JP4954911B2 - Display device - Google Patents

Description

The present invention relates to a thin and lightweight display device used for information devices such as word processors, notebook computers, various video devices and game devices, portable VTRs, digital cameras, etc., and particularly displays used both outdoors and indoors. The present invention relates to a display device used in an environment in which lighting conditions change drastically, such as a device, an automobile, an aircraft, and a ship.

  Display devices that can electrically rewrite display contents include a light-emitting type that emits light by itself and a non-light-emitting type that uses ambient light. Conventionally, electro-luminescence (EL) elements and plasma display panels (PDP) have been put into practical use as thin and light-emitting display devices, and liquid crystal displays have been put into practical use as non-light-emitting display devices. Yes.

  Inorganic and organic EL displays, which are one of the light-emitting display devices, can easily solve the low contrast and narrow viewing angle, which are the disadvantages of liquid crystal displays, and are actively researched as thin displays to replace them. Has been.

  FIG. 25 is a cross-sectional view illustrating the structure of the organic EL display element described above. In FIG. 25, an organic EL element 1 includes an ITO (Indium tin oxide) transparent electrode 3, a hole transport layer 4, a light emitting layer 5, an electron transport layer 6, a cathode (for example, an aluminum electrode) on a transparent substrate (for example, a glass substrate) 2. 7) are sequentially formed by, for example, a vacuum deposition method. When a DC voltage 8 is selectively applied between the transparent electrode 3 serving as the anode and the cathode 7, holes injected from the transparent electrode 3 pass through the hole transport layer 4, and electrons injected from the cathode 7 are transported by electrons. Through the layer 6, the light reaches the light emitting layer 5, where electrons and holes are recombined to generate light of a predetermined wavelength, and the emitted light L can be observed from the transparent substrate 2 side.

The material of the light emitting layer 5 may contain, for example, a complex compound of aluminum or zinc, but may be a layer substantially composed of only an aluminum complex (however, a combination of a plurality of types of aluminum complexes can be used) It may be a layer composed only of a zinc complex (however, a plurality of types of zinc complexes can be used in combination), or a fluorescent material added to these complex compounds.
By the way, in the case of this structure, when the ambient light in the usage environment is stronger than the emission luminance, the ambient light incident from the transparent substrate 2 side is reflected by the cathode 7 and the luminance in the state where no light is emitted, that is, the black state is high. Therefore, there is a drawback that a phenomenon called a washout phenomenon occurs in which the contrast is remarkably lowered and the display cannot be identified. Therefore, how to suppress such reflection of ambient light has been an important issue.

  As means for solving this problem, Japanese Patent Laid-Open No. 9-127855 has a structure in which circularly polarizing means 11 in which a polarizing plate 9 and a quarter-wave plate 10 are combined is provided on the front surface of the transparent substrate 2 as shown in FIG. Has been proposed. With such a structure, the ambient light incident from the transparent substrate 2 side and passing through the polarizing plate 9 and the quarter-wave plate 10 becomes circularly polarized light and is reflected by the cathode (aluminum electrode) 7 of the organic EL element. It becomes circularly polarized light of reverse polarity. When this reverse-polarized circularly polarized light passes through the quarter-wave plate 10 again, it becomes linearly polarized light parallel to the absorption axis of the polarizing plate 9, so that it is absorbed by the polarizing plate 9, so that reflection of ambient light is suppressed, Good contrast can be obtained. As a result, it is possible to prevent image reflection due to specular reflection of the metal electrode and a decrease in contrast.

  At present, a non-light emitting liquid crystal display device is practically used as a color display. Particularly widely used is a transmissive liquid crystal display device in which a light source is arranged in the background, and its use is expanding in various fields because it is particularly thin and lightweight compared to other display devices. However, although the power consumption used for the transmittance modulation of the liquid crystal element is small, a large amount of power is consumed to always turn on the background illumination (backlight) regardless of the display content, and as a result, a relatively large amount of power is required. And Furthermore, even in a transmissive color liquid crystal display device, if the ambient light is very strong and the display light brightness is relatively low, it becomes difficult to identify the display. Attempting to do so has the problem of consuming more power.

  In contrast to the light emitting display device and the transmissive liquid crystal display device as described above, the reflective liquid crystal display device can display light proportional to the amount of ambient light, and thus has a characteristic of not causing a washout phenomenon in principle. is there. Furthermore, since a backlight is not required, there is an advantage that electric power for an illumination light source is unnecessary. However, since the reflection type liquid crystal display device uses reflected light for display, there is a problem that it is difficult to identify display contents in an environment where ambient light is weak. In particular, when a color filter is used to realize color display, the color filter absorbs light, and thus the display becomes darker, and this problem becomes significant.

In order to use this reflective liquid crystal display device in an environment with low ambient light, a so-called front light illumination device has been proposed in which illumination is performed from the display surface side of the reflective liquid crystal display device. For example, Japanese Patent Application Laid-Open No. 11-249132 and Japanese Patent Application Laid-Open No. 11-249133 have proposed a structure in which an organic EL element is provided as a front light on a viewer side substrate of a reflective liquid crystal display device. Japanese Patent Laid-Open No. 10-125461 proposes a structure in which an organic EL element is disposed as a backlight on the back surface of a liquid crystal display device, and a metal electrode of the organic EL element also serves as a reflector. Further, the publication also proposes a structure in which a transparent organic EL element is disposed on a reflective liquid crystal display device and used as an auxiliary light source.
Japanese Patent Laid-Open No. 9-127858 (published on May 16, 1997) Japanese Patent Laid-Open No. 11-249132 (published on September 17, 1999) Japanese Patent Laid-Open No. 11-249133 (published on September 17, 1999) Japanese Patent Laid-Open No. 10-125461 (published on May 15, 1998)

  In the technique disclosed in Japanese Patent Laid-Open No. 9-127858, the washout phenomenon is reduced by providing the circularly polarizing means. However, this does not actively use ambient light for display. Further, when a circularly polarizing plate is used, since the light emitted from the EL element is non-polarized light, it is absorbed by the polarizing plate by about 50%, the emission intensity, The luminous efficiency is approximately halved. As described above, an element provided with an ambient light reflection preventing means combining a polarizing plate and a phase difference plate has a problem that the intensity of light emitted to the outside and the light emission efficiency are approximately halved compared to an element that does not. was there.

  In the techniques disclosed in Japanese Patent Application Laid-Open Nos. 11-249132 and 11-249133, since the organic EL element is provided in a region other than the display electrode, there is a problem that an effective aperture ratio is reduced. . Furthermore, since a cathode made of a magnesium / indium alloy is formed on the viewer side, there is a problem that external light is reflected and the contrast is lowered. These publications only mention how the organic EL element is used as a front light.

  In the technique disclosed in Japanese Patent Application Laid-Open No. 10-125461, there is a problem that a white display with a bright viewing angle and a wide viewing angle cannot be obtained because it serves as a cathode and a reflector of the organic EL element. Further, in the structure in which the transparent organic EL element is disposed on the front surface of the reflective liquid crystal display element, display deterioration occurs due to reflection of ambient light, and good display cannot be obtained. In addition, the press-sensitive input device (touch panel) disclosed in this publication and used to overlap the display device has a problem that the ambient light itself reflects ambient light and deteriorates visibility. The tendency is remarkable in the apparatus.

By the way, light emission of the organic EL element described above is non-polarized light emission. Recently has been studied organic EL material for the polarized luminescence also, EmielPeeters et al, the intensity of the intensity of right-handed circularly polarized light and _{I R} left circular polarization and _{I L,
g = 2 (I L -I R} ) / (I L tens _I R)
It is reported that a material that emits circularly polarized light with g ≠ 0 is developed (J. Am. Chem. Soc. 1997, 119, 9909-9910). However, the optimum device structure using this is not disclosed.

  In order to solve the above-described problems, the present invention uses the light emitted from the EL element together with the ambient light for display without losing the thin and light features of the reflective display device, and is visually recognized in both the dark place and the bright place. The purpose is to realize a display with excellent characteristics.

  In addition, a novel structure that can use ambient light for display as a light-emitting display device is also provided. Even in the environment where ambient light is bright, even if the display brightness of the light-emitting element is reduced, a reflective liquid crystal is used as the display element. An object is to further save energy by ensuring good display performance by the contribution of brightness.

