JP2000241811A - Field sequential liquid crystal display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a field sequential liquid crystal display device which enables a highly bright and highly precise picture display and besides attains an accurate color display. SOLUTION: The field sequential liquid crystal display device uses an organic EL light emitting panel 2 provided with three kinds of organic EL light emitting layers 22a, 22b, 22c which develop three primary colors R, G and B as a backlight and selectively emits light with three primary colors R, G or B under application of voltage. A light diffusing plate 3, which diffuses and transmits light emitted from the organic EL light emitting layers 22a, 22b, 22c to a range corresponding to a display screen of a liquid crystal shutter display panel 1 is arranged between a backlight side polarizing plate 11 out of a pair of polarizing plates 10, 11 for the liquid crystal shutter display panel 1 and the organic EL light emitting layers 22a, 22b, 22c.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a field sequential liquid crystal display device, and more particularly, to a field sequential liquid crystal display device using an organic EL light emitting panel as a backlight.

[0002]

2. Description of the Related Art As a color display device, a color filter type color liquid crystal display device is conventionally known. This is a combination of a liquid crystal cell having a black and white light shutter function and an RGB micro color filter, and realizes multi-color display or full-color display by additive color mixture. Specifically, this color liquid crystal display device has one transparent substrate in which transparent electrodes and RGB color filters are sequentially formed on the entire surface or in a stripe shape on the opposite surface, and further, an alignment layer is formed thereon, and a transparent substrate is formed on the opposite surface. Transparent electrode such as simple stripe or T
Liquid crystal is sealed between the FT array and another transparent substrate on which an alignment layer is sequentially formed to form a liquid crystal cell, and the liquid crystal cell is sandwiched between a pair of polarizing plates. Is used.

However, in such a color liquid crystal display device,
Since the image is displayed through the polarizing plate and the RGB color filters, the light transmittance is considerably low (about 1 to 3%), and therefore, there is a problem that the light use efficiency of the backlight is low. In addition, R, G, and B color filter elements are arranged so that R,
Since one dot is displayed by three pixels of G and B, it is difficult to further miniaturize a pixel having one side of about 0.3 mm at present and to perform high-definition display.

Therefore, a field sequential liquid crystal display device is known as a color display device that can solve these problems. It has a backlight (such as a three-wavelength fluorescent tube) that selectively emits three primary colors of R, G or B, and a liquid crystal cell sandwiched between a pair of polarizing plates, and is synchronized with light emission from the backlight. And a liquid crystal shutter display panel for displaying light emission from the backlight in a predetermined display pattern by selectively opening a specific region so as to be capable of transmitting light, and selectively emitting light of three primary colors from the backlight. And the display pattern of the liquid crystal shutter display panel,
The color display is performed by switching at high speed and displaying the respective display patterns of R, G and B continuously and superimposed at high speed in a time division manner. For example, if only one color of R, G, or B is displayed in a specific area, that color is displayed in that area, and two colors of R, G, and B are sequentially switched at high speed in another specific area. If the three colors of R, G, and B are sequentially switched at a high speed in another specific region and displayed in a superimposed manner, the two colors are displayed by additive color mixture in the region. In the region, three colors are displayed by additive color mixing.

According to this field sequential liquid crystal display device, a color filter is not required, which is advantageous for high luminance. In addition, a color filter system in which one dot is displayed by three pixels of R, G and B is used. Since one dot can be displayed in an area corresponding to one pixel in the system, high-definition display of about three times is possible.

[0006]

However, in the conventional field-sequential liquid crystal display device, a three-wavelength fluorescent tube is generally used as a backlight, and since the switching speed of the luminescent color is slow, each of these colors is used. However, there is a problem that the characteristics of the field sequential liquid crystal display device, which is advantageous for increasing the luminance, cannot be sufficiently achieved.

The inventor of the present invention has conceived of using an organic EL light emitting panel having a high-speed response for a backlight. However, the organic EL light emitting panel in which three kinds of light emitting layers of R, G and B are formed separately from each other. When the light-emitting panel is used as it is for a backlight, it has been found that the following problems occur. That is, in the field sequential liquid crystal display device, it is desirable that the emission luminance of each of the R, G, and B colors be uniform between the respective dots of the liquid crystal shutter display panel in order to achieve accurate color display. In order to make the luminance of each of the R, G, and B colors between the dots of the liquid crystal shutter display panel uniform, the distance from the light emitting layer to the shutter opening of the liquid crystal shutter display panel is fixed.
It is desirable to minimize the pitch between the light emitting layers in the organic EL display panel. Ideally, R, G and B are directly under each dot of the liquid crystal shutter display panel.
It is desirable to have a light source for each color. However, organic EL
When three types of light-emitting layers of R, G, and B are separately formed by a mask vapor deposition method or the like in a light-emitting panel and formed separately from each other, it is difficult to finely separate the light-emitting layers from the viewpoint of mask rigidity. Making the pitch between the layers as small as possible and forming three types of light emitting layers of R, G and B within a range corresponding to one dot of the liquid crystal shutter display panel involve manufacturing difficulties.

If the size of one dot of the liquid crystal shutter display panel (the size of the opening of the shutter) is increased, one dot is obtained.
It is possible to form three types of light emitting layers of R, G and B within a range corresponding to a dot. In this case, however, it is disadvantageous in achieving a high-definition screen display, and a liquid crystal capable of achieving a high-definition display The advantage of the shutter display panel is lost.

Further, if the distance from the light emitting layer of the organic EL light emitting panel to the shutter opening of the liquid crystal shutter display panel is increased, the irradiation range of the colored light is widened. This is advantageous in making the light emission luminance of each of the colors B and B uniform, but in this case, it is not advantageous because the thickness of the entire field sequential liquid crystal display device is increased.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and provides a field sequential liquid crystal display device capable of displaying a high-luminance and high-definition screen and achieving accurate color display. It is a technical problem to be solved.

