JP6276086B2 - Mirror device with organic EL panel - Google Patents

Description

  The present invention relates to a mirror device including an organic EL panel, and more particularly to a mirror device including a continuous mirror region in which the boundary between a mirror light-emitting region and a mirror non-light-emitting region is inconspicuous.

  In recent years, an organic EL light source has attracted attention as an illumination light source to replace incandescent lamps and fluorescent lamps, and many studies have been made. In addition, an organic EL method is attracting attention as a method for changing to a liquid crystal method or a plasma method in a display member typified by a television.

  Here, the organic EL light source is obtained by laminating an organic EL element on a base material such as a glass substrate or a transparent resin film. In addition, the organic EL element has two or more light-transmitting electrodes facing each other, and a light emitting layer made of an organic compound is laminated between the electrodes. The organic EL element emits light by the energy of recombination of electrically excited electrons and holes. Since the organic EL light source is a self-luminous device, a high-contrast image can be obtained when used as a display material. In addition, light of various wavelengths can be emitted by appropriately selecting the material of the light emitting layer. In addition, the thickness is extremely thin compared to incandescent lamps and fluorescent lamps, and light is emitted on the surface, so there are few restrictions on the installation location.

  A typical layer structure of an organic EL light source is a structure called a bottom emission type. Generally, a transparent electrode layer, a functional layer, and a back electrode layer are laminated on a glass substrate, and these are sealed by a sealing portion. It is sealed. Here, the functional layer is formed by laminating thin films containing a plurality of organic compounds. A typical functional layer configuration includes a hole injection layer, a hole transport layer, a light emitting layer, an electron transport layer, an electron injection layer, a block layer, a charge generation layer, etc., and contributes to light emission. The light emitting layer is essential. In such a layer configuration, with respect to the opposing electrode layer and the functional layer sandwiched between them, the portion including both electrode layers of the overlapping portion of these layers is an organic EL element, and the voltage between the electrode layers is reduced. When applied, the light emitting layer emits light.

  As an application product of such an organic EL light source, Patent Document 1 discloses that a mirror is extremely thin so that it is not necessary to prepare new illumination when observing an object using a mirror in a dark place. Ultra-thin electroluminescence as a mirror device with built-in EL illumination that is easy to carry and install so that the object can be brightly illuminated and easily observed with a mirror. A non-light-emitting portion is formed on a part of the substrate made of glass or plastic as a part of the organic EL device using the organic EL element, and the mirror-like cathode part of the organic EL element on the back side of the part. Glass of a bottom emission type organic EL light source so that a part of a mirror device having a structure (FIGS. 1 and 2 of Patent Document 1 and FIG. 2 of Patent Document 1) can be seen through, and a part of a normal mirror is transparent and in contact with the rear surface substrate It proposes a mirror device pasted structure (FIG. 3 of Patent Document 1).

  Patent Document 2 discloses a mirror device that makes it difficult to cast a shadow on the face without causing the user to feel dazzling, and can illuminate the face with sufficient brightness even when the user approaches the mirror body. , A mirror body having at least a peripheral part configured as a half mirror, a light emitting panel arranged in a plurality of rows from the outside to the inside on the back side of the peripheral part of the mirror body, the mirror body 2 and the user A mirror device comprising a sensor capable of measuring a distance between the light emitting panel and a control unit 7 for turning on or off each column of the light emitting panels in accordance with the distance measured by the sensor, in order to form a half mirror A mirror device having a bottom emission type organic EL panel (BEP) in contact with a thin metal layer at the periphery is proposed.

JP 2002-329418 A JP 2008-018058 A

  The present invention has been made to solve such problems in the prior art, and can make use of the characteristics of uniformity and simplicity possessed by a large-area mirror to realize a clear space. It aims at realizing a mirror device provided with an organic EL panel as. Specifically, a mirror that has a good appearance by providing a continuous mirror region in which the boundary between the non-light-emitting mirror region and the light-emitting mirror region is inconspicuous, and that can be manufactured inexpensively and easily as a large-area mirror device. The object is to provide a device.

  For such an object of the present invention, the mirror device in which the mirror-like cathode portion can be seen through a part of the substrate of the organic EL device of Patent Document 1 is a general characteristic of BEP. In the state, it utilizes the fact that the cathode metal layer of the BEP becomes a mirror surface, but in order to make a large-area mirror without a visible boundary on the mirror surface, the BEP itself needs to have a large area, Unrealistic in terms of manufacturing costs.