  It is another object of the present invention to realize a good display without reflection of ambient light even if a touch panel is provided in the display device.

  The present invention provides a new type of multi-scene display that is completely different from the conventional one by utilizing the characteristics of the circularly polarizing means and the EL element and combining it with a reflective display element having a light reflecting means. Furthermore, the present invention provides a display device capable of satisfactorily viewing display information both in the outdoors and in a dark place without losing the feature of being thin and lightweight. In addition, a new type of display is provided that allows the user to freely select various display methods according to the surrounding environment.

  That is, the display device according to the present invention has a circularly polarizing means that selectively transmits substantially circularly polarized light that is either left or right from natural light, and an EL element, and a reflective type that has at least a light reflecting means on the back surface of the EL element. A display element is provided.

  The display device of the present invention is a display device including an EL element and a reflective display element that is provided on the back surface of the EL element and has at least light reflecting means. The EL element and the reflective display element are independent of each other. The display can be controlled.

  As described above, according to the present invention, a reflective display device is configured by combining an EL element and a reflective display element (for example, an electrophoretic display element) and controlling the display of both elements independently. The display is excellent in visibility in both dark and bright places by using the light emitted from the EL element together with the ambient light for display without impairing the thin and light features of the display.

  A second characteristic configuration of the present invention is that the reflective display element is composed of a liquid crystal or inorganic birefringence modulation layer sandwiched between two substrates, at least one of which is a transparent substrate.

  The 3rd characteristic structure of this invention is that the light emitting layer of the said EL element consists of an inorganic material or an organic material.

  The 4th characteristic structure of this invention is that the said circularly-polarizing means consists of one polarizing plate and at least 1 phase difference plate.

  With the above characteristic configuration, a display with high brightness is realized by an EL element in an environment where the ambient light is dark, and in a environment where the ambient light is strong, the reflective display element changes the brightness in proportion to the ambient light. Therefore, the display contents can be easily recognized, and the washout phenomenon that occurs in the conventional light emitting display device and transmissive liquid crystal display device does not occur.

  A fifth characteristic configuration of the present invention is that, in addition to the above-described characteristic configuration, the substrate of the EL element also serves as the substrate of the reflective display element. With this configuration, it is possible to reduce the thickness and weight.

  A sixth characteristic configuration of the present invention is that, in addition to the above-described characteristic configuration, an active element for driving an EL element and an active element for driving a reflective display element are formed on the same substrate. With this configuration, it is possible to further reduce the thickness and weight.

  In addition to the second characteristic configuration described above, the seventh characteristic configuration of the present invention is that the substantially circularly polarized light incident on the birefringence modulation layer becomes circularly polarized light as it is on the reflection surface, and is opposite on the exit surface after reflection. The state in which the surrounding circularly polarized light is in the dark state, and the substantially circularly polarized light incident on the birefringence modulation layer becomes linearly polarized light on the reflecting surface and the circularly polarized light in the same direction as the incident light on the outgoing surface after reflection is bright. It is to be in a state. With this configuration, a display device with higher contrast and higher utilization efficiency can be realized.

  According to an eighth characteristic configuration of the present invention, in addition to the third characteristic configuration described above, the EL element is placed on an optically transparent substrate, at least a transparent electrode, an organic hole transport layer, and / or an organic layer. An electron transport layer, an organic light emitting layer, a metal electrode, and a sealing layer are sequentially laminated, and the transmittance of the metal electrode is 50% or more. With this configuration, a brighter display device can be realized.

  According to a ninth characteristic configuration of the present invention, in addition to the above-described characteristic configuration, when the pixel of the EL element is brightly displayed, the corresponding pixel of the reflective display element simultaneously displays the bright display, When the pixel of the EL element is in dark display, the corresponding pixel of the reflective display element displays the dark display at the same time. This configuration ensures visibility.

  According to a tenth characteristic configuration of the present invention, in addition to any one of the first to eighth characteristic configurations described above, the reflection type display is performed regardless of the display state of light emission or non-light emission of the pixels of the EL element. All pixels of the element always display a dark display. This configuration ensures visibility.

  According to an eleventh characteristic configuration of the present invention, in addition to any of the first to eighth characteristic configurations described above, all the pixels of the EL element are always in a non-light-emitting state, and The pixel displays bright to dark display. With this configuration, visibility is ensured and power consumption is reduced.

  Since the display device according to the present invention uses a reflective display element, it has a feature of low power consumption in a conventional reflective liquid crystal display device. However, simultaneously using an EL element with high power consumption and keeping it in a lighted state causes an increase in power consumption. Therefore, it is particularly effective to use any of the ninth to eleventh characteristic configurations depending on the environment to be used in order to achieve both low power consumption and visibility.

  In a twelfth characteristic configuration of the present invention, in addition to the fourth characteristic configuration described above, the circular polarization means is set so that the retardation in the substrate normal direction is 100 nm or more and 180 nm or less in order from the EL element side. The first optical retardation compensator, a second optical retardation compensator in which the retardation in the substrate normal direction is set to 200 nm or more and 360 nm or less, and a linear polarizer, and the linear polarizer The transmission axis or absorption axis of the linearly polarizing plate and the slow axis of the second optical retardation compensator are defined as θ1 as an angle between the transmission axis or absorption axis and the slow axis of the first optical retardation compensator. The value of | 2 × θ2−θ1 | is 35 degrees or more and 55 degrees or less, where θ2 is an angle formed by That is, the inventors of the present application obtained the above numerical ranges through experiments to allow good circularly polarized light to be incident on the reflective display element. With this configuration, it becomes possible to make good circularly polarized light incident on the reflective display element.

According to a thirteenth characteristic configuration of the present invention, in addition to the above-mentioned fourth characteristic configuration, the circular polarization means is provided with retardation in the substrate normal direction of the optical phase difference compensation plate in order from the EL element side. A first optical retardation compensator set to 100 nm to 180 nm, a second optical retardation compensator having a substrate normal retardation of 200 nm to 360 nm, and a substrate normal retard A third optical phase difference compensator whose foundation is set to 200 nm or more and 360 nm or less, and one polarizing plate, and the transmission axis or absorption axis of the polarizing plate and the first, second, and third polarizing plates. When the angles formed by the slow axis of the optical retardation compensation plate are θ1, θ2, and θ3, respectively,
35 ° ≦ | 2 × θ3-θ2-θ1 | ≦ 55 °
Is to arrange the polarizing plate and the optical phase difference compensation plate so that In other words, the inventors of the present application obtained the above numerical ranges through experiments to allow better circularly polarized light to enter the reflective display element. With this configuration, it becomes possible to make better circularly polarized light incident on the reflective display element.

  According to a fourteenth characteristic configuration of the present invention, in addition to the second characteristic configuration described above, a light reflecting film is provided on the first substrate as means having light reflectivity in the reflective display element, and the light reflecting film is provided. However, it has a concavo-convex shape that changes smoothly and continuously, and is made of a conductive material. With this configuration, a diffusive reflector that does not have unnecessary scattering and does not have a disturbing action (polarization canceling action) on polarized light as in the case of a flat mirror surface, that is, maintains the polarization of polarized light is realized. This greatly improves the display characteristics as compared with the case where a scattering plate is arranged on the front surface of the display device using a specular reflection plate having no diffusibility. At least when the reflective display element has a light-reflective film on the substrate opposite to the viewer side for reflective display, the reflective film has a smooth uneven shape to prevent the specularity of the reflective display. It is effective as a means.

  A fifteenth characteristic configuration of the present invention is that, in addition to the second characteristic configuration described above, the reflection film in the reflective display element is made of an inorganic dielectric mirror or an organic hologram reflection plate. With this configuration, good color display can be realized.

  A sixteenth characteristic configuration of the present invention is that, in addition to the above-described characteristic configuration, a color filter layer is formed on the back surface of the circularly polarizing means. With this configuration, a satisfactory full color display can be realized.

