JPH0854832A - Transparent thin-film el display - Google Patents

Abstract

PURPOSE:To provide a transparent thin-film EL display with which a background is usually visible by assuring the contrast of the display even when light from a rear surface side is made incident. CONSTITUTION:This transparent thin-film EL display is formed by forming a transparent thin-film EL element 5 on a glass substrate 4 and hermetically sealing a rear surface plate 6 consisting of photochromic glass and the glass substrate 4 formed with the EL element 5 by disposing the EL element on the inner side and packing a transmissive insulating material 8 therebetween. A photochromic compd. reacts to darken the rear of the EL element 5 so as to shield the light when the display of the EL element 5 is made hardly visible by the light from the rear side of the display. Then, various kinds of information are normally displayed via the front surface substrate and the visibility of the background is assured through the display. The strong incoming light from the rear surface side, in case of incidence of such light, is detected and is shut off by an optical shutter function, by which the information is surely displayed without impairing the contrast of the display. A stable display grade having excellent reliability is thus assured.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an EL (electroluminescence) display used for displays of various information terminal devices, displays for aeronautical devices, displays for vehicles, and the like. The present invention relates to a transparent thin film EL display device that can be viewed.

[0002]

2. Description of the Related Art An EL display utilizes the phenomenon of emitting light when an electric field is applied to a phosphor having zinc sulfide (ZnS) or the like as a host material, and is attracting attention as a self-luminous flat display. FIG. 2 shows a cross-sectional structure of a typical EL display device, and the emission color can be variously changed depending on the kind of the emission center element added to the light emitting layer 12.
For example, the luminous base is zinc sulfide (ZnS) and manganese (Mn
n) is added, it turns yellow-orange and terbium fluoride
(TbF ₃ ), samarium chloride (SmCl ₃ ), thulium chloride (TmC ₃
l ₃ ), and praseodymium fluoride (PrF ₃ ) are added, light is emitted in green, red, blue, and white, respectively.

As a well-known transparent thin-film EL display, there is one in which all the films in the structure shown in FIG. 2 are composed of transparent thin films. For example, August 1982 16
Nikkei Electronics' issue P.99, lines 22 to 33 (and P.98, Fig. 9) introduces a transparent thin film EL display in which both upper and lower electrodes are made of ITO transparent conductive film. Furthermore, there is a transparent thin film EL display in which an antireflection film is provided on a transparent back plate of the transparent thin film EL display so that an object to be observed arranged behind the transparent back plate can be clearly viewed (example: (Kaikaihei 3-17437 publication).

On the other hand, for the purpose of improving the contrast of a transparent thin film EL display, a structure in which black vinyl or the like is attached to a transparent back plate or a structure in which a colored paint is applied is known,
Further, it has been proposed that a protective injection fluid for a thin film EL element contains a coloring dye (eg, JP-B-58-555634).
Issue).

[0005]

However, if a black background color is added to improve the contrast, the transparency, which is the greatest feature of the transparent thin film EL display, is lost, and the background on the back surface of the display is lost. It will not be visible at all times. In addition, if the transparent back plate is provided with an antireflection film, the visibility of the background is certainly improved, but for example, when it is mounted as a direct-view (non-virtual) head-up meter on the dashboard of an automobile (see FIG. 3). ), There is a problem that sunlight or other light from a low altitude such as the sunrise or the sunset is directly incident from the back surface of the display device and the information display such as the speed cannot be seen.

Therefore, the present invention ensures a display contrast even when external light is incident on the display from the back side, and in a normal state, the transparent thin film EL display allows the background to be seen through the display. The purpose is to provide.

