously performs bright display.
A different voltage is applied to the electrode 7 in the reflective display section 9 and the electrode 7 in the transmissive display section 10 so that the transmissive display section 10 also performs dark display at the same time as the reflective display section 9 performs dark display. When a voltage (1 V) indicating that the reflective display unit 9 displays a dark image is applied to the reflective display unit 9 by the orientation mechanism 6. 7, the transmissive display unit 1 is applied to the transmissive display unit 10.
0 applies a voltage (2 V) for dark display, and the reflective display unit 9
When the reflective display unit 9 applies a voltage (2 V) for bright display, the transmissive display unit 10
By applying a voltage (1 V) that gives a bright display, the reversal of light and dark in the display was eliminated, and the same favorable display state as in Examples 2 and 3 was obtained.

From the above, it can be seen that the above Examples 2 to 4 were used.
In each of the liquid crystal display devices, both the reflective display unit 9 and the transmissive display unit 10 can achieve both the brightness of bright display and the contrast ratio, and the reflective display unit 9.
It can be seen that the brightness of the display can be matched between the and the transmissive display section 10, and a display with excellent visibility can be realized. Further, in each of the liquid crystal display devices of Examples 2 to 4, since the contrast ratio in the transmissive display unit 10 exceeds the contrast ratio in the reflective display unit 9, the display quality is further improved, and the display quality is improved. It can be seen that can be performed.

Next, among the liquid crystal display devices according to the present embodiment, a liquid crystal display device utilizing the polarization conversion action of the liquid crystal layer 1 by twist alignment of the liquid crystal layer 1 for display will be described with reference to FIGS. 9 and 10. In the following, specific examples and comparative examples will be described, but the liquid crystal display device according to this embodiment includes:
The present invention is not limited by the following examples.

[Embodiment 5] In this embodiment, the transmissive display section 10 and the reflective display section 9 are 4.5 μm in the same manner as in the method of manufacturing the liquid crystal cell for injecting liquid crystal of the first embodiment.
A liquid crystal cell for liquid crystal injection having a liquid crystal layer thickness of was prepared. That is, also in the present embodiment, the photosensitive resin is not left in the transmissive display section 10 and the insulating film 11 is patterned in the reflective display section 9 so that the photosensitive resin is formed to have a layer thickness of 3 μm. , The transmissive display unit 1 rather than the reflective display unit 9
0 was set so that the liquid crystal layer thickness was thicker.

However, in this embodiment, the electrodes 7 of the reflective display unit 9 and the electrodes 7 of the transmissive display unit 10 are electrically insulated, as shown in FIG. An electrode pattern was prepared so that a voltage was separately applied to the electrode 7 of the reflective display unit 9 and the electrode 7 of the transmissive display unit 10 from the outside.

The phase difference compensating plates 16 and 17 and the polarizing plate 14 are provided outside the respective electrode substrates in the liquid crystal cell.
・ 15 was attached. In this embodiment, the phase difference compensating plate 1
7 was constituted by one phase difference compensating plate, and the phase difference compensating plate 16 was constituted by two phase difference compensating plates. These phase difference compensating plates 1
The attachment directions of 6.17 and the polarizing plates 14 and 15 were determined according to the alignment direction (orientation direction) of the liquid crystal.

In this example, a liquid crystal display device was manufactured such that the twist alignment of the liquid crystal layer 1 (the twist angle (twist angle) of the liquid crystal alignment) was 70 degrees. The alignment treatment was performed by using a parallel alignment alignment film so that the liquid crystal alignment when no voltage was applied was parallel alignment, and performing a rubbing treatment so that the rubbing crossing angle was 250 degrees. The rubbing intersection angle is
The above definition shall be followed. Then, by introducing a liquid crystal composition having a positive dielectric anisotropy with a refractive index difference (Δn) of 0.065 between the electrode substrates in the liquid crystal cell for liquid crystal injection by a vacuum injection method, a liquid crystal layer is formed. 1 was formed. By such an alignment treatment and the action of the chiral additive added to the liquid crystal composition, as described above, the twist angle (twist angle) of the liquid crystal alignment can be made 70 degrees. The liquid crystal layer 1 thus oriented undergoes an orientation change according to the voltage from the liquid crystal at the center in the layer thickness direction of the liquid crystal layer 1 with the application of the voltage.

Table 2 shows the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 1 in the liquid crystal display device obtained in this example.
7, and the optical arrangement of the liquid crystal layer 1 (that is, the polarizing plate 14.1).
5 and the sticking directions of the phase difference compensating plates 16 and 17, and
Liquid crystal orientation) using a common orientation standard.

[Embodiment 6] In this embodiment, similarly to Embodiment 5, the transmissive display section 10 has a thickness of 7.5 μm and the reflective display section has the same structure as that of the liquid crystal cell for injecting liquid crystal of Embodiment 1. 9 was prepared to have a liquid crystal layer thickness (d) of 4.5 μm for liquid crystal injection. Also, as shown in FIG.
The electrode 7 of the reflective display unit 9 and the electrode 7 of the transmissive display unit 10 are electrically insulated, and a voltage is separately applied to the electrode 7 of the reflective display unit 9 and the electrode 7 of the transmissive display unit 10 from the outside. The electrode pattern was produced as follows.

Outside the respective electrode substrates in the liquid crystal cell, the phase difference compensating plates 16 and 17 and the polarizing plates 14 and 15 are provided.
Was affixed. In this embodiment, one phase difference compensating plate is used for each of the phase difference compensating plates 16 and 17. These phase difference compensating plates 16 and 17 and polarizing plate 14
The attachment direction of No. 15 was determined in accordance with the alignment direction (alignment direction) of the liquid crystal.

In this example, a liquid crystal display device was manufactured such that the twist alignment (twist angle of liquid crystal alignment (twist angle)) of the liquid crystal layer 1 was 90 degrees. Specifically, an alignment film having a parallel alignment is used for the alignment films 2 and 3 so that the liquid crystal alignment when no voltage is applied is a parallel alignment, and a rubbing process is performed so that the rubbing cross angle is 270 degrees. To perform an orientation treatment. Note that the rubbing intersection angle follows the above definition. Then, a difference in refractive index (Δ) between the electrode substrates in the liquid crystal cell for injecting liquid crystal.
n) by introducing a liquid crystal composition having a positive dielectric anisotropy of 0.065 by a vacuum injection method so that the liquid crystal layer 1
Was formed. By such an alignment treatment and the action of the chiral additive added to the liquid crystal composition, the twist angle (twist angle) of the alignment of the liquid crystal can be made 90 degrees as described above. The liquid crystal layer 1 thus oriented undergoes an orientation change according to the voltage from the liquid crystal at the center in the layer thickness direction of the liquid crystal layer 1 with the application of the voltage.

Table 2 shows the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 1 in the liquid crystal display device obtained in this example.
7, and the optical arrangement of the liquid crystal layer 1 (that is, the polarizing plate 14.1).
5 and the sticking directions of the phase difference compensating plates 16 and 17, and
Liquid crystal orientation) using a common orientation standard.

The optical arrangement shown in Table 2 is the arrangement of each optical element on the display surface when the observer observes the display surface, and the phase difference compensating plate 16 or 17 includes a plurality of phase difference compensating plates 17. In the case of being constituted by a phase difference compensating plate, the respective phase difference compensating plates constituting the phase difference compensating plates 16 and 17 are described in the order of actual arrangement from the observer side.

The orientation of the liquid crystal layer 1 (the orientation of the long axis of the liquid crystal molecules) is equal to the orientation of the rubbing process performed on the orientation film 2 on the substrate 4 side on the substrate 4 side.
It is equal to the direction of the rubbing process performed on the alignment film 3 on the substrate 5 side. However, when the orientation of the liquid crystal in contact with the alignment film 2 is traced to the alignment film 3 side, the liquid crystal is twisted to the left by 90 degrees. When the orientation of the liquid crystal is tracked in this way, when the rubbing orientation of the alignment film 2 is considered to be the orientation orientation of the substrate 4 (hereinafter abbreviated as the orientation orientation of the substrate 4), the rubbing of the orientation film 3 is performed. The azimuth is an azimuth that is 180 degrees inverted from the azimuth obtained by tracking the orientation of the liquid crystal according to the twist.
Hereinafter, the orientation direction on the substrate 5 side (hereinafter, abbreviated as the substrate 5 orientation direction) is defined as the liquid crystal orientation on the substrate 5 obtained by tracking the orientation of the liquid crystal from the substrate 4 orientation direction according to the twist.

Each direction in Table 2 represents a direction from a reference direction arbitrarily taken on the display surface in units of degrees.
The retardation of each phase difference compensator indicates a value for monochromatic light having a wavelength of 550 nm in units of nm.

[0208]

[Table 2] 9 and 10 show the display characteristics of the liquid crystal display devices obtained in Example 5 and Example 6, respectively. These display characteristics were measured by the same method as in Example 1. In each of the figures, the horizontal axis represents the effective value of the applied voltage, and the vertical axis represents the brightness (reflectance or transmittance). rate)
Is shown. Further, the transmittance of the transmissive display unit 10 to which both the polarizing plates 14 and 15 are not attached is set to 100%, and the reflectance of the reflective display unit 9 before attaching the polarizing plate 14 is set to 1%.
00%.

In FIG. 9, a curve 241 shows the voltage dependence of the reflectance of the reflective display section 9 with respect to the voltage between the electrodes 6 and 7 in the liquid crystal display device obtained in Example 5, and the curve 242 shows 14 shows the voltage dependence of the transmittance of the transmissive display unit 10 with respect to the voltage between the electrodes 6 and 7 in the liquid crystal display device obtained in Example 5.

As shown in FIG. 9, in the fifth embodiment, in a section where the applied voltage is 1.2 V or more, both the reflectance and the transmittance increase with an increase in the applied voltage. When the applied voltage is 1 V, the reflectance of the reflective display unit 9 is 3%, and the transmittance of the transmissive display unit 10 is 2%. When the applied voltage is 4 V, the reflectance of the reflective display unit 9 is 41%. The transmittance of the transmissive display section 10 was 40%.

In FIG. 10, a curve 251 represents the electrodes 6 and 7 in the liquid crystal display device obtained in the sixth embodiment.
Shows the voltage dependence of the reflectance of the reflective display unit 9 with respect to the voltage between the two. The curve 252 shows the transmissive display unit 10 with respect to the voltage between the electrodes 6 and 7 in the liquid crystal display device obtained in the sixth embodiment. Shows the voltage dependence of the transmittance of the sample.

As shown in FIG. 10, in the sixth embodiment, as in the fifth embodiment, in the section where the applied voltage is 1.2 V or more, both the reflectance and the transmittance increase as the applied voltage increases.
In the sixth embodiment, when the applied voltage is 1 V, the reflectance of the reflective display unit 9 is 3%, the transmittance of the transmissive display unit 10 is 2%, and when the applied voltage is 4 V, the reflectance of the reflective display unit 9 is 4%. The reflectance was 35%, and the transmittance of the transmissive display section 10 was 37%.

As described above, in each of the liquid crystal display devices obtained in Examples 5 and 6, the transmittance and the reflectance change as the voltage applied to the liquid crystal display device changes. Thus, both reflective display and transmissive display were possible.

Further, when visual observation was performed, in Examples 5 and 6, the same voltage was applied to the electrode 7 in the reflective display section 9 and the electrode 7 in the transmissive display section 10, and Even when the voltage applied to the liquid crystal layer 1 by the electrodes 6 and 7 is maintained in the reflective display unit 9 and the transmissive display unit 10 in the same manner, display is performed by the reflective display unit 9 and the transmissive display unit 10. It was confirmed that the change in lightness and darkness was the same, and no inversion of lightness and darkness of the display occurred. In this display, even if the intensity of the ambient light was changed during the observation, no change was observed in the display contents. That is, when the reflective display unit 9 performs dark display, the transmissive display unit 10 also performs dark display, and when the reflective display unit 9 performs bright display, the transmissive display unit 10 also performs bright display. Therefore, in the fifth embodiment,
In Example 6, even when the reflective display unit 9 and the transmissive display unit 10 were driven by using the same electrode 7 as shown in FIG. 1, no display inversion occurred.

Therefore, in each of the liquid crystal display devices of the fifth embodiment and the sixth embodiment, both of the reflective display unit 9 and the transmissive display unit 10 are compatible with the brightness of bright display and the contrast ratio. And the brightness of the display can be matched between the reflective display unit 9 and the transmissive display unit 10,
A display with excellent visibility can be realized. In each of the liquid crystal display devices of the fifth and sixth embodiments, since the contrast ratio in the transmissive display unit 10 exceeds the contrast ratio in the reflective display unit 9, the display quality is further improved, and the display quality is improved. Can be realized.

Further, in the sixth embodiment, compared with the fifth embodiment, the number of phase difference compensating plates to be used is small, the visibility is excellent, and the reflected light capable of high-resolution color display (color display) is obtained. A liquid crystal display device that uses both light and transmitted light for display can be provided at lower cost.

In the above-described embodiment, the liquid crystal display device which performs good reflection display and good transmission display by changing the liquid crystal layer thickness between the reflection display portion and the transmission display portion has been described. In the following description, a liquid crystal display device in which the liquid crystal layer thickness in the reflective display section is set to be equal to the liquid crystal layer thickness in the transmissive display section, and which performs good reflective display and good transmissive display will be described.

[Embodiment 3] In this embodiment, when the thickness of the liquid crystal layer in the reflective display section is equal to the thickness of the liquid crystal layer in the transmissive display section, the voltage applied to the reflective display section and the transmissive display section is changed. A liquid crystal display device that achieves good reflective display and good transmissive display by making the liquid crystal alignment different between the reflective display unit and the transmissive display unit will be described.

In the present embodiment, such a liquid crystal display device will be described.
FIG. 4 shows an example in which the liquid crystal layer thickness of the reflective display unit 9 and the transmissive display unit 10 are set to be equal in the liquid crystal display device using the retardation of the liquid crystal layer 1 for display using the liquid crystal layer 15 of FIG. With reference to FIGS. 11 to 16, description will be made using specific examples and comparative examples. However, the liquid crystal display device according to the present embodiment is not limited by the following examples.

[0220] For convenience of explanation, components having the same functions as those in Embodiments 1 and 2 are given the same reference numerals, and explanations thereof are omitted. The specific overall configuration of the liquid crystal display device according to the present embodiment is the same as that of the second embodiment except that the reflective display section 9 and the transmissive display section 10 are set to have the same liquid crystal layer thickness. Therefore, the description is omitted here.

In order to set the liquid crystal layer thickness in the reflective display section 9 and the transmissive display section 10 to be equal as shown in the present embodiment, for example, the insulating film 1 formed on the substrate 5
The electrode 7 may be directly formed on the substrate 5 without forming the electrode 1.

[Embodiment 7] In this embodiment, the insulating film 11 made of an insulating photosensitive resin is not formed on the substrate 5 in the embodiment 1 and the reflection display is performed as shown in FIG. The electrode 7 of the display unit 9 and the electrode 7 of the transmissive display unit 10 are electrically insulated, and the electrode 7 of the reflective display unit 9 and the transmissive display unit 1 are electrically insulated.
The same method as the method of manufacturing the liquid crystal cell for injecting liquid crystal of Example 1 was used, except that an electrode pattern was manufactured so that a voltage was separately applied to the 0 electrode 7 from the outside of the liquid crystal cell.
Both the reflective display unit 9 and the transmissive display unit 10 are 4.5 μm
A liquid crystal cell for liquid crystal injection having a liquid crystal layer thickness (d) of was prepared.

Then, a liquid crystal composition containing no chiral agent and having a refractive index difference (Δn) of 0.065 and having a positive dielectric anisotropy was added to the liquid crystal cell for liquid crystal injection. The liquid crystal layer 1 was formed by introduction by a vacuum injection method.

In each of the above liquid crystal cells, the phase difference compensating plates 16 and 17 and the polarizing plates 14 and 15 are provided outside the respective electrode substrates.
Was affixed. In this embodiment, the phase difference compensating plate 17 is
The phase difference compensating plate 16
Was composed of two phase difference compensating plates. The sticking directions of the phase difference compensating plates 16 and 17 and the polarizing plates 14 and 15 were determined according to the alignment direction (alignment direction) of the liquid crystal.

In this embodiment, the liquid crystal is oriented in the liquid crystal layer 1 in parallel to the substrates 4 and 5 (parallel to the display surface).
In addition to using a liquid crystal layer that is not twisted,
As a liquid crystal display system, a birefringence mode using the retardation of the liquid crystal layer 1 for display was used.

In this embodiment, retardation suitable for reflective display is used for the transmissive display section 10. Here, the reflection display unit 9 is set in the same manner as the reflection display unit 9 of Example 2 in the second embodiment, but the transmission display unit 10
Is different from Example 2 in that the thickness of the liquid crystal layer is set to be equal to that of the reflective display section 9. Therefore, in the present embodiment, the optical design is performed again in the second embodiment, and the optical arrangement of the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 17 are performed.
Is determined. In the present embodiment, the optical arrangement of the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 17 is set so that the dark display of the transmissive display unit 10 becomes good.

In this embodiment, as in the second embodiment, parallel alignment films are used for the alignment films 2 and 3 so that the liquid crystal is aligned parallel to the display surface when no voltage is applied. At the same time, the rubbing intersection angle of the alignment films 2 and 3 was set to 180 degrees to perform the alignment treatment.

In such an alignment treatment, the twist angle (twist angle) of the alignment of the liquid crystal is 0 degree, and the liquid crystal at the center of the liquid crystal layer 1 in the thickness direction of the liquid crystal layer 1 is oriented according to the voltage in response to the application of the voltage. Changes occur.

Table 3 shows the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 1 in the liquid crystal display device obtained in this example.
7, and the optical arrangement of the liquid crystal layer 1 (that is, the polarizing plate 14.1).
5 and the sticking directions of the phase difference compensating plates 16 and 17, and
Liquid crystal orientation) using a common orientation standard.

[Comparative Example 3] Here, a comparative example of the above-mentioned Example 7 will be described. In Comparative Example 3, in the liquid crystal display device shown in Example 7, the phase difference compensating plate 16 was constituted by two phase difference compensating plates, while the phase difference compensating plate 17 was constituted by one phase difference compensating plate. The liquid crystal display device was designed in the same manner as the liquid crystal display device shown in Example 7, except that the optical arrangement of the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 17 was set so that the bright display of the transmissive display section 10 was good. A liquid crystal display device was manufactured. The sticking directions of the phase difference compensating plates 16 and 17 and the polarizing plates 14 and 15 were determined according to the alignment direction (orientation direction) of the liquid crystal.

Also, in this comparative example, as in the case of the seventh embodiment, parallel alignment films are used for the alignment films 2 and 3 so that the liquid crystal is aligned parallel to the display surface when no voltage is applied. At the same time, the rubbing intersection angle of the alignment films 2 and 3 was set to 180 degrees to perform the alignment treatment.

In such an alignment treatment, the twist angle (twist angle) of the alignment of the liquid crystal is 0 degree, and the liquid crystal in the center of the liquid crystal layer 1 in the thickness direction of the liquid crystal layer 1 is aligned with the voltage in accordance with the voltage. Changes occur.

Table 3 shows the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 1 in the liquid crystal display device obtained in this comparative example.
7, and the optical arrangement of the liquid crystal layer 1 (that is, the polarizing plate 14.1).
5 and the sticking directions of the phase difference compensating plates 16 and 17, and
Liquid crystal orientation) using a common orientation standard.

[Embodiment 8] In this embodiment, in the liquid crystal display device shown in Embodiment 7, both the liquid crystal layer thickness (d) in the reflective display section 9 and the liquid crystal layer thickness (d) in the transmissive display section 10 are 7 0.5 μm, and the retardation suitable for transmissive display is used for the reflective display unit 9, and the optical arrangement of the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 17 is set so as to improve the reflective display. A liquid crystal display device designed similarly to the liquid crystal display device shown in Example 7 was manufactured.

More specifically, in this embodiment, the first embodiment
In this case, the insulating film 11 made of an insulating photosensitive resin is not formed on the substrate 5, and the electrodes 7 of the reflective display section 9 and the electrodes 7 of the transmissive display section 10 are electrically connected as shown in FIG. Example 1 except that the electrode patterns were electrically insulated, and the electrode patterns of the reflective display unit 9 and the transmissive display unit 10 were separately applied so that voltages were separately applied from outside the liquid crystal cell. The reflective display unit 9 and the transmissive display unit 10 are both 7.5 by the same method as the method of manufacturing the liquid crystal cell for liquid crystal injection.
A liquid crystal cell for liquid crystal injection having a liquid crystal layer thickness (d) of μm was prepared.

Then, a liquid crystal composition containing no chiral agent and having a refractive index difference (Δn) of 0.065 and having a positive dielectric anisotropy was added to the liquid crystal cell for liquid crystal injection. The liquid crystal layer 1 was formed by introduction by a vacuum injection method.

The phase difference compensating plates 16 and 17 and the polarizing plates 14 and 15 are provided outside the respective electrode substrates in the liquid crystal cell.
Was affixed. In this embodiment, the phase difference compensating plate 17 is
The phase difference compensating plate 16
Was composed of two phase difference compensating plates. The sticking directions of the phase difference compensating plates 16 and 17 and the polarizing plates 14 and 15 were determined according to the alignment direction (alignment direction) of the liquid crystal.

In this embodiment, the liquid crystal is oriented in the liquid crystal layer 1 in parallel to the substrates 4 and 5 (parallel to the display surface).
In addition to using a liquid crystal layer that is not twisted,
As a liquid crystal display system, a birefringence mode using the retardation of the liquid crystal layer 1 for display was used.

In this embodiment, the retardation suitable for the transmissive display is used for the reflective display section 9. Here, the transmissive display unit 10 is set in the same manner as the transmissive display unit 10 of the second embodiment in the second embodiment.
Is different from the second embodiment in that the thickness of the liquid crystal layer is set equal to that of the transmissive display section 10. Therefore, in the present embodiment, the optical design is performed again in the second embodiment, and the optical arrangement of the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 1 are performed.
7 are determined. In the present embodiment, the optical arrangement of the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 17 is set so that the reflection display becomes good.

In this embodiment, as in Embodiment 2, parallel alignment films are used for the alignment films 2 and 3 so that the liquid crystal is aligned in parallel with the display surface when no voltage is applied. At the same time, the rubbing intersection angle of the alignment films 2 and 3 was set to 180 degrees to perform the alignment treatment.

In such an alignment treatment, the twist angle (twist angle) of the alignment of the liquid crystal is 0 degree, and the liquid crystal in the center of the liquid crystal layer 1 in the thickness direction of the liquid crystal layer 1 is aligned with the voltage in accordance with the voltage. Changes occur.

Table 3 shows the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 1 in the liquid crystal display device obtained in this example.
7, and the optical arrangement of the liquid crystal layer 1 (that is, the polarizing plate 14.1).
5 and the sticking directions of the phase difference compensating plates 16 and 17, and
Liquid crystal orientation) using a common orientation standard.

The optical arrangement shown in Table 3 is the arrangement of each optical element on the display surface when the observer observes the display surface, and the phase difference compensating plate 16 or 17 includes a plurality of phase difference compensating plates 17. In the case of being constituted by a phase difference compensating plate, the respective phase difference compensating plates constituting the phase difference compensating plates 16 and 17 are described in the order of actual arrangement from the observer side.