  According to a seventeenth characteristic configuration of the present invention, in addition to the above-described characteristic configuration, a pressed coordinate detection type input device arranged to overlap the reflective display element surface is arranged on the back surface of the circularly polarizing means. is there. Even if the incident light that has passed through the circularly polarizing means and becomes substantially circularly polarized is subject to various reflections such as interfacial reflection without changing the polarization state, the reflected light is absorbed by the polarizing plate when emitted. Therefore, with such a configuration, reflected light from a pressure-sensitive input device (touch panel) that is effective as an input device for a portable device does not cause deterioration in visibility. By combining with the antireflection touch panel in this way, circularly polarized light that has passed through the touch panel can be effectively used as a display device.

18 characteristic configuration of the present invention, in addition to the third characteristic configuration of the above, the strength of the right circularly polarized light I _R, the intensity of the left circularly polarized light and _{I L, g = 2 (I} L -I _{When R 1} ) / (I _L + I _R ) is defined, the EL element emits at least light with g ≠ 0. With this configuration, the light emitted from the EL element can be used more effectively.

  According to the present invention, it is possible to use an EL element even in a dark place where the ambient light, which has been a drawback of the reflective display device, is weak or not at all, so that the application environment of the reflective display device is greatly increased. Can be enlarged. In addition, even when displaying using an EL element, ambient light is taken in and used for display, so that a display element that automatically adapts to ambient brightness, which has not existed before, can be realized.

  Hereinafter, examples of the present invention will be described in detail with reference to the drawings, but it goes without saying that the present invention is not limited to the following examples.

According to the present invention, an ambient environment dependent display device can be realized.
In the display device of the present invention, as described above, the reflective display element is disposed on the back surface of the EL element, the circular polarizing means is provided on the viewer side, and the EL element is used for display illumination of the reflective display element. Works as a display element. Alternatively, a reflective display element is provided on the back surface of the EL element, and the EL element and the reflective display element can independently control display.

  Therefore, the light emitted from the EL element is reflected by a sufficient amount toward the reflective display element, and the amount of emitted light from the display device can be increased. In this way, a display device that is thin and lightweight and capable of good display under any lighting environment is realized.

  In addition, the EL element can be operated as a display illumination and display element even in the daytime when the visibility of the reflective display element depends on ambient light. In the dark place, the EL element emits light so that the reflective display element can emit light. Display information can be visually recognized. Despite being a light emitting element, ambient light can be used, and visibility depending on the surrounding environment can be realized.

  Further, in the configuration in which the circularly polarizing means is provided on the front surface, the black floating in the dark state is not observed, and in addition, the reflection at the interface can be eliminated, so that display with high contrast is possible. With such a structure, it is possible to provide a new type of display that allows the user to freely select various display forms according to the surrounding environment.

  Furthermore, by using a light emitting layer that emits polarized light, light emitted more efficiently can be extracted to the outside.

Example 1
FIG. 1 is a schematic sectional view showing the structure of a first embodiment of a display device 12 according to the present invention. A reflective display element 14 is integrally provided on the back surface of the transmissive EL element 13, and a circularly polarizing means 16 is provided on the viewer 15 side. The EL element 13 and the circularly polarizing means 16 are disposed to face each other.

  Although these elements 13 and 14 are demonstrated here with a simple matrix drive system, they can also be driven with an active matrix system. In addition, an organic EL element is used as the EL element, and a reflective liquid crystal display element using liquid crystal is used as the reflective display element. A polarizing plate 17 and a quarter-wave plate 18 are stacked as circularly polarizing means. However, it is not limited to these.

  The EL element 13 has an integrated structure in which the light emitting layer 5 is formed on a transparent substrate 19 and is further covered with a transparent substrate 20 so that the transparent substrate 20 is in close contact with the front transparent substrate 21 of the reflective display element 14. ing. One reflective display element has a liquid crystal 23 sandwiched between a transparent substrate 21 and a transparent substrate 22. A transparent electrode 24 is formed on the transparent substrate 21, and a reflective electrode 25 is formed on the substrate 22.

  With this structure, as indicated by an arrow in FIG. 1, the light emitted from the light emitting layer 5 in the case of bright display, together with the direct light L <b> 1 emitted directly to the viewer 15 side, is combined with the liquid crystal layer 23. Is reflected to the viewer side as reflected light L2 reflected by the reflective electrode 25. The ambient light L3 is transmitted through the EL element 13, reflected by the reflective electrode 25 of the reflective display element 14, and emitted to the viewer side. That is, since the observer can use L3 in addition to L1 and L2, a very bright display is possible.

  In the case of dark display, the EL element 13 does not emit light, and the ambient light L3 is modulated by the liquid crystal layer and does not reach the observer, so that a good dark state can be realized. Since the circularly polarizing means 16 is provided, all the reflected light at the interface of the anode, cathode, substrate, etc. formed on the back side thereof is absorbed by the circularly polarizing means 16, so that a display device with very good visibility can be realized. . More preferably, it is desirable that the surface of the circularly polarizing means 16 is also subjected to an antireflection film or antiglare treatment.

Next, the structure of each component in FIG. 1 will be described in more detail.
FIG. 2 is a more detailed cross-sectional view of the EL element 13 of FIG. The substrates 19 and 20 of the EL element 13 are optically transparent materials, and appropriate materials such as plastic, glass, and ceramic can be used. The thickness of the substrate 20 is desirably as thin as possible so as not to impair the image quality of the display information of the reflective display element 14. The transparent electrode 3 for the anode can be made of a light transmissive conductive material such as ITO or SnO ₂ .

  The hole transport layer 4, the light emitting layer 5, and the electron transport layer 6, which are electroluminescent organic thin films, can employ various conventionally known configurations as layer configurations for obtaining electroluminescence. As a material for the metal electrode 7 on the cathode side, an alloy of an active metal such as Li, Mg, or Ca and a metal such as Ag, Al, or In, or a laminated structure can be used. In particular, in the present invention, since a transmissive EL element is required, the cathode is formed to be as thin as possible and to have high transparency. In this embodiment, the transmittance is 80% by forming 10 nm. In this case, if the resistance is high and there is a problem, an ITO electrode may be further laminated on the cathode metal electrode 7 as a transparent electrode. If the transmittance of the cathode metal electrode 7 is 50% or more, a good and highly efficient display device can be realized. The laminated body is entirely covered with a sealing substrate (transparent substrate) 20. As a material of the substrate 20, an appropriate material can be used as long as airtightness is maintained.

  Thus, when a direct current voltage 8 is selectively applied between the transparent electrode 3 and the cathode 7 of the anode, holes injected from the transparent electrode 3 pass through the hole transport layer 4 and electrons injected from the cathode 7 are transported by electrons. Through the layer 6, electron-hole recombination occurs in the light-emitting layer 5, and light emission of a predetermined wavelength occurs therefrom, and the emitted lights L 1 and L 2 can be observed from both sides of the transparent substrates 19 and 20.

  Various materials can be used as the material system of the light emitting layer 5. Examples thereof include fluorescent brighteners such as benzothiazole, benzimidazole, and benzoxazole, metal chelated oxinoid compounds, and styrylbenzene compounds. The light emitting layer using the light emitting material can be formed by thinning by a known method such as vapor deposition, spin coating, casting, LB, or printing. In this embodiment, a white light emitter is used for the light emitting layer, but not limited to this, RBG light emission and known materials can be used.

  FIG. 3 is a more detailed cross-sectional view of the reflective display element 14 of FIG. The reflective display element 14 includes transparent substrates 21 and 22, a twisted liquid crystal layer 23, a transparent electrode 24, a reflective electrode (light reflecting means) 25, an uneven film 28, and alignment films 26 and 27. For example, a twist liquid crystal layer 23 having a positive dielectric anisotropy is provided between the transparent substrates 21 and 22 made of glass. A transparent electrode 24 and a reflective electrode 25 are provided on the transparent substrates 21 and 22, and alignment films 26 and 27 are formed on the respective electrodes.

  The surface of the alignment film is subjected to an alignment process such as a rubbing process so that the liquid crystal molecules of the liquid crystal layer 23 are aligned in parallel to the substrate. In this case, with no voltage applied, the twist angle of the liquid crystal is set to 63 degrees as an example. The product of the birefringence of the liquid crystal and the thickness of the liquid crystal layer (μm unit, hereinafter abbreviated as Δnd) is 0.205. This can be applied to any liquid crystal layer as long as the ¼ wavelength condition is satisfied.