[0011]

According to a first aspect of the present invention, there is provided a field sequential liquid crystal display device comprising:
A backlight that selectively emits the three primary colors, and a liquid crystal cell sandwiched between a pair of polarizing layers, wherein a specific region is selectively light-transmittable and opened in synchronization with light emission from the backlight. And a liquid crystal shutter display panel for displaying light emission from the backlight in a predetermined display pattern, and selectively switching the light emission of three primary colors from the backlight and the display pattern of the liquid crystal shutter display panel in order. A field-sequential liquid crystal display device in which color display is performed by successively displaying respective display patterns of G or B in a time-division manner, wherein the backlight has three primary colors of R, G and B. An organic EL light-emitting panel that includes three types of organic EL light-emitting layers that emit light and selectively emits three primary colors of R, G, and B by applying a voltage. A light diffuser for diffusing and transmitting light emitted from the organic EL light emitting layer to a range corresponding to the display screen of the liquid crystal shutter display panel between the organic EL light emitting layer and the polarizing layer on the backlight side in the light layer. Means are arranged.

This field-sequential liquid crystal display device includes three types of organic EL light emitting layers which emit three primary colors of R, G and B as a backlight, and selectively applies three primary colors of R, G and B by applying a voltage. An organic EL light emitting panel that emits light is used. The organic EL light emitting panel is capable of emitting high-luminance surface light and has a response speed of the order of nsec, and thus has a characteristic that the response is extremely faster than that of a three-wavelength fluorescent tube or the like. For this reason, the lighting time of each color can be prolonged with an increase in the switching speed of the emission color, and as a result, the characteristics of the field sequential liquid crystal display device, which is advantageous for high luminance, can be sufficiently achieved.

Further, in this field sequential liquid crystal display device, the light emitted from the organic EL light emitting layer is diffused by a light diffusing means to a range corresponding to the display screen of the liquid crystal shutter display panel, and then the liquid crystal cell of the liquid crystal shutter display panel is turned on. Reach within. For this reason, each color light emitted from the organic EL light emitting panel is made to emit pseudo full-surface light. As a result, regardless of the pitch between the light emitting layers in the organic EL light emitting panel, the R, G, and The emission brightness of each color B becomes uniform. Therefore, accurate color display can be achieved even when the pitch between the R, G, and B light emitting layers is made larger than before and the coating is performed roughly.

[0014] Since each color light emitted from the organic EL light emitting panel can be simulated as a whole surface light emission, R, G and B between each dot of the liquid crystal shutter display panel can be obtained.
There is no need to intentionally increase the size of one dot (the size of the opening of the shutter) in order to make the emission luminance of each color uniform. Therefore, by maintaining the size of one dot as in the related art, it is possible to maintain the advantage of the liquid crystal shutter display panel capable of achieving high-definition display.

Further, in order to make the emission luminance of each of the R, G and B colors between the dots of the liquid crystal shutter display panel uniform, the distance from the light emitting layer of the organic EL light emitting panel to the shutter opening of the liquid crystal shutter display panel is dared. Since there is no need to increase the length, the thickness of the entire field sequential liquid crystal display device does not increase. (2) In the field sequential liquid crystal display device according to the second aspect, in the field sequential liquid crystal display device according to the first aspect, the light diffusing means includes a polarizing layer on the backlight side of the liquid crystal shutter display panel and the backlight. And a light diffusing member disposed between them.

In this field sequential liquid crystal display device, light is emitted from the organic EL light emitting layer by a light diffusing member disposed between the polarizing layer on the backlight side of the liquid crystal shutter display panel and the organic EL light emitting panel as the backlight. Since the emitted light is diffused to a range corresponding to the display screen of the liquid crystal shutter display panel, each of the colored lights from the organic EL light emitting panel can be made to emit pseudo full surface light. Therefore, the same effect as that of the field sequential liquid crystal display device according to the first aspect is obtained. (3) In the field sequential liquid crystal display device according to the third aspect, in the field sequential liquid crystal display device according to the first aspect, the organic EL light emitting panel includes a light transmitting substrate capable of transmitting light, and the light transmitting substrate. A transparent first electrode layer formed thereon, the organic EL light emitting layer formed on the first electrode layer so as to be divided from each other, and a second electrode layer formed on the organic EL light emitting layer. Wherein the light-transmitting substrate is a ground glass substrate as the light diffusing means.

In this field-sequential liquid crystal display device, a frosted glass substrate is disposed on the liquid crystal shutter display panel side of the organic EL light emitting panel and is capable of transmitting light from the organic EL light emitting layer. If the ground surface of the ground glass substrate is arranged outside the organic EL light-emitting panel, and if an air layer exists outside the rough surface, the color light transmitted through the ground glass substrate enters the rough surface. As a result, the light is almost uniformly diffused, so that each of the colored lights from the organic EL light emitting panel can be made to emit pseudo full-surface light. Therefore, the same effect as that of the field sequential liquid crystal display device according to the first aspect is obtained.

Further, since it is not necessary to separately provide a light diffusing plate, it contributes to thinning of the field sequential liquid crystal display device. Furthermore, since the colored light transmitted through the frosted glass substrate is almost uniformly diffused on the rough surface, it is considered that light can be prevented from being multiply reflected within the frosted glass substrate and guided to the side end surface. For this reason, an improvement in luminance can be expected due to a reduction in light that is lost by being guided to the side end face due to multiple reflection. (4) In the field sequential liquid crystal display device according to the fourth aspect, in the field sequential liquid crystal display device according to the first aspect, the organic EL light emitting panel includes a light transmitting substrate capable of transmitting light, and the light transmitting substrate. A transparent first electrode layer formed thereon, the organic EL light emitting layer formed on the first electrode layer so as to be divided from each other, and a second electrode layer formed on the organic EL light emitting layer. Wherein the translucent substrate is an opalescent glass substrate as the light diffusing means.