Further, since the liquid crystal layer 1 is not twisted, the orientation of the entire liquid crystal layer 1 when no voltage is applied (the orientation of the long axis of the liquid crystal molecules) is described. And the direction of the rubbing process performed on the alignment film 2 on the substrate 4 side.

Each azimuth represents an azimuth from a reference azimuth arbitrarily taken on the display surface in degrees, and the retardation of each phase difference compensator represents a value for monochromatic light having a wavelength of 550 nm in nm.

[0246]

[Table 3] [Comparative Example 4] In this comparative example, in the liquid crystal display device shown in Example 7, the liquid crystal is oriented in the liquid crystal layer 1 in parallel to the substrates 4 and 5 (parallel to the display surface), and A liquid crystal display designed in the same manner as the liquid crystal display device shown in Example 7 except that a liquid crystal layer twisted at 70 degrees is used, and the polarization conversion action of the liquid crystal layer 1 by the twist alignment of the liquid crystal layer 1 is used for display. The device was made.

More specifically, in this comparative example, Example 1 was used.
In this case, the insulating film 11 made of an insulating photosensitive resin is not formed on the substrate 5, and the electrodes 7 of the reflective display section 9 and the electrodes 7 of the transmissive display section 10 are electrically connected as shown in FIG. Example 1 except that the electrode patterns were electrically insulated, and the electrode patterns of the reflective display unit 9 and the transmissive display unit 10 were separately applied so that voltages were separately applied from outside the liquid crystal cell. The reflective display unit 9 and the transmissive display unit 10 are both set to 4.5 by the same method as the method of manufacturing the liquid crystal cell for liquid crystal injection.
A liquid crystal cell for liquid crystal injection having a liquid crystal layer thickness (d) of μm was prepared.

The phase difference compensating plates 16 and 17 and the polarizing plate 14 are provided outside the respective electrode substrates in the liquid crystal cell.
・ 15 was attached. In this comparative example, the phase difference compensator 1
7 was constituted by two phase difference compensating plates, and the phase difference compensating plate 16 was constituted by two phase difference compensating plates. The sticking directions of the phase difference compensating plates 16 and 17 and the polarizing plates 14 and 15 were determined according to the alignment direction (alignment direction) of the liquid crystal.

Further, in this comparative example, the alignment films 2 and 3
By using an alignment film having a parallel alignment, and performing a rubbing process so that the rubbing crossing angle is 250 degrees, so that the liquid crystal alignment when no voltage is applied is a parallel alignment.
An orientation treatment was performed. Note that the rubbing intersection angle follows the above definition. The difference in refractive index (Δn) between the electrode substrates in the liquid crystal cell for liquid crystal injection is 0.065.
Was introduced by a vacuum injection method to form a liquid crystal layer 1. By such an alignment treatment and the action of the chiral additive added to the liquid crystal composition, as described above, the twist angle (twist angle) of the liquid crystal alignment can be made 70 degrees. The amount of the chiral additive is adjusted so as to obtain the above-mentioned twist angle. The liquid crystal layer 1 thus oriented undergoes an orientation change according to the voltage from the liquid crystal at the center in the layer thickness direction of the liquid crystal layer 1 with the application of the voltage.

In this comparative example, the product (Δn · d) of the refractive index difference (Δn) of the liquid crystal composition suitable for reflective display and the thickness (d) of the liquid crystal layer was used for the transmissive display section 10. Here, the reflective display unit 9 is set in the same manner as the reflective display unit 9 of Example 5 in the second embodiment, but the transmissive display unit 10
Is different from Example 5 in that the thickness of the liquid crystal layer is set equal to that of the reflective display section 9. For this reason, in this comparative example, the optical design is performed again in Example 5, and the optical arrangement of the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 17 are performed.
Is determined. In this comparative example, the optical arrangement of the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 17 was set so that the dark display of the transmissive display unit 10 was good.

Table 4 shows the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 1 in the liquid crystal display device obtained in this comparative example.
7, and the optical arrangement of the liquid crystal layer 1 (that is, the polarizing plate 14.1).
5 and the sticking directions of the phase difference compensating plates 16 and 17, and
Liquid crystal orientation) using a common orientation standard.

Comparative Example 5 In this comparative example, in the liquid crystal display device of Comparative Example 4, the polarizing plates 14 and 15 and the phase difference compensating plate 1 were used so that the bright display of the transmissive display section 10 was improved.
A liquid crystal display device designed in the same manner as the liquid crystal display device shown in Comparative Example 4 was prepared except that the optical arrangements of Nos. 6 and 17 were set. That is, in this comparative example, in the liquid crystal display device shown in Example 7, the optical arrangement of the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 17 is set so that the bright display of the transmissive display unit 10 is improved. In addition, the liquid crystal is provided on the liquid crystal layer 1 with the substrates 4.5.
Are oriented parallel to (parallel to the display surface), and
A liquid crystal layer having a twist of 70 degrees is used.
A liquid crystal display device designed in the same manner as the liquid crystal display device shown in Example 7 except that the polarization conversion effect of the liquid crystal layer 1 by the twist alignment was used for display.

Table 4 shows the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 1 in the liquid crystal display device obtained in this comparative example.
7, and the optical arrangement of the liquid crystal layer 1 (that is, the polarizing plate 14.1).
5 and the sticking directions of the phase difference compensating plates 16 and 17, and
Liquid crystal orientation) using a common orientation standard.

[Embodiment 9] In this embodiment, in the liquid crystal display device shown in Embodiment 8, the phase difference compensating plate 16 is constituted by two phase difference compensating plates, while the phase difference compensating plate 17 is constituted by one sheet. The liquid crystal layer 1 is composed of a substrate 4 and a liquid crystal layer.
A liquid crystal layer oriented parallel to 5 (parallel to the display surface) and twisted at 70 degrees was used, and the polarization conversion effect of the liquid crystal layer 1 due to the twist orientation of the liquid crystal layer 1 was used for display. Except for the above, a liquid crystal display device designed in the same manner as the liquid crystal display device described in Example 8 was manufactured.

More specifically, in this embodiment, the first embodiment
In this case, the insulating film 11 made of an insulating photosensitive resin is not formed on the substrate 5, and the electrodes 7 of the reflective display section 9 and the electrodes 7 of the transmissive display section 10 are electrically connected as shown in FIG. Example 1 except that the electrode patterns were electrically insulated, and the electrode patterns of the reflective display unit 9 and the transmissive display unit 10 were separately applied so that voltages were separately applied from outside the liquid crystal cell. The reflective display unit 9 and the transmissive display unit 10 are both 7.5 by the same method as the method of manufacturing the liquid crystal cell for liquid crystal injection.
A liquid crystal cell for liquid crystal injection having a liquid crystal layer thickness (d) of μm was prepared.

The phase difference compensating plates 16 and 17 and the polarizing plate 14 are provided outside the respective electrode substrates in the liquid crystal cell.
・ 15 was attached. In this embodiment, the phase difference compensating plate 1
7 was constituted by one phase difference compensating plate, and the phase difference compensating plate 16 was constituted by two phase difference compensating plates. These phase difference compensating plates 1
The attachment directions of 6.17 and the polarizing plates 14 and 15 were determined according to the alignment direction (orientation direction) of the liquid crystal.

In this embodiment, the liquid crystal layer 1 has a twist alignment (twist angle of liquid crystal alignment (twist angle)) of 70.
A liquid crystal display device was manufactured so as to have a suitable temperature. Specifically, an alignment film having a parallel alignment is used for the alignment films 2 and 3 so that the liquid crystal alignment when no voltage is applied is a parallel alignment.
A rubbing treatment was performed so that the rubbing crossing angle was 250 degrees, thereby performing an orientation treatment. Note that the rubbing intersection angle follows the above definition. Then, a liquid crystal composition having a positive dielectric anisotropy with a refractive index difference (Δn) of 0.065 between the electrode substrates in the liquid crystal cell for liquid crystal injection is introduced by a vacuum injection method. Thus, the liquid crystal layer 1 was formed. By such an alignment treatment and the action of the chiral additive added to the liquid crystal composition, as described above, the twist angle (twist angle) of the alignment of the liquid crystal is reduced to 7 °.
It can be 0 degrees. Incidentally, the chiral additive,
The addition amount is adjusted so as to obtain the above-mentioned twist angle. The liquid crystal layer 1 thus oriented undergoes an orientation change according to the voltage from the liquid crystal at the center in the layer thickness direction of the liquid crystal layer 1 with the application of the voltage.

Further, in this embodiment, the product (Δn) of the refractive index difference (Δn) of the liquid crystal composition suitable for transmissive display and the thickness (d) of the liquid crystal layer is obtained.
nd) was used for the reflective display section 9. Here, the transmissive display unit 10 is set in the same manner as the transmissive display unit 10 of Example 5 in the second embodiment, but the reflective display unit 9 has the same liquid crystal layer thickness as the transmissive display unit 10. Has been
This is different from the fifth embodiment. For this reason, in this embodiment,
In Example 5, the optical design was performed again, and the polarizing plate 1
The optical arrangements 4 and 15 and the optical arrangements of the phase difference compensators 16 and 17 are determined. In this embodiment, these polarizing plates 1
4 and 15 and the optical arrangement of the phase difference compensators 16 and 17
The reflection display was set to be good.

Table 4 shows the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 1 in the liquid crystal display device obtained in this example.
7, and the optical arrangement of the liquid crystal layer 1 (that is, the polarizing plate 14.1).
5 and the sticking directions of the phase difference compensating plates 16 and 17, and
Liquid crystal orientation) using a common orientation standard.

The optical arrangement shown in Table 4 is the arrangement of each optical element on the display surface when the observer observes the display surface, and the phase difference compensating plate 16 or 17 has a plurality of phase difference compensating plates 17. In the case of being constituted by a phase difference compensating plate, the respective phase difference compensating plates constituting the phase difference compensating plates 16 and 17 are described in the order of actual arrangement from the observer side. Each azimuth in Table 4 represents an azimuth from a reference azimuth arbitrarily taken on the display surface in units of degrees, and the retardation of each phase difference compensator shows a value for monochromatic light having a wavelength of 550 nm in nm.

[0261]

[Table 4] As described above, having a liquid crystal layer thickness (d) of 4.5 μm,
In the liquid crystal display devices according to Example 7 and Comparative Examples 3 to 5, the liquid crystal layer thickness is set so as to be suitable for reflective display. For this reason, in Example 7 and Comparative Examples 3 to 5,
The optical arrangement of the polarizing plate 14 and the phase difference compensator 16 relating only to the reflective display is set to be suitable for the reflective display. On the other hand, the liquid crystal layer thickness of the transmissive display section 10 is set to be different from the liquid crystal layer thickness of the transmissive display section 10 of the liquid crystal display device in each of the examples of the second embodiment. For this reason, in Example 7 and Comparative Examples 3 to 5,
The optical arrangement of the phase difference compensator 17 and the polarizing plate 15 was set in accordance with the optical characteristics of the transmissive display section 10 of each liquid crystal display device. That is, in Example 7 and Comparative Example 4, a liquid crystal display device capable of realizing good dark display was manufactured, and in Comparative Examples 3 and 5, liquid crystal display devices capable of realizing good bright display were manufactured. .

On the other hand, a liquid crystal layer thickness of 7.5 μm (d)
In the liquid crystal display devices according to the eighth and ninth embodiments, the thickness of the liquid crystal layer is set to be suitable for transmissive display. For this reason, in Example 8 and Example 9 described above, the polarizing plate 14, the phase difference compensating plate 16,
The optical arrangement of the phase difference compensating plate 17 and the polarizing plate 15 is set so as to be suitable for transmissive display. Accordingly, in the eighth and ninth embodiments, the display characteristics of the reflective display unit 9 are determined by the optical arrangement of the polarizing plate 14 and the phase difference compensating plate 16 set in accordance with the transmissive display.

The display characteristics of each of the liquid crystal display devices obtained in Example 7, Comparative Example 3, Example 8, Comparative Example 4, Comparative Example 5, and Example 9 are shown in FIGS. FIG.
These are shown in FIGS. These display characteristics were all measured using a microscope in the same manner as in Example 1. In each of the figures, the horizontal axis represents the effective value of the applied voltage, and the vertical axis represents the brightness (reflectance). Or transmittance). Also,
Transmissive display unit 1 without polarizing plates 14 and 15 attached together
The transmittance of 0 is assumed to be 100%, and the reflectance of the reflective display unit 9 before the polarizing plate 14 is attached is assumed to be 100%.

In FIG. 11, the curve 261 corresponds to the seventh embodiment.
Shows the voltage dependence of the reflectance of the reflective display unit 9 with respect to the voltage between the electrode 6 and the electrode 7 in the liquid crystal display device obtained in the above. The curve 262 represents the electrode 6 in the liquid crystal display device obtained in the seventh embodiment. 4 shows the voltage dependence of the transmittance of the transmissive display unit 10 with respect to the voltage between the electrode and the electrode 7.

As shown in FIG. 11, in the seventh embodiment, in the section where the applied voltage is 1 V to 3 V, the transmittance increases with an increase in the applied voltage, while the reflectivity shows that the applied voltage is 1 V to 2 V.
In the section of V, the voltage increases as the applied voltage increases, and thereafter decreases as the applied voltage increases. When the applied voltage is 1 V, the reflectance of the reflective display unit 9 is 3%, and the transmittance of the transmissive display unit 10 is 3%. When the applied voltage is 2 V, the reflectance of the reflective display unit 9 is 40%. The transmittance of the transmissive display unit 10 is 18%, the reflectivity of the reflective display unit 9 when the applied voltage is 3 V is 28%, and the transmissivity of the transmissive display unit 10 is 33%.
%Met.

In FIG. 12, a curve 271 represents the electrodes 6 and 7 of the liquid crystal display device obtained in Comparative Example 3.
Shows the voltage dependence of the reflectance of the reflective display unit 9 with respect to the voltage between the two. The curve 272 shows the transmission display unit 10 with respect to the voltage between the electrodes 6 and 7 in the liquid crystal display device obtained in Comparative Example 3. Shows the voltage dependence of the transmittance of the sample.

As shown in FIG. 12, in Comparative Example 3, in a section where the applied voltage is 1 V to 2 V, both the reflectance and the transmittance increase with an increase in the applied voltage. When the applied voltage is 1 V, the reflectance of the reflective display unit 9 is 3%, and the transmittance of the transmissive display unit 10 is 18%. When the applied voltage is 2 V, the reflectance of the reflective display unit 9 is 40%. The transmittance of the transmissive display section 10 was 40%.

In FIG. 13, a curve 281 corresponds to the eighth embodiment.
Shows the voltage dependence of the reflectance of the reflective display section 9 with respect to the voltage between the electrode 6 and the electrode 7 in the liquid crystal display device obtained in the above. The curve 282 shows the electrode 6 in the liquid crystal display device obtained in Example 8. 4 shows the voltage dependence of the transmittance of the transmissive display unit 10 with respect to the voltage between the electrode and the electrode 7.

As shown in FIG. 13, in the eighth embodiment, in the section where the applied voltage is 1 V to 2 V, the transmittance increases as the applied voltage increases, while the reflectivity increases when the applied voltage is 0.7 V.
After increasing with an increase in applied voltage in a section of 1.2 V to 1.2 V, the applied voltage temporarily decreases with an increase in applied voltage in a section of 1.2 V to 1.7 V, and thereafter, the applied voltage becomes 1. 7
In the section from V to 2.3 V, the voltage rises again as the applied voltage rises. When the applied voltage is 1 V, the reflectance of the reflective display unit 9 is 24%, and the transmittance of the transmissive display unit 10 is 3%.
When the applied voltage is 1.2 V, the reflectance of the reflective display unit 9 is 40%, and when the applied voltage is 1.7 V, the reflectance of the reflective display unit 9 is 3%. At this time, the reflectance of the reflective display unit 9 was 27%, and the transmittance of the transmissive display unit 10 was 39%.

In FIG. 14, a curve 291 corresponds to Comparative Example 4
Shows the voltage dependence of the reflectance of the reflective display unit 9 with respect to the voltage between the electrode 6 and the electrode 7 in the liquid crystal display device obtained in the above. The curve 292 represents the electrode 6 in the liquid crystal display device obtained in Comparative Example 4. 4 shows the voltage dependence of the transmittance of the transmissive display unit 10 with respect to the voltage between the electrode and the electrode 7.

As shown in FIG. 14, in Comparative Example 4, in the section where the applied voltage is between 1.2 V and 3 V, both the reflectance and the transmittance are increased as the applied voltage is increased. When the applied voltage is 1.2 V, the reflectance of the reflective display unit 9 is 3%, and the transmittance of the transmissive display unit 10 is 1%. When the applied voltage is 3 V, the reflectance of the reflective display unit 9 is 36%, transparent display section 10
Was 16%.

In FIG. 15, a curve 311 corresponds to Comparative Example 5.
Shows the voltage dependence of the reflectance of the reflective display unit 9 with respect to the voltage between the electrode 6 and the electrode 7 in the liquid crystal display device obtained in the step 3. The curve 312 represents the electrode 6 in the liquid crystal display device obtained in the comparative example 5. 4 shows the voltage dependence of the transmittance of the transmissive display unit 10 with respect to the voltage between the electrode and the electrode 7.

As shown in FIG. 15, in Comparative Example 5, in the section where the applied voltage is between 1.2 V and 3 V, both the reflectance and the transmittance increase as the applied voltage increases. When the applied voltage is 1.2 V, the reflectance of the reflective display unit 9 is 3%, the transmittance of the transmissive display unit 10 is 21%, and the applied voltage is 3 V.
, The reflectance of the reflective display unit 9 is 39%, and the transmissive display unit 1
The transmittance of 0 was 35%.

In FIG. 16, the curve 321 corresponds to the ninth embodiment.
Shows the voltage dependence of the reflectance of the reflective display unit 9 with respect to the voltage between the electrode 6 and the electrode 7 in the liquid crystal display device obtained in the above, and the curve 322 represents the electrode 6 in the liquid crystal display device obtained in Example 9. 4 shows the voltage dependence of the transmittance of the transmissive display unit 10 with respect to the voltage between the electrode and the electrode 7.

As shown in FIG. 16, in the ninth embodiment, in the section where the applied voltage is 1.2 V to 3 V, the transmittance increases as the applied voltage increases, while the reflectivity increases when the applied voltage is 0.1 V to 3 V.
In the section from 9 V to 1.7 V, the voltage temporarily decreases with an increase in applied voltage, and thereafter increases with an increase in applied voltage. When the applied voltage is 1.2 V, the reflectance of the reflective display section 9 is 7%, the transmittance of the transmissive display section 10 is 32%, and the reflection of the reflective display section 9 when the applied voltage is 1.7 V. Ratio is 3%, and the reflection display unit 9 when the applied voltage is 3 V
Was 37%, and the transmittance of the transmissive display section 10 was 36%.

As is clear from the above Examples and Comparative Examples, the liquid crystal display device using the polarizing plates 14 and 15 to change the polarization state of the liquid crystal layer 1 due to the polarization conversion action such as retardation and optical rotation for display. In the case where the liquid crystal layer thickness of the liquid crystal layer 1 was matched between the reflective display section 9 and the transmissive display section 10, the same voltage was applied to the electrode 7 in the reflective display section 9 and the electrode 7 in the transmissive display section 10. At this time (when the reflective display unit 9 and the transmissive display unit 10 are driven by a common voltage), as shown in Example 7 and Comparative Examples 3 to 5,
At the time of application of a voltage that allows the brightness of the bright display and the contrast ratio to be sufficiently compatible with each other in the reflective display unit 9, the compatibility between the brightness of the bright display and the contrast ratio of the transmissive display unit 10 is not sufficient. As shown in the figure, when a voltage is applied at which the brightness of the bright display and the contrast ratio can be sufficiently compatible in the transmissive display unit 10, the change in the brightness of the reflective display unit 9 and the transmissive display unit 10
Does not match the change in the brightness of the image, and the display is not good.

However, in each of the liquid crystal display devices obtained in Examples 7, 8 and 9, the electrode 7 in the reflective display section 9 and the electrode 7 in the transmissive display section 10 were used.
By applying different voltages to (the reflective display unit 9 and the transmissive display unit 10 are driven with different voltages), a favorable display can be obtained.

That is, in each of the liquid crystal display devices according to the above-described seventh to ninth embodiments, different voltages are applied to the electrode 7 in the reflective display unit 9 and the electrode 7 in the transmissive display unit 10. The transmissive display unit 10 is also used for the reflective display unit 9.
In this case, the brightness and the contrast ratio of the bright display can be compatible with each other, and the reflective display unit 9 and the transmissive display unit 1
It can be seen that the brightness of the display can be matched with 0, and a display with excellent visibility can be realized.

As a result of a comparison between the present embodiment and the second embodiment, a liquid crystal display device utilizing the polarization conversion action such as retardation and optical rotation of the liquid crystal layer 1 using the polarizing plates 14 and 15 for display is described. In order to make the brightness and contrast ratio of bright display compatible with both the reflective display unit 9 and the transmissive display unit 10, the layer thickness of the liquid crystal layer 1 in the transmissive display unit 10 should be larger than the layer thickness of the liquid crystal layer 1 in the reflective display unit 9. It turns out that setting a large value is effective.

This embodiment and the second embodiment are described.
In each of the embodiments, the liquid crystal display mode is such that the liquid crystal alignment in the state where no voltage is applied is parallel to the plane direction of the display surface. By using a liquid crystal material with different properties or using an alignment film with different properties from the exemplified alignment film,
It goes without saying that a vertical alignment mode or a hybrid alignment mode can be used.

Further, regardless of the liquid crystal display mode using the retardation or the optical rotation of the liquid crystal layer 1, the thickness of the liquid crystal layer affects the optical characteristics, and the thickness of the liquid crystal layer in the reflective display section 9 is reduced by the transmission display. It is needless to say that the present invention realizes good optical characteristics in all of the parts where the liquid crystal layer thickness is smaller than that of the part 10.

Further, Embodiment 4 and Embodiments 7 to 9
It can be seen that, when different voltages are applied to the reflective display unit 9 and the transmissive display unit 10 by the electrodes 6 and 7 (orientation mechanism), it is possible to display well. In this case, for example, in Example 4 and Example 7, it is possible to improve the display of the transmissive display unit 10 by sufficiently applying a voltage to the transmissive display unit 10. In each of the eighth and ninth embodiments, the voltage of the reflective display unit 9 is adjusted,
Good display becomes possible. Therefore, according to the present embodiment and the second embodiment, in addition to the method of changing the liquid crystal layer thickness between the reflective display unit 9 and the transmissive display unit 10, the voltage between the reflective display unit 9 and the transmissive display unit 10 It can be seen that good display can be realized by preparing a liquid crystal cell in advance so that can be changed.

[Embodiment 4] In the present embodiment, the alignment display direction (rubbing direction) on the substrate for determining the liquid crystal alignment, that is, the alignment processing direction of the alignment film provided on each electrode substrate is determined by the reflection display unit. A liquid crystal display device that realizes good reflective display and good transmissive display by changing the liquid crystal alignment between the reflective display unit and the transmissive display unit by changing the liquid crystal orientation between the reflective display unit and the transmissive display unit will be described.