  The ¼ wavelength condition is a condition in which circularly polarized light enters the liquid crystal layer and becomes linearly polarized light after passing through. By controlling the alignment state of the liquid crystal layer with an electric field, the following bright and dark states can be realized. The almost circularly polarized light incident on the liquid crystal layer becomes circularly polarized light as it is on the reflecting surface, and the oppositely circularly polarized light on the exit surface after reflection is in the dark state, and the substantially circularly polarized light incident on the liquid crystal layer is reflected on the reflecting surface. A state where the light is linearly polarized and circularly polarized in the same direction as the incident light on the exit surface after reflection can be made bright, and nematic liquid crystals and smectic liquid crystals having negative dielectric anisotropy can be applied as the liquid crystals.

  The transparent electrode 24 is made of, for example, ITO. On the other hand, a metal such as aluminum or silver is used for the reflective electrode 25. In the present invention, the electrode 25 is provided with a reflecting function, but the present invention is not limited to this, and a reflecting means may be formed outside the substrate 22. For example, a reflective film having light reflectivity such as a hologram reflective film or a dielectric multilayer mirror may be used.

  In this embodiment in which reflectivity is added to the electrode 25, the uneven film 28 having a smooth uneven shape to the extent that the polarization of the reflected light is preserved is formed to improve the visibility. This smooth unevenness can be produced by using a predetermined mask and a photosensitive resin. The height is desirably 2 μm or less so as not to disturb the alignment of the liquid crystal. Thus, by appropriately imparting diffusibility and directivity to the reflective film, ambient light can be used effectively and a bright reflective display element can be realized.

  A voltage applying means (not shown) is connected to the electrodes 24 and 25, and the display is controlled by a voltage according to the display contents. A voltage is applied to the electrodes 24 and 25 in order to generate an electric field in the liquid crystal layer. For example, a voltage may be directly applied to the display unit from the outside of the liquid crystal element, and an active element such as a TFT element or MIM may be used. You may arrange. In this case, a nematic liquid crystal having a positive dielectric anisotropy is used for the liquid crystal layer.

  FIG. 4 shows a structure in which the EL element 13 shown in FIG. 2 and the reflective display element 14 shown in FIG. 3 are in close contact with each other and the circularly polarizing means 16 is arranged on the viewer 15 side. FIG. 4 shows the structure of the display device 12 according to the present invention shown in FIG. 1 in more detail. Since the EL element 13 is transparent, the substrate 19 is not limited to this structure, and the reflective display element 14 may be adhered. In addition, the circular polarization unit 16 is preferably disposed on the viewer side, but is not limited thereto, and may be disposed at any position as long as it is the front surface of the reflective display element 14. For example, it is possible to arrange the circularly polarizing means 16 between the transparent substrates 20 and 21.

  Next, the operation of the display device according to the present invention will be described according to the situation of ambient light. FIG. 5 shows the operation when the ambient light is sufficient and the EL element does not emit light. In this case, only ambient light is used and only the reflective display element is driven. In the bright display state shown in FIG. 5A, the circularly polarized light that has passed through the polarizing plate 17 and the quarter-wave plate 18 enters the twisted liquid crystal layer 23. This circularly polarized light passes through the twisted liquid crystal layer 23 and is converted into linearly polarized light, reflected by the reflection film 25, and passed through the twisted liquid crystal layer again with linear polarization, so that the rotation of the plane of polarization is the same direction as when incident. The circularly polarized light is emitted from the polarizing plate as it is, and a bright display is obtained.

  On the other hand, in the dark display state shown in FIG. 5B, in the voltage application state, the liquid crystal layer is untwisted and aligned along the electric field direction. Similarly, circularly polarized light that has passed through the polarizing plate and the quarter-wave plate enters the liquid crystal layer. The incident circularly polarized light passes through the liquid crystal layer 23, receives no change in polarization, and enters the reflection film 25 as circularly polarized light. The circularly polarized light reflected by the reflective film 25 becomes circularly polarized light in the opposite direction, and is incident on the liquid crystal layer 23 and the quarter wavelength plate 18 again. Then, the circularly polarized light becomes linearly polarized light which is converted by 90 degrees from that at the time of incidence, and is absorbed by the polarizing plate 17 to be darkly displayed.

  Next, the operation when only the EL element is driven will be described separately with reference to FIGS. 6 and 7 for ambient light and light emitted from the EL element. FIG. 6 shows the operation of the reflective display element in this case, and the entire surface is always set to the dark state regardless of the display data. Since the ambient light L3 is always absorbed by the circularly polarizing means 16 regardless of the brightness of the display, the contrast is not lowered by the ambient light. On the other hand, since the light emitted from the light emitting layer 5 is non-polarized light, it remains unpolarized even when it passes through the liquid crystal layer 23.

  As shown in FIG. 7A, in the light emitting state, L1 emitted to the observer side and L2 emitted to the reflector side both absorb about half of the light when passing through the circular polarization means 16. The rest is clear because it passes. As shown in FIG. 7B, when the EL element does not emit light, the display is naturally dark.

  Next, the case where the EL element and the reflective display element are simultaneously driven will be described with reference to FIGS. In this case, the ambient light L3 is effectively used by the operation of the reflective display element as described in FIG. 5, and the emitted lights L1 and L2 emitted from the light emitting layer 5 are also displayed as described in FIG. It is used effectively. That is, in the bright display state, emitted light is also used in addition to the ambient light, and in the dark display state, the ambient light is not reflected and no light is emitted, so that a good dark display can be realized.

  Although only the bright display state and the dark display state have been described here, the halftone is the same in principle, and a good halftone display can be realized.

  The EL element 13 used in the display device 12 can be manually or automatically turned off in a bright environment and turned on in a dark environment, and various manual switches, light sensors, and the like are used for switching. be able to. The reflective display element 14 functions as a light source for display. The EL element of the present invention is provided with electrodes of a simple matrix or an active matrix, and each pixel is controlled to be turned on by display data. The display contents can be displayed only by the EL element 13. This is a completely different structure from a conventional front light that is merely a light guide plate that is simply switched on or off.

  As described above, according to the present invention, a thin and light display device capable of three types of display methods, that is, only the reflective display element is driven, only the EL element is driven, and both are simultaneously driven according to the state of the ambient light. Is possible.

(Example 2)
FIG. 9 shows a configuration in which, in the display device of the present invention, full-color display is possible at the time of light emission by forming an RGB light emission pattern in the light emitting layer 31 of the EL element 32. Other basic configurations are the same as those in the first embodiment.

  The light emitting layer 31 is formed by, for example, forming a stack of an organic layer and an electrode that emits red light by vacuum deposition, and then moving the mask in parallel to vacuum another organic layer and electrode that emits green light. Lamination is performed by vapor deposition, and the mask is further moved in parallel, and another organic layer that generates blue light emission and an electrode may be laminated.

An example of a specific method for forming the light emitting layer 31 will be described. The film formation of the organic layer for obtaining green light emission is performed by placing an evaporation mask provided with an opening corresponding to the film forming portion between the glass substrate and the evaporation source. As a hole transport layer, N, N′-diphenyl-N, N′-bis (3-methylphenyl) 1,1′-biphenyl-4,4′-diamine (hereinafter simply referred to as TPD) is used as 1 The film is deposited to a thickness of 20 nm by a resistance heating method at an evaporation rate of 0.2 to 0.4 nm / s under a vacuum of 33 × 10 ⁻⁴ Pa (10 ⁻⁶ Torr). Then, tris (8-hydroxyquinoline) aluminum (hereinafter simply referred to as AIq3), which also serves as an electron transport layer and light emission, is resistively heated to a thickness of 40 nm at an evaporation rate of 0.2 to 0.4 nm / s. Vacuum deposition is performed by the method to form an electron transport layer.

  In order to obtain red light emission, for example, a red light emitting dye such as 4-dicyanomethylene-6- (p-dimethylaminostyryl) -2-methyl-4H-pyran (hereinafter, referred to as Alq3, which is an electron transporting material). This can be realized by including a Nile red or perylene diimide derivative. In order to obtain blue light emission, for example, a material that emits blue fluorescence is used as a hole transport material and laminated with an electron transport material.