[0007]

In order to solve the above-mentioned problems, the structure of the present invention is a thin film EL element in which a light emitting layer made of at least a phosphor and a transparent insulating layer are disposed between a pair of transparent electrodes. In a transparent thin film EL display in which at least one is housed in an envelope composed of a translucent front substrate and a translucent rear plate, the transparent thin film EL display is present on the back side of the thin film EL element located on the most back side. One or two or more constituent elements are characterized by arranging optical constituent elements whose light transmittance reversibly changes according to the intensity of external light incident from the back side. is there. One of the above-mentioned optical components whose light transmittance changes reversibly is darkened by light,
It is formed by a photochromic compound that discolors when light irradiation is stopped and returns to the original colorless or transparent colored state. Specifically, the back plate may be formed of photochromic glass.

Further, as another structure of the optical component whose transmittance of light reversibly changes, external light detecting means for detecting external light incident from the back surface, and an electro-optical display having an optical shutter function. Can be configured more. Examples of the electro-optical display having the optical shutter function include a liquid crystal display and an electrochromic display. Further, as the external light detecting means for detecting the external light incident from the back side, CdS, PIN photodiode or the like can be used, but by using a solar cell, the intensity (brightness) of the external light can be detected. At the same time, the electro-optical display can be operated by using the electric power generated according to the strength. Further, it is possible to further improve the display contrast by disposing an antireflection film on the front surface of the translucent front substrate with respect to the incident light such as the room light incident from the front surface of the display.

Further, in a thin film EL display having a thin film EL element in which at least a light emitting layer made of a phosphor is disposed between a pair of transparent electrodes, an external light is provided at a position on the back side of the EL element. When the external light is insensitive to the light emitted from the EL element itself in response to, and the external light becomes strong, the light shielding element functions in the direction of blocking the incident of the external light on the back side of the EL element. It may be characterized by having. Among them, the light shielding element is a translucent back plate made of photochromic glass disposed on the back side of the EL element, or when the light shielding element weakens the external light, It may be characterized in that it has reversibility that functions in a direction in which light is allowed to enter the back surface of the EL element. The transparent thin-film EL display device has a transmittance of higher than 60% when the influence of external light is small, preferably a visible light transmittance of higher than 70%, and is 60% when the influence of external light is strong. % Or less, preferably 50
The visible light transmittance may be less than or equal to%.

[0010]

When the light enters from the back side of the transparent thin film EL display and the display of the EL element becomes difficult to see, the transmittance of the light is reversibly changed immediately according to the intensity of the incident external light. A component, for example, a photochromic compound reacts to darken the back of the EL element and block light from the back. Alternatively, a solar cell is used to generate light from behind, and the electric power is used by an electro-optical display such as a liquid crystal display to act as an optical shutter to block extraneous external light.

[0011]

EFFECTS OF THE INVENTION With the above-described structure of the thin film EL display, various information is normally displayed through the front substrate, the visibility of the background is ensured through the display, and a stronger foreign object than the back side is displayed. When light is incident, it senses it and shuts out extraneous light using the optical shutter function to display information reliably without impairing display contrast, so it is stable even when mounted on vehicles, aircraft, etc. Highly reliable display quality is guaranteed. Further, by disposing the antireflection film on the front substrate, it is possible to prevent reflection due to reflection and reduction in contrast due to incident light from the front surface. Furthermore,
When the influence of external light incident from the back side of the display is small, that is, when the amount of external light is small, the visibility of the background is improved by increasing the transmittance of the transparent thin film EL display in the visible light region to more than 60%. it can. The transmittance is preferably 70
By setting it higher than%, the visibility of the background will not be impaired even when the amount of light is extremely low, such as at night. When the influence of external light becomes strong, it is 60% or less, preferably 5%.
By setting the visible light transmittance to 0% or less, the contrast can be enhanced and the visibility of the display can be secured even when strong external light such as the morning sun or the setting sun enters from the back side of the display.