In this embodiment mode, a so-called rubbing method is used to uniformly align the liquid crystal layer. In the present embodiment, in order to change the orientation direction of the alignment film provided on each electrode substrate between the reflective display portion and the transmissive display portion, the surface of the alignment film is covered with a photoresist or the like during the rubbing process of the alignment film. By doing so, it is possible to realize at least two types of liquid crystal alignment. According to the method, a liquid crystal alignment suitable for reflective display and a liquid crystal alignment suitable for transmissive display can be simultaneously realized, and as a result, it is possible to realize good reflective display and good transmissive display. Become.

Hereinafter, the liquid crystal display device according to the present embodiment will be described in more detail. For convenience of explanation, components having the same functions as those in the first to third embodiments are denoted by the same reference numerals. And description thereof is omitted.

First, FIG. 17 and FIGS. 18 (a) to 18 (e)
The alignment process of the substrate (electrode substrate 40) used in the liquid crystal display device according to the present embodiment will be described with reference to FIG.

First, as shown in FIG. 18A, the contact surface of the substrate 41 (corresponding to the substrate 4 after the formation of the electrode 6 or the substrate 5 after the formation of the electrode 7) with the liquid crystal layer 1 is formed. An alignment film material is applied (S1), and pre-baked (S1).
2) By performing curing (S3), an alignment film 42 (corresponding to the alignment film 2 or 3) is formed on the surface of the substrate 41 in contact with the liquid crystal layer 1.

Next, by subjecting the alignment film 42 to a rubbing treatment, an alignment treatment of the electrode substrate 40 provided with the alignment film 42 at the interface with the liquid crystal layer 1 on the substrate 41 is performed. At this time, in the present embodiment, first, as shown in FIG.
The rubbing screen is screened with the resist 43. In this case, first, a resist material for a rubbing screen is applied on the alignment film 42 (S4), and after prebaking (S5), a part of the alignment film 42 (first alignment processing region 42a) is exposed. To be,
UV mask exposure (S6), development (S7), curing (S8) are performed, and then the first alignment processing region 42
A rubbing process is performed on a (S9). Next, after cleaning the electrode substrate 40 after the rubbing treatment (S10), FIG.
As shown in FIG. 8C, the resist 43 is stripped (S11).

Subsequently, in order to realize a liquid crystal alignment different from the liquid crystal alignment in the first alignment processing region 42a,
As shown in FIG. 18D, the already rubbed portion (first alignment processing region 42a) is protected by a rubbing screen resist 44, and the rubbing process is performed on the unprocessed portion. In other words, a resist material for a rubbing screen is applied on the alignment film 42 from which the resist 43 has been removed (S12), and after prebaking (S13), an alignment process on the alignment film 42 other than the first alignment processing region 42a. UV mask exposure (S14) and development (S1) so that the region (the second alignment processing region 42b) is exposed.
5) The curing (S16) is performed, and then the first alignment processing region 4 is added to the second alignment processing region 42b.
A rubbing process is performed so that the processing direction is different from that of 2a (S17). Next, after cleaning the electrode substrate 40 after the rubbing treatment (S18), as shown in FIG. 18E, the resist 44 is peeled off (S19). As a result, the alignment film 42 that has been subjected to the alignment treatment in two different directions is provided.
(Orientation mechanism) was obtained.

As described above, in this embodiment, the alignment treatment patterned by the resist is performed twice or more. At this time, the processing direction is changed for each alignment process (in the above description, the two alignment processes are performed by the two alignment processes), so that at least two types of liquid crystal alignment (for example, the alignment direction). Different types of parallel orientations). In this way, by changing the orientation direction in at least one of the substrates (electrode substrates), the orientation of the reflective display unit 9 and the transmissive display unit 10 can be set independently, and good display can be achieved. It becomes possible.

Next, a liquid crystal display device which realizes different liquid crystal orientations in the reflective display portion 9 and the transmissive display portion 10 by the above-described method and uses the polarizing plates 14 and 15 will be described with reference to specific examples. Will be described. However, the liquid crystal display device according to the present embodiment is not limited by the following examples.

[Embodiment 10] In this embodiment, a liquid crystal display device was manufactured according to the method of manufacturing a liquid crystal display device shown in Comparative Example 5. Specifically, in the first embodiment, the insulating film 11 made of a photosensitive resin having an insulating property was not formed on the substrate 5 and, as shown in FIG. The electrodes 7 of the reflective display unit 9 and the electrodes 7 of the transmissive display unit 10 are electrically insulated from each other.
The reflective display unit 9 and the transmissive display unit 10 are manufactured in the same manner as the method of manufacturing the liquid crystal cell for injecting liquid crystal of Example 1 except that the electrode patterns are manufactured so that voltages are separately applied from the outside. But the liquid crystal layer thickness of both is 4.5 μm (d)
A liquid crystal cell for liquid crystal injection having a cell gap was prepared. The phase difference compensating plates 16 and 17 and the polarizing plates 14.1 are provided outside each electrode substrate in the liquid crystal cell.
5 was affixed. The phase difference compensator 16 and the phase difference compensator 17 were each composed of two phase difference compensators.

However, in this embodiment, FIGS.
18A to 18E, orientation division was performed at the time of the rubbing treatment of the orientation film 3 by the same method as the method shown in FIGS. That is, in this embodiment, the reflective display unit 9 and the transmissive display unit 10 rub the alignment film 2 on the substrate 4 side in the same direction, and rub the alignment film 3 (alignment mechanism) on the substrate 5 side. Rubbing was performed in different directions between the reflective display unit 9 and the transmissive display unit 10 so that the liquid crystal alignment directions were different between the reflective display unit 9 and the transmissive display unit 10.

In this embodiment, the reflective display section 9 includes:
A liquid crystal display mode that uses a twisted liquid crystal orientation that is parallel to the display surface (parallel to the substrates 4 and 5) is used, and the transmissive display unit 10 is parallel to the display surface (parallel to the substrates 4.5).
And a display mode utilizing untwisted liquid crystal alignment was used.

In the present embodiment, the liquid crystal layer 1 in the reflective display section 9 has a Δn · d of about 270 nm, the twist angle (twist angle) of the liquid crystal orientation is 70 degrees, and the liquid crystal layer in the transmissive display section 10 A liquid crystal display device in which Δn · d of the layer 1 was about 270 nm and the twist angle (twist angle) of the liquid crystal alignment was 0 ° was manufactured. As a result, the liquid crystal layer 1 communicating with the reflective display unit 9 and the transmissive display unit 10 is provided, and good display can be performed on both the reflective display unit 9 and the transmissive display unit 10 without changing the cell gap. A possible liquid crystal display was obtained.

Table 5 shows that the polarizers 14 and 15, the phase difference compensators 16 and 17 and the liquid crystal layer 1 in the reflective display section 9 and the transmissive display section 10 of the liquid crystal display device obtained in this example.
(I.e., the orientations at which the polarizing plates 14 and 15 and the phase difference compensators 16 and 17 are attached and the orientation of the liquid crystal) are shown using a common orientation standard.

The optical arrangement shown in Table 5 is the arrangement of each optical element on the display surface when the observer observes the display surface, and the respective phase difference compensators 16 and 17 constitute the respective phase difference compensators. The plates are described in the order of actual arrangement from the observer side. Each azimuth in Table 5 represents an azimuth from a reference azimuth arbitrarily taken on the display surface in units of degrees, and the retardation of each phase difference compensator indicates a value for monochromatic light having a wavelength of 550 nm in units of nm.

[0298]

[Table 5] Next, the operation of each optical element in the present embodiment will be described below. First, a case where no voltage is applied to the liquid crystal layer 1 will be described. In this case, the liquid crystal in the liquid crystal layer 1 is oriented in accordance with the orientation of the interface between the substrates in contact with the liquid crystal layer 1, that is, the orientation direction of the orientation films 2 and 3 provided on each electrode substrate. For example, in the tenth embodiment,
In the liquid crystal display device obtained in (1), when the chiral additive is not mixed into the liquid crystal composition, the reflective display portion 9 is twisted to the left by 70 degrees, and the transmissive display portion 10 is not twisted, and has a 0 degree twist alignment state. Has become.

For this reason, when no voltage is applied to the liquid crystal layer 1, in the reflective display section 9, Δn · d of the liquid crystal layer 1 becomes 2
When the thickness is set to about 70 nm, the liquid crystal layer 1 acts so that when circularly polarized light enters, it is converted into linearly polarized light and transmitted. Light incident on the liquid crystal layer 1 from the polarizing plate 14 side is converted into circularly polarized light by the phase difference compensating plate 16, further converted from circularly polarized light into linearly polarized light by the liquid crystal layer 1, reaches the reflecting film 8 and is reflected. . When the light reflected by the reflection film 8 is linearly polarized on the reflection film 8, the light is converted again into a transmission component of the polarizing plate 14, so that a voltage is applied to the liquid crystal layer 1 in the above-described liquid crystal display device. If not,
The display of the reflection display section 9 is a bright display.

When no voltage is applied to the liquid crystal layer 1, in the transmissive display section 10, Δn · d of the liquid crystal layer 1 becomes 25.
When it is set to about 0 nm to 270 nm, the liquid crystal layer 1
Act as a half-wave plate. That is, the circularly polarized light incident on the liquid crystal layer 1 becomes circularly polarized light orthogonal to the incident circularly polarized light. For example, when right circularly polarized light (clockwise circularly polarized light) is incident, the right circularly polarized light is changed to the left. When converted to circularly polarized light (left-handed circularly polarized light) and left circularly polarized light enters, the circularly polarized light is converted to right circularly polarized light. The light incident on the transmissive display unit 10 passes through the polarizing plate 15, is converted into circularly polarized light by the phase difference compensating plate 17, and is incident on the liquid crystal layer 1. Example 1 above
At 0, the circularly polarized light incident on the liquid crystal layer 1 from the phase difference compensator 17 is a substantially left-handed circularly polarized light. Converted to polarized light. In the phase difference compensating plate 16, the clockwise circularly polarized light is converted into linearly polarized light in the transmission axis direction of the polarizing plate 14, and the counterclockwise circularly polarized light is converted into linearly polarized light in the absorption axis direction. When no voltage is applied to the liquid crystal layer 1 in the device, the display of the transmissive display unit 10 is a bright display.

Next, a case where a voltage is applied to the liquid crystal layer 1 will be described. When a voltage is applied to the liquid crystal layer 1,
The liquid crystal in the liquid crystal layer 1 irrespective of whether it is the reflective display unit 9 or the transmissive display unit 10, depending on the voltage,
, And the polarization conversion effect is weakened accordingly. That is, since the circularly polarized light prepared by the phase difference compensators 16 and 17 passes through the liquid crystal layer 1 as it is, dark display is realized in both the reflective display unit 9 and the transmissive display unit 10.

In the tenth embodiment, the phase difference compensator 1
7, a retardation compensating plate having a retardation of 115 nm is used. In order to realize good circularly polarized light only with the phase difference compensator 17, the retardation of the phase difference compensator 17 is
It is desirable that the thickness is about 135 nm.
In the liquid crystal layer 1 of 0, since the retardation does not completely disappear at a practical voltage, the phase difference compensating plate 17 is provided so as to obtain a good contrast in consideration of the retardation.
Has been set.

[0303] The phase difference compensating plate 16 is
Has the function of converting the polarization state of light incident on the liquid crystal layer 1 into circularly polarized light having a wide wavelength. In the liquid crystal display device described above, the liquid crystal layer 1 in the reflective display section 9 is twisted at 70 degrees, and its Δn · d is set to 270 nm. For this reason, in the reflective display unit 9 in the above-described liquid crystal display device, light incident on the liquid crystal layer 1 is circularly polarized light, and this circularly polarized light is converted into linearly polarized light by the liquid crystal layer 1 and passes through the liquid crystal layer 1. The light reaches the reflection film 8. Then, the linearly polarized light on the reflection film 8 is reflected by the mirror surface of the reflection film 8, passes through each optical element in the reverse order, and finally passes through the transmission axis of the polarizing plate 14. Linearly polarized light having an oscillating electric field of Therefore, the reflective display section 9 provides a bright display.

Further, the liquid crystal composition used contains a chiral agent which causes a left-handed twist inherent in the alignment of the liquid crystal. The chiral agent changes the helical pitch specific to the liquid crystal composition mixed with the chiral agent depending on the amount of the chiral agent added. For this reason, the helical pitch is adjusted, and the voltage dependency of the brightness is matched between the reflective display unit 9 and the transmissive display unit 10 by utilizing the fact that the minimum voltage at which the liquid crystal alignment starts to change due to the helical pitch is changed. Becomes possible.

FIG. 19 shows the display characteristics of the liquid crystal display device according to the tenth embodiment thus manufactured. Note that the display characteristics shown in FIG. 19 were measured by the same method as in Example 1. The horizontal axis indicates the effective value of the applied voltage, and the vertical axis indicates the brightness (reflectance or transmittance).

In FIG. 19, the curve 331 corresponds to the first embodiment.
0 shows the voltage dependence of the reflectance of the reflective display unit 9 in the liquid crystal display device obtained in Example 10, and the curve 332 shows the voltage dependence of the transmittance of the transmissive display unit 10 in the liquid crystal display device obtained in Example 10. Show.

As can be seen from FIG. 19, the liquid crystal display device obtained in the tenth embodiment performs a bright display when no voltage is applied.
A display in a so-called normally white (NW) mode in which the reflectance and the transmittance decrease with the application of a voltage is realized. Further, in the above-described liquid crystal display device, the contrast ratio between the reflective display unit 9 and the transmissive display unit 10 can be set to approximately the same level, and the reflective display unit 9 and the transmissive display unit 1 can be set.
The brightness of the display can be matched with 0, and a display with excellent visibility can be realized.

As described above, as a specific means for changing the liquid crystal alignment between the reflective display unit 9 and the transmissive display unit 10, the twist angle of the liquid crystal layer 1 between the reflective display unit 9 and the transmissive display unit 10 is changed. Setting differently is effective for realizing good display in both the reflective display unit 9 and the transmissive display unit 10.

In the tenth embodiment, the reflective display unit 9
In order to change the twist angle of the liquid crystal layer 1 between the reflective display unit 9 and the transmissive display unit 10, a rubbing process in different directions is performed between the reflective display unit 9 and the transmissive display unit 10, and the liquid crystal layer 1 of the reflective display unit 9 is twisted. Although the combination in which the liquid crystal layer 1 of the transmissive display section 10 is not twisted is used, the means for changing the twist angle of the liquid crystal layer 1 between the reflective display section 9 and the transmissive display section 10 is, in particular, It is not limited.

For example, in addition to the above combination shown in Embodiment 10, (1) the liquid crystal layer 1 in the reflective display section 9 and the liquid crystal layer 1 in the transmissive display section 10 are both twisted, but the twist angle and the twist And (2) a combination in which the liquid crystal layer 1 in the reflective display unit 9 is not twisted but the liquid crystal layer 1 in the transmissive display unit 10 is twisted, and (3) A combination in which the inclination of the liquid crystal with respect to the substrates 4 and 5 (so-called pretilt) is different between the reflective display unit 9 and the transmissive display unit 10 may be used. Further, (4) the change of the liquid crystal alignment at the substrate interface may be combined with other means of the present invention, (5) the reflective display unit 9 and the transmissive display unit 10 have different cell gaps, (6) The reflective display unit 9 and the transmissive display unit 10 may have different electric fields.

[Embodiment 5] In each of Embodiments 2 to 4, good reflective display and good transmissive display can be obtained by using a liquid crystal display device in which liquid crystal is oriented in parallel with the substrate. I explained the configuration to realize it,
In the present embodiment, the first embodiment of the first embodiment is described.
Similarly, a liquid crystal display device in which the liquid crystal orientation direction is perpendicular to the substrate will be described. However, in the present embodiment, a design for performing display using birefringence or optical rotation (polarization conversion action) of liquid crystal using a polarizing plate without mixing a dichroic dye in the liquid crystal layer is performed. Was. For convenience of explanation, the same reference numerals are given to components having the same functions as those of the first to fourth embodiments, and description thereof will be omitted.

[0312] In the liquid crystal display device according to the present embodiment,
A liquid crystal having a negative dielectric anisotropy is used for the liquid crystal layer 1. In addition, a vertical alignment film that vertically aligns the liquid crystal is used as the alignment films 2 and 3 that sandwich the liquid crystal layer 1. In this case, when no voltage is applied to the liquid crystal layer 1, the liquid crystal molecules
The liquid crystal layer 1 is oriented almost perpendicular to the (display surface), but it is inclined with respect to the normal direction of the substrates 4 and 5 when voltage is applied, and passes in the normal direction of the layered liquid crystal layer 1. This produces a polarization conversion effect on light.

Alignment films 2 and 3 in which liquid crystal is aligned parallel to the substrate
The difference between the liquid crystal display device using the liquid crystal display device according to the present embodiment and the liquid crystal display device according to the present embodiment is that the liquid crystal display device according to the present embodiment does not require a voltage to be applied to the liquid crystal layer 1 at the interface with the electrode substrate. Up to this point, the liquid crystal is aligned in the normal direction of the substrates 4 and 5. Therefore, in order to make effective use of this, in this embodiment, an NB (normally black) mode is used for display, in which black display is performed when no voltage is applied. Specifically, the reflective display section 9 performs display by making the circularly polarized light incident on the liquid crystal layer 1. In the transmissive display unit 10,
Since the phase difference compensating plate 16 also used for the reflection display acts on the polarization of the light emitted from the liquid crystal layer 1, the liquid crystal layer 1
Is driven by an electrode pair that electrically connects the reflective display section 9 and the transmissive display section 10, and at the same time, in the transmissive display, the liquid crystal layer 1 is perpendicular to the substrates 4.5. Circularly polarized light enters the liquid crystal layer 1 in consideration of the orientation. For this reason, the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 15
In combination with the phase difference compensator 17, the retardation of the phase difference compensator arranged closer to the liquid crystal layer 1 among the plurality of phase difference compensators constituting the phase difference compensator 17 is set to 135 nm. Thereby, in the present embodiment, a good NB
Display can be realized.

Next, the polarizing plates 14 and 15 and the phase difference compensating plate 1
The setting of the liquid crystal layer 1 that gives a good bright display in the above-described combination with 6.17 will be described.

In the present embodiment, as described above, the liquid crystal layer 1 is oriented at an angle from the normal direction of the substrates 4 and 5 when a voltage is applied. When a sufficient voltage is applied to the liquid crystal layer 1, the liquid crystal layer 1 acts on the reflective display unit 9 so as to convert circularly polarized light into linearly polarized light. Desirably acts to convert circularly polarized light into reverse circularly polarized light. When the liquid crystal layer 1 has the above-described conversion function, a good bright display can be realized.

In order for the liquid crystal layer 1 to exhibit the above conversion action, for example, the alignment films 2 and 3 should be subjected to an alignment treatment so as not to cause twist in the liquid crystal, and no chiral additive should be used in the liquid crystal composition. Is desirable. That is, when the wavelength of the incident light is set to λ by applying a voltage to the liquid crystal layer 1, the retardation of the liquid crystal layer 1 is λ.
It is desirable that the liquid crystal layer 1 be set so as to change by / 4 and change by λ / 2 in the transmissive display section 10.

When the thickness of the liquid crystal layer 1 in the reflective display section 9 and the thickness of the liquid crystal layer 1 in the transmissive display section 10 are set to be different from each other, the liquid crystal layer 1 is required to perform the above-described conversion action. It is easy to set the layer 1 as described above.

Hereinafter, the liquid crystal display device according to the present embodiment will be described with reference to specific examples. However, the liquid crystal display device according to the present embodiment is not limited by the following examples. Absent.

[Embodiment 11] In this embodiment, the same method as that of the liquid crystal cell for injecting liquid crystal of Embodiment 1 is used.
A liquid crystal cell for injecting a liquid crystal having a different liquid crystal layer thickness between the reflective display section 9 and the transmissive display section 10 is manufactured. An alignment film was used. The alignment films 2 and 3 were subjected to an alignment process by rubbing so that the liquid crystal was slightly tilted from the normal direction (vertical direction) of the substrates 4 and 5.

However, in this embodiment, the liquid crystal layer thickness (d) in the reflective display section 9 is 3 μm, the liquid crystal layer thickness (d) in the transmissive display section 10 is 6 μm, and the refractive index difference (Δ
n) The liquid crystal layer 1 is formed using a liquid crystal having a negative dielectric anisotropy of 0.06, and the phase difference compensators 16 and 17 and the polarizing plates are provided outside each electrode substrate in the liquid crystal cell. 14 and 15 were pasted to produce a liquid crystal display device. The phase difference compensating plate 16 and the phase difference compensating plate 17 are respectively
It consisted of two phase difference compensators.

Table 6 shows that the polarizers 14 and 15, the phase difference compensators 16 and 17 and the liquid crystal layer 1 in the reflective display section 9 and the transmissive display section 10 of the liquid crystal display device obtained in this example.
(I.e., the orientations at which the polarizing plates 14 and 15 and the phase difference compensators 16 and 17 are attached and the orientation of the liquid crystal) are shown using a common orientation standard.

The optical arrangement shown in Table 6 is the arrangement of each optical element on the display surface when the observer observes the display surface. The plates are described in the order of actual arrangement from the observer side. Each azimuth in Table 6 indicates an azimuth from a reference azimuth arbitrarily taken on the display surface in units of degrees, and the retardation of each phase difference compensator indicates a value for monochromatic light having a wavelength of 550 nm in nm.

[0323]

[Table 6] FIG. 20 shows the display characteristics of the liquid crystal display device described in this example manufactured in this manner. Note that the display characteristics shown in FIG. 20 are measured by the same method as in Example 1. The horizontal axis indicates the effective value of the applied voltage, and the vertical axis indicates the brightness (reflectance or transmittance).

In FIG. 20, a curve 341 corresponds to the first embodiment.
1 shows the voltage dependence of the reflectance of the reflective display unit 9 in the liquid crystal display device obtained in Example 1, and the curve 342 shows the voltage dependence of the transmittance of the transmissive display unit 10 in the liquid crystal display device obtained in Example 11. Show.

As can be seen from FIG. 20, the liquid crystal display device obtained in Example 11 performs dark display when no voltage is applied.
A display in a so-called NB mode in which the reflectance and the transmittance increase with the application of a voltage is realized. In the above liquid crystal display device, the contrast ratio of the reflective display unit 9 and the transmissive display unit 10 can be set to substantially the same level, and the contrast of the display of the reflective display unit 9 and that of the transmissive display unit 10 match. And display with excellent visibility can be realized.

As described above, according to the present embodiment, in the liquid crystal display device according to the present invention in which the reflective display unit 9 and the transmissive display unit 10 simultaneously realize different liquid crystal alignments, By using an alignment means (vertical alignment film) for aligning the liquid crystal perpendicular to the substrate surface in contact with the liquid crystal (liquid crystal layer 1) in at least one of the display units 10, the reflective display unit 9, the transmissive display unit 10, Thus, it was confirmed that a transflective liquid crystal display device capable of performing good display was realized.

