JP4890394B2 - Organic electroluminescence device - Google Patents

Description

  The present invention relates to an organic electroluminescence element applied to, for example, a finder apparatus, and more particularly to an organic electroluminescence element having an improved insulating layer for preventing a short-circuit between two electrode layers.

  Conventionally, in a single-lens reflex camera, it is known that an organic electroluminescence element (hereinafter referred to as an organic EL element) is disposed in the vicinity of a subject image formation position between a pentaprism and a focusing screen. This organic EL element is partly formed as a light transmissive part that is light transmissive in the thickness direction, and light from the subject that has passed through the light transmissive part enters the finder window together with the light from the organic EL element. Then, the subject image is observed through the finder window together with the light emission display of the organic EL element.

Patent Document 1 discloses an example of an organic EL element applied to a finder device. In this case, a light emitting unit configured by laminating an anode layer, an organic layer, and a cathode layer is disposed in the light transmission unit of the organic EL element, and the focus frame is formed in the region for observing the subject image by the light emitting unit. Various marks such as. Here, since the cathode layer constituting the light emitting part is formed of a non-transparent material and blocks light from the subject, each light emitting part is visually recognized as a light shielding part even when it does not emit light.
Japanese Patent No. 3539251

  Incidentally, an insulating layer is generally laminated on the upper surface of the outer edge portion of the anode layer in order to prevent the outer edge portion from contacting the cathode layer and causing a short circuit. Since the insulating layer usually protrudes outside the outer edge of the anode layer and the cathode layer in order to ensure insulation between both electrodes, the insulating layer is formed so as to surround the cathode layer when viewed from the viewfinder window. Has been.

  The insulating layer is made of a transparent material, and thus transmits light from the subject. However, since the insulating layer cannot transmit light completely, the insulating layer is visible from the viewfinder window. Accordingly, each light-emitting portion is visually recognized as a large light-shielding portion by the combination of the cathode layer and the insulating layer, which hinders subject observation. In particular, when the light emitting unit displays a small object such as a focus point, the ratio of the area shielded by the insulating layer in the light emitting unit is increased.

  Therefore, the present invention has been made in view of the above problems, and in an organic EL element applied to a finder apparatus or the like, the insulating layer and the cathode layer can be used for object observation by improving the configuration of the insulating layer. The purpose is to prevent obstruction.

  The organic EL device according to the present invention includes a substrate, a first electrode layer disposed on the substrate, an insulating layer formed on an outer edge portion of the first electrode layer, and an organic light emitting material. An organic layer formed on the electrode layer at least in a portion where the insulating layer is not formed, and formed on the organic layer, and at least a part protrudes from the outer edge of the organic layer and also formed on the insulating layer And the insulating layer is formed so as to protrude outside the outer edge portion of at least one of the first electrode layer and the second electrode layer, and in the thickness direction of the protruding portion. The transmittance is characterized in that a portion close to the outer edge portion of one electrode layer is lower than a far portion.

  For example, the film thickness of the protruding part is made thicker at the part near the outer edge part of one electrode than at the far part, so that the transmittance is lower at the part near the outer edge part of one electrode layer than that at the far part. May be.

  Further, for example, the protruding portion is formed of a material having a relatively low transmittance per predetermined thickness at a portion close to the outer edge portion of one electrode, and a portion far from the outer edge portion of one electrode has a predetermined thickness. By forming the material with a relatively high permeation rate, the transmittance may be lower than the portion far from the outer edge of one electrode layer. In addition, it is preferable that one electrode is a non-transparent electrode.

  In the present invention, with respect to the transmittance of the insulating layer protruding from the electrode layer, by increasing the portion away from the electrode layer, the electrode layer can be made smaller and the insulating layer can be made difficult to visually recognize.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 shows a finder device of a single-lens reflex camera to which the present embodiment is applied. In the following description, a case where the present invention is applied to a single-lens reflex camera will be described. However, the present invention can also be applied to other optical devices such as a microscope and a compact camera.

  The viewfinder device 10 includes an objective lens 11, a quick return mirror 12, a focus plate 13, a pentaprism 14, an eyepiece lens 15, a light emitting display unit 16, and a viewfinder window 17.

  The reflected light reflected from the object is reflected by the quick return mirror 12 via the objective lens 11 and guided to the focus plate 13, and once formed on the focus plate 13. Thereafter, the reflected light is reflected twice by the pentaprism 14 and enters the finder window 17 through the eyepiece 15. When a release switch (not shown) is pressed, the quick return mirror 12 is retracted from the optical path, and the reflected light guided by the objective lens 11 is guided to a CCD, a film, or the like to expose them.