[0012]

EXAMPLES The present invention will be described below based on specific examples. (First Embodiment) FIG. 1 shows a schematic view of a cross section of a transparent thin film EL display device according to the present invention. Further, FIG. 2 is an enlarged schematic view of a partial cross section of FIG. 1, schematically showing a well-known structure of the thin film EL element 5. The transparent thin film EL element 5 is sequentially arranged on the non-alkali glass substrate 4 which is a translucent insulating substrate,
The following thin films are formed and configured. On the glass substrate 4, a first transparent electrode 10 made of ITO (Indium Tin Oxide) transparent conductive film, a first insulating layer 11 made of transparent tantalum pentoxide (Ta ₂ O ₅ ), etc., Light-emitting layer 12 and second insulating layer 13 whose base material is zinc sulfide (ZnS)
And a second transparent electrode 14 made of a zinc oxide (ZnO: Ga ₂ O ₃ ) transparent conductive film is laminated. Then, the back plate 6 made of separately prepared photochromic glass and the front substrate on which the transparent thin film EL element is formed are arranged so that the EL element is on the inner side, and the spacers 7 maintain a constant space between the substrates. The space is filled with a translucent insulating material 8 such as silicon oil and hermetically sealed (see FIG. 1).

Next, the above-mentioned transparent thin film EL display device, especially E
The method of manufacturing the L element 5 part will be described below. (a) ITO (Indium Tin Oxide) transparent conductive film is formed on the glass substrate 4 by DC sputtering in a mixed gas atmosphere of argon (Ar) and oxygen (O) to a thickness of 2000Å. Then, the transparent first electrode 10 was formed by processing into a desired segment-shaped pattern shape by wet etching (see FIG. 4). (b) On top of that, high-frequency sputtering was performed in a mixed gas atmosphere of argon (Ar), nitrogen (N ₂ ) and a small amount of oxygen (O ₂ ) with silicon (Si) as a target, and silicon oxynitride (SiON) of 1000 Å After forming the film to a thickness, high frequency sputtering was performed on it with a mixture of tantalum pentoxide and aluminum oxide (Ta ₂ O ₅ · Al ₂ O ₃ ) as a target in a mixed gas atmosphere of argon and oxygen.
The first insulating layer 11 was formed by continuously forming a film having a thickness of 3000 Å. (c) Next, high frequency sputtering was performed in a mixed gas atmosphere of argon and helium (He) using zinc sulfide (ZnS) added with TbOF as a target to form a light emitting layer 12a with a thickness of 5000 Å. . At this time, the film formation region was defined using a mask made of SUS or glass as shown in FIG. 5 (a). (d) Next, by using the mask shown in FIG. 5 (b) to define the film-forming region, Mn-added zinc sulfide (ZnS) was used as an evaporation pellet to a thickness of 6200Å by electron beam evaporation. The light emitting layer 12b was formed and formed on the same plane. (e) Then, in the same way as the first insulating layer, 1000 Å of SiON, T
a ₂ O ₅・ Al ₂ O ₃ 2000Å
A second insulating layer 13 was formed by depositing 1000 Å of SiON. (f) After stacking these thin films, Ga ₂ O ₃ was added
A ZnO transparent conductive film was formed into a film having a thickness of 4500 Å by ion plating and processed into a predetermined shape by a photoetching method to form a transparent second electrode 14.

As the constituent material of the first insulating layer 11 and the second insulating layer 13 in the above-mentioned transparent thin film EL element, the above-mentioned Si is used.
It is not limited to ON and Ta ₂ O ₅ / Al ₂ O ₃ , but other than strontium titanate (SrTiO ₃ ), barium tantalate (BaTa ₂ O ₆ ), hafnia (HfO ₂ ), silicon nitride (Si ₃ N _{3 4} ), a transparent insulating film such as alumina (Al ₂ O ₃ ) may be used. Further, in the above description, the two types of light emitting layers 12a and 12b are formed in the same plane, but one type or more types may be used as long as they are transparent.