  In addition, in the mirror apparatus in which a part of a normal mirror of Patent Document 1 is transparent and a BEP is attached thereto, the transparent substrate of the BEP has a thickness exceeding at least 10 μm. There is a problem that a continuous mirror region in which the boundary of the light-emitting mirror region is inconspicuous cannot be obtained.

  Furthermore, the mirror apparatus of Patent Document 2 is a mirror apparatus in which a part of the normal mirror of Patent Document 1 is transparent and a BEP is pasted thereon, and the transparent part is a half mirror. The problem of the occurrence of boundary in can be expected to be alleviated to some extent by using a half mirror, but it is not perfect, and since there are two metal layers as reflection layers in the half mirror part, the image reflected on the mirror surface In the first place, the BEP radiates light to the outside through the half mirror, so that the light emission from the organic EL element is disturbed by the half mirror and radiated to the outside. There is a problem that loss is large.

  In view of the above, there is a need for a technology that practically provides a wall member that utilizes the uniformity and simplicity of a large-area mirror and that can realize a clear space.

  In view of the above situation, the present inventor has noted that, in a so-called top emission organic EL panel (TEP), in general, only a thin film layer formed physically or chemically on the light emitting surface is formed. That is, the same structure as a mirror in which a mirror metal layer is formed on a transparent glass plate is realized by placing TEP on the transparent glass plate with its light emitting surface facing the transparent glass plate, that is, the metal of TEP. An attempt was made to give the electrode layer the same function as the mirror metal layer on the glass plate in the mirror device. With such a configuration, only the thin film layer exists on the light emitting surface as described above, and the penetration of moisture and the like into the organic EL element cannot be sufficiently prevented, and the generation and growth of dark spots (DS). It was thought that the general weak point of TEP that could not be sufficiently prevented could be reinforced with a transparent glass plate having a high water vapor barrier property.

The present invention derived based on such an idea includes an organic EL panel 13 and a light-emitting organic compound sandwiched between two opposing electrode layers on one main surface of the transparent glass plate 10. A mirror device 1 including an organic EL panel 13 including a functional layer 22 including a light emitting layer, and including a non-light-emitting mirror region 3 and the light-emitting mirror region 4 when viewed from the other main surface. ,
A mirror metal layer 2 forming a mirror surface of the mirror device 1 is formed on the one main surface, and is a mirror non-light-emitting metal layer 11 corresponding to the non-light-emitting mirror region 3 and one electrode layer 21. A mirror-emitting metal electrode layer 21 corresponding to the light-emitting mirror region 4, and
The mirror non-light emitting metal layer 11 and the mirror light emitting metal electrode layer 21 have an overlapping region 5 that overlaps when viewed from the other main surface, and
In the overlap region 5, the thin film layer 6 has a thickness of 1 μm or more and 10 μm or less, and is the other electrode layer 23 in order from the mirror non-light emitting metal layer side 11 toward the mirror light emitting metal electrode layer 21. The mirror device 1 includes only the transparent electrode layer 23 and the thin film layer 6 including the functional layer 22 as a part of the organic EL panel 13.

  In the above description and the following description, for the sake of explanation, the reference numerals in FIG. 1 are used for description, but the present invention is not limited to these reference numerals.

  FIG. 1 is a conceptual cross-sectional view of an arrangement portion of an organic EL panel 13 of a mirror device 1 according to an embodiment of the present invention.

  According to the configuration of the present invention, since the continuous mirror region in which the boundary between the non-light-emitting mirror region 3 and the light-emitting mirror region 4 is inconspicuous is provided, it has a good appearance and the light emission from the organic EL panel 13 is not lost. The mirror device 1 of the present invention, which is a radiable glass plate with a light-emitting mirror, can be provided inexpensively and easily.

  In the mirror device 1 of the present invention, the power feeding area to the organic EL panel 13 is covered with the non-light emitting mirror area 3. Therefore, the internal structure such as the wiring in the power feeding area does not appear on the appearance. Therefore, a good appearance can be obtained.

  Further, since the boundary portion with the non-light-emitting mirror region 3 is not conspicuous when the light is turned off, a mirror surface integrated with the light-emitting mirror region 4 is formed, so that the uniformity is high and the appearance is good.