  The light-emitting display unit 16 is composed of an organic EL element, and is disposed on a transverse region between the focus plate 13 and the pentaprism 14 and intersecting an optical path through which light from the subject passes. It is arranged. Light emitted from each light emitting unit of the light emitting display unit 16 is also incident on the finder window 17 through the pentaprism 14 and the eyepiece 15. The light emitting display unit 16 can also be disposed between the quick return mirror 12 and the focus plate 13.

  FIG. 2 is a schematic plan view of the light emitting display unit 16. 3 to 5 are diagrams illustrating an example of a light emitting unit provided in the light emitting display unit 16. As shown in FIG. 2, the light emitting display unit 16 includes a rectangular finder field region 21 and a finder field region 24 that surrounds the top, bottom, left, and right outside of the finder field region 21 and is formed in a rectangular frame shape. The The finder visual field area 21 is visible from the finder window 17, but the finder visual field area 24 is an area that cannot be viewed from the finder window 17.

  The rectangular finder visual field area 21 includes a rectangular photographing visual field area 22 for observing a subject, and a light shielding area 23 that surrounds the upper, lower, left, and right outer sides of the photographing visual field area 22 and is formed in a rectangular frame shape. The The imaging view field region 22 is a region through which light from a subject enters and is transmitted, and is a light transmission portion used for subject observation. The light shielding region 23 is a region where light incident on the finder window 17 (see FIG. 1) from the subject and the light emitting display unit 16 is shielded by a light shielding mask (not shown). However, the light-shielding region 23 may be provided with a light-emitting portion as necessary, and an opening may be provided in the light-shielding mask, so that various types of information may be light-emitting displayed. The various types of information include various symbol marks indicating the exposure value used for photographing, the photographing mode, and the presence or absence of flash emission.

  As shown in FIGS. 3 to 5, the light emitting display unit 16 includes a transparent substrate 27, a light emitting unit 26 disposed on the upper surface of the transparent substrate 27, an anode line 30, a cathode line 33, and a transparent sealing member 28. . In the present embodiment, the transparent substrate 27 is disposed on the eyepiece side, the transparent sealing member 28 is disposed on the objective side, and the light emitting display unit 16 is observed by the observer from the transparent substrate 27 side. The transparent sealing member 28 seals each light emitting unit 26 by disposing each light emitting unit 26 between the transparent substrate 27. The transparent sealing member 28 and the transparent substrate 27 are made of a transparent member such as glass and synthetic resin, for example.

  As shown in FIG. 2, a plurality of light emitting units 26 are provided and are arranged in the photographing visual field region 22. Specifically, in the central region of the imaging field of view region 22, the light emitting unit 26 is arranged with nine light emitting unit rows arranged side by side in three rows on the top and bottom, and at the center. One each is arranged so as to sandwich the region. The light emitting unit 26 is used as a focus mark. For example, when shooting is performed with autofocus, one light emitting unit 26 corresponding to the focused position is caused to emit light.

  The anode line 30 and the cathode line 33 are electrode lines for supplying power to each light emitting unit 26. As shown in FIG. 2, a plurality of anode wires 30 are provided, and one end of each anode wire 30 is arranged at each light emitting portion 26 and the other end is arranged at the outer edge portion of the light emitting display portion 16. Are connected to a power source (not shown). Since each anode line 30 is independently connected to a power source without being electrically connected to the other anode line 30, each light emitting unit 26 can independently control light emission. On the other hand, the cathode line 33 is composed of a main cathode line 33A, one end of which is disposed at the outer edge of the light-emitting display unit 16, and a plurality of branch cathode lines 33B branched from the main cathode line 33A. A part of the branched cathode lines 33B is further branched to form another branched cathode line 33B. Each branch cathode line 33 </ b> B extends to each light emitting unit 26, and each end of the branch cathode line 33 </ b> B is disposed in each light emitting unit 26. In FIG. 2, the anode line 30 is indicated by a solid line and the cathode line 33 is indicated by a broken line.

  As shown in FIG. 3, in each light emitting portion 26, one end of each anode line 30 is formed in a circle so as to follow the shape of the focus mark, and becomes an anode layer 31. Further, the end portion of the branched cathode line 33 </ b> B extending to each light emitting portion 26 is disposed away from the anode layer 31.