Furthermore, the first and second transparent electrodes are not limited to the above combination. First transparent electrode 1
At least one of 0 and the second transparent electrode 14 may have a shape of a portion to be luminescently displayed, that is, a 7-segment number, character, or figure (indicated by a one-dot chain line or a two-dot chain line in FIG. 4). Therefore, as shown in FIG. 6, the light emitting display portion of characters, figures, etc. should be formed by the overlapping portion A of the first transparent electrode 18 and the second transparent electrode 19 (in this case, the numeral 1 is formed). You can also

(G) After that, the lower edge portion on the glass substrate 4 is connected by contacting each end portion of the transparent connecting portion 16 extending from each first transparent electrode 10 and each second transparent electrode 14. The terminal portion 3 is formed. The connection terminal portion 3 is formed by depositing a conductive metal such as nickel or gold by a vapor deposition method or a sputtering method.
The electrodes are finely divided and formed at each end of the transparent connection portion 16 by a photoetching method so as not to short-circuit.

In FIG. 4 shown in the above description, the view seen from the display side is used for the sake of easy understanding, but in the above example, the EL element is formed on the translucent front substrate. Therefore, the pattern shape viewed from the EL element side is formed in an inverted shape.

(H) On the back side of the front substrate with the transparent thin film EL element thus formed, the back plate made of the above-mentioned photochromic glass is provided with a diameter of about 50 for gap formation.
A transparent resin bead (not shown) having a diameter of μm is provided so as to be superposed with a certain gap therebetween, and the transparent adhesive 7
Glue with. (i) Next, a moisture-proof silicon oil 8 is filled between the substrates from an oil injection port formed by cutting out a part of the spacer 7,
Seal the oil inlet with an adhesive. In this state, since the peripheral corners of the front plate 4 and the rear plate 6 are exposed, the upper edge portion and the left and right side edge portions of the transparent display portion 2 (FIG. 3) are covered with synthetic resin or the like for protection. You may.

The automobile display 1 thus constructed
As shown in FIG. 3, the transparent display section 2 is erected on the dashboard inside the windshield of the automobile,
The connection terminal portion 3 as shown in FIG. A drive circuit (not shown) is connected to the connection terminal portion 3. At that time, it may be connected to the drive circuit or the like via a flexible thing such as a flexible printed board.

When an AC voltage is applied to the first transparent electrode 10 and the second transparent electrode 14 from the drive circuit through the connection terminal portion 3, the light emitting layer 12 sandwiched therebetween emits light, but by a control circuit (not shown), By controlling the portion of the first transparent electrode 10 or the second transparent electrode 14 to which an AC voltage is applied, a number indicating the vehicle speed or a figure for warning is emitted and displayed. In this embodiment, the numeral part is displayed in green and the warning graphic is displayed in yellow-orange.

At this time, the transparent display portion 2 on the dashboard
Since only the numbers, characters, and figures are displayed on the vehicle, the driver can clearly recognize the display without shifting the line of sight in front of the driver or hindering the field of vision in the front. Furthermore, when strong external light such as the morning sun or the setting sun comes in from the front (backward direction of the display), the photochromic glass that forms the rear plate quickly turns brown, and the driver is confused by the external light. The information such as characters and figures displayed on the display unit can be read without being displayed.
When strong external light is no longer incident due to a change in direction, the photochromic glass returns to its original transparent state, and the field of view in the front is not obstructed, and information such as characters and figures displayed on the display is displayed. You can see clearly while looking at the background in front.

In the first embodiment, the back plate is made of photochromic glass, but the back plate may be made of ordinary transparent glass and a thin film of the photochromic compound may be arranged on the glass. In addition, the rear plate is made of normal transparent glass, and the second transparent thin film EL element formed on the front substrate is
A thin film of a photochromic compound may be formed on the transparent electrode 19. Further, this thin film may be a plastic film or plate containing a photochromic compound. Although the example of the segment display device is taken up in the present embodiment, the same effect can be obtained in the dot matrix display device.

Second Embodiment In the first embodiment, the thin film EL element 5 is formed on the translucent front substrate 4, but the thin film EL element may be formed on the photochromic glass which is the back plate. Absent. FIG. 7 is a schematic diagram showing a cross-sectional structure of one transparent thin film EL display device 100 of such an embodiment.