The organic EL panel 13 includes the mirror light emitting metal electrode layer 21, the functional layer 22, and the transparent electrode layer 23 formed on the other main surface of the insulating substrate 20, and
It is preferable that the back surface metal layer 15 electrically connected to the mirror light emitting metal electrode layer 21 is provided on one main surface of the insulating substrate 20, and the mirror metal light emitting metal electrode layer 21 is reliably and simply provided from the outside. It becomes the structure which can be supplied with electricity.

  In TEP, it is common to provide a power feeding region adjacent to the light emitting region on the light emitting surface. In TEP having such a structure, the mirror light emitting metal electrode layer 21 is formed on the transparent glass plate 10 according to the present invention. Therefore, it is difficult to obtain the boundary continuity effect according to the present invention, and the moisture invasion suppression effect to the TEP according to the present invention is obtained. It will not be easy.

  On the other hand, in the present invention, the back surface metal layer 15 according to the present invention is provided, and this is electrically connected to the mirror light emitting metal electrode layer 21. Specifically, the through hole in the surface of the insulating substrate 20 is provided. Are electrically connected via the backside metal layer 15 material or the mirror light emitting metal electrode layer 21 material, so that the boundary continuity effect according to the present invention and the TEP according to the present invention can be achieved. It is possible to easily obtain the effect of suppressing moisture penetration.

  Moreover, according to the structure of this invention, it is not necessary to newly provide the wiring etc. for supplying electric power to the mirror light emitting metal electrode layer 21 from the outside.

The organic EL panel 13 is a metal pad layer 24 formed on the other main surface of the insulating substrate 20 and covered with the mirror non-light emitting metal layer 11 when viewed from the other main surface,
It is preferable that the metal pad layer 24 electrically connected to the transparent electrode layer 23 is provided, and the transparent electrode layer 23 can be reliably and simply supplied with power from the outside.

  More preferably, the transparent electrode layer 23 is formed so as to cover the entire region where the functional layer 22 is formed in the surface of the insulating substrate 20 and to form an in-plane end portion only in the surface of the metal pad layer 24. Thus, at the same time as the formation of the transparent electrode layer 23, electrical connection to the metal pad layer 24 is realized, and at the same time, it becomes a structure that easily prevents moisture from entering the organic EL element 30.

  Further, the metal pad layer 24 is preferably electrically connected to the mirror non-light emitting metal layer 11 and has a structure capable of reliably and simply supplying power to the transparent electrode layer 23 from the outside. That is, by supplying power to the organic EL panel 13 according to the present invention from the outside through the mirror non-light emitting metal layer 11 that is the mirror metal layer 2 formed on the transparent glass plate 10, wiring for panel power supply is provided. It is not necessary to provide a separate mirror, and it is inexpensive and simple, particularly when the mirror device has a large area. In addition, not only the panel but also the non-light-emitting mirror layer 3 is energized. Therefore, it is possible to provide the entire mirror surface with a function of preventing fogging due to water vapor adhesion. Further, according to the configuration of the present invention, the mirror non-light-emitting metal layer 11 can be used not only for hiding the power supply region related to the panel but also as a part of the power supply member. As the conductive material portion 17 for electrically connecting the metal pad layer 24 to the mirror non-light emitting metal layer 11, a conductive paste such as a silver paste can be used.

  The thin film layer 6 preferably includes a transparent insulating sealing layer 7 that is in contact with the mirror non-light-emitting metal layer 11, and can have a structure that prevents moisture from entering the organic EL element 30. .

  Moreover, it is preferable to set it as the mirror apparatus provided with the transparent refractive index adjustment resin layer 12 between the said transparent glass plate 10 and the said organic electroluminescent panel 13, and a boundary can be made not conspicuous and a light emission loss is prevented. You can also.

  Moreover, it is preferable to set it as the mirror apparatus 1 provided with the thermosetting resin sealing wall 16 which contact | connects the said mirror non-light-emission metal layer 11 and the said back surface metal layer 15 at least, and water | moisture permeation to the organic EL element 30 is further carried out. It can be effectively stopped. Such a thermosetting resin sealing wall 16 prevents the intrusion of moisture more effectively and protects the energization path after confirming the electrical characteristics of the entire apparatus, thereby ensuring the product yield. From the viewpoint of simplicity, after the organic EL panel 13 is placed on and adhered to the transparent glass plate 10 by the conductive material portion 17, a thermosetting resin is applied and cured around the organic EL panel 13, and the organic EL element 30 side is formed. Therefore, it is preferable that the conductive material portion 17 and the metal pad layer 24 are formed outside and in contact therewith.

