JP2680721B2 - Thin film EL panel - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial applications]

The present invention relates to a thin film EL panel having a plurality of color filters and capable of multicolor display.

[Prior art]

At present, a so-called double-insulation thin-film EL panel in which an Mn-doped ZnS film (hereinafter referred to as “ZnS: Mn film”) is used as a light-emitting layer and insulating layers are provided on both sides of the light-emitting layer is widely used. ing. The ZnS: Mn film has the highest brightness and is excellent in device stability and reliability. Therefore, the thin-film EL panels that are currently in practical use are only those that use this ZnS: Mn film. Further, using the above ZnS: Mn film, in addition to a thin-film EL panel that emits yellow-orange light, for example, using a Tb-doped ZnS film, a thin-film EL panel that emits green light has been widely studied. Attempts have been made to combine the thin-film EL panel with the above-mentioned thin-film EL panel to make the thin-film EL panel multi-colored or full-colored, but it is still insufficient in terms of emission brightness and stability and reliability of the element. Therefore, in order to facilitate control of color purity, a thin film EL panel has been proposed which is capable of multicolor display using a color filter. Conventionally, as a thin film EL panel capable of multicolor display using a color filter, there is one as shown in FIG. In this thin film EL panel, an electrode 72 in which an Al film is patterned in a stripe shape is formed on a glass substrate 71, and the electrode 72 is formed.
An insulating layer 73, a light emitting layer 74, and an insulating layer 73 are formed in this order on the 72, and further ITO is formed on the insulating layer 75 so as to be orthogonal to the electrodes 72.
A transparent electrode 76 is formed by patterning a (tin-doped indium oxide) film in a stripe shape. Then, the electrode 72
The region where the transparent electrode 76 and the transparent electrode 76 face each other is a picture element. Then, red filters 77a and green filters 77b are alternately formed on the transparent electrodes 76. Another thin film EL panel is the above thin film EL panel in which a black filter is further formed between the picture elements.

[Problems to be solved by the invention]

By the way, a thin film EL panel generally has a structure in which a large number of thin films are laminated, and therefore even if each thin film is transparent,
Reflection of light occurs at the interface and the reflectance of incident light from the outside is high. Therefore, in the former thin film EL panel of the related art, not only individual picture elements but also between picture elements are provided. In some cases, incident light from the outside is reflected to give a white color, which causes a problem of deterioration in display quality. Further, in the latter thin film EL panel of the above-mentioned conventional, since the black color filter is formed between the picture elements, it is possible to suppress reflection of incident light from the outside, but in this case, In addition to the red and green color filters, a relatively time-consuming process of forming a black color filter is additionally required, and the thin film EL panel becomes expensive. Therefore, it is an object of the present invention to provide a thin film EL panel that can suppress reflection of incident light from the outside without increasing cost and that has good display quality.

[Means for Solving the Problems]

In order to achieve the above object, the thin film EL panel of the present invention,
The light emitting layer, the light emitting layer is narrowed through an insulating film and is formed in a stripe shape. The electrodes are orthogonal to each other and a plurality of color filters having different visible light transmission characteristics are provided. In the thin film EL panel in which a voltage is applied to the electrodes which are orthogonal to each other as a picture element in a region to be made to emit light, the picture element of the light emitting layer emits a red color filter between the picture element and the picture element. An overlapping part that overlaps the green color filter is formed,
The visible light transmission characteristics of the overlapping portion are substantially the same as the visible light transmission characteristics of the black color filter. Furthermore, a light emitting layer that emits yellow light is used as the light emitting layer, and The feature is that it has a picture element on which a yellow color filter is formed.