  As shown in FIGS. 3 to 5, the insulating layer 40 is laminated on the anode layer 31 in each light emitting unit 26. When viewed from above, the insulating layer 40 is formed in an annular shape so as to avoid the central portion 31 </ b> C of the anode layer 31, and the outer edge portion 40 </ b> S is disposed outside the outer edge portion 31 </ b> S of the anode layer 31. That is, the insulating layer 40 is laminated on the outer edge portion 31S of the anode layer 31, and is also laminated on the upper surface of the transparent substrate 27 so as to protrude outward from the outer edge portion 31S. The insulating layer 40 prevents the outer edge portion 31S of the anode layer 31 from coming into contact with the cathode layer 50 described later, and prevents a short circuit that occurs between the two electrodes. However, the insulating layer 40 is not laminated on the separated cathode line 33B, but is formed in an annular shape in which a portion where the separated cathode line 33B is provided is cut away when viewed from above as shown in FIG.

  On the upper surface of the anode layer 31, an organic layer 45 is laminated in the central portion 31C where the insulating layer 40 is not laminated. As a result, the organic layer 45 is formed in a circular shape when viewed from above, and is formed in an annular shape. It will be surrounded by the insulating layer 40. However, a part of the organic layer 45 protrudes outward from the central portion 31 </ b> C, and a part of the organic layer 45 is also laminated on the upper surface of the insulating layer 40.

  On the organic layer 45, a cathode layer 50 formed in a circular shape when viewed from above is laminated. The cathode layer 50 is stacked on the entire top surface of the organic layer 45, and protrudes outward from the outer edge 45 </ b> S of the organic layer 45 and is also stacked on the top surface of the insulating layer 40. However, the outer edge portion 50S of the cathode layer 50 is disposed on the inner side of the outer edge portion 40S of the insulating layer 40, whereby the insulating layer 40 protrudes outside the outer edge portion 50S of the cathode layer 50 and is laminated. Yes. The cathode layer 50 is also laminated on the upper surface of the end of the branch cathode line 33B outside the outer edge 45S of the organic layer 45, and is electrically connected to the branch cathode line 33B.

  Each electrode line (that is, anode line 30 and cathode line 33) and anode layer 31 are made of transparent conductive materials such as ITO (Indium Tin Oxide), ATO (antimony doped tindioxide), ZnO (zinc oxide), IZO (Indium Zinc Oxide) and the like. It is formed from a metal compound and is configured as a transparent electrode. The insulating layer 40 is an insulating material such as polyimide or an acrylic derivative compound, and is formed from a synthetic resin having transparency.

  The organic layer 45 is formed by laminating a hole transport layer, an organic light emitting layer composed of an organic light emitting material, an electron transport layer composed of an electron transport material, and the like, and a voltage is applied from both electrode layers 31 and 50. By doing so, it is configured to emit predetermined light such as red, green, blue, and white. The cathode layer 50 is formed of a non-transparent cathode metal material such as aluminum, indium, magnesium, calcium, titanium, yttrium, lithium, and alloys thereof, and is configured as a non-transparent electrode.

  Since the cathode layer 50 is formed of a non-transparent material and substantially blocks light from the subject, the cathode layer 50 is visually recognized as a light-blocking portion when the light-emitting portion 26 does not emit light. On the other hand, the insulating layer 40 protrudes outside the outer edge portion 50S of the cathode layer 50 as described above. When observed from the transparent substrate 27 side, the protruding portion 41 of the insulating layer 40 is provided with the branched cathode line 33B. The cathode layer 50 is surrounded in an annular shape except for the portion.

  In the present embodiment, the protruding portion 41 of the insulating layer 40 is laminated on the transparent substrate 27, and is provided with a step 40G so that the thickness on the outer peripheral side is thin, and is formed in a step shape. Thus, the protruding portion 41 has an inner peripheral portion 42 having a film thickness D1 that forms the inner peripheral side with the step 40G as a boundary, and a film thickness D2 that forms the outer peripheral side with the step 40G as a boundary and is smaller than the film thickness D1. The outer peripheral part 43 which has.