Furthermore, this invention is a manufacturing method of the mirror apparatus 1 of this invention,
Forming the functional layer 22 using the shadow mask 1, and
And a step of forming the transparent electrode layer 23 so as to cover the entire exposed surface of the functional layer 22 using a shadow mask 2 different from the shadow mask 1.

  According to the configuration of the present invention, the presence of the transparent electrode layer 23 prevents intrusion of moisture into the organic EL element 30, and the power feeding path to the transparent electrode layer 23 is formed simultaneously with the formation of the transparent electrode layer 23. Secured by

When manufacturing the mirror device 1 including the transparent insulating sealing layer 7,
After forming the transparent insulating sealing layer 7, it is preferable that the manufacturing method includes a step of lifting off a part of the transparent insulating sealing layer 7. More preferably, the transparent insulating sealing layer 7 is formed on the entire surface of the insulating substrate 20 after forming each layer. After that, it is lifted off outside the transparent electrode layer 23, more preferably lifted off so that the surface of the metal pad layer 24 is exposed, and particularly preferably at the entire peripheral edge of the insulating substrate 20. In addition to the lift-off, it is possible to prevent moisture from entering the organic EL element 30 and to easily secure a power feeding path from the mirror non-emitting metal layer 11 to the transparent electrode layer 23 by the conductive material portion 17.

  The effect of the present invention is that a mirror emission region can be easily and inexpensively formed on a large-area mirror while maintaining the continuity and uniformity of the mirror surface. Applicable to large area mirrors. In other words, low-cost and simple provision of a large-area glass plate with a light-emitting mirror that has a continuous mirror region where the boundary between the mirror light-emitting region and the mirror non-light-emitting region is inconspicuous and can emit light from the organic EL panel without loss it can.

It is a cross-sectional conceptual diagram in the organic EL panel 13 arrangement | positioning part of the mirror apparatus 1 in one Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described. In addition, this invention is not limited to the following embodiment, A various change is possible within the technical common sense of those skilled in the art.

(Mirror device 1)
As shown in FIG. 1, the mirror device 1 of the present embodiment includes a non-light-emitting mirror region 3 and a light-emitting mirror region 4 as seen from above in FIG. Is the main body.

  On one main surface of the mirror device 1, that is, one main surface of the transparent glass plate 10, a mirror metal layer 2 forming the mirror surface is disposed so as to be a mirror when viewed from the other main surface, The mirror metal layer 2 includes a mirror non-light-emitting metal layer 11 formed on the transparent glass plate 10 corresponding to the non-light-emitting mirror region 3, and a part of the organic EL panel 13 corresponding to the light-emitting mirror region 4. It is one of the features of the present invention that it includes a mirror-emitting metal electrode layer 21 formed as follows.

  That is, the mirror device 1 includes an organic EL panel 13 as a light source on one main surface, and a transparent non-light emitting metal layer 11 is formed on at least a part of one main surface as shown in FIG. The glass plate 10 and at least one organic EL panel 13 including the mirror light emitting metal electrode layer 21 are formed.

  The organic EL panel 13 is arranged such that the transparent glass plate 10 faces the light-emitting mirror region 4 where the mirror non-light-emitting metal layer 11 is not formed, and the transparent electrode layer 23 side that is the light-emitting surface faces the transparent glass plate 10. The mirror device 1 is formed by mounting and adhering. At this time, the mirror non-light-emitting metal layer 11 and the mirror light-emitting metal electrode layer 21 have the overlapping region 5 that overlaps when viewed from the other main surface 21. It is one of the features of the present invention that the mirror region is continuously formed. As seen from the other main surface of the mirror device 1, it is possible to provide the overlapping region 5 only in a part of the periphery of the light-emitting mirror region 4 so that only that part becomes a continuous mirror. It is preferable to provide the superimposing region 5 over the entire circumference of 4 so that the entire light-emitting mirror region 4 becomes a mirror continuous with the surrounding non-light-emitting mirror region 3.