In this field sequential liquid crystal display device, in the organic EL light emitting panel, the translucent substrate which is disposed on the liquid crystal shutter display panel side and is capable of transmitting light from the organic EL light emitting layer is a milky glass substrate. Since the color light transmitted through the milky glass substrate is substantially evenly diffused during the transmission, each color light from the organic EL light emitting panel can be made to be pseudo whole surface light. Therefore, the same effect as that of the field sequential liquid crystal display device according to the first aspect is obtained.

Further, since it is not necessary to separately provide a light diffusing plate, it contributes to a reduction in the thickness of the field sequential liquid crystal display device. Further, since the color light transmitted through the milky glass substrate is substantially uniformly diffused during the transmission, it is considered that the light can be prevented from being multiple reflected inside the milky glass substrate and guided to the side end surface. For this reason, an improvement in luminance can be expected due to a reduction in light that is lost by being guided to the side end face due to multiple reflection. (5) In the field sequential liquid crystal display device according to the fifth aspect, in the field sequential liquid crystal display device according to the fourth aspect, the light transmitting substrate and the liquid crystal shutter display panel are disposed between the two. It is characterized by being joined while interposing a substance having a refractive index equal to the refractive index.

In this field sequential liquid crystal display device, the translucent substrate of the organic EL light emitting panel is a milk glass substrate, and the translucent substrate and the liquid crystal shutter display panel are interposed between the translucent substrate and the liquid crystal shutter display panel. Since it is joined while interposing a substance having the same refractive index as that of
In addition to the same functions and effects as the field sequential liquid crystal display device according to the fourth aspect, the following functions and effects are also provided.

That is, since a substance having the same refractive index as the glass base material of the milky glass substrate is interposed between the milky glass substrate as the light-transmitting substrate and the liquid crystal shutter display panel, Color light incident on the interface with the substance is prevented from being reflected on the interface. Therefore, the loss of light due to multiple reflections in the milky glass substrate can be further reduced, which greatly contributes to the improvement in luminance.

A liquid crystal shutter display panel and an organic EL
Since the light-emitting panel is joined, the strength can be improved structurally.

[0024]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A field sequential liquid crystal display device according to the present invention includes a liquid crystal shutter display panel and an organic EL light emitting panel as a backlight. The structure of the liquid crystal shutter display panel may be such that a liquid crystal cell having a shutter function is sandwiched between a pair of polarizing plates. The specific configuration of the liquid crystal cell includes a pair of transparent substrates, a pair of transparent electrodes respectively formed on opposing surfaces of the respective transparent substrates, a pair of alignment films respectively formed on the respective transparent electrodes, and Can be configured to include a sealing material that joins and seals the periphery while maintaining a predetermined distance, and a liquid crystal sealed in the sealing space.

Each of the above-mentioned polarizing plates may be provided with a polarizing layer having linear polarization axes orthogonal to each other. A glass substrate or a plastic substrate can be used as the transparent substrate. The liquid crystal sealed in the liquid crystal cell of the liquid crystal shutter display panel is an OCB (Optically Compensated Benzene) having a high response speed and capable of high-speed switching.
d) Mode of nematic liquid crystal, ferroelectric liquid crystal or TN (Twi
Sted Nematic) Liquid crystal or the like can be used.

The alignment film is for aligning liquid crystal molecules in a certain direction on the surface, and is formed by rubbing the surface of a film of a heat-resistant resin such as polyimide with a cloth such as nylon in a certain direction. be able to. Examples of the transparent electrode include ITO, AZO (Al-added ZnO), SnO _{2, and the} like as in the related art. This transparent electrode layer can be formed by a method such as sputtering.

Each of the transparent electrodes is formed by a predetermined patterning such as a stripe pattern. By applying a voltage, the molecular arrangement of the liquid crystal is changed only in a specific region in a unit of one dot, and the relationship with the pair of polarizing layers is changed. Thus, the light transmittance can be changed only in the region. For this reason, by selectively opening a specific area so as to be capable of transmitting light in synchronization with light emission from the backlight, light emission from the backlight can be displayed in a predetermined display pattern, and the three primary colors from the backlight can be displayed. , And the display pattern of the liquid crystal shutter display panel is sequentially switched at a high speed so that R, G or B
The color display can be performed by successively displaying the respective display patterns in a time division manner.

The organic EL light-emitting panel as a backlight includes three types of organic EL light-emitting layers that emit three primary colors of R, G and B, and selectively emits three primary colors of R, G and B by applying a voltage. Is what you do. As a specific structure of the organic EL light emitting panel, a light transmitting substrate capable of transmitting light, a transparent first electrode layer formed on the light transmitting substrate,
The organic EL device includes three types of organic EL light emitting layers emitting three primary colors of R, G, and B formed separately from each other on the first electrode layer, and a second electrode layer formed on the organic EL light emitting layer. It can be.

As the light-transmitting substrate, a transparent glass substrate is usually used, but a transparent synthetic resin substrate can also be used. As will be described later, a frosted glass substrate that can diffuse and transmit light almost uniformly on a rough surface, or a milk glass substrate that diffuses light almost uniformly while transmitting through the substrate can also be used. As a material of the transparent first electrode layer, ITO, AZO (Al-added ZnO), SnO ₂
And the like. This transparent first electrode layer can be formed by a method such as sputtering. The pattern of the transparent first electrode layer is not particularly limited, and the transparent first electrode layer can be formed in a pattern similar to a conventional one such as a stripe shape.

