JPH02177294A - Electroluminescence element - Google Patents

Abstract

PURPOSE:To display a plurality of contents with a single EL element by forming a luminous layer on a transparent electrode formed on a transparent electrode base film, forming a plurality of high dielectric layers and rear electrodes alternately on the luminous layer and making the high dielectric layers of a material having a high dielectric constant. CONSTITUTION:A luminous layer 3 is formed on a transparent electrode 2 formed on a transparent electrode base film 1. Furthermore, both sides of a luminous unit 8 comprising the alternate lamination of a plurality of high dielectric layers 4 and rear electrodes 5, are sealed. In addition, the high dielectric layers 4 are made of a material having a high dielectric constant, and the rear electrode 5 is arbitrarily shaped. Also, low dielectric layers 13 and 14 are formed with a material having a low dielectric constant in front of the high dielectric layers 4 or the rear electrodes 5. According to the aforesaid construction, it is possible to display a plurality of contents with a single electroluminescence element.

Description

[Detailed description of the invention]

[Industrial Field of Application] The present invention relates to an electroluminescent device that emits light by an electric field.

[Prior art] The structure of a conventional electroluminescent device is that a transparent electrode formed on a transparent electrode base film, one luminescent particle containing zinc sulfide and an activating agent such as copper or chlorine, and an organic A light emitting layer made of a binder (such as cyanoethyl cellulose) is formed, and a back electrode is formed on the other side of the light emitting layer via a layer containing a high dielectric material such as barium titanate. This is sandwiched between hygroscopic films, and the outside thereof is sandwiched between moisture-proof films such as polychlorinated trifluoroethylene that constitute the top and bottom package films. The outer peripheries of both moisture-proof films are sealed by thermocompression bonding. In an electroluminescent device configured as described above, if the entire surface emits light but not the entire surface, and thereby displays characters, figures, symbols, etc., the transparent electrode or back electrode may have a desired shape. The non-light-emitting portion is removed, or a light-shielding member is provided in front of the electroluminescent element. Furthermore, Japanese Patent Publication No. 63-43240 discloses a decorative member that can display multiple display contents by combining a separate member, which is a transparent plate coated with translucent paint, on the front side of an electroluminescent element having a light-shielding member. has been done. [Problems to be Solved] When the transparent electrode or back electrode of an electroluminescent element is formed into a desired shape as in the conventional example above, the non-light-emitting part does not emit light forever and only a single light-emitting shape is formed. I couldn't get it. Further, when a part of the light emitting surface is covered with a light shielding member, a separate member is provided outside the electroluminescent element, which affects the size and shape of the light emitting device. In order to display a plurality of display contents, it is necessary to replace the external light shielding member, which is troublesome and increases costs. In the decorative member proposed in Japanese Patent Publication No. 63-43240, one display content is displayed using an electroluminescent element, and the other display content is drawn with paint or the like and does not emit light. The impression given to the user was completely different depending on the displayed content. In addition, the display content was changed depending on whether it was daytime or in a bright place, or at night or in a dark place, and it was difficult to freely switch the display content on all types of circular tombs. SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an electroluminescent element that can freely switch between a plurality of display contents without providing any separate external member, and that can be manufactured easily. [Means for Solving the Problems] An electroluminescent device according to the present invention includes a transparent electrode formed on a transparent electrode base film, a light emitting layer formed thereon, and further comprising a plurality of high dielectric layers and a plurality of back electrodes. Both sides of the light emitting unit, which is formed by alternately laminating layers, are sealed. The high dielectric layer is made of a material with a high dielectric constant, and the back electrodes are each formed into an arbitrary shape. In addition, in front of the high dielectric layer or in front of the back electrode,