The organic EL panel 13 can be bonded to the transparent glass plate 10 by sandwiching an adhesive material between these mirror device members. As the method, one or more selected from the group consisting of a transparent refractive index adjusting resin layer 12 to be described later, a conductive material portion 17 to be described later, and a thermosetting resin sealing wall 16 to be described later, which is a mirror device member. It is preferable that the adhesive material be used. More preferably, it is to carry out any one of the following three methods (1) to (3), particularly preferably a combination thereof, and most preferably to carry out all of these. .
(1) The resin liquid to be the transparent refractive index adjusting resin layer 12 made of an adhesive material is surely distributed uniformly in the center of the light-emitting mirror region 4 of the transparent glass plate 10 while surrounding the region. (2) Organic, after dripping the minimum amount which does not spread as much as possible to the non-light-emitting mirror region 3 and, more preferably, temporarily fixing while preventing air bubbles from entering between the panel and the glass plate A conductive paste that becomes the conductive material portion 17 is applied to the power feeding portion of the organic EL panel 13 as a paste that can be dried and solidified by evaporation of the solvent to form a porous conductive film having a certain adhesion. Gluing,
(3) The resin liquid before curing of the curable resin to be the thermosetting resin sealing wall 16 as the adhesive material is placed around the non-light emitting surface of the organic EL panel 13 with the panel placed on glass. More preferably, the entire circumference of the transparent glass plate 10 surrounding the non-mirror surface side of the transparent glass plate 10 is coated, cured, and bonded. Such a mirror device 1 of the present invention includes a plurality of organic EL panels 13. A plurality of large areas can be obtained by placing the mirror non-light emitting metal layer 11 across two or more organic EL panels 13 in a plane distribution in the plane of the transparent glass plate 10. The mirror device 1 having the light-emitting mirror region 4 is particularly effective. Since the mirror non-light-emitting metal layer 11 is disposed across two or more organic EL panels 13, the common mirror Feeding area of a plurality of organic EL panels 13 adjacent to each other by the light emitting metal layer 11 Since the area can be covered, the number of parts can be reduced.

(Mirror glass plate)
The transparent glass plate 10 on which the mirror non-light-emitting metal layer 11 according to the present invention is formed has a complete mirror surface at least at a part corresponding to the light-emitting mirror region 4, preferably at a part corresponding to the region. It is the same as a normal glass mirror except that the mirror metal layer 2 is not formed. From the viewpoint of radiating the light emitted from the organic EL panel 13 according to the present invention from the mirror device 1 without loss, it is preferable that this region has the transparency that the transparent glass plate 10 originally has.

  Hereinafter, the “transparent glass plate 10 on which the mirror non-light emitting metal layer 11 is formed” according to the present invention will be referred to as “mirror glass plate”. That is, in the “mirror glass plate” according to the present invention, the mirror metal layer 2 that can be a perfect mirror surface only in the portion corresponding to the non-light-emitting mirror region 3 is used as the mirror non-light-emitting metal layer 11. Is formed.

  In order to adjust the mirror surface appearance, particularly the brightness, of the non-light-emitting mirror region 3 and the light-emitting mirror region 4 when the light is turned off, to make them substantially the same, and the long-term reliability of the mirror surface of the mirror glass plate In order to ensure this, it is preferable to provide a transparent adjustment layer 19 between the transparent glass plate 10 and the mirror non-light emitting metal layer 11, and a transparent material can be used as the material thereof.

(Transparent glass plate 10)
The transparent glass plate 10 according to the present invention is a plate that has a mirror non-light emitting metal layer 11 formed on one main surface thereof and serves as a main body of the mirror device 1 according to the present invention. From the viewpoint of achieving the effects of the present invention in ten parts, it is preferably a large-area glass plate, and from the viewpoint of a bright mirror surface mirror device 1 having a high reflectance, a glass plate having no absorption in the visible light region. It is preferable that

  As the glass material, any glass material can be used depending on the purpose, but from the viewpoint of a mirror device having a large area and a reduced cost, white plate glass, blue plate glass, etc. can be used, more preferably large. The area is to use blue plate glass.

  In general, an organic EL element may be deteriorated by intrusion of an alkali component from the substrate, and it is necessary to use an expensive high-quality member that does not adversely affect the element of a contamination component as a related member.