  An Mg—Ag (30: 1) alloy is used as the metal electrode of the cathode, and it is formed to a thickness of 1 nm in order to ensure light transmission. If the resistance value is high and problematic, an ITO film may be laminated. The RGB patterning method is not limited to the mask vapor deposition used here, and an inkjet method or a thermal transfer method can also be applied.

  Thus, the light emitting layer 31 that emits RGB light is completed, and the EL element 32 is obtained. With such a configuration, full-color display is possible when a voltage is applied to the EL element to emit light. On the other hand, when no voltage is applied to the EL element, the reflective display element displays good black and white display. In either case, contrast reduction due to ambient light does not occur, and good display characteristics can be obtained. A contrast of 100 was obtained when only the light emitting layer 31 was driven, a contrast of 20 when only the reflective display element 14 was driven, and a contrast of 80 when both were driven simultaneously. Further, in the display device 30 of this example, since the reflective film 25 is formed on the liquid crystal layer 23 side, high-definition display without parallax was obtained.

(Example 3)
Next, in FIG. 10, in the display device of the present invention, by forming an RGB light emission pattern on the light emitting layer 31 of the EL element 32 and further providing a color filter layer 35 on the transparent substrate 21 of the reflective display element 34, A configuration capable of full-color display in any of the display methods will be described. Other basic configurations are the same as those in the second embodiment.

  In the figure, the display device 33 has substantially the same configuration as the display device 30 of Example 2, but a pigment dispersion type color filter layer 35 that transmits red, green, and blue light is formed on the glass substrate 21. It is characterized by doing. In the color filter layer 35, a red color filter, a green color filter, and a blue color filter each correspond to a single pixel in one picture element, and the red, green, and blue color filters are arranged in stripes. Yes. Then, a planarizing film 36 is formed on the color filter layer 35, and the transparent electrode 24 is formed thereon to form a display electrode.

  In this embodiment, the color filter layer 35 is formed as follows by applying a pigment dispersion method. First, a photosensitive coloring resist in which a red pigment is uniformly dispersed in a transparent photosensitive resin is applied on the glass substrate 21. In this example, as an example, CR2000 manufactured by Fuji Film Orin Co., Ltd. was formed by spin coating at 2.0 μm at 650 revolutions. Thereafter, prebaking is performed at 80 ° C., exposure and development are performed using a predetermined mask, and finally baking is performed at 220 degrees for 30 minutes to form a red pattern. Furthermore, green and blue patterns are formed by the same process using CG2000 and CB2000 manufactured by Fuji Film Olin Co., Ltd., and the color filter layer 35 is formed. In some cases, a black matrix may be formed between the red, green, and blue color filter patterns. In that case, black resist CK2000 manufactured by Fuji Film Orin Co., Ltd. can be applied.

  The color design of the color filter is very important in configuring the device. For example, in the color filter layer 35 of the reflective display element as in this embodiment, the incident ambient light L3 passes through the color filter layer twice as shown in FIG. Therefore, the density of the color filter is designed in consideration of this. Moreover, the manufacturing method of a color filter is not limited to a pigment dispersion type, For example, the electrodeposition method is also possible. Further, the formation position of the color filter is not limited to the substrate 21 but may be the substrate 19 or 20 on the EL element side. Further, it may be in contact with the light emitting layer 31. In this case, the anode of the light emitting layer can be used as an electrode for forming an electrodeposition color filter. That is, the color filter may be formed anywhere as long as it is behind the circular polarization means 16.

  According to the present embodiment, by providing the EL element with the RBG light emitting layer and forming the color filter layer 35 on the reflective display element 34, multicolor or full color display having a wide color reproducibility range is possible. Further, in this configuration, the color purity is increased and the efficiency is improved by matching the light emission characteristics of the light emitting layer 31 and the peak wavelength of the characteristics of the color filter layer 35.

Example 4
Next, FIG. 11 shows that in the display device of the present invention, an RGB light emission pattern is formed on the light emitting layer 31 of the EL element 32, and a reflective color filter layer 39 is provided on the transparent substrate 22 of the reflective display element 38. Thus, a configuration capable of full-color display in any of the display methods is shown. Other basic configurations are the same as those in the third embodiment.

  In the figure, a planarizing layer 40 is formed on the reflective color filter layer 39, ITO is formed thereon as a transparent electrode 41, and a light absorption layer 42 is formed on the back surface of the reflective color filter layer 39.

  As the light reflection type color filter, an organic volume hologram optical color filter or an inorganic dichroic mirror can be applied. In this case, it is necessary to provide a light absorption layer on the back surface. The light absorption layer may be formed at any position as long as it is the back surface of the reflective color filter. For example, it may be in contact with the direct reflection type color filter, or may be formed on the back surface of the transparent substrate 22 as in this embodiment.

  As described above, the thin and light display device 37 is realized. For example, even when the display of the reflective display element 38 depends on external light such as daytime, the EL element 32 is used as the display illumination and display element of the reflective display element 38. Can act as In a dark place such as at night, the display information can be visually recognized by causing the EL element to emit light.

(Example 5)
Next, FIG. 12 shows a display device 43 using a light emitting layer 45 that emits circularly polarized light as the EL element 44 in the display device of the present invention. Other basic configurations are the same as those in the third embodiment. From the circularly polarized light emitting layer 45, clockwise circularly polarized light emission L4 and L5 emit light. Whether the circularly polarized light emission is clockwise or counterclockwise can be controlled by the material composition and its processing. In this embodiment, clockwise circularly polarized light is emitted.

Next, a method for forming a circularly polarized light emitting layer will be described. As a circularly polarized light-emitting material, Poly {2,5-bis [(S) -2-methylbutoxy] -1,4-phenylene} vinylene} -co-{[2,5-bis [(3R, 3S)-(3 7-dimethylity) oxy] -1,4-phenylene] vinylene}
Is synthesized. A solution obtained by mixing this with a solution of chloroform: 0-dichlorobenzene = 7: 1 at a rate of 4 mg / mL was prepared, and this was applied on a glass substrate on which ITO having a thickness of 100 nm (1000 mm) was formed by sputtering. Spin coat under atmosphere. Then, after baking at 60 ° C. to volatilize the solvent, an aluminum electrode is formed thereon by vapor deposition.

When a voltage of 20 V was applied using the ITO side of this element as the anode and the aluminum side as the cathode, the g value was -1.1 × 10 ⁻¹ with emitted light having a wavelength of 600 nm.
Where g value and the intensity of right-handed circularly polarized light and _{I R,} the intensity of left-handed circularly polarized light and _{I L g = 2 (I L} -I R) / (I L tens _I R)
Defined as

From this value, when the intensity of light having a wavelength of 600 nm is normalized to 1, it is calculated that I _L = 0.47 and I _R = 0.53. Thus, it was confirmed that circularly polarized light was emitted.

  Next, the light utilization efficiency of this display device will be described with reference to FIGS. The circularly polarized light means 16 is set so that the incident light is converted to clockwise circularly polarized light, and the ambient light L3 passes through the circularly polarized light means 16 to become clockwise circularly polarized light and enters the liquid crystal layer 23.

  Here, when the circularly polarized light emitting layer 45 emits light, clockwise circularly polarized light L4 and L5 are emitted. Accordingly, the clockwise circularly polarized light of the ambient light L3 and the circularly polarized light L5 of the circularly polarized light emitting layer 45 are combined and incident on the liquid crystal layer 23. The twisted liquid crystal layer is set so as to be converted from clockwise circularly polarized light into linearly polarized light, and becomes linearly polarized light on the reflective film 25. The reflected light passes through the twisted liquid crystal layer and the quarter-wave plate 18 again, so that the plane of polarization becomes linearly polarized light in the same direction as that of the incident light, and passes through the polarizing plate 17 as it is to provide a bright display. On the other hand, since L4 emitted to the viewer side is clockwise circularly polarized light, it passes through the circularly polarizing means 16 as it is and becomes bright display.

  By polarized light emission in this way, the light extraction efficiency is doubled compared to non-polarized light emission, and a good bright state can be realized. When the polarized light emitting layer 45 does not emit light, a good dark state can be realized as in the first embodiment. In this way, when the display device 43 is configured using the polarized light emitting layer 45 that emits circularly polarized light in which g ≠ 0, emitted light can be extracted more efficiently.