The structure of this transparent thin film EL display 100 is as follows.
On the translucent front substrate 4 and the photochromic glass 6 which is the back plate, the transparent thin film EL elements 10 having different emission colors are provided.
1, 102 are formed, and the thin film EL elements 101, 10 of each other are formed.
Formed in the shape of 2 facing each other, by exactly overlapping each display area in the mirror symmetry shape,
The color change from the same place can be displayed. Therefore, for example, the speed display can be changed to the signal colors of green, yellow, and red according to the vehicle speed. Even in this case,
As mentioned above, even if external light enters from the back side,
The photochromic glass forming the back plate quickly turns brown, and the driver can read information such as characters and figures displayed on the display unit without being disturbed by external light.

(Third Example) Another example of "an optical component whose transmittance of light reversibly changes according to the intensity of incident external light" other than the photochromic compound will be shown. That is, in FIG. 8, a transparent thin film EL display in the case where a solar cell 9 is used as a means for detecting external light incident from the back side and a liquid crystal display (LCD) 61 is used as an electro-optical display having an optical shutter function. 200 is shown.

Liquid crystal display 6 acting as an optical shutter
1 is a transparent thin film E using a transparent glass back plate 6 '.
It is formed on the rear side of the L element 5. This liquid crystal display 6
8 is not shown in FIG. 8, but in addition to the liquid crystal layer of the liquid crystal display 61, an alignment film and transparent electrode layers are arranged on both sides thereof, and a polarizing plate is attached to the outermost layer. This is a so-called transmissive liquid crystal display. However, the relationship between the liquid crystal and the polarizing plate is normally open (transparent), and is set so as to be closed (darkened) when energized.

The solar cell 9 for detecting external light is formed as a thin film on the transparent glass substrate 6 (not the photochromic glass of the second embodiment) on the outer side (back side) of the liquid crystal display 61. ing. The solar cell 9 is a photovoltaic element using various semiconductor materials such as amorphous silicon (a-Si), but it is essential here that it is transparent. One example of this is a three-layer PIN a-Si
The solar cells 9 may be configured such that both sides thereof are made of transparent electrodes such as ITO, the band gap is adjusted, and the visible region is transmitted.

As means for detecting external light incident from the back side, CdS cells, PIN photodiodes and the like can be used as well. However, by using the solar cell 9, the intensity (brightness) of external light can be determined. In addition to the detection, the liquid crystal display 61 can be operated by using the electric power generated according to the strength, which is advantageous in that it is not necessary to make a separate power supply for energizing the liquid crystal display 61. . Further, by matching the power output of the solar cell 9 and the load of the liquid crystal display 61, it is possible to omit circuit components such as a comparator.

FIG. 10 shows the minimum necessary circuit configuration of the solar cell 9 and the liquid crystal display 61. The role of these (solar cell and liquid crystal display) here does not require precise control, and serves the purpose if the influence of external light is suppressed.
Therefore, in this circuit configuration, a constant voltage circuit configuration for stabilizing the output of the solar cell, which is usually composed of a Zener diode and a resistor, is omitted. Of course, other circuit configurations may be used if necessary.

Although FIG. 8 shows each component integrally, it may have a structure in which the respective parts are laminated within a range not impairing the transparency.

Also in this transparent thin film EL display 200, as described above, even if external light is incident from the back side, the solar cell 9 and the liquid crystal display 61 arranged on the back side can adjust the intensity of the incident light. Photoelectromotive force is generated, and the liquid crystal display 61 is activated by the generated electric power to shut out the external light. Therefore, the driver is not disturbed by the external light, and the information such as characters and figures displayed on the display unit is displayed. Can be read.