  On the other hand, although the mirror device 1 of the present invention includes the organic EL element 30, the substrate 20 and the transparent glass plate 10 of the mirror device 1 are different from each other, and alkali glass is used as the material of the transparent glass plate 10. As a member related to the organic EL element 30, if the area occupied by the light-emitting area 4 is small, the cost does not increase even if a high-quality member is used. This is one of the features of the present invention.

  For the same reason, chemically tempered glass can be used as the transparent glass plate 10 according to the present invention, which is preferable from the viewpoint of a large-area and high-strength mirror device. Of course, it is also preferable to use normal heat strengthened glass.

(Mirror non-light emitting metal layer 11)
The material of the mirror non-light emitting metal layer 11 is preferably silver or aluminum having high reflectivity and conductivity, and more preferably silver.

(Organic EL panel 13)
In the organic EL panel 13 according to the present invention, for example, as shown in FIG. 1, a metal electrode layer 21 is formed as one electrode layer on the other main surface of the insulating substrate 20, and a functional layer 22 is formed thereon. An electron injection layer, an electron transport layer, a light emitting layer, a hole transport layer, and a hole injection layer are formed, and a transparent electrode layer 23 is formed thereon as the other electrode layer. By doing so, the organic EL element 30 is formed. And a transparent insulating sealing layer 7 is further provided thereon to complete the structure. The back surface metal layer 15 is provided on one main surface of the insulating substrate 20, or the metal pad layer 24 is provided in a region where the organic EL element 30 is not formed on the other main surface of the insulating substrate 20. be able to.

(Mirror Luminescent Metal Electrode Layer 21)
The material of the mirror light emitting metal electrode layer 21, particularly at least the mirror functional layer 21-2 in contact with the functional layer 22, may be the same material as that of the mirror non-light emitting metal layer 11. It is preferable from the viewpoint of unifying the reflectance of the light source and achieving the boundary continuity effect according to the present invention, and it is a device having high characteristics to be a cathode (cathode) for supplying electrons to the organic EL device 30 in lighting or the like It is preferable from a viewpoint of forming, and it is more preferable to form with silver.

  The mirror light emitting metal electrode layer 21, particularly at least the mirror functional layer 21-2 in contact with the functional layer 22, is preferably a thin film formed in a vacuum such as vacuum deposition or sputtering, and the surface can be easily mirrored. can do.

(Functional layer 22)
The functional layer 35 is a layer that is provided between the transparent electrode layer 23 and the mirror light emitting metal electrode layer 21 and includes a light emitting layer capable of emitting light containing at least one organic compound. The functional layer 22 is composed of a plurality of layers mainly made of organic compounds. The functional layer 22 can be formed of a known material such as a low molecular dye material or a conjugated polymer material used in a general organic EL device. The functional layer 22 generally has a multilayer structure composed of a plurality of layers such as a hole injection layer, a hole transport layer, an organic light emitting layer, an electron transport layer, and an electron injection layer.

  In general, the functional layer 22 is transparent or almost transparent when the light is turned off, and the functional layer 22 according to the present invention is transparent.

The functional layer 22 preferably includes a layer containing molybdenum oxide (MoO ₃ ) as a part of the hole injection layer and as a layer in contact with the transparent electrode layer 23, and a transparent electrode formed after the formation thereof. It is possible to reduce damage to the element when the layer 23 is formed.

(Transparent electrode layer 23)
The material of the transparent electrode layer 23 is not particularly limited as long as it is transparent and has conductivity. For example, indium tin oxide (ITO), indium zinc oxide (IZO), tin oxide Transparent conductive oxides such as (SnO2) and zinc oxide (ZnO) are employed. The transparent electrode layer 23 is preferably an anode (anode) for supplying holes to the organic EL element 30 in lighting or the like from the viewpoint of forming an element with high characteristics, and more preferably formed of ITO.

  The transparent electrode layer 23 can be provided with an ultra-thin metal layer or a fine metal wire in the transparent electrode layer 23 from the viewpoint of preventing the occurrence of a voltage drop in the layer while maintaining its transparency.

(Transparent insulating sealing layer 7)
The material of the transparent insulating sealing layer 7 is not particularly limited as long as it has transparency, insulating properties, and sealing properties, but one or more kinds selected from oxygen, carbon, and nitrogen are used. It is preferably formed of a silicon alloy composed of an element and a silicon element, silicon nitride or silicon oxide containing a bond of Si—O, Si—N, Si—H, N—H, etc., and an intermediate solid solution of both Particularly preferred is silicon oxynitride.