[Action]

Between the picture element and the picture element, an overlapping part is formed in which color filters having different visible light transmission characteristics are overlapped, and the visible light transmission characteristic of this overlapping portion is almost the same as the visible light transmission characteristic of the black color filter. Therefore, the reflection of the external light incident between the picture elements can be suppressed. Further, since the red color filter and the green color filter are used as the color filters forming the overlapping portion, the overlapping portion between the picture elements becomes black, and the reflection of incident light from the outside incident on this portion Is kept low and the display quality of red and green is good. In addition, since the yellow light emitting layer is used as the light emitting layer and the picture element in which the yellow color filter is formed is provided on the yellow light emitting layer, the yellow color filter suppresses reflection of external light to a low level, and By controlling the yellow emission color of the emission layer to a desired color tone, the display quality of the yellow emission color can be improved.

【Example】

Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments. FIG. 1 is a sectional view of the thin film EL panel of the first embodiment. In this thin film EL panel, an electrode 2 in which an Al film is patterned in a stripe shape is formed on a glass substrate 1, and a Si film is formed on the electrode 2.
Insulating layer 3, ZnS: M consisting of laminated film of O ₂ film and Si ₃ N ₄ film
A light emitting layer 4 made of an n film, an insulating layer 5 made of the above laminated film, and a transparent electrode 6 formed by patterning an ITO film in a stripe shape so as to be orthogonal to the electrode 2 are sequentially formed. A region where the electrode 2 and the transparent electrode 6 face each other is a pixel. And
On every other transparent electrode 6 and on the insulating layer 5 adjacent to the transparent electrode 6 and in a region where the transparent electrode 6 is not formed, a red color filter 7a is dyed or a pigment-dispersed photoreceptor method is used. Formed by. Further, a green color filter 7b is dyed or dispersed on the transparent electrode 6 on which the red color filter 7a is not formed, on the region where the transparent electrode 6 is not formed and on the red color filter 7a formed in this region. It is formed by a photoconductor method or the like. That is, the green color filter 7b and the red color filter 7a are overlapped with each other between the picture elements. In the above configuration, the transmission spectrum of the portion where the green color filter 7b and the red color filter 7a overlap each other is almost the same as the transmission spectrum of the black color filter whose transmittance is almost zero in the entire visible light region as shown by the solid line in FIG. In the same manner, the reflection of incident light from the outside incident between the picture elements can be suppressed to a low level without forming a black color filter as in the conventional case, and the display quality is improved. Next, a second embodiment is shown in FIG. In this thin film EL panel, an electrode 12 in which an Al film is patterned in a stripe shape is formed on a glass substrate 11, and an insulating layer 13 composed of a laminated film in which a SiO ₂ film and a Si ₃ N ₄ film are laminated on the electrode 12. The light emitting layer 14 made of a ZnS: Mn film, the insulating layer 15 made of the above laminated film, and the ITO film were made the electrode 1 described above.
A transparent electrode 16 patterned in a stripe shape so as to be orthogonal to 2 is sequentially formed. The electrode 12 and the transparent electrode
The area where 16 faces is the picture element. Also, attach the end with adhesive 19
A seal glass 18 fixed to the electrode 12 is provided above the transparent electrode 16. Then, every other transparent electrode 16 and a red color filter 17a are formed on the lower surface of the seal glass 18 in a region facing the insulating layer 15 in a region where the transparent electrode 16 is not formed, by a dyeing method or a pigment dispersion photoreceptor method. And the like. Further, the lower surface of the red color filter 17a in the area facing the area between the transparent electrode 16 and the transparent electrode 16, and the lower surface of the seal glass 18 between the red color filter 17a and the red color filter 17a on the green color filter 17b. Are formed by a dyeing method or a pigment dispersion photoreceptor method. That is, the green color filter 17 is provided on the lower surface of the seal glass 18 facing the area between the picture elements.
b and the red color filter 17a overlap to form an overlapping portion. In the above configuration, the transmission spectrum of the portion where the green color filter 17b and the red color filter 17a overlap each other is almost the same as the transmission spectrum of the black color filter whose transmittance is almost zero as shown by the solid line in FIG. In the same manner, the reflection of incident light from the outside incident between the picture elements can be suppressed to a low level without forming a black color filter as in the conventional case, and the display quality is improved. Next, a third embodiment is shown in FIGS. This example is
As shown in FIG. 3, using the photolithography technique, the red and green color filters 37a and 37b on the picture element,