It is characterized in that the low dielectric layer forming the non-light emitting portion is formed of a material with a low dielectric constant. [Function] An electroluminescent element emits light by applying an electric field to a light-emitting layer, and an electrode is placed through a high dielectric layer, and an electric field is applied to the light-emitting layer. In the present invention, a plurality of high dielectric layers and back electrodes are alternately stacked. When an electric field is applied to the transparent electrode and the back electrode of the first layer, a polarization of positive and negative charges occurs inside the high dielectric layer due to the influence of the charge on the back electrode, similar to conventional electroluminescent elements. As a result, an electric field is applied to the light emitting layer. Since the electric field is applied by the back electrode, light is emitted in the shape of the back electrode. When an electric field is applied to the transparent electrode and the back electrode of the second and subsequent layers, positive and negative charges are biased upward and downward within the high dielectric layer under the influence of the charge of the back electrode. The next back electrode that is in contact with this high dielectric layer is not electrically conductive at this time, and due to the influence of the bias in the charge of the high dielectric layer, the back electrode has a charge similar to that of the high dielectric layer. This results in a bias. Subsequently, the next high dielectric layer is affected by the back electrode, and the internal charge distribution becomes uneven. In this way, charge bias occurs within each layer, and eventually an electric field is applied to the light emitting layer. Since the electrical influence is transmitted only to the portion that is in contact with the electrically conductive back electrode, light is emitted according to the shape of the electrically conductive back electrode. Since light is emitted in the shape of one of the plurality of back electrodes that is electrically connected, the display content can be changed by the number of back electrodes. Furthermore, a low dielectric layer can be provided in front of the high dielectric layer. This low dielectric layer is made of a material with a low dielectric constant (such as epoxy resin, which is a common printing resin), and is formed in the shape of a portion where it is not desired to emit light. In this case, even if the charge distribution inside the high dielectric layer is biased due to the effect of the electrically connected back electrode, the low dielectric layer is not affected by the bias, and the charge does not become biased. Therefore, the low dielectric layer blocks the electric field, and the portion where the low dielectric layer is located does not emit light. Therefore, redundant parts such as lead lines for forming the shape of display contents using the back electrode can be erased. Furthermore, the outline of the light emitting section can be made clear. The case where a low dielectric layer is provided on the front surface of the back electrode is similar to the above case. [Example] An example of the present invention will be described with reference to the drawings. As shown in FIG. 1, a light emitting layer 3 is laminated on a transparent electrode 2 formed on a transparent electrode base film 1, and a first high dielectric layer 4 and a first high dielectric layer 4 are formed on the other surface of the light emitting layer 3. A back electrode 5, a second high dielectric layer 6, and a second back electrode 7 are sequentially stacked. The front and back surfaces of the light-emitting unit 8 thus formed are sandwiched between hygroscopic films 9.10, and the outside thereof is sandwiched between moisture-proof films 11.12. The outer periphery of the moisture-proof films 11 and 12 is sealed by thermocompression bonding. The first and second high dielectric layers 4.6 are made of a material with a high dielectric constant, such as barium titanate. The first back electrode 5 is formed, for example, in the shape of an arrow as shown in FIG. 2, and the second back electrode 7 is formed in a circular shape as shown in FIG. Further, extraction electrodes (not shown) protrude to the outside from the transparent electrode 2 and the first and second back electrodes 5.7, respectively. First,
Second. The back electrode 5.7 is provided with lead lines 5a, 7a connected to the lead electrode, and the transparent electrode 2 is formed except for the lead line 5as7a. Next, the operation of this electroluminescent device will be explained. When an electric field is applied between the first back electrode 5 and the transparent electrode 2, the electric field is applied to the light emitting layer 3 via the first high dielectric layer 4. This emits light in the shape of an arrow. Further, when an electric field is applied between the second back electrode 7 and the transparent electrode 2, the second high dielectric layer 6, the first back electrode 5,
Inside each of the first high dielectric layers 4, charge distribution becomes uneven, and an electric field is applied to the light emitting layer 3. This emits circular light. According to this embodiment, for example, in a traffic signal display, it is possible to display two types of indications: ``You can only proceed in the specified direction'' (arrow) and ``Go 1jTJ (circle)'' using one electroluminescent element.Next Another embodiment of the present invention will be described with reference to FIGS. 4 to 6. A light-emitting layer 3 is laminated on a transparent electrode 2 formed on a transparent electrode base film 1, and the other of the light-emitting layers 3 , the first low dielectric layer 13, the first high dielectric layer 4, the first back electrode 5, the second low dielectric layer 14, and the second high dielectric layer 1m
