JP6076015B2 - Organic EL light emitting system - Google Patents

Description

  The present invention relates to an organic EL light emitting system using an organic EL (Electro Luminescence) light emitting panel. In particular, the present invention relates to an organic EL light emitting system using a difference in viewing angle characteristics of an organic EL light emitting panel.

  In recent years, organic EL light-emitting panels have attracted attention as a lighting device that can replace incandescent lamps and fluorescent lamps, and many studies have been made.

Here, the organic EL light emitting panel is obtained by providing a sealing structure and a casing on an organic EL device. Further, the organic EL device is formed by laminating an organic EL element on a base material such as a glass substrate and forming a power feeding structure for feeding power to the organic EL element.
And an organic EL element makes two electrodes which one or both have translucency oppose, and laminated | stacked the light emitting layer which consists of an organic compound between this electrode. The organic EL device emits light by the energy of recombination of electrically excited electrons and holes.
That is, the organic EL light emitting panel is a self-luminous device, and can emit light of various wavelengths by appropriately selecting the material of the light emitting layer.

  In addition, the organic EL light-emitting panel has a feature that the thickness is extremely small and light compared to incandescent lamps, fluorescent lamps, and LED lighting, and light is emitted in a planar shape, so that there are few restrictions on the installation location. . Furthermore, since the organic EL light emitting panel has higher luminous efficiency than incandescent lamps and fluorescent lamps, the organic EL light emitting panel has the features of low power consumption and low heat generation.

  In recent years, lighting devices are required not only to function as direct lighting but also to have additional functions such as improving the design of space. For example, there is a demand for a lighting device having a decoration function that matches the user's hobby.

JP 2012-69257 A

  By the way, a lighting device using an organic EL device (hereinafter, also referred to as an organic EL lighting device) has better viewing angle characteristics than illumination of an LED or the like, but depending on the viewing direction (angle) of the light emitting surface. Will be different. For this reason, in recent organic EL lighting devices, a device for mainly further improving the viewing angle characteristics has been devised (for example, Patent Document 1).

As a result of repeated researches to improve the viewing angle characteristics as in the past, the inventor has achieved a certain degree of viewing angle characteristics by changing the composition of the organic EL device or attaching a polarizing film to the light emitting surface of the organic EL device. It was discovered that the viewing angle characteristics can be controlled to a predetermined condition (for example, a desired color temperature range).
Therefore, the inventor tried to obtain not only a function as an illumination but also a decoration effect by arranging a plurality of organic EL devices having different viewing angle dependencies by taking advantage of the viewing angle dependence. ,Developed.

  That is, an object of the present invention is to develop an organic EL light emitting system capable of obtaining not only a function as illumination but also a decoration effect at the time of lighting.

  The invention according to claim 1 for solving the above-described problem is an organic EL light-emitting panel in which a plurality of organic EL light-emitting panels are laid out in a planar shape to form one light-emitting plane. Has a cross-sectional structure in which two electrode layers and an organic light emitting layer are sandwiched between the electrode layers on a substrate, and is formed between the light emitting plane and a normal to the light emitting plane. The angle is the maximum color temperature of the organic EL light-emitting panels forming the light emission plane when the light emission plane is observed from a predetermined angle in a range of −30 degrees to 30 degrees with respect to the normal as a reference. The difference in color temperature between the organic EL light-emitting panel and the organic EL light-emitting panel having the minimum color temperature is 400K or less, and is an angle formed between the light-emitting plane and a normal line to the light-emitting plane. The The maximum color temperature among the organic EL light emitting panels forming the light emitting plane when the light emitting plane is observed from a predetermined angle in the range of −80 degrees to −50 degrees or 50 degrees to 80 degrees with respect to the normal line The organic EL light emitting system is characterized in that the difference in color temperature between the organic EL light emitting panel having a color difference and the organic EL light emitting panel having the minimum color temperature is 500K or more.

The “organic EL light-emitting panel” referred to here is an organic EL panel having two electrodes and an organic light-emitting layer, and includes an organic EL panel having a tandem structure (multilayer structure). This is a concept including an organic EL matrix capable of an active matrix driving method.
Here, the “color temperature” includes not only a color temperature that is a point on the black body locus but also a correlated color temperature that represents a point in the vicinity of the point on the black body locus.