[Embodiment 6] In this embodiment, when the display is performed by changing the liquid crystal alignment with a voltage, the alignment state of the liquid crystal is changed on the display surface (substrate) in at least one of the reflective display portion and the transmissive display portion. A liquid crystal display device that performs display by changing the orientation of the liquid crystal while maintaining the state parallel to ()) will be described. That is, in the liquid crystal display device according to the present embodiment, the liquid crystal molecules rotate in at least one of the reflective display portion and the transmissive display portion in parallel with the display surface (substrate) by applying a voltage. .

Hereinafter, the liquid crystal display device according to the present embodiment will be described using specific examples. However, the liquid crystal display device according to the present embodiment is not limited to the following examples. Absent. Note that, for convenience of explanation, components having the same functions as those of the first to fifth embodiments are denoted by the same reference numerals, and description thereof is omitted.

[Embodiment 12] In this embodiment, an I-type liquid crystal display device used to realize a wide viewing angle in a transmission type liquid crystal display device is used.
By using PS (in-plane switching) mode for transflective liquid crystal, the liquid crystal molecules are rotated in parallel to the substrate by the lateral electric field in the in-plane direction to the substrate, and the liquid crystal display has an optical switch function. The device will be described below with reference to FIGS. 21 (a) and 21 (b).

Although the IPS mode itself has been used in the field of transmission type liquid crystal display devices,
Since the change in the liquid crystal alignment on the comb-shaped electrode used when using the S mode is insufficient for transmissive display, the liquid crystal alignment on the comb-shaped electrode did not contribute to the display, and good display could not be realized. However, according to this embodiment, a reflective display is realized in a region on the comb-shaped wiring which cannot be used in the conventional IPS system, and a transflective liquid crystal display device with high light use efficiency can be obtained.

FIG. 21A is a sectional view of a main part of the liquid crystal display device according to the present example when no voltage is applied.
FIG. 1B is a cross-sectional view of a main part of the liquid crystal display device shown in FIG. 21A when a voltage is applied. 21 (a) and 21 (b) show that the liquid crystal cell in the liquid crystal display device is formed by a plane perpendicular to the direction in which the electrode wiring (terminal) of the comb-shaped electrode provided in the liquid crystal cell extends. The cross section when cut is shown.

In the liquid crystal display device shown in FIGS. 21 (a) and 21 (b), the liquid crystal layer 1 has a light-transmitting substrate 51.
And a comb-shaped electrode 53 having light reflectivity (display content rewriting means, voltage applying means, alignment mechanism) and sandwiched by a substrate 54 having light reflectivity. On the side opposite to the surface facing the optical fiber 54), the phase difference compensating plate 16 and the polarizing plate 14 are provided.
Outside (that is, on the side opposite to the surface facing the substrate 51), the phase difference compensating plate 17 and the polarizing plate 15 are provided. In this embodiment, the phase difference compensating plate 16 is constituted by one phase difference compensating plate, and the phase difference compensating plate 17 is constituted by two phase difference compensating plates.

Also in this embodiment, the liquid crystal display device has a structure in which one of the substrates 54 (electrode substrate) provided between the liquid crystal layer 1
An insulative photosensitive resin is applied by spin coating, and furthermore, the transmissive display section 1 is irradiated by ultraviolet irradiation with a mask.
No insulating resin 11 (orientation mechanism) is formed in the reflective display section 9 so that the photosensitive resin is formed in a predetermined layer thickness. Thereby, the layer thickness of the liquid crystal layer 1 in the transmissive display section 10 is set smaller than the layer thickness of the liquid crystal layer 1 in the reflective display section 9.

In the liquid crystal display device according to the present embodiment, the insulating film 1 is formed on the glass substrate 52.
1, a comb-shaped electrode 53 (orientation mechanism) having light reflectivity is formed. The comb-shaped electrode 53 is connected to the liquid crystal layer 1.
Is a reflective pixel electrode which also serves as a liquid crystal drive electrode and a reflective film (reflecting means) for driving the pixel, and is made of a metal having a high light reflectance.

In the above liquid crystal display device, the transmissive display section 1
At 0, the alignment state of the liquid crystal molecules 1a changes due to the electric field applied by the comb-shaped electrode 53. In the reflective display section 9, the liquid crystal layer 1 is driven by the electric field generated by the comb-shaped electrode 53, and the reflection action of the comb-shaped electrode 53 is used for display.

In this embodiment, the wiring of the comb-shaped electrode 53 is used as the reflection means, but the comb-shaped electrode 53 has an uneven structure on its surface in order to impart light scattering. Alternatively, a film having light scattering properties may be further formed in a region facing the comb-shaped electrode 53 outside the glass substrate 51.

In the liquid crystal display device shown in FIGS. 21 (a) and 21 (b), the comb-shaped electrodes 53a.
Different potentials are applied to 53b, and an electric field is generated between the comb electrodes 53a and 53b. As shown in FIG. 21 (b), the transmissive display section 10 has comb electrodes 53a and 53b.
In this portion, the liquid crystal alignment is largely changed by the comb-shaped electrode pair (comb-shaped electrodes 53a and 53b) while keeping the orientation parallel to the glass substrate 52. In addition, the reflective display section 9 corresponds to a position immediately above the comb-shaped electrodes 53 (comb-shaped electrodes 53a and 53b). In this portion, the liquid crystal alignment not only changes the azimuth along the plane of the glass substrate 52 but also changes the orientation of the glass substrate 52. Also changes to the direction perpendicular to. This is as shown in FIG. 21 (b).
At 0, the lines of electric force (shown by broken lines in the figure) are
Extend substantially in parallel to the
This is because the lines of electric force have components perpendicular to the glass substrate 52.

[0338] Table 7 shows the polarizing plate 1 in the reflective display section 9 and the transmissive display section 10 of the liquid crystal display device according to this example.
4.15, the phase difference compensating plates 16 and 17, and the optical arrangement of the liquid crystal layer 1 (ie, the orientations of the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 17 and the orientation of the liquid crystal) are common. Are shown using the standard of

The optical arrangement shown in Table 7 is the arrangement of each optical element on the display surface when the observer observes the display surface. Each of the phase difference compensating plates constituting the phase difference compensating plate 17 is , The actual arrangement from the observer side.

The orientation of the liquid crystal layer 1 (liquid crystal molecules 1a
On the substrate 51 side is equal to the rubbing direction on the substrate 51 surface, and on the substrate 54 side is equal to the rubbing direction on the substrate 54 surface. Less than,
The orientation of the liquid crystal layer 1 on the substrate 51 side is the orientation of the substrate 51,
The orientation of the liquid crystal layer 1 on the substrate 54 is referred to as the orientation of the substrate 54.

Each azimuth in Table 7 represents the azimuth from a reference azimuth arbitrarily taken on the display surface in degrees, and the retardation of each phase difference compensator is 550 nm in wavelength.
Are shown in units of nm for monochromatic light.

Here, the direction in which the electrode wiring (terminal) of the comb-shaped electrode 53 extends is in the direction of 65 degrees, and the liquid crystal orientation is changed between the transmissive display section 10 and the reflective display section 9 with the application of voltage. The liquid crystal molecules 1a both oriented in the 75-degree direction changed to have an orientation larger than the 75-degree direction. Also,
In the liquid crystal display device, Δn · d of the liquid crystal layer 1 in the reflective display unit 9 is set to around 130 nm, and Δn · d of the liquid crystal layer 1 in the transmissive display unit 10 is set to around 240 nm.

[0343]

[Table 7] In the liquid crystal display device set as described above, when no voltage is applied to the liquid crystal layer 1, both the reflective display unit 9 and the transmissive display unit 10 perform dark display. When a voltage is applied to the liquid crystal layer 1 from this state, the liquid crystal molecules 1 a
Direction in which the third electrode wiring (terminal) extends (65 in the above setting).
Azimuth), the orientation azimuth changes.
Therefore, in the above liquid crystal display device, a bright display is realized by changing the orientation of the liquid crystal when a voltage is applied.

FIG. 22 shows the display characteristics of the liquid crystal display device according to the present example manufactured in this manner. FIG.
The display characteristics described in No. 2 were measured by the same method as in Example 1. The abscissa indicates the effective value of the applied voltage, and the ordinate indicates the brightness (reflectance or transmittance).

In FIG. 22, the curve 351 corresponds to the first embodiment.
2 shows the voltage dependency of the reflectance of the reflective display unit 9 in the liquid crystal display device obtained in Example 2, and the curve 352 shows the voltage dependency of the transmittance of the transmissive display unit 10 in the liquid crystal display device obtained in Example 12. Show. Incidentally, the reflective display section 9 includes a comb-shaped electrode 53.
Although there are differences in the optical characteristics depending on the position above, the optical characteristics of a typical portion are described here.

As can be seen from FIG. 22, in the liquid crystal display device obtained in the twelfth embodiment, when no voltage is applied, both the reflective display section 9 and the transmissive display section 10 perform dark display. In the liquid crystal display device, the reflectance and the transmittance increase with the application of the voltage. When the applied voltage is 2 V, the reflectance of the reflective display unit 9 and the transmittance of the transmissive display unit 10 are both 3%. When the applied voltage is 5 V, the reflectivity of the reflective display unit 9 is 35%. Display unit 10
Was 38%. Therefore, according to the above-described liquid crystal display device, both the reflective display unit 9 and the transmissive display unit 10 can achieve both the brightness of bright display and the contrast ratio, and provide a display with excellent visibility. Can be realized. Further, according to the liquid crystal display device described above, the contrast ratio in the transmissive display unit 10 exceeds the contrast ratio in the reflective display unit 9, so that the display quality can be further improved and good display can be performed.

As described above, according to the twelfth embodiment,
It has been confirmed that a reflective display is realized in a region on the comb-shaped wiring 53 that cannot be used for display in the conventional IPS system, and that a transflective liquid crystal display device with high light use efficiency can be obtained.

In the present embodiment, as a method of realizing the above-described liquid crystal alignment, a method using a ferroelectric liquid crystal display mode and a method using an anti- A method utilizing a dielectric liquid crystal display mode or the like can be used.

Therefore, in the following Example 13, a liquid crystal display device using a ferroelectric liquid crystal display mode for display will be described as another liquid crystal display device for realizing the above-described liquid crystal alignment.

[Embodiment 13] In this embodiment, in the liquid crystal display device shown in Embodiment 1, a surface-stabilized ferroelectric liquid crystal is used as a liquid crystal material, and the liquid crystal layer thickness (d) is 1 in the transmissive display section 10. 0.4 μm and 0.7 μm in the reflective display unit 9, and Δn · d of the liquid crystal layer 1 is 130 n in the reflective display unit 9.
m, it is set to about 260 nm in the transmissive display section 10, and instead of forming the reflective film 8 on the electrode 7 corresponding to the reflective display section 9, reflection is performed on an area corresponding to the reflective display section 9 as an electrode. A liquid crystal cell designed in the same manner as the liquid crystal cell shown in Example 1 except that electrodes were used was produced.

Specifically, on the substrate 5 (glass substrate),
No photosensitive resin remains in the transmissive display section 10 and the reflective display section 9
Then, an insulating film 11 is patterned and formed so that the photosensitive resin is formed to have a layer thickness of 0.7 μm, a reflective electrode is formed in a portion where the insulating film 11 is formed (reflective display portion 9), and the insulating film 11 is formed. A transparent electrode was formed in the formation section (transmission display section 10). Then, an alignment film 3 is formed on the electrode forming surface of the substrate 5.
By forming and subjecting the alignment treatment by rubbing,
An electrode substrate was manufactured. Note that the configuration of the electrode substrate (opposing substrate) disposed to face the electrode substrate is the same as that described in the first embodiment. Then, a ferroelectric liquid crystal composition containing the surface-stabilized ferroelectric liquid crystal is introduced between the two electrode substrates to form a liquid crystal cell, and a phase difference compensating plate 16 is provided outside each electrode substrate in the liquid crystal cell. No. 17 and polarizing plates 14 and 15 were attached to produce a liquid crystal display device. In this embodiment,
The phase difference compensating plate 16 was constituted by one phase difference compensating plate, and the phase difference compensating plate 17 was constituted by two phase difference compensating plates.

Table 8 shows the polarizing plates 14 and 15 and the phase difference compensating plates 16 and 1 in the liquid crystal display device obtained in this example.
7, and the optical arrangement of the liquid crystal layer 1 (that is, the polarizing plate 14.1).
5 and the sticking directions of the phase difference compensating plates 16 and 17, and
The liquid crystal orientation directions for bright display and dark display) are shown using a common orientation standard.

The optical arrangement shown in Table 8 is the arrangement of each optical element on the display surface when the observer observes the display surface. , The actual arrangement from the observer side. Each azimuth in Table 8 represents an azimuth from a reference azimuth arbitrarily taken on the display surface in units of degrees, and the retardation of each phase difference compensator indicates a value for monochromatic light having a wavelength of 550 nm in nm.

[0354]

[Table 8] The liquid crystal display device manufactured in this manner was a liquid crystal display device having good brightness and contrast ratio in both the reflective display unit 9 and the transmissive display unit 10.

As described above, in a liquid crystal display device which simultaneously realizes different liquid crystal alignment and liquid crystal layer thickness in the reflective display section 9 and the transmissive display section 10, the liquid crystal layer 1 by applying a voltage can be used.
Even if the orientation change direction changes in the plane of the liquid crystal layer, a favorable display can be obtained as the transflective liquid crystal display device of the present invention. And, the liquid crystal display device is IP
When using the S mode, the IPS
It is possible to improve the light use efficiency as compared with the conventional transmission type liquid crystal display device using the mode. Further, the above-described liquid crystal display device according to the present embodiment can be used in a mode such as a ferroelectric liquid crystal.

[Embodiment 7] In this embodiment, a description will be given of a specific element substrate and a color filter substrate for active matrix driving which enable the configuration of the liquid crystal display device according to the present invention.

When manufacturing the liquid crystal display device according to the present invention for the purpose of image display, the ratio between the transmissive display portion and the reflective display portion is determined by the frequency of use between the transmissive display portion and the reflective display portion. It is practically important to design according to.

That is, in the first mode of use, similarly to the currently used transmissive liquid crystal display device, the transmitted light from the illuminating device (backlight) as the background illuminating means is used for main display, and the reflective display portion is used. Is used for preventing washout (hereinafter, abbreviated as transmissive semitransparent).

In the second mode of use, the reflective display is mainly used for display. The backlight which consumes a large amount of power is frequently turned off depending on the situation to reduce the power consumption and to illuminate the surrounding area. When the display content cannot be confirmed only by reflection display due to weak light, the backlight is turned on and used (hereinafter, referred to as semi-transmission with reflection).

In these two modes of use,
Because the main display is different from the transmissive display or the reflective display, the ratio of the display area between the transmissive display unit and the reflective display unit and the color filter color design for color display are different. become.

First, a transmissive-dominant semi-transmissive liquid crystal display device that mainly transmits light will be described below, taking as an example a liquid crystal display device using a TFT element, which is one of the active matrix systems, for display. . For convenience of explanation, components having the same functions as those in the first to sixth embodiments are given the same reference numerals, and the description thereof is omitted.

First, the substrate structure of a transmissive-dominant transflective liquid crystal display device using a TFT element for display will be described with reference to FIG.
This will be described below with reference to FIGS.

FIG. 23A shows a TF for realizing a transmissive-dominant transflective liquid crystal display device according to the seventh embodiment.
FIG. 23B is a plan view of a principal part of the T element substrate, and FIG.
Reflection display section 9 in TFT element substrate shown in FIG.
FIG. 23C is a view showing the drive electrode 19 (see FIGS. 1, 4, 24, and 25). FIG.
FIG. 3 is a diagram showing a transparent pixel electrode 20 on the FT element substrate.

FIG. 24 shows the TFT shown in FIG.
FIG. 23 is a cross-sectional view taken along line AA ′ of the element substrate. More specifically, the TFT element substrate shown in FIG. It is a figure shown by the section which passes through part 26. Further, FIG. 25 is a cross-sectional view of the TFT element substrate shown in FIG.
FIG. 3 is a cross-sectional view taken along a line −B ′, showing a cross-sectional structure of a boundary portion between adjacent pixels.

The pixel electrode 18 for driving the liquid crystal layer 1 (see FIGS. 1 and 4) is shown in FIG. 23 (a), FIG. 24 and FIG.
As shown in FIG. 5, the reflective display section 9 includes a drive electrode 19 (display content rewriting means, voltage applying means) and a transparent pixel electrode 20 made of ITO (display content rewriting means, voltage applying means). The drive electrode 19 may be a reflective electrode having reflectivity. In addition, the driving electrode 19 and the transparent pixel electrode 20 may be electrically connected to each other when the liquid crystal display method used for display is a display method that does not show light / dark inversion even when displaying at the same voltage. .

The driving electrode 19 and the transparent pixel electrode 20 are connected to a drain terminal 22 of a TFT element 21 for controlling a voltage used for display for each pixel. The driving electrode 19 has an opening 19a for transmission display,
When the drive electrode 19 is a reflective electrode, the area where the transmission display opening 19a is formed is used as the transmission display section 10 for transmission display.

In the lower layer of the drive electrode 19, a TFT element 21, wirings 23 and 24, an auxiliary capacitance section 26 and an auxiliary capacitance line 27 are arranged. However, since a material having a light-shielding property such as a metal is used for these components,
In the present embodiment, the TFT element substrate is manufactured so that these components are not arranged in the transmissive display opening 19a. In FIG. 23A, the drive electrode 19 is indicated by a two-dot chain line.

Also, as shown in FIG.
The main part of the drive electrode 19 of the reflective display section 9 is formed with the wirings 23 and 24 for driving the TFT element 21 and the TFT element 21. The surface of the substrate 19 (the TFT element substrate surface) is separated by the organic insulating film 25. The organic insulating film 25 is formed of an organic insulating material having a low dielectric constant and has a thickness of 3 μm.
This is because the parasitic capacitance component formed between the pixel electrode 18 and the wiring 23 serving as the gate wiring of the TFT element 21 or the wiring 24 serving as the source wiring of the TFT element 21 is different from the TFT element 2.
The liquid crystal display device according to the present embodiment is for preventing a gate signal waveform and a source signal waveform for controlling the opening / closing operation of the first device from being delayed or distorted, thereby enabling a high-resolution dot matrix display. This is to improve the optical characteristics of the reflective display unit 9 and the transmissive display unit 10 in.

The pixel electrode 18 is connected to the TFT element 2
1 drain terminal 22. The drain terminal 22 is an n + -doped n + amorphous silicon layer and functions as a drain electrode of the TFT element 21. In the TFT element substrate according to the present embodiment,
I which is arranged to be in contact with this drain terminal 22
The TO electrode is used as the transparent pixel electrode 20, and the drive electrode 19 of the reflective display unit 9 is formed on the organic insulating film 25 patterned so as to cover a part of the transparent pixel electrode 20.
Are formed. That is, in the transmissive-dominant transflective liquid crystal display device using the TFT element substrate shown in FIG. 24, the transparent pixel electrode 20 used for transmissive display and the drive electrode 19 used for reflective display are formed of an organic insulating film Are electrically connected at the pattern boundary. The drive electrode 19 of the reflective display section 9 has a surface as shown in FIGS. 24 and 25 for the purpose of preventing the display surface from being mirror-finished.
Smooth irregularities may be formed.

As shown in FIG. 25, at the boundary between adjacent pixels on the TFT element substrate, the organic insulating film 25 is formed so as to cover the wiring 24 connected to the source terminal 28 of the TFT element 21. And the organic insulating film 2
The drive electrode 19 of the reflective display unit 9 is formed on the display 5.

The TFT element substrate thus manufactured is
By appropriately setting the relationship between the thickness of the organic insulating film 25 and the dielectric constant, a parasitic capacitance component formed between the pixel electrode 18 and the wirings 23 and 24 via the organic insulating film 25 can be suppressed. As shown in FIG.
It is possible to extend the drive electrode 19 of the reflective display section 9 to just above 4. In this case, it is possible to design the gap between the adjacent pixel electrodes 18 to be narrow, and in the pixel gap,
Since the leakage electric field from the wirings 23 and 24 to the liquid crystal layer 1 is reduced, the orientation of the liquid crystal layer 1 is hardly disturbed. Therefore, by appropriately setting the relationship between the film thickness of the organic insulating film 25 and the dielectric constant, the liquid crystal alignment of the liquid crystal layer 1 can be controlled to the vicinity of the boundary between the pixel electrodes 18, and so-called transmission with a high aperture ratio is achieved. A TFT element substrate of a main transflective liquid crystal display device can be manufactured. In the present embodiment, the organic insulating film 25
With an organic insulating material having a relative dielectric constant of 3.5 and a film thickness of 3 μm.
It formed so that it might become.

As described above, in this embodiment, the area available for transmissive display is 45% of the entire pixel area, and the area available for reflective display is 38% of the entire pixel.
An FT element substrate was manufactured. The TFT element substrate has an aperture ratio of about 50% in a transmissive display section of a transmissive TFT liquid crystal display device that has been widely used in the past, and
Since a substantially equal ratio of the transmissive display unit 10 is ensured, and the display light intensity of the reflective display unit 9 is added to the transmissive display light to perform display, the transmissive subject semi-transmissive with high use efficiency of light available for display. It can be said that it is a TFT element substrate of a liquid crystal display device of the type.

As described above, high light utilization efficiency can be realized in the present embodiment because the TFT elements 21
This is because it is possible to arrange components that do not transmit light, such as the wirings 23 and 24, the auxiliary capacitance portion 26, and the auxiliary capacitance line 27, and the light used for the liquid crystal display is impaired by these components. Because there is no.

Next, a color filter substrate used to face the TFT element substrate manufactured as described above is shown in FIG.
6 (a) and FIG. 26 (b).

The color filter substrate shown in FIG.
As shown in FIG. 26A and FIG. 26B, three color filters 61R and 61 of red (R), green (G), and blue (B) are provided.
G · 61B is formed. Each of the three color filters 61R, 61G, and 61B is formed of a photosensitive resin in which a pigment is dispersed, and is formed on a glass substrate 62 by a photolithography technique in the form of stripes matched to the pixels of the TFT element substrate. The colored layers are formed in a planar shape, and are formed separately for each color.

Further, on the surface of the glass substrate 62 on which the color filters 61R, 61G, and 61B are formed, FIG.
As shown in FIG. 6B, these color filters 61R.
A smoothing layer 501 made of a transparent acrylic resin is provided so as to cover 61G and 61B. On the smoothing layer 501, a counter electrode 502 (display content rewriting means, voltage applying means) of the pixel electrode 18 on the TFT element substrate has a thickness of 140 nm. IT
O is formed by sputtering using a shielding mask covering a region other than the predetermined region. Thus, the color filters 61R, 61G, and 61B are separated by a transparent region for each color.

FIG. 26 (a) shows the positional relationship of the color filter substrate and the TFT element substrate being superimposed on each other. The driving electrode 19 formed on the reflective display section 9 of the TFT element substrate is used for transmission display. The opening 19a (that is, the transmissive display unit 10) is completely covered by the R, G, and B stripe color filters 61R, 61G, and 61B, while the reflective display unit 9 has the color filter 61R of the drive electrode 19. Only the portion in the extending direction of 61G / 61B is covered with the color filters 61R / 61G / 61B, and the color filters 61R / 61G / 61B are covered.
The transparent region between the driving electrodes 1 formed on the reflective display unit 9
9 (the above color filters 61R and 61G)
(A part other than the 61B stretching direction).