(Fourth Embodiment) "Optical component whose light transmittance reversibly changes according to the intensity of incident external light"
As another example of the above, FIG. 9 shows a transparent thin film EL display device 300 when an electrochromic display device (ECD) 62 is used as an optical shutter function. The electrochromic display (ECD) 62 is formed on the transparent glass substrate 6 (not the photochromic glass of the second embodiment). As a means for detecting external light, the solar cell 9 is used as in the third embodiment. The electrochromic display (ECD) 62 includes an electrochromic display (ECD) 62 that uses an electrolytic solution as an electrolyte and an all-solid-state electrochromic display (ECD) 62 that uses a solid electrolyte.

The ECD 62 is known as a low power consumption type display because it is colored and decolored depending on the polarity of electricity and usually has a memory property, but it has no memory property when used in this case. Is preferred. ECD6
In the configuration in which 2 has a memory property, it is necessary to energize for decoloring. Therefore, a circuit configuration for that is provided.

From this point of view, in FIG. 9, the transparent thin film E in the case of using the all-solid-state ECD 62 of the type having no memory property is used.
The L indicator 300 is shown. In addition, its all-solid-state ECD 62
A schematic view of the cross-sectional structure of is shown in FIG. In Figure 9, EC
The D 62 is formed on the back plate 6 ', and when external light is incident from the back side, the photovoltaic cell is generated according to the intensity of the incident light by the combination of the solar cell 9 and the ECD 62. At the same time, the electric power causes the ECD 62 to be colored blue (dark blue) and shuts out external light.
Characters displayed on the display without being disturbed by external light,
Information such as figures can be read.

(Fifth Embodiment) Here, when the external light intensity (external light amount) is small, that is, when the external environment is dark (eg, from evening to night), the visibility (contrast) of the display is good, but the background is good. However, when the external light intensity (external light intensity) is large, that is, when the external environment is bright (for example, on a snowy road or under daylight), the visible line of the background is good. The visibility (contrast) of the display deteriorates. Therefore, it is necessary to increase the transmittance when the external environment is dark, and conversely, it is necessary to decrease the transmittance when the external environment is bright. Therefore, what kind of transmittance should be set in these cases was investigated by the visibility evaluation by the following subjective evaluation method (feeling test).

In the evaluation test, as shown in FIG. 3, the transparent thin film EL display 2 of the comparative example is erected on the dashboard inside the windshield of the automobile, and the rear side (rear side) of the display 2 is transmitted. Various acrylic plates having different rates were attached to the display unit 2 so as to be in close contact with each other, and the evaluation environment was the same as much as possible at the same place. The transparent thin film EL display 2 of the comparative example is a conventional type transparent thin film EL display 2 in which the rear plate of the first embodiment has a transparent glass substrate 6 and its transmittance is not changed by external light.

30 subjects (20 adult males, 1 female)
(0 person) exchanged acrylic plates with different transmittances in a random order and presented them, and the visibility was evaluated by 5 grades. FIG. 12 shows the transparent thin film E when there is no influence of external light.
The evaluation results of the visibility of the L display 2 and the background are shown in FIG. 13, and the evaluation results of the visibility of the transparent thin film EL display 2 and the background when there is an influence of external light are shown.

From the results shown in FIGS. 12 and 13, the following was found. When there is no influence of external light,
That is, it has been found that when the external environment is relatively dark, a very good visibility of the background can be obtained by making the transmittance in the visible light region higher than 60%, preferably higher than 70%. Further, when there is an influence of external light, that is, when the external environment is bright, 60% or less, preferably 5% or less.
It was found that by setting the visible light transmittance to 0% or less, the contrast can be increased and relatively good visibility of the display can be obtained.

Therefore, when there is no influence of external light, the visibility of the background can be improved by making the transmittance in the visible light region higher than 60%, preferably higher than 70%. Further, when there is an influence of external light, the visibility of the transparent thin film EL display 2 can be improved by setting the transmittance in the visible light region to 60% or less, preferably 50% or less.