The organic EL light emitting layer can be composed of a hole transport layer, a light emitting layer formed on the hole transport layer, and an electron transport layer formed on the light emitting layer. Among them, as the material of the hole transport layer, a tertiary amine derivative such as a triphenyldiamine derivative, a di (tri) azole derivative such as a (di) styrylbenzene (pyrazine) derivative, a diolefin derivative, an oxadiazole derivative, Examples thereof include those used in conventional organic EL devices such as quinosaline derivatives, furan compounds, hydrazone compounds, naphthacene derivatives, coumarin compounds, quinacridone derivatives, indole compounds, pyrene compounds, and anthracene compounds.

As the light emitting layer, a trisquinolino aluminum complex, a distyrylbiphenyl derivative, an oxadiazole derivative, or the like used in a conventional organic EL device is used. Examples of the electron transport layer include polysilane, oxadiazole derivatives, and trisquinolino aluminum complexes.

Each layer constituting the organic EL light emitting layer is formed by a vacuum evaporation method, a Langmuir-Blodgett evaporation method,
It can be formed by a dip coating method, a spin coating method, a vacuum gas evaporation method, an organic molecular beam epitaxy method, or the like. The three types of organic EL light-emitting layers that emit the three primary colors of R, G, and B can be formed separately from each other by a mask vapor deposition method as in the related art.

Examples of the material of the second electrode layer formed on the organic EL light emitting layer include a conductive metal such as an Mg-Ag alloy and Al. If the second electrode layer is formed of a material having a metallic luster, light traveling from the organic EL light emitting layer toward the second electrode layer can be directed toward the light transmitting substrate by reflection at the second electrode layer. Thus, the amount of emitted light can be increased. The pattern of the second electrode layer can also be formed in a pattern similar to the conventional one such as a stripe pattern corresponding to the pattern of the first electrode layer. However, since the second electrode layer is formed over the organic EL light-emitting layer, it cannot be formed by a film formation method such as sputtering, which operates at a high temperature. Therefore, the material of the metal electrode layer is selected from materials that can be formed by an evaporation method or the like.

Here, the organic luminescent material used for the organic EL luminescent layer has a drawback that its water resistance is low and its life is shortened by moisture. Further, the second electrode layer made of an Mg alloy or the like formed on the organic EL light emitting layer also has a drawback that its resistance to water and oxygen is low. Therefore, as in the conventional case, the organic E
The L light emitting layer, the second electrode layer, and the like are hermetically sealed in a sealing member, and an inert substance (nitrogen gas, helium gas, argon gas, etc.) It is preferable to encapsulate an inert gas such as, for example, a fluorine-based inert liquid, etc.) and a moisture absorbent (eg, an alkali metal oxide or an alkaline earth metal oxide). For sealing the organic EL element, for example, a box-shaped or plate-shaped sealing glass or resin having an opening on one side is used as a sealing member, and the periphery of the sealing glass or the like is bonded to the periphery of the light-transmitting substrate. It can be performed by bonding with a sealing agent such as an agent, or by forming an enclosed space only with a sealing member and disposing a translucent substrate or the like inside the enclosed space.

Here, the liquid crystal shutter display panel and the organic EL light-emitting panel having the above-mentioned structures may be configured to be integrally joined from the viewpoint of reducing the thickness of the entire display device and improving the structural strength. preferable. In the field sequential liquid crystal display device of the present invention, the light emitted from the organic EL light emitting layer is emitted between the backlight side polarizing layer and the organic EL light emitting layer of the pair of polarizing layers on the display screen of the liquid crystal shutter display panel. A light diffusing means for diffusing and transmitting light to a corresponding range is arranged.

The light diffusing means is not particularly limited as long as it has a function of diffusing and transmitting light emitted from the organic EL light emitting layer to a range corresponding to the display screen of the liquid crystal shutter display panel. In addition, the arrangement position of the light diffusing means is particularly between the backlight-side polarizing layer of the pair of polarizing layers constituting the liquid crystal shutter display panel and the organic EL light-emitting layer constituting the organic EL light-emitting panel. Not limited. By arranging the light diffusion means in this way,
The light emitted from the organic EL light emitting layer reaches the polarizing layer on the backlight side after being diffused by the light diffusing means to a range corresponding to the display screen of the liquid crystal shutter display panel.

Some preferred embodiments of the light diffusing means are described below. As one mode of the light diffusing means, a light diffusing member disposed between the polarizing layer on the backlight side of the liquid crystal shutter display panel and the organic EL light emitting panel as the backlight can be used. Light is substantially evenly diffused while passing through the inside. As the light diffusing member, a plate-like or film-like thing can be adopted. For example, a light diffusion plate in which glass fibers having a different refractive index from the resin substrate are uniformly dispersed in a transparent polycarbonate resin substrate, or a white pigment is uniformly dispersed in a transparent polycarbonate resin film, or the surface of a polycarbonate resin film. If a light-diffusing film printed with a white pigment is used as a light-diffusing member and these are interposed between the polarizing layer on the backlight side of the liquid crystal shutter display panel and the light-transmitting substrate of the organic EL light-emitting panel. Good. Further, a film containing light-scattering particles or a concavo-convex film may be formed directly on the polarizing layer on the backlight side of the liquid crystal shutter display panel or on the surface of the light-transmitting substrate of the organic EL light-emitting panel. Further, the polarizing plate on the backlight side is configured to include the substrate made of the light diffusion film and the polarizing layer formed on the substrate, and the substrate made of the light diffusion film is arranged on the backlight side. This polarizing plate can be provided on a transparent substrate on the backlight side.