FIG. 27 shows the arrangement of the reflective display section 9 and the transmissive display section 10 and the color filters 61R, 61G, and 61B in combination with the color filter substrate and the TFT element substrate. FIG. 27 shows a state where the color filter substrate and the TFT element substrate are overlapped with each other at a position to be used as a liquid crystal display device, and the color filter substrate and the TFT element substrate are cut at the position of CC ′ in FIG. C-C 'of the main part of the liquid crystal display device shown in FIG.
FIG.

As described above, the transmissive display section 10 has
Any of R, G, B color filters 61R, 61G,
61B are formed, and portions of the reflective display section 9 other than the extending direction of the color filters 61R, 61G, and 61B correspond to transparent areas between the color filters 61R, 61G, and 61B.

As a result, the same color filters 61R, 61G, and 61B as the color filters 61R, 61G, and 61B used for transmissive display act on a part of the reflective display section 9, and the remaining reflective display section 9 has a color filter. Filter 61R
61G and 61B do not work. As a result, color display (color display) can be performed with respect to the reflective display, and the reflectance required for the reflective display unit can be secured.

Incidentally, FIGS. 26 (a) and 26 (b)
The transmission color appearing in the light transmitted through the color filter substrate manufactured as shown in FIG. 7 is the same as the transmission color of R, G, B used in the transmission type liquid crystal display device for each pixel of R, G, B. Or may be appropriately adjusted according to the application.

The TF shown in FIG. 26 (a) and FIG.
In the combination of the T element substrate and the color filter substrate, all of the transmissive display sections 10
Display is performed by light passing through 61G and 61B, and the reflective display unit 9 performs display using the same color filters 61R, 61G, and 61B as the transmissive display unit 10, and the remaining portion performs color display. The display is performed without using the filters 61R, 61G, and 61B. This is because the color filters 61R, 61G, 61B of the transmissive display unit 10
This is because if the color filter 61R, 61G, and 61B are not used, the brightness is insufficient. Therefore, a portion not using the color filters 61R, 61G, and 61B is provided in the reflective display unit 9 to supplement the brightness.

Further, as in the present embodiment, in consideration of the fact that the display light passes through the color filters 61R, 61G, and 61B twice, the color filters 61R. Color filters 61R, 61G, and 61B having higher brightness than 61G and 61B may be provided.

In this embodiment, at least the color filter 61 is provided on the transmissive display section 10 in accordance with the purpose of use.
R, 61G, and 61B may be formed, and the reflective display unit 9 may have a region (part) where the color filters 61R, 61G, and 61B are not provided, and the color filters 61R, 61G, and 61B are provided only in the transmissive display unit 10. Alternatively, the reflective display unit 9 may be provided with no color filters 61R, 61G, and 61B.

The reflection display section 9 has color filters 61R and 6R.
In the case where 1G / 61B is not provided, the display voltage signal required for transmissive display is a signal suitable for color display, and the display voltage signal required for reflective display is a signal suitable for monochrome display. For this reason, for example, the ratio at which each pixel of R, G, and B contributes to lightness is proportional to the luminous transmittance (Y value) of each color in the transmissive display unit 10, but each pixel in the reflective display unit 9 is In this case, there is a problem in driving such that the values become completely equal.

That is, for example, when the brightness of the display is compared between the case where only the pixel B is in the bright display and the case where only the pixel G is in the bright display, the color filters 61R and 61
In the transmissive display unit 10 in which the G · 61B is arranged, the brightness differs in consideration of the luminous transmittance.
This is a problem that the brightness is the same in the reflective display unit 9 in which R, 61G, and 61B are not arranged.

As a method for preventing such a problem, a color filter 61R / 61G /
A method of changing the area of a region of the reflective display unit 9 where color display is not performed for each of the R, G, and B pixels in accordance with the Y value of each of the R, G, and B colors of the 61B. This allows
The contribution of the R, G, and B pixels to the brightness from the monochrome display of the reflective display unit 9 is adjusted by changing the area of the reflective display unit 9, and the brightness of the monochrome display based on the area of the reflective display unit 9 is adjusted. Can be reflected on the display luminance of each color.

The same effect can be obtained by designing the color filter coverage of the reflective display section 9 so as to be G, R, and B in ascending order. According to this method,
Further, there is an advantage that a slight green coloring seen in a normal polarizing plate can be corrected. In addition, when the color filter substrate and the TFT element substrate are arranged to overlap each other as shown in FIG. 26A, there is an advantage that the positional accuracy of the overlap between the TFT element substrate and the color filter substrate can be relatively large. . This is because the color filter non-formed portion of the reflective display unit 9 is present on both sides of one pixel, and when one of them increases due to positional displacement, the other decreases.

When the above-described TFT element substrate and color filter substrate are used, when transmissive display is performed, a conventional illuminating device (backlight) as a background illuminating means is used together with a conventional transmissive display TFT. The same display as the liquid crystal display device is possible, and further, even when the ambient light is very strong, the reflected light performs display close to the display content of the transmissive display, so that the display content can be confirmed, Even when the ambient light is strong, a high-resolution color liquid crystal display device with no washout and no parallax can be realized.

Next, the configuration of the TFT element substrate and the color filter substrate was changed so that the main use condition was used as a liquid crystal display device with low power consumption using reflected light of ambient light for display, and the intensity of ambient light was reduced. FIGS. 28, 29 (a) and 29 (b) show the substrate structure of a reflective-dominant transflective liquid crystal display device that uses transmissive display only when it is not sufficient.
This will be described below with reference to FIG.

FIG. 28 is a plan view of a principal part of a TFT element substrate for realizing a reflection-dominant transflective liquid crystal display device according to the seventh embodiment. Is shown. In FIG. 28, the driving electrode 1
9 is indicated by a two-dot chain line.

As shown in FIG. 28, in the reflection-dominant transflective liquid crystal display device, the size of the transmissive display opening 19a in the drive electrode 19 and the size of the transparent pixel electrode 20 are adjusted by the transmissivity-dominant transflectiveness. It has the same configuration as the above-mentioned transmissive-dominant semi-transmissive liquid crystal display device, except that it is set smaller than that of the TFT element substrate used in the liquid crystal display device of the type.

That is, also in the reflection-dominant transflective liquid crystal display device, the pixel electrode 18 for driving the liquid crystal layer 1 (see FIGS. 1 and 4) is driven to drive the reflection display section 9 as shown in FIG. Electrode 19 and transparent pixel electrode 20 made of ITO
The drive electrode 19 and the transparent pixel electrode 20 are connected to a drain terminal 22 of a TFT element 21 that controls a voltage used for display on a pixel-by-pixel basis. The driving electrode 19 has a transmission display opening 19a.
Is formed, and when the driving electrode 19 is a reflective electrode, the area for forming the transmission display opening 19a serves as the transmission display section 10 (see FIGS. 24, 25, and 27).
Used for transmissive display.

[0394] In the lower layer of the drive electrode 19, TF
T element 21, wiring 23 and wiring 24, auxiliary capacitance section 26
And an auxiliary capacitance line 27, and these components are arranged so as not to be arranged in the transmissive display opening 19a.

However, in the TFT element substrate shown in FIG. 28, the ratio of the transmissive display section 10 is smaller than that of the TFT element substrate used in the transmissive-dominant transflective liquid crystal display device shown in FIGS. It is set to be smaller and the ratio of the reflective display section 9 (see FIGS. 24, 25, and 27) becomes larger.

As described above, in the present embodiment, as the TFT element substrate for the reflective-dominant transflective liquid crystal display device, the area available for transmissive display is 13% of the area of the entire pixel.
%, And a TFT element substrate in which the area available for reflective display occupies 70% of the entire pixel was manufactured.

[0397] The ratio of the transmissive display portion 10 in the TFT element substrate for the above-mentioned transflective liquid crystal display device is 13%.
The ratio is smaller than the ratio of the transmissive display unit 10 in the TFT element substrate for the transmissive-dominant transflective liquid crystal display device. However, the reflection-dominant transflective liquid crystal display device using the TFT element substrate has a problem in that the transmission display is performed only when the display content cannot be confirmed by the reflection display.
Since the power consumption can be reduced by limiting the lighting time of a lighting device (backlight) as background lighting means, sufficient practicability can be ensured.

Next, the structure of a color filter substrate used in combination with this TFT element substrate will be described with reference to FIG.
This will be described below with reference to FIG.

As shown in FIGS. 29 (a) and 29 (b), the color filter substrate for the reflection-dominant semi-transmissive liquid crystal display device also has the transmission characteristics shown in FIGS. 26 (a) and 26 (b). Similarly to the color filter substrate for the main transflective liquid crystal display device, three color filters 61R and 61R of red (R), green (G), and blue (B) are formed on the glass substrate 62.
G · 61B are formed in a stripe shape, and these color filters 61R · 61G · 6 are formed on the surface of the glass substrate 62 on which the color filters 61R · 61G · 61B are formed.
A smoothing layer 501 made of a transparent acrylic resin is provided so as to cover 1B, and ITO is formed thereon by sputtering as a counter electrode 502 of a pixel electrode of a TFT element using a shielding mask covering a region other than a predetermined region. Is filmed.

However, the color filter substrate for the transflective liquid crystal display device shown in FIGS. 29 (a) and 29 (b) is the same as that shown in FIGS. 26 (a) and 26 (b). The color filters 61R, 61G, and 61B are set so that the planar shape and the spectral transmittance of each color are different from those of the color filter substrate for the transmission type liquid crystal display device.

More specifically, in a color filter substrate for a reflection-dominant transflective liquid crystal display device, the reflection display section 9 of the TFT element substrate is formed by color filters 61R, 61G, and 61B.
The color filters 61R and 6R are all covered with (colored layer).
1G / 61B is formed, and the color filter 61R / 61G / 61B applies display light to the color filter 61R / 61G / 61B twice in the reflective display unit 9 so as to show good display in reflective display. In consideration of the light passing through, the display light is supplied to the color filters 61R, 61G, and 61.
It is manufactured with high brightness so that it passes through B twice and has good brightness.

[0402] Therefore, in the reflective display section 9, good reflective display is realized by the combination of the TFT element substrate having a large proportion of the reflective display section 9 as described above and the color filter substrate adapted to the TFT element substrate as described above. I do.

In the transmissive display section 10, although the proportion of the transmissive display opening 19a is small, the combined use of an illuminating device (backlight) as a background illuminating means allows the transmissive display to be used only when ambient light is insufficient. Also on the display, the display contents can be confirmed. In this respect, the reflection-dominant transflective liquid crystal display device according to the present embodiment is different from the conventional reflection-type liquid crystal display device. When the transmissive display is performed by the color filters 61R, 61G, and 61B adjusted for reflective display, the display color of the transflective liquid crystal display device according to the present embodiment is insufficient, although the saturation is insufficient. Confirmation is possible.

Therefore, when performing color display with the above-mentioned semi-transmissive liquid crystal display device of the reflection main body, at least the color filters 61R, 61G, and 61B are provided at each reflection display portion in each pixel.
And color filters 61R, 61G, and 61B are not used in the transmissive display section 10, or the color filters arranged in at least a part of the transmissive display section 10 on the reflective display section 9 are provided. 61R ・ 61G ・ 61B
Color filters 61R and 61 having saturation equal to or higher than
It is particularly effective to dispose G · 61B.

As described above, in the reflection-dominant transflective liquid crystal display device, the color filters 61R, 61G, and 61B are formed at least in the reflection display section, and the transmission display section 10 is not provided with the color filters 61R, 61G, and 61B. It may be configured to have a region (part), and the transmissive display unit 10 does not use the color filters 61R, 61G, and 61B.
The transmissive display unit 10 may perform monochrome display. In the latter case, since the light transmittance increases, the transmission display unit 10 can be set smaller. This allows
A larger area of the reflective display section 9 can be secured,
A better display can be obtained in the reflection display during normal use.

In this case, similarly to the transmissive-dominant transflective liquid crystal display device, in the reflective-dominant transflective liquid crystal display device, the area of the display portion that does not perform color display, that is, in this case, transmissive display The area of the region in which the color display of the section 10 is not performed is determined by R of the color filters 61R, 61G, and 61B.
It may be changed for each of the R, G, and B pixels in accordance with the Y value of each of the G, B colors. That is, in order to properly set the contribution of the R, G, and B pixels to the brightness of the monochrome display of the transmissive display unit 10 in consideration of the luminous transmittance, each of the R, G, and B pixels is transparent. Each of the above substrates may be manufactured so that the ratio of the display area is different.

On the other hand, although the power consumption at the time of lighting the illumination device (backlight) as the background illumination means increases, the illumination light of the illumination device (backlight) is made sufficiently strong so that
It is also possible to use a high-saturation color filter adapted to the transmissive display in the transmissive display unit 10. In this case, not only the saturation but also the color reproducibility of the transmissive display can be ensured.
In any case, the lighting device (backlight)
Minimizing the lighting time is important to reduce power consumption.

As described above, according to the present embodiment, it is possible to reduce power consumption in normal use, to prevent the reflective display unit 9 from being washed out, and to reduce In addition, it is possible to realize a transflective liquid crystal display device which is capable of performing transmissive display using a background illumination means (backlight).

In the above description, the TFT element 21 is used as the switching element of the active matrix system, and the TFT element 21 is exemplified by a bottom gate type amorphous silicon TFT element. The switching element used in the embodiment is not particularly limited to this. For example, a polysilicon TFT element or a two-terminal element M
It may be an IM (Metal Insulator Metal) element or the like. Needless to say, it is not necessary to use these active elements.

In each of the liquid crystal display devices according to the present embodiment, as described above, a TFT element having a structure in which the drive electrode 19 serving as a display electrode and the wirings 23 and 24 are separated by the organic insulating film 25. By using a substrate, it is possible to change the thickness of the liquid crystal layer in the reflective display unit 9 and the transmissive display unit 10 by the thickness of the organic insulating film 25. In addition, in these liquid crystal display devices, even if the thickness of the organic insulating film 25 is set to a value of about 3 μm which enables high-capacity display in terms of wiring resistance and parasitic capacitance of the TFT element substrate, As described in the first and second embodiments, it is possible to obtain a liquid crystal layer thickness difference capable of sufficiently realizing good display in both the reflective display portion 9 and the transmissive display portion 10.

Therefore, by employing the TFT element substrate having the structure shown in FIG. 23A or FIG. 28 and the liquid crystal display system described in the first or second embodiment, a liquid crystal display capable of high capacity display is provided. The device can be realized.

Further, the TFT element substrate having the structure using the organic insulating film 25 as described above has already been partially put into practical use in a liquid crystal display device of a normal TFT element driving system only for transmissive display. Has few technical issues and is highly practical.

[0413] The inventors of the present application have studied the production of a reflective film having good reflection characteristics by imparting smooth unevenness to the reflective film for the purpose of preventing the display surface from being mirror-finished in the reflective liquid crystal display device. Are repeated. As a result, it has been found that a similar uneven surface can be produced also in the organic insulating film 25 used in the present invention, and the TFT for a transmissive-dominant transflective liquid crystal display device shown in FIGS. In the element substrate, irregularities are formed in a portion corresponding to the reflective display section 9.

As described above, in the present embodiment, the liquid crystal display device is used in two types, that is, a transmissive semi-transmissive type and a reflective semi-transmissive type. It has been described that the ratio of the display area between the transmissive display unit and the reflective display unit and the design of the color of the color filter in the case of color display are different depending on whether to perform the display or the reflective display.

Therefore, in the following embodiment 8, the ratio between the transmissive display section and the reflective display section in the liquid crystal display device according to the present invention will be described.

[Embodiment 8] The ratio between the transmissive display section and the reflective display section must be set in consideration of visibility.
Considering the phenomenon of human visual adaptation, the brightness perceived by the sight (perceived lightness) is calculated by Stevens et al. (“Brightness F
unction: Effect of Adaptation ”, Journalof the Op
tical Society of America, Vol. 53, No. 3, p375). According to this document, even when the human eye is looking at the same brightness, the perceived brightness depends on the adapted brightness, and there is a quantitative relationship there. I understand.

FIG. 30 shows the relationship between the adaptation luminance and the sample luminance, which are obtained by converting units from the literature of Stevens et al. And give equivalent perceived lightness of 5 to 45 bril. In FIG. 30, the horizontal axis represents the adaptation luminance (unit:
cd / m ² ), and the vertical axis indicates the luminance of the sample presented to the person (sample luminance (unit: cd / m ² )).

In FIG. 30, point A is the perceived brightness when a person who has adapted to an adaptation luminance of 1 cd / m ² observes a sample having a luminance surface of 10 cd / m ² , and point B is
Adaptation luminance of 1700 cd / m ² is 300 c
It represents the perceived lightness when observing a sample having a luminance plane of d / m ² . From FIG. 30, since the perceived brightness at point A and point B are the same value (9.4 brill),
It can be seen that the human perceived brightness is affected not only by the brightness of the display surface but also by the adaptation brightness.

Next, the adaptation of the viewer on the display surface of the liquid crystal display device will be considered. First, consider what the observer will adapt. When a person observes an object and adapts to the brightness of the object, the adaptation target is the luminance of the surface of the object to be viewed around the visual environment, and the surface of the object to be viewed is Generally depends on various environmental conditions. However, it is useful to consider the adaptation target as one index, that is, assume that the surface of the observation target is a reflection surface that reflects ambient light, and consider this case. The reason is that, whether indoors or outdoors, a person sees and adapts to the light source that is emitting light, compared to a situation where a person adapts to the reflective surface of an object illuminated by the light source. This is because it is natural to think that there is less. Hereinafter, the adaptation of the observer who adapts his / her vision to the reflection surface of the observation target will be considered.

[0420] When the luminance surface of the observation object is a reflection surface,
The adaptation luminance shown in FIG. 30 is a value obtained by multiplying the illuminance on the target surface by the illumination light source that illuminates the target surface to which the observer adapts, by a certain value. When the illuminance is L (unit: lux), and the luminance is B (unit: cd / m ² ), the luminance (B) of a surface having a reflectance of R with respect to a perfect diffuse reflection surface is represented by B = L × R / π. Here, the reflectance of the surface of the Munsell color chart N5, which is said to have the average reflectance of a normal human observation target, is used, and the surface of the Munsell color chart N5 illuminated by a certain illuminance is used. It is appropriate to consider the luminance as the adaptation luminance. In this case, R is 0.2.

Further, the illumination light source illuminating the surface of the Munsell color chart N5 which is a representative of the observation object is not only the adaptation object, that is, the surface of the Munsell color chart N5 but also the perceived lightness under the adaptation conditions. Assume that the target sample surface for which is evaluated is also illuminated at the same time. With this assumption, the perceived brightness of the reflective display unit when observing the liquid crystal display device is linked to the illuminance for illuminating the liquid crystal display device through the adaptation luminance. With this, based on the data of the psychophysical experiment,
It is possible to specifically select the reflectance and the ratio of the area of the reflective display unit.

According to the study by the inventors of the present application, a specific standard of perceived brightness can be translated into a brightness as shown in Table 9.
This actually reproduces some combinations of the adaptation luminance and the sample luminance, and concludes that such a lightness expression is appropriate, and is a measure of the setting of the reflective display unit based on the perceived lightness. .

[0423]

[Table 9] Here, the typical reflectance (R) of the reflection type liquid crystal display device
Is about 30% in the polarizing plate system, and the operation of the transflective liquid crystal display device according to the present invention will be described using this numerical value.

A straight line 601 shown in FIG.
5 shows the display operation of the liquid crystal display device in%. That is,
The illuminance of the illumination light source that illuminates the luminance plane to which the observer adapts is L
(Unit: lux), the adaptation luminance of the surface of the Munsell color chart N5 is the reflectance (R) of the surface of the Munsell color chart N5.
= 20%) affects the luminance (L / π) of the perfect diffuse reflection surface illuminated by the same illumination, so that 0.2 × L / π. Similarly, the reflectance illuminated by the same illumination is 3
The sample luminance of the display surface of the liquid crystal display device (target sample) of 0% is 0.3 × L / π. That is, the illuminance (L)
, And the horizontal axis is 0.2 L / π and the vertical axis is 0.3 L
A straight line obtained by plotting points satisfying the relationship of / π is a straight line 601. Further, similarly to the case where the above-described liquid crystal display device having a reflectance of 30% is a target sample, a liquid crystal display device having a reflectance of 10% is a target sample, and the horizontal axis is 0.2 L / π and the vertical axis is 0. A straight line obtained by plotting points satisfying the relationship of 1 L / π is a straight line 60.
2.

Next, the environment in which the above-mentioned liquid crystal display device having a reflectivity of 30% can be used will be considered below. In the brightest lighting conditions that people experience in everyday life, the illuminance of direct sunlight in fine weather (about 100,000 lux),
The adaptation luminance by the surface of the Munsell color chart N5 is about 6000c.
d / m ² . At this time, the perceived brightness of the display surface of the liquid crystal display device having a reflectance of 30% is as shown in FIG.
Straight lines 605 and 6 indicating an adaptation luminance of 6000 cd / m ²
The perceived lightness at the intersection with 01 is about 30 brill, and as shown in Table 9, the perceived dazzling value.
Further, the perceived lightness under a darker illumination is a lower value than the above-mentioned perceived lightness, and the illuminance that can secure the perceived lightness of 10 bril is obtained by back-calculating the above equation using the corresponding value of the adaptation luminance. , About 450 lux. In other words, if a bright display of 10 br or more and 30 br or less is required, the minimum illuminance is 450 lux and the maximum illuminance is 100,000 lux. (For example, a room with lighting of 450 lux or more) can be used, but in a darker place, the illuminance is not sufficient and perception is difficult.

The relationship between the adaptation luminance and the sample luminance when the reflectance is 50% is shown by a straight line 603 (FIG. 30). As can be seen from the straight line 603, when reflection display is realized with a reflectance of 50% or more, as in a normal white paper,
A perceived brightness of 30 brills in a high illuminance environment of 1800 lux or more (for example, a room near a bright window, under direct sunlight, etc.)
Will be exceeded. This indicates that white paper feels dazzling in such an environment. Therefore, it is inappropriate to use such a display surface having a reflectance of 50% or more in a high illuminance environment from the viewpoint of visibility, and when performing a reflective display in such an environment, the display surface ( It can be seen that the reflectance of the (luminance surface) is desirably about 30%.

On the other hand, in the reflection display at a reflectance of 30% and the reflection display at a reflectance of 10% represented by the straight lines 601 and 602, the illuminance giving a perceived brightness of 10 brills is about 450 lux and 3000 lux, respectively. It is. That is,
When the reflectivity becomes 1/3, it becomes necessary to provide 6.7 times brighter illumination. This means that if the illumination is increased because the reflectivity of the liquid crystal display device has dropped, the human eye must adapt to bright reflectors other than the liquid crystal display device and increase the illumination to the reciprocal of the change ratio of the reflectivity. Is generated.

Further, as can be seen from FIG. 30, display on a display having a constant luminance (for example, a general light-emitting display device) has a problem that it feels very dark especially when the surroundings are bright. are doing.