The term "darkening" in the claims means that the transparent state or the transparent colored state causes discoloration to blue, brown or the like, and the transmittance decreases. Also, reversible change means that what was transparent was colored by light and its transmittance decreased, and then it disappeared and became transparent again, or vice versa. The degree of rate (hysteresis, etc.) is not a concern here. Further, the intensity of external light can be rephrased as the brightness of external light. What is photochromic glass?
A glass containing a photochromic compound almost uniformly,
Or, it is a glass having photochromic properties.

Since the EL element is a self-luminous element, it is possible that the photochromic compound responds to this light. However, since EL light has a relatively sharp emission spectrum, it is distinguished from external light having a wide spectrum. Can be attached. This is because the photochromic glass can be freely made by adding appropriate components, either glass requiring ultraviolet light for darkening or glass darkening with longer wavelength visible light. That is, as a modified example of the claims, an optical component whose light transmittance reversibly changes according to the intensity of incident external light does not easily react with the emission spectrum of the EL display, and is wide from the outside. The transparent thin film EL display according to claim 1, which is made of a photochromic compound that reacts with respect to the spectrum.

[Brief description of drawings]

FIG. 1 is a transparent thin film E according to a first specific embodiment of the present invention.
It is the schematic diagram which showed the cross-section of L indicator.

FIG. 2 is a schematic view showing a partially enlarged sectional structure of FIG. 1, and is a schematic sectional view of a general EL element.

FIG. 3 is an image diagram showing a state in which the transparent thin film EL display device of the first embodiment of FIG. 1 is used on a dashboard of an automobile.

FIG. 4 is a diagram showing a plane (electrode wiring) of the transparent thin film EL display for automobile of the embodiment of FIG.

5 is a view showing a mask for forming a light emitting layer of the transparent thin film EL display for automobiles shown in FIG.

FIG. 6 is a schematic plan view showing a configuration of a light emitting display portion such as characters and figures.

FIG. 7 shows two transparent thin films E having different emission colors according to the second embodiment.
It is a schematic diagram showing the cross section of the display which piled up the L element.

FIG. 8 is a schematic view showing a cross section of a transparent thin film EL display device in which a solar cell of the third embodiment and a liquid crystal display device are combined.

FIG. 9 is a schematic view showing a cross section of a transparent thin film EL display in which the solar cell of the fourth embodiment and an electrochromic display are combined.

FIG. 10 is an equivalent circuit diagram of an optical shutter portion in which the solar cell of the third embodiment and a liquid crystal display are combined.

FIG. 11 is an all-solid-state EC having no memory property according to the fourth embodiment.
It is a schematic diagram showing the cross section of D.

FIG. 12 is a table showing the visibility of the transparent thin film EL display and the background when there is no influence of external light in the fifth embodiment.

FIG. 13 is a table showing the visibility of the transparent thin film EL display and the background in the case where there is an influence of external light in the fifth embodiment.

[Explanation of symbols]

1 Automotive Display 2 Transparent Display Section 3 Connection Terminal Section 4 Glass Substrate (Translucent Insulating Substrate = Front Substrate) 5 Transparent Thin Film EL Element 6 Back Plate (Photochromic Glass Substrate or Normal Glass Substrate) 7 Spacer 8 Translucent Insulating fluid (silicon oil) 9 Solar cell 10 First transparent electrode (eg ITO) 11 First insulating layer (eg Ta ₂ O ₅ : Al ₂ O ₃ / SiON) 12 Light emitting layer (eg ZnS: Mn) 13 Second insulating layer (eg SiON / Ta ₂ O ₅ : Al ₂ O ₃ / SiON) 14 Second transparent electrode (ZnO) 61 Liquid crystal display 62 Electrochromic display (all solid ECD) 100 Photochromic glass as a back plate Transparent thin film EL display 200 having thin film EL element formed thereon 200 A solar cell is used as a means for detecting external light incident from the back side, and a liquid crystal display (LCD) is used as an electro-optical display having an optical shutter function. Transparent thin example E
L display 300 Transparent thin-film EL display using an all-solid-state ECD 62 of a type without memory

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical indication location G09F 9/30 365 D 7426-5H H05B 33/02 33/04 33/08 (72) Inventor Hattori Shoichi Aichi Prefecture Showa-cho 1-1-chome Nihon Denso Co., Ltd.