As another mode of the light diffusing means, a frosted glass substrate used as a light-transmitting substrate constituting an organic EL light-emitting panel can be used. In this case, the ground surface is arranged so that the rough surface of the ground glass substrate is outside the organic EL light-emitting panel (the liquid crystal shutter display panel side), and an air layer is present outside the rough surface to thereby provide the rough surface. Thus, light can be diffused and transmitted almost uniformly. In this embodiment, for example, the light-transmitting substrate constituting the organic EL panel is a ground glass substrate having an outer rough surface, and the rough surface of the ground glass substrate and the transparent substrate constituting the liquid crystal shutter display panel are provided. This can be achieved by bonding the peripheral edge of the frosted glass substrate and the peripheral edge of the transparent substrate with an adhesive or the like while an air layer is interposed between the polarizing plate and the polarizing plate.

Further, as another mode of the light diffusing means, a milk glass substrate used as a light-transmitting substrate constituting an organic EL light-emitting panel can be used. In this case, light is substantially uniformly diffused while passing through the milky glass substrate.
In the case of adopting such an embodiment, a milky glass substrate as a light-transmitting substrate and a liquid crystal shutter display panel are joined together while a material having a refractive index equivalent to the refractive index of the milky glass substrate is interposed therebetween. Is preferred. This is because it is possible to suppress the color light incident on the interface with the substance from the opalescent glass substrate from being reflected on the interface.

In this embodiment, for example, a translucent substrate constituting an organic EL panel is made of a milky glass substrate, and between the milky glass substrate and a polarizing plate provided on a transparent substrate constituting a liquid crystal shutter display panel. While forming a predetermined gap,
The periphery of the milky glass substrate and the periphery of the transparent substrate are joined with an adhesive or the like to form a sealed space, and a liquid, gel, or solid substance in the sealed space and having a refractive index of the milky glass substrate This can be achieved by enclosing a substance having a refractive index equivalent to that of. Such an encapsulating material includes ZrO
₂ , a silicone oil or a silicone gel whose refractive index is adjusted by a TiO ₂ or Al ₂ O ₃ filler can be exemplified.

An adhesive (for example, ZrO ₂ , TiO ₂ , or the like) having a refractive index equivalent to that of the milky glass substrate is provided between the milky glass substrate and the polarizing plate provided on the transparent substrate constituting the liquid crystal shutter display panel. An epoxy adhesive whose refractive index has been adjusted by an Al ₂ O ₃ filler)
The milky glass substrate and the transparent substrate may be bonded. This further contributes to a reduction in the thickness of the entire field sequential liquid crystal display device.

[0042]

The present invention will be described below in detail with reference to examples. (Embodiment 1) This embodiment embodies the field sequential liquid crystal display device according to claim 1 or 2.

FIG. 1 shows a field-sequential liquid crystal display device according to the present embodiment, which includes a liquid crystal shutter display panel 1, an organic EL light emitting panel 2 as a backlight, and a liquid crystal shutter display panel 1 and an organic EL light emitting panel 2. And a light diffusion plate 3 as an interposed light diffusion means. The liquid crystal shutter display panel 1 has a configuration in which a liquid crystal cell having a shutter function is sandwiched between a pair of polarizing plates 10 and 11. The specific configuration of the liquid crystal cell is such that a pair of transparent glass substrates 12 and 13, a pair of transparent electrodes 14 and 15 formed on opposing surfaces of the respective transparent glass substrates 12 and 13, and A sealing material 1 that joins and seals the periphery while maintaining a predetermined interval between the pair of alignment films 16 and 17 formed and the transparent glass substrates 12 and 13.
8 and a liquid crystal 19 enclosed in the enclosed space.

The polarizing plates 10 and 11 are made of a polyvinyl alcohol-iodine system and have a structure in which polarizing layers having a linear polarizing axis are sandwiched between plastic films, and the polarizing axes of the respective polarizing layers are orthogonal to each other. It is arranged as follows. The liquid crystal 19 is an OCB (Optically Compensated Bend) mode nematic liquid crystal, which has a high response speed and can be switched at high speed, specifically, a TD6004XX (Chisso) liquid crystal.

The alignment films 16 and 17 are for aligning liquid crystal molecules in a certain direction on the surface, and rub the surface of a film of a heat-resistant resin such as polyimide with a cloth such as nylon in a certain direction. Can be formed. The alignment directions of the alignment films 16 and 17 are along the surfaces of the transparent glass substrates 12 and 13, and the alignment direction of the alignment film 16 and the alignment direction of the alignment film 17 are orthogonal to each other.

The transparent electrodes 14 and 15 are formed by patterning in the form of stripes perpendicular to each other by sputtering, and have a thickness of 1000 to 2000 °. For this reason, the liquid crystal shutter display panel 1 uses the intersection of the two transparent electrodes 14 and 15 as one dot unit, and changes the molecular arrangement of the liquid crystal 19 only in a specific region in one dot unit by applying a voltage. Polarizing plates 10, 1
Due to the relationship with 1, the light transmittance can be changed only in this region. The size of one dot is 100 μm.
m × 100 μm, which maintains the advantage of the liquid crystal shutter display panel 1 capable of achieving high definition display. Further, the transparent electrodes 14 and 15 may be such that one is the whole surface and the other is a pixel size and is switched by a TFT or the like.