However, in the transflective liquid crystal display device according to the present invention, the constant luminance is determined by the background illumination light and the transmittance in the transmissive display unit, and the constant reflectance is determined by the reflective display unit. The sum with the luminance (sample luminance) is used for display. That is, in the transflective liquid crystal display device according to the present invention, for example, display with display luminance indicated by a curve 604 shown in FIG. 30 is realized. As shown by the curve 604, in the transflective liquid crystal display device according to the present invention, when the illuminance of illumination is high, visibility is ensured by reflective display, and when the illuminance of illumination is low, background illumination is used. Visibility can be ensured by transmissive display using a lighting device (backlight) as a means.

FIG. 31 shows the result of perceived brightness obtained by changing the illuminance using the display brightness of the transflective liquid crystal display device. As a comparison, FIG. 31 also shows the relationship between the illuminance and the perceived brightness in the transmissive liquid crystal display device, and the relationship between the illuminance and the perceived brightness in the reflective liquid crystal display device. Here, the calculation of the perceived lightness is such that the reflectance when the entire display area is a reflective color display is 30%,
The transmissivity when the entire display area is transmissive color display is 7.5
%, The backlight luminance is 2000 cd / m ² , the illuminance on the surface to which the observer has adapted is equal to the illuminance on the display surface of the liquid crystal display device, and the reflectance of the adaptation target surface is the Munsell color chart N
Assuming a lightness of 5, it was set to 20%.

In FIG. 31, the value of the perceived brightness when the illuminance is changed differs depending on the ratio (Sr) of the reflective display portion of the displayable area in the transflective liquid crystal display device. A curve 611 indicates the relationship between illuminance and perceived brightness in a normal transmissive liquid crystal display device that performs only Sr = 0, that is, only transmissive display and does not perform reflective display. The luminance of the display surface of the transmissive liquid crystal display device is 150 cd / m ² , and when the illuminance is about 6000 lux or more, the perceived brightness is 10 b / m ^2.
ril or less. Therefore, in order to secure a perceived brightness of 10 brill or more by changing a part of the transmissive display unit to the reflective display unit, as shown by the curve 612, Sr
= 0.1, that is, 1/10 of the displayable area needs to be used as the reflective display section.

A curve 613 is a curve showing the relationship between illuminance and perceived lightness in a reflective liquid crystal display device that performs only reflective display, that is, Sr = 1. The reflectivity of the display surface of the reflection type liquid crystal display device is 30% as compared with the perfect diffusion reflection surface.
When the illuminance is about 450 lux or less, the perceived brightness becomes 10 br or less. Therefore, in order to secure a perceived brightness of 10 brill or more by changing a part of the reflective display unit to the transmissive display unit, as shown by the curve 614, Sr = 0.9, that is, 1 in the displayable area. It is necessary to provide a transmissive display section having an area of / 10.

According to FIG. 31, the Sr value is in the range of 0.1 to 0.1.
At 0.9, the perceived lightness is 10 brill or more, 30 b
It can be seen that good display of less than ril can be performed, and when the above Sr is set to 0.30 (curve 615) or 0.50 (curve 616), the perceived brightness is not less than 20 bril and less than 30 bril. It turns out that a bright and favorable display can be performed.

In addition, surface reflection occurs on the surface of the liquid crystal display device. This display obstruction effect due to surface reflection is more remarkable as the surrounding illuminance is higher. FIG. 31 also shows the relationship between perceived lightness and illuminance due to this surface reflection (curve 617). Although the surface reflection is greatly affected by the surface treatment, the curve 617 indicates that the surface reflection generated at the interface between the medium having a refractive index of 1.5 and air has the same diffusivity as that of the perfect diffusion surface ( That is, the reflectance by surface reflection is 4%.
3) shows the relationship between the perceived lightness and the illuminance of the surface.
Therefore, considering the surface reflection, the area of the reflective display unit is:
It is preferable that the sum of the area of the reflective display section and the area of the transmissive display section is 30% or more (that is, Sr ≧ 0.3) in order to perform better display.

According to the above analysis, according to the present embodiment, when color display is performed by both the reflective display unit and the transmissive display unit, the reflection in the sum of the area of the reflective display unit and the area of the transmissive display unit is performed. It can be seen that good display can be performed when the area ratio of the display unit is 30% or more and 90% or less.

Note that even when color display is not used for at least one of the reflective display and the transmissive display, the area ratio of each display portion for performing a good display can be analyzed by the same method as described above. In any case, good display is realized when the ratio of the area of the reflective display unit to the sum of the area of the reflective display unit and the area of the transmissive display unit is within the above-described range. can do. still,
Both the transmissive-dominant transflective liquid crystal display device and the reflective-dominant transflective liquid crystal display device described in Embodiment 7 above
The ratio of the area of the reflective display unit to the sum of the area of the reflective display unit and the area of the transmissive display unit is manufactured at the above-described preferable ratio.

[Embodiment 9] In this embodiment, an active matrix type liquid crystal display device using the liquid crystal display method described in Embodiments 1 and 2 above, more specifically, a TFT element A liquid crystal display device that achieves color display using a substrate will be described with reference to specific examples. However, the liquid crystal display device according to this embodiment is not limited to the following examples.

[0438] The manufacturing process of the active matrix type liquid crystal display device according to this embodiment includes a process of manufacturing a TFT element substrate, a process of manufacturing a color filter substrate, and a process of using the TFT element substrate and the color filter substrate. A liquid crystal cell for injecting liquid crystal, and a step of injecting liquid crystal into the obtained liquid crystal cell for injecting liquid crystal to assemble it as a liquid crystal display device.

First, a method of manufacturing an active matrix liquid crystal display device according to each of the following examples in the present embodiment will be described in order from the step of manufacturing the TFT element substrate.

The TFT element substrate is shown in FIGS.
As shown in FIG. 7, a TFT element 21 is formed for each pixel on a light-transmitting substrate 29 by the following steps.

The substrate 2 on which the TFT element 21 is formed
As 9, a glass substrate made of non-alkali glass containing no alkali component was used. First, on the substrate 29, the wiring 23 as the gate wiring and the tantalum to be the auxiliary capacitance line 27 are formed by sputtering, and the wiring 23 and the auxiliary capacitance line 27 are formed by patterning. At this time, the wiring 23 and the auxiliary capacitance line 27 are patterned so that the level difference between the wirings (the wiring 23 and the auxiliary capacitance line 27) becomes gentle, and the wiring 24 and the auxiliary capacitance line 27 are formed on these wirings. Disconnection is prevented by improving the covering property.

Further, the wiring 23 and the auxiliary capacitance line 2
7 has a tantalum oxide (Ta ₂ O)
₅ ) A layer was formed, and a silicon nitride film serving as a gate insulating film was formed thereon. Further, the TFT element 21
A hydrogenated amorphous silicon layer as an intrinsic semiconductor layer (i-layer) serving as a switching region and a silicon nitride layer as an etching stopper layer are formed in this order by a chemical vapor deposition (CVD) method using monosilane gas and sputtering (nitriding). (Silicon). Next, after patterning the silicon nitride layer as the uppermost etching stopper layer, the TFT element 21 is formed by CVD using a monosilane gas mixed with a phosphine gas.
An n ⁺ layer serving as the source terminal 28 and the drain terminal 22 was formed. Next, the n ⁺ layer and the i layer were patterned, and further, the gate insulating film was patterned.
At this time, the silicon nitride in the connection terminal portion outside the display area in the wiring 23 (gate wiring) was also removed.

Next, ITO which becomes the transparent pixel electrode 20 is
A film was formed by sputtering so as to be in contact with the source terminal 28 and the drain terminal 22, and a tantalum film serving as the wiring 24 as a source wiring was formed by sputtering. This tantalum is patterned to form wiring 2
The transparent pixel electrode 20 was formed by patterning the ITO film formed thereunder. The transparent pixel electrode 20 is in contact with the source terminal 28 and the drain terminal 22 as described above, and also plays a role of forming ohmic contacts between these terminals (the source terminal 28 and the drain terminal 22) and the wirings 23 and 24. .

Next, an organic insulating film 2 having an uneven structure on its surface is formed on the TFT element 21 as an insulating film for a reflective display section.
5 is formed, and aluminum serving as a drive electrode 19 of the reflective display unit 9 is formed by sputtering so as to be in contact with the transparent pixel electrode 20 at a contact hole serving as a transmissive display opening provided in the organic insulating film 25. By patterning the obtained aluminum film by dry etching, a drive electrode 19 as a reflective electrode having an uneven structure similar to the uneven structure on the surface of the organic insulating film 25 was formed.

In each of the above-described patterning steps, each component is formed into a required shape based on a design by a photolithography technique. In the photolithography process, a photosensitive resin film (resist) coating / drying process, a pattern exposure process, a developing process, a resist baking / hardening process, a dry etching process, a wet etching process, and a resist peeling / removing process were used in combination.

The concave-convex structure formed on the reflective display section 9 was manufactured by applying an insulating photopolymerizable resin material and performing a pattern exposure step, a development step, and a curing step. That is, a dot-shaped pattern was formed in the developing step, and a smoothing layer was further formed on the dot pattern using the same material. The organic insulating layer 25
Are not formed on the transmissive display section 10.

[0447] On the TFT element substrate manufactured by the above-described steps, a TFT element 21 is provided for each pixel, and each pixel includes a reflective display section 9 and a transmissive display section 10. Here, two types of TFT element substrates, a TFT element substrate shown in FIG. 23A and a TFT element substrate shown in FIG. 28, are produced, and the ratio of the transmissive display section 10 to the reflective display section 9 is as described above. In the seventh embodiment, the ratio is set as described in the description of each liquid crystal display device.

Next, a process for manufacturing a color filter substrate will be described. The color filter substrate manufacturing process includes the steps of forming R, G, and B colored layers (color filters) on the substrate, forming a flattening layer on the color filters,
Forming a counter electrode facing the transparent pixel electrode 20 on the TFT element substrate side driven by the TFT element 21 on the flattening layer.

[0449] In this embodiment, the color filter substrate is provided on a glass substrate 62 with red (R), green (G), and blue (B) as shown in FIG. 26 (b) or 29 (b). 3) Color filters 61R, 61G, 61B
Are formed in a stripe shape, and a smoothing layer 501 is formed on the surface of the glass substrate 62 on which the color filters 61R, 61G, and 61B are formed so as to cover the color filters 61R, 61G, and 61B. 502
Was formed.

In the formation of the color filter substrate,
The color filters 61R, 61G, and 61B were formed by patterning a resin material in which a pigment was dispersed in a photosensitive resin by a photolithography method. In addition, as a method of manufacturing the color filters 61R, 61G, and 61B, a method other than the method using the above-described pigment dispersion, for example, an electrodeposition method, a film transfer method, and a dyeing method can be adopted.
There is no particular limitation.

The flattening layer 501 is formed by applying an acrylate resin having a high light transmittance on the surface of the glass substrate 62 on which the color filters 61R, 61G, and 61B are formed, and curing the resin by heat. The counter electrode 502 formed on the flattening layer 501 is a counter electrode facing the pixel electrode 18 driven by the TFT element 21. ITO is deposited as a transparent electrode through a mask by sputtering, and a necessary flat surface is formed. It was formed by shaping.

In the present embodiment, two types of color filter substrates, a color filter substrate with a high saturation set for transmissive display and a color filter substrate with a high brightness set for reflective display, are manufactured. did. Then, the color filter substrate in which the saturation is set high is shown in FIG.
A color filter substrate manufactured in a pattern shown in FIG. 26B and having a high brightness was manufactured in a pattern shown in FIGS. 29A and 29B.

Next, the TFT fabricated as described above
In order to manufacture a liquid crystal display device using an element substrate and a color filter substrate, a process for manufacturing a liquid crystal cell for injecting liquid crystal by arranging the TFT element substrate and the color filter substrate to face each other will be described.

In this step, first, the opposing surfaces of the TFT element substrate and the color filter substrate (the surface on which the TFT element 21 is formed on the TFT element substrate and the color filters 61R
A soluble polyimide solution was arranged by an offset printing method in the liquid crystal display area on the G / 61B forming surface), and an alignment film was formed through a drying and baking process. Further, the alignment film was subjected to an alignment treatment for determining a liquid crystal alignment direction by a rubbing method. It should be noted that whether the alignment film has a parallel alignment or a vertical alignment differs depending on each example described later.

Subsequently, spherical spacers having a uniform particle size are scattered on one of the TFT element substrate and the color filter substrate thus treated, and on the other side, a liquid crystal layer is sealed and the TFT element substrate and the color filter substrate are dispersed. An encapsulating sealant for fixing is printed, and a conductive paste for conducting the counter electrode 502 is disposed from the TFT element substrate side to the color filter substrate side.

The TF on the TFT element substrate is
The surface on which the T element 21 is formed and the surface on which the color filters 61R, 61G, and 61B of the color filter substrate are formed are arranged to face each other, the two substrates (the TFT element substrate and the color filter substrate) are aligned, and the sealing agent and the conductive material are pressed under pressure. The paste was cured.

Through the above steps, a mother glass substrate 21 on which a plurality of liquid crystal cells for liquid crystal injection were arranged was produced, and the mother glass substrate was cut to produce a cell for liquid crystal injection.

Thereafter, a liquid crystal composition was introduced into the liquid crystal cell without liquid crystal injection by a vacuum injection method, and a photopolymerizable resin was applied to the liquid crystal introduction port so that the introduced liquid crystal layer did not come into contact with the outside air. And polymerized and cured by ultraviolet light,
A liquid crystal cell was manufactured.

Next, in order to prevent electrostatic breakdown of the TFT element 21, the short ring portion disposed at the end of the TFT element substrate so as to short-circuit each wiring terminal is removed, and the TF is removed.
An external circuit for driving the T element 21 was connected. Further, a backlight serving as a light source for transmissive display was arranged to manufacture an active matrix liquid crystal display device according to the present embodiment.

[Embodiment 14] An active matrix type liquid crystal display device according to this embodiment uses a GH method.
The transmissive liquid crystal display device is a transflective liquid crystal display device, and uses the GH method in Example 1 of the first embodiment for display.

The liquid crystal composition used in this example was prepared in accordance with Example 1 of Embodiment 1. That is, in this example, the liquid crystal composition using the dichroic dye (dichroic dye 12) described in Example 1 was used. In this example, a vertical alignment film having a vertical alignment property was used as the alignment film, and an alignment process was performed by rubbing so as to obtain a uniform vertical alignment. In this example, since the GH method using a dichroic dye in the liquid crystal composition was adopted,
No phase difference compensator and polarizing plate were attached to the liquid crystal cell.

In this embodiment, since the transmissive display is mainly used, the color filters 61R, 61G, and 61B are designed to have high saturation similarly to the conventional color filter of the transmissive display system. They were arranged as shown in FIGS. 26 (a) and 26 (b). As shown in FIG. 23A, the TFT element substrate combined with the color filter substrate used was a TFT element substrate having a large transmissive display opening 19a and a wide transmissive display section 10.

In the liquid crystal display device according to this embodiment, as shown in FIGS. 26A and 26B, the drive electrode 19 in the reflective display section 9 is partially (the drive electrode 19 in the drive electrode 19). Color filter 61R / 61G / 61
The color filters 61R, 61G,
61B) is covered with the same color filters 61R, 61G, and 61B as the transmissive display opening 19a forming area to be the transmissive display section 10, and there is no color filter and a display that allows white light to pass therethrough. It also has a part.

[0464] A display signal was input to the liquid crystal display device manufactured as described above, and visual observation was performed. As a result, in the present embodiment, it was necessary to constantly turn on the backlight. However, when the backlight was turned on, both the brightness and the contrast ratio were good, and sufficient display was always possible. Further, the display contents could be visually recognized even under direct sunlight, and no washout occurred.

That is, in the present embodiment, a liquid crystal display device having high brightness is realized by a backlight in an environment where ambient light is weak, similarly to a conventional transmissive liquid crystal display device. Since the unit 9 changes the brightness in proportion to the ambient light, it is possible to confirm the display contents, and the washout that occurs in a conventional light emitting display device or a transmission type liquid crystal display device does not occur, and a high resolution color without parallax. A liquid crystal display device can be realized. In this embodiment,
Very good reflection display without parallax (double image) was realized.

[Embodiment 15] An active matrix type liquid crystal display device according to this embodiment employs a GH method.
The liquid crystal display device is a transflective liquid crystal display device mainly using reflection, and uses the GH method in Example 1 of Embodiment 1 for display.

In this example, as in Example 14, the liquid crystal composition was prepared in accordance with Example 1 of Embodiment 1. That is, also in this example, the liquid crystal composition using the dichroic dye (dichroic dye 12) described in Example 1 was used. In this example, a vertical alignment film having a vertical alignment property was used as the alignment film, and an alignment process was performed by rubbing so as to obtain a uniform vertical alignment. In this example, since a GH system using a dichroic dye in the liquid crystal composition was employed, no retardation compensator and polarizing plate were attached to the liquid crystal cell.

In this embodiment, since the reflective display is mainly used, the color filters 61R, 61G, and 61B are manufactured so as to have higher brightness than the color filters used in the conventional transmission type liquid crystal display device. The color filter substrates were arranged as shown in FIGS. 29A and 29B. TFT to be combined with this color filter substrate
As shown in FIG. 28, the element substrate is provided with an opening 1 for transmissive display.
9a is small and the reflective display section 9 is set large.
An element substrate was used.

A display signal was input to the above-mentioned liquid crystal display device manufactured as described above, and visual observation was performed. As a result, the above-described liquid crystal display device according to the present embodiment does not require the backlight to be turned on in daytime lighting and outside light environments,
Reflective display was possible. In this embodiment, a very good reflection display without parallax (double image) was realized. Also,
When the ambient light was so dark that observation by reflected light was impossible, the display contents could be viewed by turning on the backlight.

That is, in this embodiment, as described above,
Color filters 61R, 61G, 6 for reflection display
Since 1B and the color filter substrate are used, color display using only reflected light is possible. For this reason, it is possible to turn off the backlight in ordinary indoor lighting or outdoors in the daytime and use only the reflective display. Also,
By turning on the backlight as needed, visibility can be ensured even when the illumination is dark.

In the liquid crystal display device according to the present embodiment,
Unlike a conventional transmissive liquid crystal display device, it is not necessary to keep the backlight on all the time, it is possible to reduce power consumption, and it is possible to prevent the reflective display unit 9 from being washed out. Accordingly, transmissive display using a backlight can be performed.

[Embodiment 16] An active matrix type liquid crystal display device according to this embodiment is a transmissive-dominant semi-transmissive liquid crystal display device using the polarization conversion effect of a liquid crystal layer for display. This is a liquid crystal display device using the polarizing plate method in Example 5 of Example 2 for display.

The liquid crystal composition used in this example was prepared according to Example 5 of the second embodiment. Also,
In this embodiment, a phase difference compensating plate (phase difference compensating plates 16 and 17) is provided in a liquid crystal cell (TFT liquid crystal panel) into which liquid crystal is injected.
And polarizing plates (polarizing plates 14 and 15). Further, in the present example, the alignment treatment was performed on the alignment film having the parallel alignment by the rubbing method so that the rubbing crossing angle was 250 degrees.

In the present embodiment, as in the case of the fourteenth embodiment, since the transmissive display is mainly used, the color filter 61R
61G and 61B were designed to have the same transmission color as the conventional transmission display color filter, and the color filter substrates were arranged as shown in FIGS. 26 (a) and 26 (b). As shown in FIG. 23 (a), the TFT element substrate to be combined with the color filter substrate has a large transmissive display opening 19a and a wide transmissive display section 10 for the TFT element substrate.
An FT element substrate was used.

In the liquid crystal display device according to the present embodiment, as shown in FIGS. 26A and 26B, the drive electrode 19 of the reflective display section 9 is partially (the drive electrode 19).
, The color filters 61R, 61G, 61B in the direction in which the color filters 61R, 61G, 61B extend.
(A portion opposed to the color filter 61) is the same as the color filter 61 in the formation region of the transmissive display opening 19a to be the transmissive display portion 10.
It is covered with R, 61G, and 61B, has no color filter, and has a display portion that reflects white light.

A display signal was input to the liquid crystal display device manufactured as described above, and visual observation was performed. As a result, in the present embodiment, it was necessary to constantly turn on the backlight. However, when the backlight was turned on, both the brightness and the contrast ratio were good, and sufficient display was always possible. Further, the display contents could be visually recognized even under direct sunlight, and no washout occurred.

That is, in the present embodiment, a liquid crystal display device having high brightness is realized by a backlight in an environment where ambient light is weak, similarly to a conventional transmissive liquid crystal display device, while a reflective display is realized when ambient light is strong. Since the brightness is changed by the unit 9 in proportion to the ambient light, it is possible to confirm the display contents, and it is understood that the washout that occurs in the conventional light emitting display device or the transmission type liquid crystal display device does not occur. In this embodiment,
Very good reflection display without parallax (double image) was realized.

[Embodiment 17] The active matrix type liquid crystal display device according to this embodiment is a reflection-dominant transflective liquid crystal display device using the polarization conversion effect of a liquid crystal layer for display. This is a liquid crystal display device using the polarizing plate method in Example 5 of Example 2 for display.

In this example, as in Example 16, the liquid crystal composition was prepared in accordance with Example 5 of Embodiment 2. Also in this embodiment, a liquid crystal cell (TFT liquid crystal panel) into which liquid crystal is injected is provided with a phase difference compensator (phase difference compensators 16 and 17; see Example 5) and a polarizer (polarizers 14 and 15). Affixed. In this example, the alignment treatment was performed on the alignment film having the parallel alignment by the rubbing method so that the rubbing crossing angle was 250 degrees.

Also, in this embodiment, as in the case of the fifteenth embodiment, since the reflective display is mainly used, the color filter 61R
61G and 61B are manufactured so as to have higher brightness than the color filters used in the conventional transmissive liquid crystal display device, and the color filter substrate is made of FIG. 29 (a) and FIG.
They were arranged as shown in FIG. 9 (b). As shown in FIG. 28, a TFT element substrate combined with this color filter substrate was used in which the transmissive display opening 19a was small and the reflective display section 9 was large.

A display signal was input to the liquid crystal display device manufactured as described above, and visual observation was performed. As a result, the above-described liquid crystal display device according to the present embodiment does not require the backlight to be turned on in daytime lighting and outside light environments,
Reflective display was possible. In this embodiment, a very good reflection display without parallax (double image) was realized. Also,
When the ambient light was so dark that observation by reflected light was impossible, the display contents could be viewed by turning on the backlight.

That is, in this embodiment, as described above,
Color filters 61R, 61G, 6 for reflection display
Since 1B and the color filter substrate are used, color display using only reflected light is possible. For this reason, it is possible to turn off the backlight in ordinary indoor lighting or outdoors in the daytime and use only the reflective display. Also,
By turning on the backlight as needed, visibility can be ensured even when the illumination is dark.

In the liquid crystal display device according to the present embodiment,
Unlike a conventional transmissive liquid crystal display device, it is not necessary to keep the backlight on all the time, it is possible to reduce power consumption, and it is possible to prevent the reflective display unit 9 from being washed out. Accordingly, transmissive display using a backlight can be performed.

As described above, according to Embodiments 14 to 17, according to the present embodiment, a high-resolution active matrix liquid crystal display realizing the liquid crystal display system shown in Embodiments 1 and 2 is realized. It has been shown that the device can be realized.