  Since the insulating layer 40 is formed of the same transparent material and has the same transmittance per predetermined thickness, the transmittance of the inner peripheral portion 42 having a large film thickness is lower than the transmittance of the outer peripheral portion 43. Accordingly, when viewed from the transparent substrate 27 side, as shown in FIG. 6, the protruding portion 41 surrounds the cathode layer 50 while being in contact with the outer edge portion 50S, and the inner peripheral portion 42 having a relatively low transmittance, and the inner peripheral portion. And an outer peripheral portion 43 that further surrounds 42 and has a relatively high transmittance. That is, the transmittance in the thickness direction of the protruding portion 41 is lower in the portion close to the outer edge portion 50S of the cathode layer 50 than in the far portion.

  With the above configuration, when the organic layer 45 does not emit light, when the protruding portion 41 is viewed from the transparent substrate 27 side as shown in FIG. 6, the inner peripheral portion 42 is a relatively dark portion, and the outer peripheral portion 43 is relatively It will be visually recognized as a bright part. Then, when the non-transmissive cathode layer 50 is surrounded by the transmissive insulating layer 40 that gradually becomes brighter toward the outside, an illusion that the cathode layer 50 appears to be small is brought about. Makes it difficult to perceive object observation.

  Further, in the light emitting display portion 16, the thickness direction between the portion of the insulating layer 40 where the outer peripheral portion 43 is provided and the portion 60 outside the insulating layer 40 (that is, the portion where the insulating layer is not provided, see FIG. 6). Therefore, the outer edge portion 40S of the insulating layer 40 is difficult to see and the insulating layer 40 is also difficult to visually recognize. The outer peripheral portion 43 of the insulating layer 40 does not have the cathode layer 50 laminated on the upper surface thereof, so that the insulation between the two electrode layers does not deteriorate even if the film thickness D2 is reduced. .

  In the present embodiment, the thickness of the insulating layer 40 other than the protruding portion 41 is the same as that of the inner peripheral portion 42, but may be different.

  Next, a method for manufacturing the light emitting display unit 16 according to the present embodiment will be described. In the present embodiment, first, the anode line 30, the anode layer 31, and the cathode line 33 are formed on the transparent substrate 27 by photolithography. Next, the insulating layer 40 is formed on the anode line 30, the anode layer 31, and the transparent substrate 27 by, for example, photolithography. At this time, first, an insulating film having a film thickness D2 is coated over the entire region where the insulating layer 40 is laminated, including the region where the outer peripheral portion 43 is laminated. Thereafter, an insulating film having a predetermined film thickness (= D1-D2) is further coated on a region other than the region where the outer peripheral portion 43 is laminated, and the insulating layer 40 having a different film thickness between the outer peripheral portion 43 and other portions is formed. To do. Next, the organic layer 45 and the cathode layer 50 are sequentially deposited by sputtering or the like, whereby the organic EL element 10 is obtained.

FIG. 7 is a cross-sectional view for illustrating a second embodiment of the present invention.
In the first embodiment, the inner peripheral part 42 and the outer peripheral part 43 have different transmittances in the thickness direction between the outer peripheral part and the inner peripheral part by making the film thicknesses different. Then, the transmittance | permeability in a thickness direction is varied by making the material which forms the inner peripheral part 42 and the outer peripheral part 43 different.

  That is, the outer peripheral portion 43 of the insulating layer 40 is formed of a material having a relatively high transmittance per predetermined thickness (for example, 1 μm), while the portions other than the inner peripheral portion 42 and the protruding portion 41 have a predetermined thickness. It is formed of a material having a relatively low transmittance per unit. On the other hand, the film thickness of the outer peripheral part 43 is formed to be the same as the film thickness D1 of the inner peripheral part 42, whereby the transmittance in the thickness direction of the outer peripheral part 43 is in the thickness direction of the inner peripheral part 42. It becomes higher than the transmittance.

  Also in this embodiment, when the organic layer 45 does not emit light, when the protruding portion 41 is viewed from the transparent substrate 27 side, the inner peripheral portion 42 is viewed as a relatively dark portion and the outer peripheral portion 43 is viewed as a relatively bright portion. Will be. Therefore, also in this embodiment, the cathode layer 50 is visually recognized as being small, and the outer edge portion 40S of the insulating layer 40 is difficult to be visually recognized.

  In addition, the material from which the transmittance | permeability per predetermined thickness for forming the inner peripheral part 42 and the outer peripheral part 43 differs is obtained, for example by using different insulating materials, or while using the same insulating material. It is obtained by adding a dye, a pigment or the like to the material of the inner peripheral portion 42. In the present embodiment, the outer peripheral portion 43 and the inner peripheral portion 42 have the same film thickness. However, if the transmittance in the thickness direction of the outer peripheral portion 43 is higher than that of the inner peripheral portion 42, these films are used. The thicknesses need not be the same.