The organic EL light-emitting panel 2 includes a transparent glass substrate 20 as a light-transmitting substrate capable of transmitting light, a transparent first electrode layer 21 made of an ITO film formed on the transparent glass substrate 20, and Each of the three primary colors R, G, and B, which are formed on the first electrode layer 21 so as to be divided from each other, are generated.
Types of organic EL light emitting layers 22a, 22b, 22c and Mg formed on the organic EL light emitting layers 22a, 22b, 22c
-A second electrode layer 23 made of an Ag alloy, a back glass substrate 24 as a sealing member, and a sealing in which the peripheries of the transparent glass substrate 20 and the back glass substrate 24 are joined to form a sealed space therebetween. And an adhesive 25 as an agent.

The first electrode layer 21 is formed in a stripe shape on the transparent glass substrate 20 by sputtering.
Its thickness is 1000-2000 °. The above organic EL
The light emitting layers 22a, 22b, and 22c are formed of a hole transport layer formed on the first electrode layer 21, and three types of light emitting layers emitting three primary colors of R, G, and B formed on the hole transport layer. And an electron transporting layer formed on the light emitting layer, each of which is formed from a known organic material by a mask vapor deposition method, and has a total thickness of 1000 to 1500 °.
The organic EL light emitting layers 22a, 22b, and 22c are alternately formed in stripes on the first electrode layers 21 formed in stripes.

In this embodiment, T is used as the hole transport layer.
Alq ₃ doped with DCM (laser dye) using PD (triphenylamine dimer) as an R light emitting layer.
(Aluminoquinolinol complex), a quinacridone derivative as a G light emitting layer, an oxadiazole derivative as a B light emitting layer, and Alq ₃ as an electron transport layer. The second electrode layer 23 has a thickness of 1500 by a mask evaporation method.
It is formed in a stripe shape perpendicular to the first electrode layer 21.

The first electrode layer 21 and the second electrode layer 23
Crosses each other to form a pixel emitting a predetermined color of R, G or B. In this embodiment, the pixel pitch is set to about 1 mm. The back glass substrate 24 and the transparent glass substrate 20 as the sealing member have the same shape and the same size, and the peripheral edges of the both are ultraviolet curable adhesives 25.
It is joined by. The use of an ultraviolet-curing adhesive prevents a problem that the organic EL light emitting layer is deteriorated due to a high temperature at the time of bonding. Thus, an airtight sealed space 26 is formed by the transparent glass substrate 20, the rear glass substrate 24, and the adhesive 25, and the sealed space 26 is formed.
The inside is filled with nitrogen gas. Note that the pressure of the nitrogen gas is set to be 1 atm at room temperature (25 ° C.). The nitrogen gas is sealed in the sealing space 26 in advance by the first electrode layer 21, the organic EL light emitting layers 22a, 22b,
Transparent glass substrate 20 on which 2c and second electrode layer 23 are formed
And the rear glass substrate 24 in a nitrogen gas with an adhesive 25.

Therefore, in this organic EL light-emitting panel 2, the organic EL light-emitting panel 2
When a DC voltage is applied to the L light emitting layers 22a, 22b, 22c, light is emitted in each color, and the light is transmitted through the first electrode layer 21 and the transparent glass substrate 20. The liquid crystal shutter display panel 1 and the organic EL light emitting panel 2 having the above configuration are
The light diffusion plate 3 is interposed between the polarizing plate 11 and the transparent glass substrate 20 on the organic EL light emitting panel 2 side, and the periphery thereof is joined by the adhesive 4. The light diffusing plate 3 is in contact with the polarizing plate 11 and the transparent glass substrate 20 without any gap. The transparent glass substrate 1 of the liquid crystal shutter display panel 1
2, 13 and the transparent glass substrate 2 of the organic EL light emitting panel 2
0 is the same shape and the same size, and the thickness is 1.
It is the same as 1 mm. Further, the polarizing plates 10, 11 and the light diffusing plate 3 have the same shape and the same size, and the thickness of the light diffusing plate 3 is 1.5 mm.

The light diffusing plate 3 is formed by uniformly dispersing glass fibers having a different refractive index from the resin substrate in a transparent polycarbonate resin substrate.
While transmitting the light, the light is almost uniformly diffused to a range corresponding to the display screen of the liquid crystal shutter display panel 1. Therefore, in the field sequential liquid crystal display panel of the present embodiment, a specific area of the liquid crystal shutter display panel 1 is selectively opened so as to be able to transmit light in synchronization with light emission from the organic EL light emitting panel 2 as a backlight. Light emission from the organic EL light emitting panel 2 can be displayed in a predetermined display pattern, and selective light emission of three primary colors from the organic EL light emitting panel 2 and the display pattern of the liquid crystal shutter display panel 1 are sequentially switched at high speed. , R, G or B, color display can be performed by continuously displaying the respective display patterns in a time division manner. And
The organic EL light emitting panel 2 is capable of emitting light with high brightness and has a response speed of the order of nsec. For this reason, the lighting time of each color can be prolonged with an increase in the switching speed of the emission color, and as a result, the characteristics of the field sequential liquid crystal display device, which is advantageous for high luminance, can be sufficiently achieved.

In the field sequential liquid crystal display device, the organic EL light emitting layers 22a, 22b, 22c
Is diffused by the light diffusing plate 3 to a range corresponding to the display screen of the liquid crystal shutter display panel 1, and then reaches the liquid crystal 19 in the liquid crystal shutter display panel 1. For this reason, each color light emitted from the organic EL light emitting panel 2 is a pseudo whole-surface light emission. As a result, regardless of the size of the pixel pitch in the organic EL light emitting panel 2, R , G and B have uniform emission luminance. Therefore, accurate color display can be achieved despite the pixel pitch of the organic EL light emitting panel 2 being about 1 mm, which is larger than the conventional one.