(Example 6)
Next, FIG. 14 shows a display device 46 in which the transparent substrate covering the light emitting layer 5 of the EL element 13 and the front transparent substrate of the reflective display element 14 are integrated as one substrate 47 in the display device of the present invention. Show. Other basic configurations are the same as those in the first embodiment. This configuration can further reduce the thickness and weight.

(Example 7)
Next, FIG. 15 shows a display device 48 in which the transparent electrode 24 for driving the light emitting layer 5 and the liquid crystal layer 23 of the EL element is formed on the same transparent substrate 19 in the display device of the present invention. Since this configuration can be configured with only two substrates, the thickness and weight can be further reduced. FIG. 15 is an enlarged cross-sectional view of only one pixel.

  An active element 49 for controlling the light emitting layer 5 and an active element 50 for controlling the liquid crystal layer 23 are provided on the transparent substrate 19. A transparent protective film 60 is formed on the active elements 49 and 50, and the active element 50 and the transparent electrode 24 that drives the liquid crystal are connected via the contact hole 61. As the active element, a three-terminal element typified by TFT (Thin Film Transistor) and a two-terminal active matrix element typified by MIM (metal-insulator-metal) are applicable.

  In this configuration, the reflective electrode 25, which is one of the electrodes for driving the liquid crystal, and the cathode, which is one of the electrodes for driving the light emitting layer, are not shared, and thus there is an advantage that various ideas can be applied to the reflective electrode 25. For example, but not limited to this, it is possible to form the concavo-convex film described in detail in Example 1, or to apply the reflective color filter described in detail in Example 4.

(Example 8)
In the circularly polarizing means 16 having the configuration shown in FIG. 1, circularly polarized light can be obtained in a wider band by using the polarizing plate 17 and a plurality of retardation films. In this embodiment, the display contrast is further improved by using two or three sheets.

  A specific configuration is shown in FIGS. In FIG. 16, when the phase difference between the first optical phase difference compensation plate 51 and the second optical phase difference compensation plate 52 is observed from the direction of the incident light of the display device, it is arranged to be 135 nm and 270 nm, respectively. Show the case. In FIG. 17, θ1 (angle formed by the polarizing plate transmission axis azimuth 53 and the slow axis azimuth 54 of the first optical phase difference compensator) = 75 °, θ2 (polarizing plate transmission axis azimuth 53 and second optical phase difference). When arranged so that the angle formed by the slow axis direction 55 of the compensation plate) = 15 °, the light incident on the display device passes through the polarizing plate 17, the optical retardation compensation plate 52, and the optical retardation compensation plate 51. Thus, the light is substantially clockwise circularly polarized light in the visible light wavelength region.

That is, the circularly polarizing means 16 includes, in order from the EL element 13 side, a first optical retardation compensation plate 51 in which the retardation in the substrate normal direction is set to 100 nm or more and 180 nm or less, and the retardation in the substrate normal direction is 200 nm. The second optical retardation compensator 52 set to 360 nm or less and a linearly polarizing plate (polarizing plate 17). The transmission axis or absorption axis of the linearly polarizing plate and the second optical position are defined as θ1 as an angle formed between the transmission axis or absorption axis of the linearly polarizing plate and the slow axis of the first optical retardation compensation plate 51. When the angle formed with the slow axis of the phase difference compensation plate 52 is θ2,
35 ° ≦ | 2 × θ2-θ1 | ≦ 55 °
The linearly polarizing plate (polarizing plate 17) and the optical phase difference compensating plates 51 and 52 are arranged so that

  FIG. 18 shows that the phase differences between the first optical phase difference compensation plate 51, the second optical phase difference compensation plate 52, and the third optical phase difference compensation plate 56 are 135 nm, 270 nm, and 270 nm, respectively. The structure of the circularly-polarizing plate which has the three optical phase difference compensating plates arrange | positioned to is shown. As shown in FIG. 19, the installation angle is θ1 (angle formed by the polarizing plate transmission axis azimuth 53 and the slow axis azimuth 54 of the first optical retardation compensator) = 100.2 °, θ2 (polarizing plate transmission axis) The angle between the azimuth 53 and the slow axis azimuth 55 of the second optical retardation compensator = 34.2 °, θ3 (the polarizing plate transmission axis azimuth 53 and the slow axis azimuth 57 of the third optical retardation compensator) ) = 6.5 °, the light incident on the display device passes through the polarizing plate 17 and the optical phase difference compensation plates 56, 52, 51, and compensates for the two optical phase differences. It becomes circularly polarized light at a wider wavelength than when using a plate.

That is, the circular polarization means 16 includes, in order from the EL element 13 side, a first optical phase difference compensation plate 51 in which the retardation in the substrate normal direction of the optical phase difference compensation plate is set to 100 nm or more and 180 nm or less, A second optical phase difference compensation plate 52 disposed on the first optical phase difference compensation plate 51 and having a retardation in the substrate normal direction set to 200 nm or more and 360 nm or less, and a second optical phase difference compensation plate The first optical phase difference compensation plate 56 is disposed on the second optical phase difference compensation plate 56, and the retardation in the substrate normal direction is set to 200 nm or more and 360 nm or less, and 1 is disposed on the third optical phase difference compensation plate 56. Sheet polarizing plate 17. When the angles formed by the transmission axis or absorption axis of the polarizing plate 17 and the slow axes of the first, second, and third optical phase difference compensating plates 51, 52, and 56 are θ1, θ2, and θ3, respectively. ,
35 ° ≦ | 2 × θ3-θ2-θ1 | ≦ 55 °
The polarizing plate 17 and the optical phase difference compensating plates 51, 52, and 56 are arranged so that

  In the embodiments described above, a uniaxial stretched film is used as the optical retardation compensator. However, the retardation film is made of biaxiality, that is, a three-dimensionally controlled refractive index film or a liquid crystal polymer. Can be applied, and the viewing angle can be expanded.

Example 9
Next, FIG. 20 shows a display device 58 in which a touch panel (pressed coordinate detection type input device) 59 is provided on the back surface of the circularly polarizing means 16 as information input means in a portable device which is the main field of use of the display device of the present invention. Show. For comparison, FIG. 21 shows a conventional configuration 61 in which a touch panel 59 is provided on the viewer side of the display device.

  In the conventional configuration 61, the reflected light component of the touch panel is directly observed and the visibility is greatly deteriorated. This reflected light was generated not only by the gap held between the pressing position detecting transparent electrodes but also by the gap held between the touch panel support substrate and the polarizing plate 17. On the other hand, in the configuration 58 of this example, such a reflected light component was not observed at all, and a very good display similar to the case where the touch panel was not provided was shown. Reflected light due to the gap sandwiched between the transparent electrodes for detecting the pressed position of the touch panel is not observed, and reflection due to the interface between the pressing force transmission preventing gap, the touch panel support substrate, and the EL element substrate 19 is not observed. An input device integrated display device capable of effectively using the polarization state for display has been realized.

  As mentioned above, although the Example of this invention was described, it can change variously based on the technical idea of this invention besides the above-mentioned Example.

  A combination of a solar battery and a secondary battery may be used as a power source for the EL element. An inorganic EL or a light emitting diode may be used as the EL element.

Moreover, the kind of organic EL element used for each Example is not limited to the above-mentioned Example, A combination may be changed and the kind of liquid crystal element is not limited to the above-mentioned Example. In addition, although the above-mentioned Example demonstrated using the liquid crystal element, it is not restricted to this, The application of the inorganic birefringence modulation layer with an optical-electrical conversion function is also possible. For example, instead of the liquid crystal layer 23, PLZT which is another optoelectronic element can be used. This PLZT is one of electro-optic ceramics and exhibits transparency and birefringence. Further, the PLZT has the general formula _{(Pb 1-x La x)} (Zr 1-y Ti y) expressed as _{1-x / 4 O 3 (} 0 <x ≦ 0.3,0 <y ≦ 1.0) It can be expressed as lead zirconate titanate doped with lanthanum. In this substance, various optical characteristics (Δnc) can be controlled by an electric field according to the composition ratio of each component.

  In addition, the EL element can emit light only in part of the display screen. For example, when a moving image is displayed in a part of the screen, the EL element corresponding to that part is increased in light intensity to realize a display with high brightness, and other parts may be adjusted to a brightness that allows easy viewing of character information. Good. This is because the optimum brightness for viewing video differs from the optimum brightness for viewing character information, and it has been difficult to adjust the brightness partially according to the display content on the screen.