Claims (13)

[Claims] 1. A thin film EL element having a light emitting layer made of at least a phosphor and a transparent insulating layer between a pair of transparent electrodes, comprising a translucent front substrate and a translucent rear plate. In a transparent thin film EL display having at least one built-in inside an envelope, one or two or more components existing on the back side of the thin film EL element located on the most back side are provided on the back side. A transparent thin-film EL display comprising an optical component whose light transmittance reversibly changes in accordance with the intensity of external light incident from. 2. The transparent material according to claim 1, wherein the optical component comprises a photochromic compound which is darkened by light and fades when light irradiation is stopped to return to an original colorless or transparent colored state. Thin film EL display. 3. The back plate is the optical component made of photochromic glass.
Or the transparent thin film EL display device according to item 2. 4. A thin film EL element having a light emitting layer made of a phosphor and a transparent insulating layer between a pair of transparent electrodes, comprising a transparent front substrate and a transparent rear plate. In a transparent thin film EL display having at least one built-in envelope, an external light detecting means for detecting external light incident from the back side at a position on the back side of the thin film EL element located on the back side. , A transparent thin-film EL display having a normally transparent electro-optical display having an optical shutter function. 5. A thin film EL device having a light emitting layer made of a phosphor and a transparent insulating layer disposed between a pair of transparent electrodes in an envelope made of a transparent front substrate and a back plate. In a transparent thin film EL display having at least one built-in, a solar cell for detecting external light incident from the back side is provided at a position on the back side of the thin film EL element located on the back side, and an optical shutter function. A configuration in which a transparent electro-optical display is usually arranged, the intensity of the external light is detected by the solar cell, and the electro-optical display is operated by using electric power generated according to the intensity A transparent thin film EL display characterized by the following. 6. The transparent thin film EL display according to claim 4, wherein the electro-optical display is a liquid crystal display. 7. The transparent thin film EL display device according to claim 4, wherein the electro-optical display device is an electrochromic display device. 8. The transparent thin film EL display device according to claim 1, further comprising an antireflection film provided on the front surface of a translucent front substrate. 9. A thin film EL display having a thin film EL element in which a light emitting layer made of at least a phosphor is disposed between a pair of transparent electrodes, wherein external light is provided at a position on the back side of the EL element. When the external light is insensitive to the light emitted from the EL element itself in response to, and the external light becomes strong, the light shielding element functions in the direction of blocking the incident of the external light on the back side of the EL element. A transparent thin-film EL display comprising: 10. The transparent thin film EL display device according to claim 9, wherein the light shielding element is a translucent back plate made of photochromic glass, which is disposed on the back side of the EL element. . 11. The light shielding element has a reversibility that functions in a direction in which the external light is allowed to enter the back side of the EL element when the external light becomes weak. The transparent thin film EL display according to claim 9 or 10. 12. A thin film EL having at least a light emitting layer made of a phosphor and a transparent insulating layer provided between a pair of transparent electrodes.
In a transparent thin film EL display in which at least one element is built in an envelope composed of a translucent front substrate and a translucent back plate, the element is located on the back side of the thin film EL element located on the most back side. Any one of the existing one or two or more components is an optical component in which the transmittance of light in the visible region reversibly changes according to the intensity of external light incident from the back side, and the external component A transparent thin film EL display device having a transmittance of more than 60% when the influence of light is small and changing to a transmittance of 60% or less when the influence of the external light is strong. 13. When the influence of the external light is small, 70%
The transparent thin film EL display device according to claim 12, which has a higher transmittance and changes to a transmittance of 50% or less when the influence of the external light is strong.