Further, the liquid crystal shutter display panel 1 and the organic EL light emitting panel 2 are joined by an adhesive 4,
Further, since the light diffusing plate 3 is interposed between the two without any gap, the strength of the field sequential liquid crystal display device can be extremely improved structurally. (Embodiment 2) The present embodiment shown in FIG. 2 embodies the field sequential liquid crystal display device according to claim 1 or 2. In the first embodiment, the light diffusing plate 3 is used as a light diffusing member. Instead of using the light diffusion film 5, the other configuration is the same as that of the first embodiment.

That is, in this field-sequential liquid crystal display device, the light-diffusing film 5 in which a white pigment is uniformly dispersed in a polycarbonate resin film is formed of an organic E film.
It is attached on the surface of the polarizing plate 11 on the side of the L light emitting panel 2. The light diffusion film 5 has the same shape and the same size as the polarizing plate 11, and has a thickness of 0.2 mm.
During the transmission through the light diffusion film 5, the light is substantially uniformly diffused to a range corresponding to the display screen of the liquid crystal shutter display panel 1.

Therefore, according to this embodiment, as in the first embodiment, it is possible to achieve high luminance and accurate color display. The liquid crystal shutter display panel 1
And the organic EL light-emitting panel 2 were bonded without any gaps by the adhesive 4 via the light diffusion film 5, so that
Similarly to the above, the strength of the field sequential liquid crystal display device can be extremely improved structurally.

Further, in this field sequential liquid crystal display device, since the light diffusing film 5 is used as the light diffusing member, the field sequential liquid crystal display device is thinner than the first embodiment in which the light diffusing plate 3 is employed. Contribute to (Embodiment 3) The present embodiment shown in FIG. 3 embodies the field sequential liquid crystal display device according to claim 1, 3, or 4.

That is, in this field sequential liquid crystal display device, a frosted glass frosted glass substrate 6 as a light diffusing means is provided on the translucent substrate of the organic EL light emitting panel 2.
Is adopted. The frosted glass substrate 6 made of opalescent glass has a rough surface 6a formed on almost the entire surface on one surface, and the rough surface 6a is disposed outside the organic EL light-emitting panel 2. The periphery of the frosted glass substrate 6 made of milk glass and the organic E of the liquid crystal shutter display panel 1
By bonding the periphery of the transparent glass substrate 13 on the L light emitting panel side with the adhesive 4 having a predetermined thickness, the gap between the rough surface 6a and the polarizing plate 11 provided on the surface of the transparent glass substrate 13 is obtained. The air layer 6b is interposed.

The other structure is the same as that of the first embodiment. In this field sequential liquid crystal display device,
Colored light from the organic EL light emitting / emitting layers 22a, 22b, 22c diffuses substantially evenly while passing through the frosted glass substrate 6 of the opalescent glass, and diffuses and transmits almost evenly on the rough surface 6a. The light is substantially uniformly diffused to a range corresponding to one display screen. Therefore, each color light emitted from the organic EL light-emitting panel 2 can be made to be pseudo whole-surface light emission. Therefore, according to the present embodiment, similarly to the first embodiment, it is possible to achieve high luminance and accurate color display.

The liquid crystal shutter display panel 1 and the organic E
Since the L light emitting panel 2 and the L light emitting panel 2 are joined by the adhesive 4, the strength of the field sequential liquid crystal display device can be structurally improved. Further, in this field sequential liquid crystal display device, there is no need to separately provide a light diffusing plate, which contributes to a reduction in the thickness of the field sequential liquid crystal display device. If the surface of the substrate 6 is engraved at a predetermined uniform depth and a rough surface is provided on the engraved surface, the thickness of the adhesive 4 can be reduced by the amount of the engraving. It is possible to further contribute to a reduction in the thickness of the device.

In addition, the color light transmitted through the frosted glass frosted glass substrate 6 is almost evenly diffused during the transmission, and the color light transmitted through the substrate 6 is almost uniformly diffused on the rough surface 6a. It is considered that it is possible to suppress the light being guided to the side end face due to multiple reflection in the inside 6. For this reason, an improvement in luminance can be expected due to a reduction in light that is lost by being guided to the side end face due to multiple reflection.

In the third embodiment, the example in which the rough surface is provided on the surface of the opalescent glass has been described. However, substantially the same operation can be achieved by employing either the opalescent glass or the coarse glass. The effect can be achieved. In other words, this is a case where a mere opalescent glass substrate having no rough surface or a mere rough glass substrate having a rough surface provided on the surface of transparent glass is used as the light-transmitting substrate of the organic EL light-emitting panel 2. Can achieve substantially the same effect.

(Embodiment 4) The present embodiment shown in FIG. 4 embodies the field sequential liquid crystal display device according to the first, fourth or fifth aspect. That is, in this field sequential liquid crystal display device,
The translucent substrate of the organic EL light emitting panel 2 employs a milky glass substrate 7 as a light diffusing means. The periphery of the milky glass substrate 7 and the organic EL of the liquid crystal shutter display panel 1
By joining the periphery of the transparent glass substrate 13 on the light emitting panel side with the adhesive 4 having a predetermined thickness, the opalescent glass substrate 7 and the polarizing plate 11 provided on the surface of the transparent glass substrate 13 are bonded.
A sealed space 8 having a predetermined gap (which can be set to about 0.1 to 1.0 mm, but is set to 0.5 mm in the present embodiment) is formed between them. In the enclosing space 8, ZrO ₂ , TiO ₂ are used as substances 9 having a refractive index equivalent to the refractive index of alkali glass serving as a matrix material of the milky glass substrate 7 (1.51 in this embodiment). ₂ , Al
Silicone oil (refractive index: 1.5) whose refractive index is adjusted by ₂ O ₃ fine particle filler is sealed.