(Example 10)
Still another embodiment of the present invention will be described below with reference to FIGS. FIG. 22 is a schematic diagram of a display device 70 according to the tenth embodiment of the present invention. Note that the EL element 13 shown in FIG. 2 may have the structure shown in FIG. 2 in detail.

  In this display device 70, an electrophoretic display element 71 is disposed opposite to the back surface of an EL element (electroluminescent element) 13, and both of them are provided integrally. The EL element 13 has a transmission part at least in part. Note that the EL element 13 and the electrophoretic display element 71 are driven by a simple matrix driving method below, but can also be driven by an active matrix method. As the EL element 13, for example, an organic EL element can be used. The electrophoretic display element 71 is an example of a reflective display element.

  In the EL element 13, the light emitting layer 5 is formed on the transparent substrate 19, and the light emitting layer 5 is covered with the transparent substrate 20. The transparent substrate 20 is in close contact with the front transparent substrate 21 of the electrophoretic display element 71, and the EL element 13 and the electrophoretic display element 71 are integrated.

  The electrophoretic display element 71 as a reflective display element has an electrophoretic layer 72 sandwiched between the transparent substrate 21 and the transparent substrate 22. A transparent electrode 24 is formed on the inner surface of the transparent substrate 21, and a transparent electrode 25 is formed on the inner surface of the transparent substrate 22.

  As shown by the arrows in FIG. 22, in the bright state of the display device 70, the light emitted from the light emitting layer 5 is directly emitted as direct light L <b> 1 and reflected light L <b> 2 reflected from the electrophoretic layer 72 and emitted. The light is emitted to the viewer 15 side. In addition, the ambient light L3 passes through the EL element 13 and enters the electrophoretic layer 72 of the electrophoretic display element 71, where it is reflected and emitted to the viewer 15 side. That is, since the display device 70 can use the ambient light L3 for display in addition to the direct light L1 and the reflected light L2, a very bright display is possible. In the dark display, the light emitting layer 5 does not emit light, and the ambient light L3 is absorbed by the electrophoretic layer 72 and does not reach the observer. Therefore, a good dark state can be realized.

  In the display device 70 of the present embodiment, as described above, the electrophoretic display element 71 using the fact that the charged pigment in the medium moves by applying a voltage without using a polarizing plate is used as the reflective display device. Yes.

Here, the electrophoretic display element 71 will be described in detail.
FIG. 23 shows a cross-sectional view of the electrophoretic display element 71. In the electrophoretic display element 71, two glass substrates 21 and 22, for example, at least one of which has translucency are opposed to each other at a predetermined interval. A pair of transparent electrodes 24 and 25 such as planar ITO are formed on the inner surfaces of the glass substrates 21 and 22 facing each other.

  An electrophoretic layer 72 is sandwiched between the two glass substrates 21 and 22. In the electrophoretic layer 72, for example, a colored dispersion medium 73 colored in black and a charged white pigment 74 dispersed in the colored dispersion medium 73 are microencapsulated. The white pigment 74 is disposed on a part of the colored dispersion medium 73, for example, a hemispherical portion of the colored dispersion medium 73 having a spherical shape.

  In such an electrophoretic display element 71, with respect to the pair of transparent electrodes 24, 25, for example, as shown in the bright state of FIG. 23, the upper transparent electrode 24 has a positive voltage and the lower transparent electrode 25 has a negative voltage. Is applied, the negatively charged white pigment 74 dispersed in the colored dispersion medium 73 is electrophoresed toward the anode (transparent electrode 24) by the Coulomb force, and the white pigment 74 is moved to the upper anode (transparent electrode 24). Adhere to. When the observer 15 observes the electrophoretic display element 71 in such a state from the glass substrate 21 side, the portion where the white pigment 74 adheres and forms a layer appears white through the transparent electrode 24 and the glass substrate 21. It will be.

  On the other hand, if the polarity of the voltage applied to the transparent electrodes 24 and 25 is reversed, the white pigment 74 adheres to the opposite transparent electrode 25 to form a layer, as shown in the dark state of FIG. Therefore, when the observer 15 observes the electrophoretic display element 71 from the glass substrate 21, the white pigment 74 is hidden behind the black dispersion medium 73, so that the electrophoretic display element 71 appears black.

  When the application of voltage is stopped, the white pigment layer 74 attached to the transparent electrode 25 maintains its attached state. Therefore, after the white pigment layer 74 once adheres to the transparent electrode 25, the voltage for maintaining the attached state. It is not necessary to apply a voltage other than applying. Thus, since the display device 70 does not use a polarizing plate, the display device 70 becomes a bright reflective display device.

For the EL element 13, the structure of FIG. 2 used in Example 1 can be applied as it is. This figure is a cross-sectional view showing only the EL element 13 in the display device 12. In the EL element 13 shown in the figure, the transparent substrates 19 and 20 need to be made of an optically transparent material. For example, plastic, glass, ceramic, and other transparent materials can be used as appropriate. The thickness of the transparent substrate 20 is preferably as thin as possible so as not to impair the image quality of the display information of the electrophoretic display element 71 (reflection display element 14). For the transparent electrode 3 serving as an anode, a light-transmitting conductive material such as ITO or SnO ₂ can be used.

  In the display device 70 of the present embodiment, the EL element 13 is used, for example, by turning it off during bright daytime and turning it on in a dark place. The driving method is, for example, a manual type (switching method using a manual switch). In this case, various types of manual switch structures can be applied. Further, the driving method can be a method that can be automatically switched using, for example, an optical sensor. In addition, the EL element 13 has a function of a display light source for the electrophoretic display element 71, while the display using only the electroluminescent element 13 is also possible.

  The front light generally referred to is of a light guide plate type, and the display state does not change depending on the display contents, and only the entire surface is switched ON or OFF. Therefore, the display device of the present invention including the EL element 13 is completely different from the conventional display device including the front light. In other words, the EL element 13 included in the display device of the present invention has electrodes for simple matrix driving and active matrix, and controls lighting of each pixel by display data.

  As described above, in the display device 70, three types of display modes are possible depending on the state of external light: driving only the electrophoretic display element 71, driving only the EL element 13, and both driving simultaneously. Furthermore, it can be made thin and light.

(Example 11)
Still another embodiment of the present invention will be described below with reference to FIG.
FIG. 24 is a schematic view of a display device 80 according to the eleventh embodiment of the present invention. As shown in the figure, in the display device 80, the light emitting layer 5 of the EL element (electroluminescent element) and the transparent electrode 24 for driving the electrophoretic layer 72 are formed on the same transparent substrate 19. Therefore, since the display device 80 includes only two transparent substrates (the transparent substrate 19 and the transparent substrate 22), the display device 80 can be made thinner and lighter. FIG. 24 is an enlarged cross-sectional view of only one pixel.

  In the display device 80, an active element 49 that controls the light emitting layer 5 and an active element 50 that controls the electrophoretic layer 72 are provided on the transparent substrate 19. A transparent protective film 60 is formed on the active elements 49 and 50, and the active element 50 and the transparent electrode 24 that drives the electrophoretic layer 73 are connected via the contact hole 61.

  As the active elements 49 and 50, a three-terminal element typified by a TFT (Thin Film Transistor) and a two-terminal active matrix element typified by a MIM (metal-translator-metal) can be applied. In this embodiment, the light emitting layer 5 and the electrophoretic layer 72 can be controlled independently by individual TFTs (active elements 49 and 50), for example. As for the number of TFTs, it is more preferable to use a plurality of TFTs in order to control the light emitting layer 5.

  The reflection type display element is called not only a liquid crystal display element using one polarizing plate as described above, or an electrophoretic display element, but also a guest-host liquid crystal not using a polarizing plate or a so-called gyricon display. The present invention can be applied to a display device of a twist ball type or a reflective display of a toner display in which toner moves by an electric field.