6. The second back electrode 7 is sequentially laminated. The front and back surfaces of the light emitting unit 15 constructed in this manner are sandwiched between hygroscopic films 9 and 10, and further sealed with a moisture-proof film 1.12. Similar to the previous example, the first and second high dielectric JFi4
．． Reference numeral 6 is made of a material having a high dielectric constant, and extraction electrodes (not shown) protrude from the transparent electrode 2 and the first and second back electrodes 5 and 7, respectively. The first back electrode 5 may be configured as shown in FIG. 6, for example.
The second back rT11
ji1 is formed in the shape of the letter "A" as shown in FIG. Lead wires 5a and 7a- are provided to provide electrical continuity from the lead electrode to the back electrode 5.7. The first and second low dielectric layers 13.14 are made of a material that has a low dielectric constant and is not affected by an electric field. The first low dielectric layer 13 is formed to cover the lead wire 5a, and the second low dielectric layer 14 is formed to cover the lead wire 7a and in a portion where the second back electrode 7 is not provided. ing. When an electric field is applied between the first back electrode 5 and the transparent electrode 2, the electric field is applied to the light emitting layer 3 through the first high dielectric layer 4, and light is emitted in the shape of the letter "A". do. At this time,
Since the first low dielectric layer 13 blocks the electric field, the portion of the lead wire 5a does not emit light. When an electric field is applied between the second back electrode 7 and the transparent electrode 2, charge distribution occurs inside the second high dielectric layer 6, the first back electrode 5, and the first high dielectric layer 4. is biased, an electric field is applied to the light-emitting layer 3, and it emits light in the shape of the letter "A". At this time,
Since the second low dielectric layer 14 blocks the electric field, the parts other than the letter "A", including the lead line 7a, do not emit light. Note that the first low dielectric layer 13 also blocks the electric field, but in this case, the portion where the first low dielectric layer 13 is formed is included in the non-light emitting portion formed by the second low dielectric layer 14. There is no impact because it is. In this embodiment, two back electrodes 5.7 and two high dielectric layers 4.6 are laminated, but it is also possible to form a larger number of layers. Further, when providing a low dielectric layer, it is sufficient to provide it only at necessary positions, and there is no need to provide the low dielectric layer for all back electrodes. The low dielectric layer may be provided in front of the back electrode, and the effect is the same as when it is provided in front of the high dielectric layer. The method of sealing the light emitting unit 8.15 is not limited to the example described above. A high dielectric layer, a light emitting layer, and a transparent electrode are further provided on the plurality of laminated high dielectric layers and back electrodes, so that light can be emitted from both the front and back surfaces. In this case, when forming the low dielectric layer, it is necessary to form one layer at a time on the front and rear sides, sandwiching the back electrode. [Effect] As described above, according to the present invention, one electroluminescent element can produce l! It is possible to display the display contents of numbers. There is no need to provide a separate external member, and manufacturing is simple. All of the multiple display contents are caused by light emission from electroluminescent elements, and there is no visual difference between them.
It is possible to switch freely. Further, by providing a low dielectric layer, a portion of the back electrode that is not desired to be displayed, such as a lead line, can be rendered non-emissive. Furthermore, the outline of the displayed content can be made clearer.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of an electroluminescent device according to the present invention, FIGS. 2 and 3 are front views of a display section for explaining its operation, and FIG. 4 is a sectional view of another embodiment of the present invention. Figure 5,
FIG. 6 is a front view of the display section for explaining its operation. DESCRIPTION OF SYMBOLS 1... Transparent electrode base film, 2... Transparent electrode, 3... Light emitting layer, 4... First high dielectric layer, 5... First back electrode, 6... Second high dielectric layer. Dielectric layer, 7. Second back electrode, 8 Light emitting unit, 13 First low dielectric layer, 14 Second low dielectric layer, 15 Light emitting unit. that's all

Claims (2)

[Claims] (1) Both sides of a light emitting unit in which a light emitting layer is formed on a transparent electrode formed on a transparent electrode base film, and a plurality of high dielectric layers and a plurality of back electrodes are alternately laminated on the light emitting layer. is sealed, the plurality of high dielectric layers are formed of a material with a high dielectric constant, and the plurality of back electrodes are each formed in an arbitrary shape. . (2) The device according to claim 1, wherein a low dielectric layer serving as a non-light-emitting portion is formed of a material with a low dielectric constant on the front surface of the high dielectric layer or the front surface of the back electrode. Electroluminescent element.