  Further, as the transparent insulating sealing layer 7, it is preferable to use an insulating sealing layer having a multilayer structure from the viewpoint of improving sealing performance. It is preferable that the first transparent insulating sealing layer formed by the dry method from the 30 side and the second transparent insulating sealing layer formed by the wet method are laminated in this order.

  The first transparent insulating sealing layer is a layer formed by chemical vapor deposition, and more specifically, is preferably a layer formed by a plasma CVD method using silane gas, ammonia gas or the like as a raw material. Such a 1st transparent insulating sealing layer can be formed into a film following the formation process of the organic EL element 30 implemented in the atmosphere with little moisture content.

  The second transparent insulating sealing layer is a layer formed through a chemical reaction after applying a liquid or gel material. More specifically, the second transparent insulating sealing layer is preferably made of dense silica. The second transparent insulating sealing layer is preferably made from a polysilazane derivative. In the case where the second transparent insulating sealing layer is formed by silica conversion using a polysilazane derivative, a weight increase occurs during silica conversion, and volume shrinkage is small. Further, it is possible to make cracks sufficiently at a temperature that the resin can withstand when the silica film is converted (solidified).

Here, the polysilazane derivative is a polymer having a silicon-nitrogen bond, and is composed of Si—N, Si—H, N—H, etc., such as SiO ₂ , Si ₃ N ₄ , and an intermediate solid solution SiOxNy thereof. It is a precursor polymer. The polysilazane derivative also includes a derivative in which a hydrogen part bonded to Si is partially substituted with an alkyl group or the like.

  Among the polysilazane derivatives, perhydropolysilazane in which all side chains are hydrogen, and derivatives in which a hydrogen part bonded to silicon is partially substituted with a methyl group are particularly preferable.

  Moreover, it is preferable to apply and use this polysilazane derivative in the solution state melt | dissolved in the organic solvent. As the organic solvent to be dissolved, hydrocarbon solvents such as aliphatic hydrocarbons, alicyclic hydrocarbons and aromatic hydrocarbons, ethers such as halogenated hydrocarbon solvents, aliphatic ethers and alicyclic ethers can be used. .

  As described above, the second transparent insulating sealing layer is preferably formed by laminating a material different from the first insulating sealing layer as the sealing layer. By complementing mutual defects, the sealing performance is improved. It is possible to prevent the occurrence of new dark spots over time or to suppress the expansion of the generated dark spots.

  The average thickness of the insulating sealing layer 7 is preferably 1 μm to 9 μm, and more preferably 2 μm to 5 μm.

  The thickness of the first transparent insulating sealing layer serving as a part of the transparent insulating sealing layer 7 is preferably 1 μm to 5 μm, and more preferably 1 μm to 2 μm.

  Further, the thickness of the second transparent insulating sealing layer serving as a part of the transparent insulating sealing layer 7 is preferably 1 μm to 5 μm, and more preferably 1 μm to 3 μm.

(TEP substrate)
Such an organic EL panel 13 according to the present invention is preferably formed on a TEP substrate according to the present invention as shown in FIG. Here, the TEP substrate according to the present invention includes the back surface metal layer 15 on one main surface, and at least a part of the mirror light emitting metal electrode layer 21 in the center on the other main surface. And at least one through hole 25 connecting the back surface metal layer 15 and at least a part of the mirror light emitting metal electrode layer 21 in the vicinity of the center of the surface. It is a substrate.

  By the way, the surface of the mirror light emitting metal electrode layer 21 in contact with the functional layer 22 should be smooth in the order of nm from the viewpoint of making the organic EL element 30 a high performance element and making the surface a sufficient mirror surface. Preferably, as described above, the outermost mirror functional layer 21-2 is preferably formed as a thin film. And the smoothness of the surface of this mirror function layer 21-2 will depend on the surface state of the mirror base layer 21-2 in the mirror light emitting metal electrode layer 21 which is the foundation. Therefore, as such a mirror base layer 21-2, a metal film or a metal plate whose surface is polished is preferable.