Only the point that the red and green color filters 37a and 37b between the picture elements are separated is different from the first embodiment, and the other parts are the same as the first embodiment. The description is omitted. 3 is a cross-sectional view taken along the plane parallel to the direction in which the electrode 2 extends, and FIG. 4 is a plane parallel to the direction in which the transparent electrode 6 extends. It is sectional drawing at the time of cutting. Also in the above configuration, as in the first embodiment, the transmission spectrum of the portion where the green color filter 37b and the red color filter 37a overlap is such that the transmittance is almost zero in the visible light range as shown by the solid line in FIG. The transmission spectrum is almost the same as that of the black color filter, and the reflection of incident light from the outside incident between the above picture elements can be suppressed to a low level without forming a black color filter as in the past. Display quality is improved. In the first, second and third embodiments, when the ZnS: Mn film is formed by the electron beam evaporation method, this ZnS: Mn film is
The Mn film becomes cubic. And of this cubic ZnS: Mn film
Since the Mn ²⁺ ion has an emission spectrum having a peak at a wavelength of 5850Å, the emission color of this cubic ZnS: Mn film is yellow-orange. Further, when the above ZnS: Mn film is formed by the CVD method (chemical vapor deposition method), this ZnS: Mn film becomes a hexagonal crystal. And the Mn ²⁺ ions of this hexagonal ZnS: Mn film are
The hexagonal ZnS: Mn film has a yellow emission color because it has an emission spectrum with a peak at a wavelength of 5800Å. Therefore, when the cubic ZnS: Mn film is used as the ZnS: Mn film, the light emitting layer emits yellow-orange light, so that the red emission brightness of the pixel forming the red color filter becomes high, When a hexagonal ZnS: Mn film is used as the ZnS: Mn film, the light emitting layer emits yellow light, and thus the green emission brightness of the pixel having the green color filter becomes high. In general, since high luminance is required for green, it is desirable that the light emitting layer is made of a hexagonal ZnS: Mn film. Next, a fourth embodiment is shown in FIG. In this thin film EL panel, an electrode 52 in which an Al film is patterned in a stripe shape is formed on a glass substrate 51, and an insulating film 53 made of a laminated film in which a SiO ₂ film and a Si ₃ N ₄ film are laminated on the electrode 52, A light emitting layer 54 made of a hexagonal ZnS: Mn film having a yellow emission color, an insulating layer 55 made of the above laminated film, and a transparent electrode 56 in which an ITO film is patterned in a stripe shape so as to be orthogonal to the electrode 52 are sequentially formed. doing. A region where the electrode 52 and the transparent electrode 56 face each other is a pixel. And every other transparent electrode 56 and transparent electrodes
A red color filter 57a is formed on the insulating layer 55 in a region where 56 is not formed by a dyeing method or a pigment dispersion photoreceptor method. Further, on every two transparent electrodes 56 on which the red color filter 57a is not formed and on a part of the insulating layer 55 on both sides of the transparent electrode 56 where the transparent electrodes 56 are not formed, The yellow color filter 57c is formed by a dyeing method or a pigment dispersion photoreceptor method. Further, the red color filters 57a and the alternate transparent electrodes 56 are formed on every two transparent electrodes 56 on which the red color filter 57a and the yellow color filter 57c are not formed and on the regions where the transparent electrodes 56 are not formed. A green color filter 57b is formed on a part of the insulating layer 55 on both sides of. That is, the green color filter 57b and the red color filter 57a are overlapped with each other between the picture elements. In the above-mentioned configuration, the transmission spectrum of the portion where the green color filter 57b and the red color filter 57a overlap each other is almost the same as the transmission spectrum of the black color filter whose transmittance is almost zero as shown by the solid line in FIG. In the same manner, the reflection of incident light from the outside incident between the picture elements can be suppressed to a low level without forming a black color filter as in the conventional case, and the display quality is improved. In addition, since the yellow color filter 57c is formed on the pixel that emits yellow light, this yellow color filter 57c reduces reflection of external light, and the yellow color filter is provided on the pixel that emits yellow light. The contrast is improved as compared with the case in which it is not formed. Moreover, the yellow color filter 57c controls the emission color of the picture element emitting yellow light to a desired color tone, and the display quality is improved. In the first to fourth embodiments, the color filters forming the overlapping part are the red color filter and the green color filter, but even when the color filters forming the overlapping part are the blue color filter and the red color filter. Similarly to the first to fourth embodiments, it is possible to suppress the reflection of the light incident between the picture elements from the outside from the outside. The point is that a combination of color filters having a color such that the visible light transmittance of the overlapping portion is substantially the same as that of the black color filter may be used.