In Examples 14 to 17, the organic insulating film 25 was formed on the active matrix substrate (TFT element substrate).
(Corresponding to the insulating film 11), a liquid crystal display device having a liquid crystal layer thickness different between the reflective display portion 9 and the transmissive display portion 10 was manufactured.
Needless to say, a similar effect can be expected.

[Embodiment 10] In this embodiment, a change in luminance of a backlight used in a liquid crystal display device according to the present invention will be described below.

There are mainly three purposes for changing the brightness of the backlight. The first purpose is to ensure visibility. As described in the eighth embodiment, the human perceived brightness is defined by the adaptation brightness and the brightness of the display surface. Therefore, in order to realize good visibility display, it is effective to change the brightness of the backlight according to the perceived brightness of the human eye according to the adaptation brightness, as shown in the eighth embodiment. In addition, it is desirable to change the luminance of the display surface by controlling the luminance of the backlight according to the adaptation luminance so that the perceived lightness is not less than 10 brills and less than 30 brils. That is, the backlight also serves as a display surface luminance changing unit. Thereby, the visibility in a situation where the transmissive display mainly contributes to the display can be improved. Here, the value of the perceived brightness defined in the eighth embodiment assumes the brightness of the display surface in proportion to the adaptation brightness to which the person has adapted. , A good display can be obtained.

[0488] The second object is to reduce power consumption. In some cases, turning on or off the backlight does not significantly affect the visibility. For example, when the liquid crystal display device is a transflective liquid crystal display device, the illuminance of illumination light for illuminating the liquid crystal display device from the surroundings is sufficiently high, and the luminance of the display surface is mainly maintained by the reflective display portion. It is.
In such a case, even if the luminance in the transmissive display is high, the luminance of the display surface may not be affected. In such a case, it is desirable to turn off the backlight to reduce power consumption.

[0489] The third object is to perform color display only on one of the reflective display and the transmissive display.
One purpose is to provide a single liquid crystal display device with a plurality of functions by intentionally creating a use state in which color display and black and white display can be switched by turning on a backlight.

[0490] For example, when a monochrome display is performed without disposing a color filter in the reflective display section and a color filter is disposed only in the transmissive display section, the resolution of the reflective display is determined by using the color filter. Since it can be higher than the transmissive display unit that displays one black and white unit with multiple pixels, reflective display performs high resolution black and white display,
The transmissive display is not high in resolution but is capable of color display. Conversely, a color filter can be used only in the reflective display. in this case,
One liquid crystal display device can have functions for different uses. Therefore, by switching between color display and black and white display by turning on the backlight, or by changing the emission color, it is possible to greatly change the display content depending on the lighting state.

As described above, the brightness of the backlight is
In each case, it can be controlled by an appropriate signal in accordance with the purpose of use and the state of use. When changing the brightness of the backlight according to the adaptation brightness described above, the brightness of the backlight is, for the purpose of improving visibility, for example, the illuminance of illumination incident on the display surface or the type of display of the liquid crystal display device. It is possible to control according to the visual environment.

When the luminance of the backlight is controlled by the illuminance, the backlight is turned off when the illuminance is high, and when the illuminance is low, the backlight is illuminated weakly to avoid glare. In this case, it is desirable to control the lighting state of the backlight, such as turning on the backlight strongly.

[0493] In this case, depending on the state of the user or the like, the presence or absence of the backlight and the control of the luminance are controlled by a signal from various external devices connected to the liquid crystal cell or the liquid crystal display device or by timer control. By doing so, unnecessary power consumption can be reduced.

[0494] Further, in controlling the luminance of the backlight, for example, when the user performs any operation on the device provided with the liquid crystal display device, or turns on the backlight only for a predetermined period after that. Thus, it is possible to achieve both reduction in power consumption of the entire device and provision of a good display to the user. The brightness of the backlight may be controlled by various other signals other than the illuminance of the illumination incident on the display surface as described above.

A signal input by a user to a touch panel (pressed coordinate detection type input means) arranged on the display surface of the liquid crystal cell, whether or not the backlight is turned on or off, or a reflective display unit or a transmissive display unit It is also very effective to control the liquid crystal alignment in the above and to control the luminance of the backlight in conjunction with a signal that calls attention to other users. As described above, by controlling the luminance of the display surface from outside the liquid crystal cell, it is possible to obtain a liquid crystal display device that is compatible with both visibility and low power consumption.

[Embodiment 11] In this embodiment, a touch panel (pressed coordinate detection type input means) is used as an information input means in a portable device which is a main application field of the liquid crystal display device of the present invention. A specific configuration of the liquid crystal display device according to the present invention will be described. Note that, for convenience of explanation, components having the same functions as those in Embodiments 1 to 10 are given the same reference numerals, and descriptions thereof are omitted.

In this embodiment mode, a touch panel is overlaid on the liquid crystal display device of Example 17 in Embodiment 9 to produce a transflective liquid crystal display device integrated with an input device. FIG. 32 shows a configuration of a liquid crystal display device integrated with an input device according to the present embodiment. In the liquid crystal display device according to the present embodiment, the basic configuration other than the touch panel 71, that is, the configuration of the liquid crystal cell and the backlight 13 is the same as those of the seventeenth embodiment and the second embodiment in the ninth embodiment. Since it is the same as the fifth embodiment, the description is omitted here.

The touch panel 71 includes a transparent electrode layer 72
And a support substrate 75 provided with a transparent electrode layer 74. These movable substrates 73
And the support substrate 75, the transparent electrode layer 72 and the transparent electrode layer 74
Are opposed to each other, and are arranged facing each other with a predetermined gap by a spacer (not shown) so that the transparent electrode layers do not come into contact with each other in the energized state. Thus, the transparent electrode layer 72 provided on the movable substrate 73 and the transparent electrode layer 74 provided on the support substrate 75 do not contact each other in a normal state, but the movable substrate 7
3 is indicated (pressed) with a finger or a pen,
They come into contact with each other at designated locations. Therefore, the touch panel 71 is
The device functions as an input device by detecting the contact position (coordinate position) between the transparent electrode layer 72 and the transparent electrode layer 74 by the pressing force applied to the device.

[0499] The touch panel 71 is
By attaching the phase difference compensating plate 16 and the polarizing plate 14 on 3, between the phase difference compensating plate 16 and the substrate 4 of the liquid crystal cell,
It is arranged integrally with the phase difference compensator 16 and the polarizing plate 14. In the present embodiment, in order to obtain the effect of the polarizing plate of Example 17 with the polarizing plate 14 attached to the touch panel 71, the movable substrate 73 and the supporting substrate 75 forming the touch panel 71 are birefringent. It is made of a material without any.

In the present embodiment, the liquid crystal display device is supported by the touch panel 71 so that the liquid crystal display device has an effect of preventing the transmission of the pressing force between the touch panel 71 and the substrate 4 of the liquid crystal cell. A gap is provided between the substrate 75 and the substrate 4 of the liquid crystal cell, and by keeping this gap constant, the pressing force to the touch panel 71 is not transmitted to the liquid crystal cell without using a pressing force buffering member.

[0501] In the liquid crystal display device integrated with the input device having the above-described configuration, the brightness of the backlight 13 is changed by the signal of the touch panel 71 so that when the user is not observing the display, the brightness of the backlight 13 is reduced. Can be turned off, and the backlight 13 can be turned on as information is input to the touch panel 71. Therefore, according to the present embodiment, a liquid crystal display device that achieves both good display and reduced power consumption can be realized. Further, according to the present embodiment, the polarizing plate 14 and the touch panel 7
By arranging 1 and the liquid crystal cell in the order described above, the absorption by the polarizing plate 14 also absorbs unnecessary reflected light from the touch panel 71 and can reduce the unnecessary reflected light, thereby improving visibility. Can be.

[0502] As described above, the first liquid crystal display device includes the pair of substrates having the alignment means (for example, the alignment film) on the opposing surfaces, and the liquid crystal layer sandwiched between the pair of substrates. A liquid crystal display device provided with a liquid crystal display element, wherein an alignment mechanism (for example, a display in the liquid crystal layer) for causing at least two kinds of different alignment states to be simultaneously taken in arbitrary and different regions used for display in the liquid crystal layer. An electrode used to apply a different voltage to an arbitrary and different region used for generating a different electric field, an applied voltage, or an arbitrary and different region used for display in the liquid crystal layer is provided respectively. At least two types of alignment films that have been subjected to alignment processing in different directions, or at least two types of different thicknesses in a region used for display in the liquid crystal layer. The insulating film and the substrate formed, a specific liquid crystal material, a liquid crystal layer structure formed so as to be independently driven, a polarizing plate, a phase difference compensating plate, or a combination thereof). A reflective means (for example, a reflective film or a reflective electrode) is arranged in at least one of the regions exhibiting different alignment states in the liquid crystal layer, and the region exhibiting the different alignment state is a reflective display unit for performing reflective display;
It has a configuration used for a transmissive display unit that performs transmissive display.

According to the above configuration, since the liquid crystal has different alignment states at the same time, when a dye such as a dichroic dye is used for display, for example, the amount of light absorption (absorbance) and the optical anisotropic When the property is used, the magnitude of the modulation amount of each optical physical quantity such as the phase difference can be changed for each region where the liquid crystal alignment is different. Therefore, according to the above configuration, it is possible to obtain a transmittance or a reflectance based on the magnitude of the modulation amount of the optical physical quantity according to the alignment state of the liquid crystal layer,
This makes it possible to set optical parameters independently for the transmissive display unit and the reflective display unit. Therefore, according to the above configuration, there is no parallax, a high contrast ratio can be realized, visibility can be improved when the surroundings are dark, and good visibility can be achieved even when ambient light is strong. Can be obtained. For this reason, according to the above configuration, excellent visibility and high resolution display are possible,
A transflective liquid crystal display device that can use both reflected light and transmitted light for display can be provided.

[0504] Further, the second liquid crystal display device has a structure in which, in the first liquid crystal display device, the above-mentioned alignment mechanism is display content rewriting means for rewriting the display content with the passage of time.

According to the above configuration, the display content rewriting means and the alignment mechanism can be realized by the same means, and the first liquid crystal display device can be obtained without adding a new configuration. it can. In this case, the display content rewriting means used for taking a plurality of states having different liquid crystal alignments includes an electric liquid crystal alignment control means which is currently widely used for rewriting display contents with time. That is, it goes without saying that various means used for applying a voltage, such as electrodes, can be used. in this case,
For example, by using different electrodes for the transmissive display unit and the reflective display unit, or by changing the voltage itself between the transmissive display unit and the reflective display unit, a plurality of liquid crystal layers having different alignment states in the liquid crystal alignment are formed. Regions can be provided.

Further, when the degree of modulation of each optical physical quantity such as the amount of light absorption and the phase difference due to optical anisotropy is changed independently between the reflective display unit and the transmissive display unit, the liquid crystal is not affected by the application of voltage. Even when the orientation direction is substantially the same in the entire region used for display of the liquid crystal layer, in the region where the liquid crystal layer thickness of the liquid crystal layer is different, the orientation direction of the liquid crystal layer is substantially changed in the region. Has the same function as. In particular, in a GH system using a dye such as a dichroic dye and utilizing light absorption, and in a polarizing plate system utilizing a birefringence or optical rotation phenomenon,
Each phenomenon of light absorption and birefringence that occurs in the liquid crystal layer,
These phenomena are accompanied by the propagation of light, and each of the phenomena has a relationship between the propagation distance of light in the liquid crystal layer and the degree of those phenomena. Further, display light passes through the liquid crystal layer twice in a reciprocating manner in the reflective display portion, and passes through the liquid crystal layer only once in the transmissive display portion. However, when the reflection display unit and the transmission display unit are set in the same manner, sufficient brightness and contrast ratio cannot be obtained, and the above problem cannot be solved.

Accordingly, a third liquid crystal display device has a liquid crystal display element having a pair of substrates having alignment means (for example, alignment film) provided on opposing surfaces, and a liquid crystal layer sandwiched between the pair of substrates. Wherein the region used for display in the liquid crystal layer comprises at least two types of regions having different liquid crystal layer thicknesses, and each region having a different liquid crystal layer thickness is a reflective display. And a transmissive display unit, at least a reflective means (for example, a reflective film or a reflective electrode) is disposed on the reflective display unit, and the liquid crystal layer thickness of the reflective display unit is smaller than that of the transmissive display unit. Have.

According to the above arrangement, it is possible to obtain the transmittance or the reflectance based on the magnitude of the modulation of the optical physical quantity in the region where the thickness of the liquid crystal layer is different. , Optical parameters can be set independently. Therefore, according to the above configuration, there is no parallax, a high contrast ratio can be realized, visibility can be improved when the surroundings are dark, and good visibility can be achieved even when ambient light is strong. Can be obtained. For this reason, according to the above configuration, the visibility is excellent,
In addition, it is possible to provide a transflective liquid crystal display device capable of high-resolution display and capable of using both reflected light and transmitted light for display.

The fourth liquid crystal display device is the liquid crystal display device according to any one of the first to third liquid crystal display devices, wherein at least one of the pair of substrates is in contact with a region used for displaying the liquid crystal layer. The liquid crystal layer has a configuration in which at least two types of different alignment directions are provided to the alignment on the interface of the liquid crystal layer in contact with the region on the contact surface.

As means for simultaneously providing different alignment states of the liquid crystal alignment, for example, in addition to the display content rewriting means, for example, at least two kinds of means are provided at the interface on the substrate in contact with the liquid crystal layer. It is possible to use an alignment film or the like that has been subjected to an alignment treatment so as to give a different alignment direction to the alignment at the interface of the liquid crystal layer in contact therewith. In this manner, at least two different alignment directions are provided to the region on the contact surface in contact with the region used for display of the liquid crystal layer on the surface of the substrate so as to give the alignment at the interface of the liquid crystal layer in contact therewith. Is applied, the liquid crystal layer, at the time of applying a voltage, in at least two different regions to be used for display in the liquid crystal layer, simultaneously exhibit at least two different alignment states, the alignment in the liquid crystal layer Reflective display and transmissive display can be performed in regions in different states.

In this case, by changing the elevation angle of the liquid crystal alignment with respect to the substrate and the azimuth thereof, both the alignment of the liquid crystal that determines the optical characteristics and the change in the alignment when a voltage is applied can be changed. The display suitable for each display can be performed by the reflective display unit and the transmissive display unit.

According to the above-described means and orientation mechanism, good display can be realized in both the reflective display unit and the transmissive display unit. However, color display (color display), monochrome display, or Depending on the desired display, such as whether display is mainly performed by reflective display or display is mainly performed by transmissive display, the ratio between the reflective display unit and the transmissive display unit may have an optimal ratio for performing a good display. Exists.

That is, in the fifth liquid crystal display device, in any one of the first to fourth liquid crystal display devices, the ratio of the area occupied by the reflective display portion to the total area of the reflective display portion and the transmissive display portion is different. , 30% or more and 90% or less.

According to the above configuration, when color display is performed by both the reflective display unit and the transmissive display unit, favorable display can be performed by both the reflective display unit and the transmissive display unit.

[0515] From the viewpoint of visibility, it is desirable that the display content is not inverted between the reflective display portion and the transmissive display portion. This is because, in a situation where the lighting environment changes or a change in the lighting environment is difficult to predict, if the display content is inverted between the reflective display unit and the transmissive display unit, the contrast ratio of the display increases due to the intensity of the ambient light. From the viewpoint of visibility, such a change in the contrast ratio becomes a phenomenon similar to that of washout, and causes a significant deterioration in visibility.

Therefore, if the reflective display unit simultaneously displays a bright display when the transmissive display unit is a bright display, and the reflective display unit simultaneously displays a dark display when the transmissive display unit is a dark display, the visibility is increased. It is very important in securing.

For this reason, the sixth liquid crystal display device has
In any one of the fifth liquid crystal display devices, the reflective display unit may be a bright display simultaneously when the transmissive display unit is a bright display, and the reflective display unit may be a dark display simultaneously when the transmissive display unit is a dark display. have.

[0518] According to the above configuration, the sixth liquid crystal display device has the configuration of the first or third liquid crystal display device, so that when the transmissive display unit performs bright display, the reflective display unit simultaneously. Is a bright display, and the reflective display unit can be a dark display at the same time as the transmissive display unit is a dark display.
In particular, according to the liquid crystal display device, even if the display content is inverted between the reflective display portion and the transmissive display portion as it is, for example, using the display content rewriting means in the alignment mechanism, the reflective display portion and By individually controlling the rewriting of the display contents with the transparent display unit, the display can be easily aligned. Therefore, according to the above configuration, good visibility can be ensured.

[0519] The seventh liquid crystal display device comprises the first to sixth liquid crystal display devices.
In any one of the above liquid crystal display devices, the liquid crystal layer has a configuration made of a liquid crystal composition obtained by mixing a dichroic dye into the liquid crystal.

According to the above arrangement, the liquid crystal layer is made of a liquid crystal composition obtained by mixing a dichroic dye into the liquid crystal, so that the reflection display unit and the transmissive display unit absorb light. Can be optimized.

[0521] As a display system for performing good display on both the reflective display unit and the transmissive display unit, it is also effective to use a system using a polarizing plate to display birefringence or optical rotation. .

Therefore, the eighth liquid crystal display device has the first to
In any one of the seventh liquid crystal display devices, a polarizing plate is provided on at least one of the pair of substrates on a non-contact surface side with a liquid crystal layer.

According to the above configuration, birefringence can be optimized in the reflective display unit and the transmissive display unit, and a favorable display can be performed. At this time, in order to use a polarizing plate method for the reflective display unit and secure sufficient display in the transmissive display unit in the third liquid crystal display device, not only the display surface side, but also the light incident side of the transmissive display unit. It is also necessary to have a polarizing plate.

[0524] In the eighth liquid crystal display device,
The amount of change in the phase difference of light caused by the change in orientation of the liquid crystal layer due to the voltage is set so as to be suitable for light that reciprocates through the liquid crystal layer in the reflective display unit, and is suitable for light that passes through the liquid crystal layer in the transmissive display unit. It is desirable to set the value to the value for switching the display.

[0525] Therefore, the ninth liquid crystal display device according to the eighth liquid crystal display device includes a voltage applying means (for example, an electrode) for applying a voltage to the liquid crystal layer.
When a voltage is applied, the phase difference of the display light on the reflection means of the reflective display unit is approximately 90 between the bright display and the dark display.
A voltage is applied so that the difference between the two levels is equal to one another, and the phase difference of the display light emitted from the liquid crystal layer in the transmissive display section is about 180 degrees between the bright display and the dark display. are doing.

In this case, the liquid crystal orientation in the liquid crystal layer is specifically, as shown in the tenth liquid crystal display device.
The liquid crystal layer is at least 60 degrees and 10 degrees between the pair of substrates.
The liquid crystal layer is twist-oriented at a twist angle of 0 ° or less, or as shown in an eleventh liquid crystal display device, the liquid crystal layer is twisted at a twist angle of 0 ° or more and 40 ° or less between the pair of substrates. Preferably, they are oriented.

[0527] The liquid crystal layer is formed between the pair of substrates by 60
By configuring the liquid crystal display device so as to be twisted at a twist angle of not less than 100 degrees and not more than 100 degrees, the liquid crystal layer of the transmissive display portion displays a change in polarization close to the optical rotation according to the twist of the orientation of the liquid crystal. In a reflective display unit, a change in polarization due to the control of optical rotation and retardation can be used for display.

Further, by configuring the liquid crystal display device such that the liquid crystal layer is twist-aligned between the pair of substrates at a twist angle of 0 ° or more and 40 ° or less, the liquid crystal layer of the transmissive display section can be formed. In both cases, the change in retardation can be used for display in the liquid crystal layer of the reflective display section.

Therefore, the tenth liquid crystal display device has a configuration in which the liquid crystal layer is twist-oriented between the pair of substrates at a twist angle of 60 degrees or more and 100 degrees or less.

In the eleventh liquid crystal display device, the liquid crystal layer is
A twist orientation is provided between the pair of substrates at a twist angle of 0 degree or more and 40 degrees or less.

[0531] According to the ninth to eleventh liquid crystal display devices, it is possible to obtain a change amount of the phase difference suitable for the reflective display or the transmissive display in the reflective display unit and the transmissive display unit, respectively.
The display can be switched between the bright display and the dark display.

In any one of the first to sixth, eighth, and ninth liquid crystal display devices, the change in the orientation of the liquid crystal is as follows:
Sufficient display is possible only by changing the azimuth in a plane parallel to the substrate.

That is, the twelfth liquid crystal display device is the same as any one of the first to sixth, eighth, or ninth liquid crystal display devices,
The liquid crystal display element has a configuration in which at least one of the reflective display portion and the transmissive display portion performs display by changing the alignment state of the liquid crystal layer by rotating liquid crystal molecules in parallel to the substrate. I have.

Further, according to the following configuration, the insufficiency of the liquid crystal alignment, which causes the low light transmittance, which is a problem of the conventional in-plane switching system, is positively utilized as a reflective display for display. In addition, the low light utilization efficiency of the in-plane switching method can be overcome.

That is, a thirteenth liquid crystal display device is the liquid crystal display device according to the twelfth liquid crystal display device, wherein the liquid crystal display element includes a voltage applying means for generating an electric field in the liquid crystal layer in an in-plane direction of the substrate. And a transmissive display unit.

The orientation of the liquid crystal layer may be a parallel orientation which has been often used for display, or may be a vertical orientation in which the liquid crystal is oriented perpendicular to the substrate.

[0537] A fourteenth liquid crystal display device is the liquid crystal display device according to any one of the first to ninth, twelfth, and thirteenth liquid crystal display devices, wherein at least one of the pair of substrates is in contact with the liquid crystal layer. The display device has a configuration in which an alignment film having vertical alignment is provided in a region corresponding to at least one of the reflective display portion and the transmissive display portion on the surface.

As described above, when the substrate is provided with the alignment film having the vertical alignment property and the liquid crystal is in the vertical alignment in which the liquid crystal is vertically aligned with respect to the substrate, there is an advantage that the display contrast ratio is improved. In addition, the liquid crystal display device of the first to ninth, twelfth, or thirteenth liquid crystal display device is effective in performing good display.

[0539] The fifteenth liquid crystal display device is the liquid crystal display device according to any one of the first to fourteenth liquid crystal display devices, wherein at least one of the pair of substrates is one of the reflective display portion and the transmissive display portion. An insulating film is provided at least in a region corresponding to the reflective display portion, and the insulating film is formed such that a film thickness of the region corresponding to the reflective display portion is larger than a region corresponding to the transmissive display portion. Configuration.

That is, the above-mentioned liquid crystal display device has an insulating film on at least one of the substantially smooth substrates sandwiching the liquid crystal layer, and the insulating film is provided in the region corresponding to the transmissive display portion and in the reflective display portion. Either the film is formed to be thinner than the corresponding region, or the insulating layer is formed only in the region corresponding to the reflective display portion, and the insulating film is formed in the region corresponding to the transmissive display portion. Not.

According to the above arrangement, the area used for display in the liquid crystal layer is formed by a liquid crystal display device having at least two different liquid crystal layer thicknesses (that is, the liquid crystal layer thickness is different between the reflective display portion and the transmissive display portion). (A different liquid crystal display device) can be easily obtained.

The insulating film not only functions as a means for adjusting the thickness of the liquid crystal layer, but also forms a display electrode on the surface of the reflective display portion where the insulating film is in contact with the liquid crystal layer. Can be applied to the liquid crystal layer without loss.