The other structure is the same as that of the first embodiment. In this field sequential liquid crystal display device,
The color light emitted from the organic EL light emitting / emitting layers 22a, 22b, 22c is substantially evenly diffused while passing through the opalescent glass substrate 7, and is almost uniformly diffused to a range corresponding to the display screen of the liquid crystal shutter display panel 1. Therefore, each color light emitted from the organic EL light-emitting panel 2 can be made to be pseudo whole-surface light emission. Therefore, similar to the first embodiment, it is possible to achieve high luminance and accurate color display.

In this field sequential liquid crystal display device, there is no need to separately provide a light diffusing plate.
It contributes to the thinning of field sequential liquid crystal display devices. Further, the color light transmitted through the milky glass substrate 7 is almost uniformly diffused during the transmission, so that the milky glass substrate 7
It is considered that light is guided to the side end face due to multiple reflections in the inside. For this reason, an improvement in luminance can be expected due to a reduction in light that is lost by being guided to the side end face due to multiple reflection.

In addition, since the substance 9 having the same refractive index as that of the opalescent glass substrate 7 is interposed between the opalescent glass substrate 7 and the liquid crystal shutter display panel 1, the substance 9 is removed from the opalescent glass substrate 7. The reflection of the coloring light incident on the boundary surface at the boundary surface is suppressed. Therefore, light loss due to multiple reflections in the milky glass substrate 7 can be further reduced, which greatly contributes to improvement in luminance.

The liquid crystal shutter display panel 1 and the organic E
Since the L light-emitting panel 2 is joined, structural strength can be improved.

[0068]

As described above in detail, according to the field sequential liquid crystal display device of the present invention, it is possible to display a high-brightness and high-definition screen and to increase the pixel pitch of the organic EL light-emitting panel to about 1 mm. However, accurate color display can be achieved. Also, organic EL
As much as the pixel pitch of the light emitting panel can be increased, R,
Since the application of each of the light emitting layers of G and B can be roughened, the manufacture thereof is also simplified.

[Brief description of the drawings]

FIG. 1 is a schematic sectional view of a field sequential liquid crystal display device according to a first embodiment.

FIG. 2 is a partial cross-sectional view schematically showing a main part of a field sequential liquid crystal display device according to a second embodiment.

FIG. 3 is a schematic sectional view of a field sequential liquid crystal display device according to a third embodiment.

FIG. 4 is a schematic sectional view of a field sequential liquid crystal display device according to a fourth embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Liquid crystal shutter display panel 2 ... Organic EL light-emitting panel 3 ... Light diffusing plate 5 ... Light diffusing film 6 ... Milky glass ground glass substrate 7 ... Milky glass substrate 10, 11 ... Polarizing plate 19 ... Liquid crystal 20 ... Translucent substrate 21 ... Transparent first electrode layers 22a, 22b, 22c ... Organic EL light emitting layers 23 ... Second electrode layers

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Naoki Ogawa 1 Toyota Town, Toyota City, Aichi Prefecture Inside Toyota Motor Corporation (72) Inventor Nori Kawabashi 1 Toyota Town, Toyota City, Aichi Prefecture Inside Toyota Motor Corporation ( 72) Inventor Kazuhide Ota 1 Toyota Town, Toyota City, Aichi Prefecture Inside Toyota Motor Co., Ltd. FA44Z FB02 FC02 FC23 FD14 GA01 HA07 HA12 LA15 3K007 AB04 AB17 CA01 CB01 DA01 DB03 EB00 FA02

Claims (5)

[Claims] 1. A backlight which selectively emits three primary colors of R, G and B, and a liquid crystal cell sandwiched between a pair of polarizing layers, and a specific region is synchronized with light emission from the backlight. A liquid crystal shutter display panel which selectively emits light so as to be capable of transmitting light to display light emitted from the backlight in a predetermined display pattern.
A field-sequential display in which color display is performed by sequentially switching the primary color selective light emission and the display pattern of the liquid crystal shutter display panel and continuously displaying each of the R, G or B display patterns in a time-division manner. A liquid crystal display device, wherein the backlight emits three primary colors of R, G, and B.
Organic EL light emitting layers, and R, G
Or an organic EL light-emitting panel that selectively emits the three primary colors of B, between the polarizing layer on the backlight side and the organic EL light-emitting layer of the pair of polarizing layers. A light diffusing means for diffusing and transmitting the light emitted to a range corresponding to the display screen of the liquid crystal shutter display panel. 2. The liquid crystal shutter display panel according to claim 1, wherein the light diffusing means is a light diffusing member disposed between the backlight side polarizing layer of the liquid crystal shutter display panel and the backlight. Field sequential liquid crystal display device. 3. The organic EL light-emitting panel includes a light-transmitting substrate capable of transmitting light, a transparent first electrode layer formed on the light-transmitting substrate, and a partition on the first electrode layer. The organic EL light emitting layer formed by the above, and a second electrode layer formed on the organic EL light emitting layer, wherein the translucent substrate is a ground glass substrate as the light diffusing means. 2. The field sequential liquid crystal display device according to claim 1, wherein: 4. The organic EL light-emitting panel includes a light-transmitting substrate capable of transmitting light, a transparent first electrode layer formed on the light-transmitting substrate, and a partition on the first electrode layer. The organic EL light emitting layer formed by the above, and a second electrode layer formed on the organic EL light emitting layer, wherein the translucent substrate is an opalescent glass substrate as the light diffusing means The field sequential liquid crystal display device according to claim 1, wherein: 5. The liquid crystal shutter display panel according to claim 1, wherein the transparent substrate and the liquid crystal shutter display panel are joined together with a substance having a refractive index equivalent to that of the transparent substrate interposed therebetween. The field sequential liquid crystal display device according to claim 4.