【The invention's effect】

As is clear from the above description, the thin-film EL panel of the present invention is provided with an overlapping portion of the color filter between the picture elements, and the visible light transmission characteristics of the overlapping portion are the same as those of the visible light of the black color filter. Since the transmission characteristics are almost the same, the reflection of external light incident between the picture elements can be suppressed and the display quality can be improved without increasing the cost. Further, since the red color filter and the green color filter are used as the color filters forming the overlapping portion, the overlapping portion becomes substantially black and the display quality of the red and green emission colors can be improved. Further, by using a light emitting layer that emits yellow light as a light emitting layer,
Since the picture element in which the yellow color filter is formed is provided on the light emitting layer that emits yellow light, the overlapping portion becomes black, and the display quality of the red and green emission colors can be improved, and the yellow color filter It is possible to suppress reflection of external light to a low level, control the yellow emission color of the light emitting layer to a desired color tone, and improve the display quality of the yellow emission color.

[Brief description of the drawings]

FIG. 1 is a sectional view of a first embodiment of a thin film EL panel of the present invention, FIG. 2 is a sectional view of a second embodiment of the present invention, and FIGS. 3 and 4 are a third embodiment of the present invention. 5 is a sectional view of a fourth embodiment of the present invention, FIG. 6 is a light transmission characteristic diagram of a color filter, and FIG. 7 is a sectional view of a conventional thin film EL panel. 1,11,51,71 …… Glass substrate, 2,12,52,72 …… Electrode, 3,5,13,15,53,55,73,75 …… Insulating layer, 4,14,54,74 ...... Emitting layer, 6,16,56,76 …… Transparent electrode, 7a, 17a, 37a, 57a, 77a …… Red color filter, 7b, 17b, 37b, 57b, 77b …… Green color filter, 18 …… Seal glass, 19 …… Adhesive, 57c …… Yellow color filter.

 ─────────────────────────────────────────────────── ─── Continuation of front page (56) Reference JP-A-63-148597 (JP, A) JP-A 2-40890 (JP, A) JP-A 63-121296 (JP, A) JP-A 62- 104000 (JP, A) JP 61-29094 (JP, A) JP 64-69691 (JP, A) JP 61-237394 (JP, A)

Claims (1)

(57) [Claims] 1. A light emitting layer, electrodes which are formed in a striped shape with an insulating film interposed therebetween and are orthogonal to each other, and a plurality of color filters having different visible light transmission characteristics. A region where the orthogonal electrodes face each other is used as a picture element, and a voltage is applied to the mutually orthogonal electrodes,
In the thin-film EL panel that is designed to emit the picture elements of the light emitting layer, the red color filter and the green color filter are overlapped with each other between the picture elements, and the visible light of the overlapped section is formed. Of the black color filter is almost the same as the visible light transmission characteristic. Furthermore, a light emitting layer emitting yellow light is used as the light emitting layer, and a yellow color filter is formed on the light emitting layer emitting yellow light. Thin film EL characterized by having
panel.