It is a schematic sectional drawing of the 1st Example of the display apparatus by this invention. FIG. 2 is a more detailed cross-sectional view of the EL element of FIG. 1. FIG. 2 is a more detailed cross-sectional view of the reflective display element of FIG. 1. FIG. 2 is a more detailed cross-sectional view of the display device of FIG. 1. 5A is a diagram illustrating a display operation in a bright display state by ambient light when the EL element does not emit light in the display device illustrated in FIG. 1, and FIG. 5B is a diagram illustrating a display operation in the dark display state. FIG. FIG. 7 is a diagram illustrating a display operation using emitted light and ambient light when only the EL element is driven in the display device shown in FIG. 1. 7A is a diagram illustrating a display operation in a bright display state when only the EL element is driven in the display device illustrated in FIG. 1, and FIG. 7B is a diagram illustrating a display operation in a dark display state. . 8A is a diagram for explaining the display operation in the bright display state when the EL element and the reflective display element are driven in the display device shown in FIG. 1, and FIG. 8B is a display in the dark display state. It is operation | movement explanatory drawing. It is a schematic sectional drawing of the 2nd Example of the display apparatus by this invention. It is a schematic sectional drawing of the 3rd Example of the display apparatus by this invention. It is a schematic sectional drawing of the 4th Example of the display apparatus by this invention. It is a schematic sectional drawing of the 5th Example of the display apparatus by this invention. 13A is a diagram illustrating a display operation in a bright display state in the display device using polarized light emission illustrated in FIG. 12, and FIG. 13B is a diagram illustrating a display operation in a dark display state. It is a schematic sectional drawing of the 6th Example of the display apparatus by this invention. It is a schematic sectional drawing of the 7th Example of the display apparatus by this invention. It is sectional drawing of the circularly-polarizing means using two optical phase difference compensating plates in the further another Example of the display apparatus by this invention. It is a figure which shows the setting azimuth | direction of the polarizing plate of the circularly-polarizing means of FIG. 16, and an optical phase difference compensating plate. It is sectional drawing of the circularly-polarizing means using three optical phase difference compensating plates in the further another Example of the display apparatus by this invention. It is a figure which shows the setting azimuth | direction of the polarizing plate of the circularly-polarizing means of FIG. 18, and an optical phase difference compensating plate. In the display apparatus of this invention, it is sectional drawing which shows the structure which provided the touch panel in the back surface of the circularly-polarizing means. In the conventional display apparatus, it is sectional drawing which shows the structure which provided the touch panel in the front surface of the display apparatus. It is a schematic sectional drawing which shows the further another Example of the display apparatus by this invention. FIG. 23 is an operation explanatory diagram of the electrophoretic display element shown in FIG. 22. It is a schematic sectional drawing which shows the further another Example of the display apparatus by this invention. It is sectional drawing of the conventional EL element. It is sectional drawing of the EL element which gave the conventional antireflection.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Organic EL element 2 Transparent substrate 3 Transparent electrode 4 Hole transport layer 5 Light emitting layer 6 Electron transport layer 7 Cathode 8 Power supply 9 Polarizing plate 10 1/4 wavelength plate 11 Circular polarization means 12 Display device 13 EL element 14 Reflective display element 15 Observer 16 Circularly polarizing means 17 Polarizing plate 18 1/4 wavelength plate
19-22 Transparent substrate 23 Liquid crystal layer 24 Transparent electrode 25 Reflective electrode (light reflecting means)
26,27 Alignment film 28 Uneven film

Claims (19)

A circularly polarizing means that selectively transmits either circularly polarized light that is either left or right from the external light, and a light-transmitting EL element, and a reflective display element on the back of the EL element,
A transparent substrate shared by the EL element and the reflective display element; an active element that drives the EL element; and an active element that drives the reflective display element. A display device characterized by being formed on the same surface. In a display device comprising an EL element and a reflective display element provided on the back surface of the EL element and having a light reflecting means,
The EL element and the reflective display element can independently control display,
A transparent substrate shared by the EL element and the reflective display element; an active element that drives the EL element; and an active element that drives the reflective display element. A display device characterized by being formed on the same surface.   The display device according to claim 1, wherein the reflective display element includes a liquid crystal or inorganic birefringence modulation layer sandwiched between two substrates, at least one of which is a transparent substrate.   The display device according to claim 1, wherein a light emitting layer of the EL element is made of an inorganic material or an organic material.   The display device according to claim 1, wherein the circularly polarizing means includes one polarizing plate and at least one retardation plate.   The display device according to claim 1, wherein the substrate of the EL element also serves as the substrate of the reflective display element.   The almost circularly polarized light incident on the birefringence modulation layer is converted into a circularly polarized state as it is on the reflecting surface and the opposite circularly polarized light on the exit surface after reflection is set to the dark state, and the substantially circularly polarized light incident on the birefringence modulation layer is 4. The display device according to claim 3, wherein a state in which the light is linearly polarized on the reflecting surface and a circularly polarized light in the same direction as the incident light on the light exiting surface after reflection is a bright state.   The EL element is formed by laminating at least a transparent electrode, an organic hole transport layer, an organic light emitting layer, an organic electron transport layer, a metal electrode, and a sealing layer on an optically transparent substrate. The display device according to claim 4, wherein the transmittance is 50% or more. The display device according to any one of claims 1 to 8,
When the pixel of the EL element is brightly displayed, the corresponding pixel of the reflective display element simultaneously displays bright display, and when the pixel of the EL element is darkly displayed, the corresponding pixel of the reflective display element Displays a dark display at the same time. The display device according to any one of claims 1 to 8,
A display device characterized in that all pixels of the reflective display element always display a dark display regardless of the display state of light emission or non-light emission of the pixel of the EL element. The display device according to any one of claims 1 to 8,
A display device, wherein all pixels of the EL element are always in a non-light emitting state, and pixels of the reflective display element display bright and dark displays. The display device according to claim 5,
The circular polarization means is composed of two optical phase difference compensation plates, and in order from the EL element side, a first optical phase difference compensation plate whose retardation in the substrate normal direction is set to 100 nm or more and 180 nm or less, The retardation in the normal direction of the substrate is composed of a second optical retardation compensator having a retardation of 200 nm or more and 360 nm or less, and a linear polarizing plate, and the transmission axis or absorption axis of the linear polarizing plate and the first optical position When the angle between the slow axis of the phase difference compensator and the slow axis of the second optical phase difference compensator is θ2 when the angle formed with the slow axis of the phase difference compensator is θ1,
35 ° ≦ | 2 × θ2-θ1 | ≦ 55 °
A display device, wherein a polarizing plate and an optical retardation compensation plate are arranged so that The display device according to claim 5,
The circularly polarizing means is composed of three optical phase difference compensators, and the retardation in the substrate normal direction of the optical phase difference compensator is set to 100 nm or more and 180 nm or less in order from the EL element side. An optical retardation compensator, a second optical retardation compensator disposed on the first optical retardation compensator, and having a retardation in the substrate normal direction of 200 nm or more and 360 nm or less; A third optical phase difference compensation plate that is disposed on the optical phase difference compensation plate and having a retardation in the substrate normal direction of 200 nm or more and 360 nm or less, and a third optical phase difference compensation plate. And an angle formed by the transmission axis or absorption axis of the polarizing plate and the slow axes of the first, second, and third optical phase difference compensators, respectively, θ1, When θ2 and θ3 are set,
35 ° ≦ | 2 × θ3-θ2-θ1 | ≦ 55 °
A display device, wherein a polarizing plate and an optical retardation compensation plate are arranged so that The display device according to claim 3,
The display device, wherein the reflective display element includes a light reflecting film, and the light reflecting film has a smooth and continuously changing uneven shape and is made of a conductive material. The display device according to claim 3,
The reflective display element includes a light reflecting film, and the light reflecting film is composed of an inorganic dielectric mirror or an organic hologram reflecting plate. The display device according to any one of claims 1, 3 to 15,
Furthermore, a color filter layer is formed on the back surface of the circularly polarizing means. The display device according to any one of claims 1, 3 to 16,
The display device further comprises a pressing coordinate detection type input device on a back surface of the circularly polarizing means. The light emitting layer of the EL element is composed of an inorganic material or an organic material,
When the EL element is defined as g = 2 (IL-IR) / (IL + IR) where IR is the intensity of right-handed circularly polarized light and IL is the intensity of left-handed circularly polarized light, it emits at least light that is g ≠ 0. The display device according to claim 1.   The display device according to claim 2, wherein the reflective display element is an electrophoretic display element.

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