  A procedure for forming a TEP substrate according to the present invention including a member including such a polished metal surface is as follows. That is, an insulating substrate 20 having a through hole serving as a through hole 25 is attached to the back side of the polished metal surface of this member, and a metal pad layer is formed around the region where this member is attached on the insulating substrate 20 before, after or simultaneously. A metal layer to be 24 is formed. Thereafter, the back metal layer 15 is formed on the surface of the insulating substrate 20 on the side where the member is not affixed, preferably with the exception of the periphery, while preferably protecting the polishing metal surface and the metal pad layer 24 surface. It is a procedure to do.

  The material of the mirror base layer 21-2, the back surface metal layer 15, and the metal pad layer 24 is not particularly limited as long as it has electrical conductivity. For example, aluminum, SUS, copper, silver, iron, Gold, platinum, etc. can be used.

  From the viewpoint of preventing a short circuit between the positive and negative electrodes of the element, an insulating material portion 29 whose bottom surface reaches the surface of the insulating substrate 20 is formed between the mirror base layer 21-2 and the metal pad layer 24. The material is preferably an insulating thermosetting resin material.

DESCRIPTION OF SYMBOLS 1 Mirror apparatus 2 Mirror metal layer 3 Non-light-emitting mirror area 4 Light-emitting mirror area 5 Superimposition area 6 Thin film layer 7 Transparent insulating sealing layer 10 Transparent glass plate 11 Mirror non-light-emitting metal layer 12 Transparent refractive index adjustment resin layer 13 Organic EL panel DESCRIPTION OF SYMBOLS 15 Back surface metal layer 16 Thermosetting resin sealing wall 17 Conductive material part 19 Transparent adjustment layer 20 Insulating substrate 21 Mirror metal electrode layer (one electrode layer)
22 Functional layers (including light emitting layer)
23 Transparent electrode layer (the other electrode layer)
24 Metal pad layer 25 Through hole 29 Insulating material part 30 Organic EL element (laminated body)

Claims (9)

On one main surface of the transparent glass plate, an organic EL panel comprising an organic EL panel and a functional layer including a light emitting layer containing a light-emitting organic compound sandwiched between two opposing electrode layers, and A mirror device including a non-light-emitting mirror region viewed from the other main surface and the light-emitting mirror region,
A mirror metal layer forming a mirror surface of the mirror device is formed on the one main surface, and is a mirror non-light-emitting metal layer corresponding to the non-light-emitting mirror region, and one of the electrode layers and the light-emitting mirror region A mirror-emitting metal electrode layer corresponding to
The mirror non-light emitting metal layer and the mirror light emitting metal electrode layer have overlapping regions as seen from the other main surface; and
In the overlapping region, a thin film layer having a thickness of 1 μm or more and 10 μm or less, the transparent electrode layer being the other electrode layer in order from the mirror non-light emitting metal layer side to the mirror light emitting metal electrode layer; A mirror device including only a thin film layer including the functional layer as a part of the organic EL panel. The organic EL panel includes the mirror light emitting metal electrode layer, the functional layer, and the transparent electrode layer formed on the other main surface of the insulating substrate, and
The mirror device according to claim 1, further comprising a back metal layer electrically connected to the mirror light emitting metal electrode layer on one main surface of the insulating substrate. The organic EL panel is a metal pad layer formed on the other main surface of the insulating substrate and covered with the mirror non-light emitting metal layer as viewed from the other main surface,
The mirror apparatus according to claim 2, comprising a metal pad layer electrically connected to the transparent electrode layer. The mirror device according to claim 3, wherein the metal pad layer is electrically connected to the mirror non-light emitting metal layer.   The mirror device according to any one of claims 1 to 4, wherein the thin film layer includes a transparent insulating sealing layer in contact with the mirror non-light emitting metal layer.   The mirror apparatus in any one of Claims 1-5 provided with a transparent refractive index adjustment resin layer between the said transparent glass plate and the said organic electroluminescent panel. The mirror device according to claim 2 , comprising at least a thermosetting resin sealing wall in contact with the mirror non-light emitting metal layer and the back metal layer. A method of manufacturing a mirror device according to any one of claims 1 to 7,
Forming the functional layer using the shadow mask 1, and
Forming a transparent electrode layer using a shadow mask 2 different from the shadow mask 1 so as to cover the entire exposed surface of the functional layer. It is a manufacturing method of the mirror device according to claim 5,
After forming the said transparent insulation sealing layer, the manufacturing method of the mirror apparatus including the process of lifting off one part.