In this case, a light-reflective film is formed as a reflection means on a substrate arranged opposite to the substrate on the display surface side,
The fact that the film having light reflectivity has an uneven structure is effective as a means for preventing specularity of reflection display without impairing the resolution without impairing the display performance of the transmissive display unit. By having the uneven structure similar to the uneven structure of the light-reflective film, the light-reflective film having the uneven structure can be easily formed.

In the case of performing color display using each of the above liquid crystal display devices, it is important to design not only a liquid crystal layer but also a color filter layer which is important for coloring. According to the study by the present inventors, there are two main use modes of the transflective liquid crystal display device.

One is that, in normal use, transmission display is mainly used, and reflection display is additionally used to prevent washout in an illumination environment where ambient light is extremely strong. This is a mode of use mainly based on transmissive display, which secures a great variety of usable lighting environments compared to liquid crystal display devices that only use transmissive display, and the other is power consumption in normal use. Taking advantage of the nature of the reflective display that the amount is small, and in an environment with weak lighting,
This is a mode of use mainly using reflective display, which secures a great variety of usable environments as in the previous mode of use by turning on and using an illumination device called a so-called backlight.

In the above usage mode (a usage mode mainly for transmissive display), at least a region corresponding to at least the transmissive display portion among the regions constituting the display region of each pixel on one of the pair of substrates. In addition, by disposing a color filter having a transmissive color, a liquid crystal display device that is excellent in visibility and capable of high-resolution color display, and can use both reflected light and transmitted light for display. Can be provided.

When color display is performed in such a manner, each pixel is provided with a color filter having a transmissive color at least in the transmissive display section, and no color filter is used in the reflective display section, or It is particularly effective to arrange a color filter having the same lightness as the color filter arranged in the transmissive display section on at least a part of the reflective display section, or to arrange a color filter having a transmissive color with a higher lightness than that. .

This is because, when color display is performed, if the color filter of the transmissive display unit is used as it is in the reflective display unit, the brightness will be insufficient. In the case of performing color display also in the reflective display unit, no color filter is used. By providing the area on the reflective display unit or by arranging a color filter on the reflective display unit with a transmissive color that is higher in brightness than the transmissive display unit, the brightness can be supplemented, and color display can also be performed on the reflective display In addition, the reflectance required for the reflective display unit can be ensured.

In the reflective display unit, considering that the display light passes through the color filter twice, a color filter having a transmissive color with higher brightness than the transmissive display unit is provided in the reflective display unit. Is desirable.

[0550] Further, in a mode of use mainly involving transmissive display, in the case where the reflective display section has a region without a color filter, a display voltage signal necessary for transmissive display is a signal suitable for color display. The display voltage signal necessary for reflective display is a signal suitable for monochrome display in an example in which no color filter is used in the reflective display section. Therefore, in the case where a color filter is not provided in the reflective display unit, the ratio of pixels of each color contributing to lightness is proportional to the luminous transmittance of each color in the transmissive display unit, but in the reflective display unit,
In the case where a color filter is not provided in the reflective display section because the same is obtained for each color, the area where the color display of the reflective display section is not performed in accordance with the luminous transmittance of each color of the color filter used for the transmissive display. It is desirable to change the area of.

That is, in the sixteenth liquid crystal display device, in any one of the first to fifteenth liquid crystal display devices, a transmission region of a region constituting a display region of each pixel on one of the pair of substrates is provided. A color filter having a transmissive color is arranged in a region corresponding to the display unit, and at least a part of a region corresponding to the reflection display unit among the regions constituting the display region corresponds to the transmission display unit in the substrate. And a color filter having the same lightness as the color filter arranged in the region where the color filter is arranged.

According to the above configuration, the brightness can be compensated, color display can be performed not only for transmissive display but also for reflective display, and the reflectance required for the reflective display section can be secured. And a transflective liquid crystal display device capable of color display can be provided.

The seventeenth liquid crystal display device is the same as the first to fifteenth liquid crystal display devices, except that one of the pair of substrates has a transparent display portion in a region constituting a display region of each pixel. In the corresponding area, a color filter having a transmissive color is arranged, and in at least a part of the area corresponding to the reflective display section among the areas constituting the display area, in the area corresponding to the transmissive display section on the substrate. The color filter has a configuration in which a color filter having a transmission color higher in brightness than the disposed color filters is disposed.

According to the above configuration, when performing color display, brightness is supplemented, color display can be performed not only for transmissive display but also for reflective display, and the reflectance required for the reflective display section is ensured. Can be mainly used for transparent display,
A transflective liquid crystal display device capable of color display can be provided. In this case, in the reflective display section, the display light passes through the color filter twice. For this reason, in the area corresponding to the reflective display section, by disposing a color filter having a higher transmission color than the color filter arranged in the area corresponding to the transmissive display section on the substrate, the brightness is further increased, A better color display can be performed.

Further, the eighteenth liquid crystal display device has
In any one of the seventeenth liquid crystal display devices, a color filter having a transmissive color at least in a region corresponding to a transmissive display portion among regions constituting a display region of each pixel in one of the pair of substrates. Is arranged, and
The configuration is such that the area of the area where the color display is not performed in the reflective display unit is set in accordance with the luminous transmittance of the transmitted color of the color filter.

According to the above configuration, the ratio of the pixels of each color contributing to lightness can be changed by the luminous transmittance of each color, and as a result, good display can be realized.

[0557] In the second mode of use (the mode of use mainly for reflective display), at least the reflective display section of the area constituting the display area of each pixel on one of the pair of substrates. By disposing a color filter having a transmissive color in an area corresponding to, excellent visibility and high-resolution color display are possible, and both reflected light and transmitted light can be used for display. A liquid crystal display device can be provided.

When color display is performed as described above, each pixel is provided with a color filter having a transmissive color at least in a reflective display section to perform color display, and a color filter is provided in the transmissive display section. Do not use, or
It is particularly effective to dispose a color filter having a transmission color having the same color saturation as or higher than that of the color filter disposed on the reflection display portion on at least a part of the transmission display portion.

In a usage mode mainly using a reflective display,
When a black and white display is performed without using a color filter in the transmissive display unit, the transmittance of light increases, so that the transmissive display unit can be set smaller. As a result, the area of the reflective display section can be secured larger, and a better display can be obtained in the reflective display during normal use.

Further, in the usage mode mainly using the reflective display, by changing the area of the area where the color display is not performed in the transmissive display section in accordance with the luminous transmittance of each color of the color filter used for the reflective display, The contribution of the transmissive display unit to the brightness of the monochrome display in each pixel can be appropriately set in consideration of the luminous transmittance.

That is, in the nineteenth liquid crystal display device, in any one of the first to fifteenth liquid crystal display devices, at least one of the regions constituting the display region of each pixel on one of the pair of substrates is provided. In the area corresponding to the reflective display,
It has a configuration in which a color filter having a transmission color is provided.

According to the above configuration, it is possible to provide a liquid crystal display device which is excellent in visibility and can perform high-resolution color display when performing display mainly based on reflective display. In this case, in particular, the reflective display unit performs color display, and the transmissive display unit performs black-and-white display without using a color filter, thereby increasing the light transmittance. For this reason, in such a case, it is possible to set the transmissive display section to be even smaller, to secure a larger area of the reflective display section, and to obtain a better display in the reflective display during normal use. Obtainable.

In the twentieth liquid crystal display device, in the nineteenth liquid crystal display device, the area of a region in which the color display of the transmissive display section is not performed is set in accordance with the luminous transmittance of the transmitted color of the color filter. It has the configuration that has been done.

[0564] According to the above arrangement, when performing display mainly using reflective display, the contribution of each pixel to the brightness from the monochrome display of the transmissive display section is appropriately set in consideration of the luminous transmittance. Therefore, a better display can be obtained.

Further, the twenty-first liquid crystal display device comprises
In a fifteenth liquid crystal display device, a color filter having a transmissive color is arranged in a region corresponding to a reflective display portion among regions constituting a display region of each pixel on one of the pair of substrates, and In at least a part of a region corresponding to the transmissive display portion among the regions constituting the display region, the substrate has a transmissive color having a color saturation equal to or higher than that of the color filter arranged in the region corresponding to the reflective display portion on the substrate. It has a configuration in which a color filter is provided.

According to the above arrangement, good color display can be performed in both the reflective display unit and the transmissive display unit.
A transflective liquid crystal display device mainly comprising a reflective display can be provided.

Since the above-described liquid crystal display device has the reflective display section as described above, it also has the characteristic of low power consumption in the conventional reflective liquid crystal display device. However, using illumination light that consumes a large amount of power and keeping it in a lighting state causes an increase in power consumption.

Therefore, the twenty-second liquid crystal display device has the first to
In any one of the twenty-first liquid crystal display devices, the liquid crystal display device further includes a lighting device configured to input light from a back surface of the liquid crystal display device, and the lighting device includes a display surface brightness changing unit configured to change a brightness of a display surface. It has a configuration that doubles.

According to the above configuration, it is possible to achieve both low power consumption and visibility by changing the luminance of the display surface by the lighting device.

[0570] Further, the twenty-third liquid crystal display device has the twenty-second liquid crystal display device.
In the above liquid crystal display device, the illumination device has a configuration in which the luminance of the display surface is changed according to the adaptation luminance so that the perceived lightness is not less than 10 brills and less than 30 brils.

The perceived lightness is defined by the adaptation luminance and the luminance of the display surface. At this time, the above lighting device
Depending on the display content of the liquid crystal display device and the adaptation luminance that changes depending on the visual environment such as illumination, the brightness of the display surface is changed so that the above-mentioned perceived lightness is obtained by changing the intensity of lighting, extinguishing, or illumination. Changing is very preferable in achieving both low power consumption and visibility. In particular, when the illuminating device is controlled from outside the liquid crystal display element by a pressed coordinate detection type input unit such as a touch panel, the above-described effect becomes more remarkable.

According to the above arrangement, visibility in a situation where transmissive display mainly contributes to display can be improved, good visibility can be realized, and low power consumption can be realized. Can be achieved.

Further, in the transflective liquid crystal display device as described above, it is easier to use a pressed coordinate detection type input means such as a touch panel as compared with a reflective liquid crystal display device using a so-called front light. There are significant advantages in this regard. Therefore, realizing good display in a semi-transmissive type using such pressed coordinate detection type input means is effective for a good input device integrated type liquid crystal display device with low power consumption.

[0574] That is, the twenty-fourth liquid crystal display device is, in any one of the first to twenty-third liquid crystal display devices, arranged so as to be superimposed on the display surface, and detects a pressed coordinate position which is detected by being pressed. It has a configuration provided with detection type input means.

According to the above configuration, it is possible to provide a good input device integrated liquid crystal display device with low power consumption.

Further, when such pressed coordinate detecting type input means is used, it can be easily detected that the observer is using the display device by the signal of the pressed coordinate detecting type input means. In accordance with this signal, changing the brightness of the lighting device which affects the power consumption of the liquid crystal display device to change the brightness of the display surface, or changing the liquid crystal alignment can reduce power consumption and improve visibility. It is effective to achieve both.

Therefore, the twenty-fifth liquid crystal display device has the twenty-second liquid crystal display device.
Alternatively, in the twenty-third liquid crystal display device, the display device further includes a pressed coordinate detection type input unit that is disposed on the display surface and detects a coordinate position pressed by being pressed. It has a configuration in which the brightness of the display surface is changed in conjunction with the output signal of the input means.

According to the above arrangement, the use of the display device by the observer is easily detected by the signal of the pressed coordinate detection type input means, and the power consumption of the liquid crystal display device is determined in accordance with this signal. By changing the luminance of the lighting device that controls the luminance and the luminance of the display surface, it is possible to achieve both reduction in power consumption and good visibility.

The twenty-sixth liquid crystal display device is the same as the first or second liquid crystal display device, but is arranged so as to be overlaid on the display surface, and detects a coordinate position pressed by being pressed. Means, wherein the alignment mechanism has a configuration for changing the alignment state of the liquid crystal layer in at least one of the reflective display unit and the transmissive display unit in conjunction with an output signal of the pressed coordinate detection type input unit. I have.

According to the above arrangement, it is easy to detect that the observer is using the display device by the signal of the pressed coordinate detection type input means. Thus, both reduction in power consumption and good visibility can be achieved.

In the case where the liquid crystal display device includes both the pressed coordinate detection type input means and the polarizing plate, the pressed coordinate detection type input means and the polarizing plate may include a polarizing plate, a pressed coordinate detection type input means, The liquid crystal display elements are arranged in this order.

[0582] That is, the 27th liquid crystal display device is, in any one of the 1st to 26th liquid crystal display devices, arranged so as to be superimposed on the display surface, and detects a pressed coordinate position which is detected by being pressed. A detection type input means and a polarizing plate are provided, and the polarizing plate, the pressed coordinate detection type input means, and the liquid crystal display element are arranged in this order.

According to the above configuration, it is possible to provide a liquid crystal display device with a low power consumption, which is integrated with an input device and includes a polarizing plate and input means for detecting a pressed coordinate and uses birefringence for display.

Also, by arranging the polarizing plate, the pressed coordinate detecting type input means and the liquid crystal display element in this way, the absorption by the polarizing plate also absorbs the unnecessary reflected light by the pressed coordinate detecting type input means. The unnecessary reflected light can be reduced. Therefore, according to the above configuration, the visibility of the liquid crystal display device can be improved, and good visibility can be realized.

[0585]

As described above, the liquid crystal display device of the present invention comprises: a pair of substrates having alignment means provided on opposing surfaces;
What is claimed is: 1. A liquid crystal display device comprising a liquid crystal display element having a liquid crystal layer sandwiched between a pair of substrates, wherein at least two different alignment states are simultaneously provided in arbitrary and different regions used for display in the liquid crystal layer. The liquid crystal layer is provided with a reflection means in at least one of the regions exhibiting different alignment states, and the region exhibiting the different alignment state is a reflective display. This configuration is used for a display unit and a transmissive display unit that performs transmissive display.

According to the above arrangement, since the liquid crystal has different alignment states at the same time, for example, when a dye such as a dichroic dye is used for display, the amount of light absorption (absorbance) and the optical anisotropic When the property is used, the magnitude of the modulation amount of each optical physical quantity such as the phase difference can be changed for each region where the liquid crystal alignment is different. Therefore, according to the above configuration, it is possible to obtain a transmittance or a reflectance based on the magnitude of the modulation amount of the optical physical quantity according to the alignment state of the liquid crystal layer,
This makes it possible to set optical parameters independently for the transmissive display unit and the reflective display unit. Therefore, according to the above configuration, it is possible to provide a transflective liquid crystal display device which is excellent in visibility, can perform high-resolution display, and can use both reflected light and transmitted light for display. This has the effect that it can be performed.

The liquid crystal display of the present invention has the following features.
The orientation mechanism is a display content rewriting means for rewriting the display content over time.

According to the above configuration, the display content rewriting means and the alignment mechanism can be realized by the same means, and the liquid crystal display device can be obtained without adding a new configuration. To play.

As described above, the liquid crystal display device of the present invention
It is arranged on the display surface, comprising a pressed coordinate detection type input means for detecting the coordinate position pressed by being pressed, the orientation mechanism, in conjunction with the output signal of the pressed coordinate detection type input means In this configuration, the alignment state of the liquid crystal layer in at least one of the reflection display unit and the transmission display unit is changed.

According to the above arrangement, it is easily detected that the observer is using the display device by the signal of the pressed coordinate detection type input means. In addition, there is an effect that both reduction in power consumption and good visibility can be achieved.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of a main part of a liquid crystal display device according to a first embodiment of the present invention.

FIG. 2 is a display characteristic diagram of the liquid crystal display device described in Example 1.

FIG. 3 is a display characteristic diagram of the liquid crystal display devices described in Comparative Examples 2 and 3.

FIG. 4 is a cross-sectional view of a main part of a liquid crystal display device according to Embodiment 2 of the present invention.

FIG. 5 is a diagram illustrating a definition of a rubbing cross angle.

FIG. 6 is a display characteristic diagram of the liquid crystal display device described in Example 2.

FIG. 7 is a display characteristic diagram of the liquid crystal display device described in Example 3.

FIG. 8 is a display characteristic diagram of the liquid crystal display device described in Example 4.

FIG. 9 is a display characteristic diagram of the liquid crystal display device described in Example 5.

FIG. 10 is a display characteristic diagram of the liquid crystal display device described in Example 6.

FIG. 11 is a display characteristic diagram of the liquid crystal display device described in Example 7.

FIG. 12 is a display characteristic diagram of the liquid crystal display device described in Comparative Example 3.

FIG. 13 is a display characteristic diagram of the liquid crystal display device described in Example 8.

14 is a display characteristic diagram of the liquid crystal display device described in Comparative Example 4. FIG.

FIG. 15 is a display characteristic diagram of the liquid crystal display device described in Comparative Example 5.

FIG. 16 is a display characteristic diagram of the liquid crystal display device described in Example 9.

FIG. 17 is a process chart of a substrate alignment process used in the liquid crystal display device according to the fourth embodiment of the present invention.

18 (a) to (e) are schematic cross-sectional views schematically showing an alignment treatment step shown in FIG.

FIG. 19 is a display characteristic diagram of the liquid crystal display device described in Example 10.

FIG. 20 is a display characteristic diagram of the liquid crystal display device described in Example 11.

21A is a cross-sectional view of a main part of the liquid crystal display device according to Example 12 when no voltage is applied, and FIG.
FIG. 5 is a cross-sectional view of a main part of the liquid crystal display device shown in FIG.

FIG. 22 is a display characteristic diagram of the liquid crystal display device described in Example 12.

FIG. 23A is a diagram illustrating a TFT for realizing a transmissive-dominant transflective liquid crystal display device according to a seventh embodiment of the present invention;
It is a principal part top view of an element substrate, (b) is a figure which shows the drive electrode of the reflective display part in the TFT element substrate shown in (a), (c) is the figure in the TFT element substrate shown in (a). FIG. 3 is a diagram illustrating a transparent pixel electrode.

FIG. 24 is a cross-sectional view of the TFT element substrate shown in FIG.
FIG. 3 is a sectional view taken along line A ′.

FIG. 25 is a cross-sectional view of the TFT element substrate shown in FIG.
FIG. 3 is a sectional view taken along line B ′.

FIG. 26A is a diagram illustrating a color filter formed on a color filter substrate of a transmission-dominant transflective liquid crystal display device according to a seventh embodiment of the present invention, and TFs illustrated in FIG.
The main part of the transmissive-dominant transflective liquid crystal display device, in which the positional relationship between the drive electrode formed in the reflective display portion of the T-element substrate and the transmissive display opening is indicated by a partial breakage of the color filter substrate. It is a top view, (b) is sectional drawing of the color filter substrate shown to (a).

FIG. 27 is a view showing C of a main part of the liquid crystal display device shown in FIG.
FIG. 4 is a sectional view taken along line -C ′.

FIG. 28 is a plan view of a main part of a TFT element substrate for realizing a reflective-dominant transflective liquid crystal display device according to a seventh embodiment of the present invention;

FIG. 29A shows a color filter formed on a color filter substrate of a reflection-dominant transflective liquid crystal display device according to a seventh embodiment of the present invention, and a reflection display portion of the TFT element substrate shown in FIG. 28; FIG. 9B is a plan view of a main part of the reflective-dominant transflective liquid crystal display device, showing a positional relationship between the drive electrodes formed in the liquid crystal display device and the transmissive display openings by partially breaking the color filter substrate; () Is a cross-sectional view of the color filter substrate shown in (a).

FIG. 30 is an isometric diagram showing a relationship between adaptation luminance that gives equivalent perceived brightness and sample luminance.

FIG. 31 is a characteristic diagram showing a relationship between illuminance and perceived lightness in the transflective liquid crystal display device according to the eighth embodiment of the present invention.

FIG. 32 is a fragmentary cross-sectional view showing a schematic configuration of an input device-integrated liquid crystal display device according to Embodiment 11 of the present invention;

[Explanation of symbols]

Reference Signs List 1 liquid crystal layer 1a liquid crystal molecules 2 alignment film (alignment mechanism) 3 alignment film (alignment mechanism) 4 substrate 5 substrate 6 electrode (display content rewriting means, voltage applying means, alignment mechanism) 7 electrode (display content rewriting means, voltage applying means) , Alignment mechanism) 8 reflective film (reflective means) 9 reflective display section 10 transmissive display section 11 insulating film (alignment mechanism) 12 dichroic dye (alignment mechanism) 13 backlight (illumination device, display surface luminance changing means) 14 polarization Plate 15 Polarizer 16 Phase difference compensator 17 Phase difference compensator 18 Pixel electrode (display content rewriting means, voltage applying means) 19 Drive electrode (display content rewriting means, voltage applying means) 19a Transmissive display opening 20 Transparent pixel electrode (Display content rewriting means, voltage applying means) 21 TFT element 22 Drain terminal 23 Wiring 24 Wiring 25 Organic insulating film 26 Auxiliary capacitance part 27 Auxiliary capacitance line 28 Saw Terminal 29 substrate 40 electrode substrate 41 substrate 42 alignment film (alignment mechanism) 42a alignment treatment area 42b alignment treatment region 52 glass substrate 53 comb electrode (display content rewriting means, voltage applying means,
Alignment mechanism) 54 substrate 61R color filter 61G color filter 61B color filter 62 glass substrate 71 touch panel (press coordinate detection type input means) 72 transparent electrode layer 73 movable substrate 74 transparent electrode layer 75 support substrate 100 liquid crystal cell (liquid crystal display element) 101 Electrode substrate 102 Electrode substrate 200 Liquid crystal cell (liquid crystal display element) 201 Electrode substrate 202 Electrode substrate 501 Smoothing layer 502 Counter electrode (display content rewriting means, voltage applying means)

Continuing from the front page (72) Inventor Seiichi Mitsui 22-22 Nagaikecho, Abeno-ku, Osaka-shi, Osaka F-term (reference) 2H089 HA18 RA05 RA06 TA04 TA07 TA17 2H090 KA05 KA06 LA01 LA04 LA20 MA02 MA14 2H091 FA15Y FD04 GA03 GA06 HA07 HA08 LA13 2H092 GA12 PA02 PA12 QA07 QA08

Claims (3)

[Claims] 1. A liquid crystal display device comprising: a liquid crystal display element having a pair of substrates having alignment means provided on opposing surfaces, and a liquid crystal layer sandwiched between the pair of substrates. Provided with an alignment mechanism for simultaneously taking at least two different alignment states in arbitrary and different areas used for display in the display, and in at least one of the regions showing different alignment states in the liquid crystal layer. A liquid crystal display device provided with a reflection unit, wherein the regions exhibiting different alignment states are used for a reflection display unit for performing a reflection display and a transmission display unit for performing a transmission display. 2. The liquid crystal display device according to claim 1, wherein said alignment mechanism is a display content rewriting means for rewriting the display content as time passes. 3. An apparatus according to claim 1, further comprising: a pressed coordinate detecting type input means which is disposed on the display surface and detects a coordinate position pressed by being pressed. 3. The liquid crystal display device according to claim 1, wherein an alignment state of a liquid crystal layer in at least one of the reflective display unit and the transmissive display unit is changed in response to a signal.