  In the first embodiment, in the protruding portion 41, only one step 40G is provided, and only two steps (the outer peripheral portion 43 and the inner peripheral portion 42) are provided at portions having different transmittances in the thickness direction. However, as long as the film thickness is reduced toward the outer periphery, three or more stages having different film thicknesses may be provided. Of course, in the second embodiment as well, three or more portions having different transmittances may be provided.

  Further, as shown in FIG. 8, a part or all of the protruding portion 41 is formed so that the film thickness continuously decreases toward the outer periphery, and the transmittance in the thickness direction of the protruding portion 41 increases toward the outer periphery. You may form so that it may become large continuously. Further, as in the second embodiment, the material for forming the protruding portion may be made different so that the transmittance of the protruding portion 41 continuously increases toward the outside.

  In the present embodiment, the light emitted from the light emitting unit 16 is a bottom emission type emitted from the transparent substrate 27 side, but may be a top emission type emitted from the sealing member 28 side. In the case of the top emission type, the sealing member 28 is disposed on the eyepiece side, the transparent substrate 27 is disposed on the objective side, and the cathode layer 50 that is a non-transparent electrode is sequentially formed on the transparent substrate 27 from the transparent substrate 27 side. The organic layer 45 and the anode layer 31 that is a transparent electrode are laminated. Even in this case, when viewed from the sealing member 28 side, the protruding portion 41 of the insulating layer 40 is formed so as to protrude outward from the outer edge portion 50S of the cathode layer 50, and the transmission of the protruding portion 41 in the thickness direction is formed. The rate is set higher on the outer peripheral side than on the inner peripheral side by the same configuration as in the first and second embodiments.

  In each of the above embodiments, the cathode layer 50 is formed as a non-transparent electrode. However, the cathode layer 50 may be formed of a transparent conductive metal compound or the like and configured as a transparent electrode layer.

It is a schematic diagram of the finder apparatus of a single-lens reflex camera. It is a top view when the light emission display part is seen from the eyepiece side. It is a top view when a light emission part is seen from the objective side. It is sectional drawing on the IV-IV line in FIG. It is sectional drawing on the VV line in FIG. It is a top view which shows how the light emission part looks when it sees from a finder window. It is sectional drawing of the light emission part in 2nd Embodiment. It is sectional drawing of the light emission part for showing the modification of 1st Embodiment.

Explanation of symbols

16 Light-emitting display part 22 Field of view (light transmission part)
26 Light-Emitting Section 30 Anode Line 31 Anode Layer 33 Cathode Line 40 Insulating Layer 41 Protruding Section 45 Organic Layer 50 Cathode Layer

Claims (5)

A substrate,
A first electrode layer disposed on the substrate;
An insulating layer formed on an outer edge of the first electrode layer;
An organic layer containing an organic light emitting material and formed on at least a portion of the first electrode layer where the insulating layer is not formed;
A second electrode layer formed on the organic layer, and at least a part of the second electrode layer protruding from the outer edge of the organic layer and also formed on the insulating layer,
The insulating layer has transparency and is formed so as to protrude outside the outer edge portion of at least one of the first and second electrode layers, and transmits the protruding portion in the thickness direction. rate, the portion close to the outer edge of the one electrode layer is rather low than distant parts,
An organic electroluminescence element, which is applied to a finder device of a camera and causes a light-emitting display from the organic layer to be observed together with a subject image by light from a subject passing through the organic electroluminescence element.   2. The organic electroluminescent element according to claim 1, wherein a thickness of the protruding portion is thicker at a portion near the outer edge portion of the one electrode than at a far portion.   The protruding portion is formed of a material having a relatively low transmittance per predetermined thickness at a portion near the outer edge portion of the one electrode, and a portion far from the outer edge portion of the one electrode has the predetermined thickness. The organic electroluminescent element according to claim 1, wherein the organic electroluminescent element is formed of a material having a relatively high permeation rate. The organic electroluminescent element according to claim 1, wherein the one electrode layer is a non-transparent electrode. 5. The organic electroluminescent element according to claim 1, wherein the organic electroluminescent element intersects an optical path between the focus plate and the pentaprism or between the quick return mirror and the focus plate through which light from the subject passes. A finder device for a single-lens reflex camera, wherein the finder device is disposed on a crossing region.

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