According to the configuration of the present invention, an angle formed between the light emission plane and a normal line to the light emission plane, and the light emission from a predetermined angle in a range of −30 degrees to 30 degrees with respect to the normal line. When the plane is observed, the difference in color temperature between the organic EL light-emitting panel having the maximum color temperature and the organic EL light-emitting panel having the minimum color temperature among the organic EL light-emitting panels forming the light-emitting plane is 400K or less. It has become. In other words, the angle of viewing when the user looks at the light emission plane (the angle at which the user looks at the light emission plane) is within a range of −30 degrees to 30 degrees. Among them, the difference in color temperature between the organic EL light emitting panel having the maximum color temperature and the organic EL light emitting panel having the minimum color temperature is 400K or less. That is, in the range where the viewing angle is from −30 degrees to 30 degrees, the color temperature difference (difference in the ratio between blue-violet light and red light) is small, so the difference in the appearance of the luminescent color between the organic EL light-emitting panels (darkness) The difference) is small, and it seems that all the organic EL light-emitting panels forming the light-emitting plane emit light in substantially the same color as in normal lighting.
Further, according to the configuration of the present invention, the angle is formed between the light emitting plane and a normal to the light emitting plane, and is −80 degrees to −50 degrees or 50 degrees to 80 degrees with respect to the normal. When the light emission plane is observed from a predetermined angle in the range, among the organic EL light emission panels forming the light emission plane, between the organic EL light emission panel having the maximum color temperature and the organic EL light emission panel having the minimum color temperature. The difference in color temperature is 500K or more. That is, the maximum viewing angle among the plurality of organic EL light emitting panels at a predetermined viewing angle in a range where the viewing angle when the user looks at the light emitting plane is −80 degrees to −50 degrees or 50 degrees to 80 degrees. The difference in color temperature between the organic EL light emitting panel having the color temperature and the organic EL light emitting panel having the minimum color temperature is 500K or more. That is, since the color temperature difference (difference in the ratio between blue-violet light and red light) is large in the range where the viewing angle is from -80 degrees to -50 degrees or 50 degrees to 80 degrees, the emission color between the organic EL light emitting panels is large. The difference in appearance (difference in light and shade) is large, and the light and shade of light emission colors are clear between the organic EL light emitting panels. In other words, a predetermined organic EL light emitting panel has a higher intensity of blue-violet light or red light than other organic EL light emitting panels.
In this way, the appearance from the user varies depending on the difference in the viewing angle, for example, whether the pattern or the like is lifted by forming a pattern or the like using the difference in the viewing angle at the viewing angle. Can impress the user.

The above-described invention is formed from a plurality of types of organic EL light emitting panels having different viewing angle dependencies, and at least one type of the organic EL light emitting panels among the plurality of types of organic EL light emitting panels is An angle formed between the light emission plane and a normal line to the light emission plane, and when the light emission plane is observed from an angle of −80 degrees to 80 degrees with respect to the normal line, the one type of organic EL among the angle in the range of -80 to 80 degrees of light-emitting panel, the difference between the maximum color temperature and the minimum color temperature may be organic EL light-emitting system that has become less 700K.

  Here, “viewing angle dependency” refers to a property in which the contrast ratio and the color appearance differ depending on the viewing direction (angle) of the light emission plane.

According to the configuration of the present invention, the difference between the maximum color temperature and the minimum color temperature between the respective angles in the range of −80 degrees to 80 degrees is 700 K or less in at least one type of organic EL light emitting panel. The thing is adopted. That is, the difference in the appearance of the luminescent color depending on the viewing angle of the at least one organic EL light emitting panel is small. Therefore, a pattern or the like can be formed by a combination with an organic EL light emitting panel having a large viewing angle dependency. That is, the pattern and the like look different depending on the viewing angle, and the decoration effect is great.

The above-described invention is formed from a plurality of types of organic EL light emitting panels having different viewing angle dependencies, and at least one type of the organic EL light emitting panels among the plurality of types of organic EL light emitting panels is An angle formed between the light emission plane and a normal line to the light emission plane, and when the light emission plane is observed from an angle of −80 degrees to 80 degrees with respect to the normal line, the one type of organic EL among the angle in the range of -80 to 80 degrees of light-emitting panel, the difference between the maximum color temperature and the minimum color temperature may be organic EL light-emitting system that has become more 1200 K.

According to the configuration of the present invention, at least one type of organic EL light emitting panel has a difference between the maximum color temperature and the minimum color temperature of 1200K or less between the respective angles in the range of −80 degrees to 80 degrees. The thing is adopted. That is, there is a great difference in the appearance of the emitted color depending on the viewing angle of the at least one organic EL light emitting panel. Therefore, a pattern or the like can be formed by a combination with an organic EL light emitting panel having a small viewing angle dependency. That is, the pattern and the like look different depending on the viewing angle, and the decoration effect is great.

The above-described invention is formed from a plurality of types of organic EL light emitting panels having different viewing angle dependencies, and at least one type of the organic EL light emitting panels among the plurality of types of organic EL light emitting panels is Among the electrode layers, an electron transport layer is interposed between one electrode layer and the organic light emitting layer, and the electron transport layer is formed of a non-light emitting organic material, and the thickness of the electron transport layer is it may be organic EL light-emitting system that has become a 30nm or 300nm or less.

According to the configuration of the present invention, the thickness of the electron transport layer is not less than 30 nm and not more than 300 nm. That is, the color temperature at each viewing angle is controlled by the thickness of the electron transport layer. Specifically, the difference between the maximum color temperature and the minimum color temperature is controlled so as to be larger than a predetermined size, and the difference in the appearance of the luminescent color at the viewing angle between other organic EL light emitting panels is given. It is easy. Therefore, it is easy to select an organic EL light emitting panel having different viewing angle dependency.

The above-described invention is formed from a plurality of types of organic EL light emitting panels having different viewing angle dependencies, and at least one type of the organic EL light emitting panels among the plurality of types of organic EL light emitting panels emits light. it may be organic EL light emitting system emitting surface polarizing film that covered forming part of the plane.

According to the structure of this invention, the polarizing film has covered the light emission surface which forms a part of light emission plane. That is, the color temperature at each viewing angle is controlled by the polarizing film. Specifically, the difference between the maximum color temperature and the minimum color temperature is controlled so as to be larger than a predetermined size, and the difference in the appearance of the luminescent color at the viewing angle between other organic EL light emitting panels is given. It is easy. Therefore, it is easy to select an organic EL light emitting panel having different viewing angle dependency.

  According to the organic EL light emitting system of the present invention, it is possible to display, for example, a figure or the like using the difference in the appearance of the luminescent color at the viewing angle, and the design is excellent.

1 is a perspective view of an organic EL light emitting system of the present invention. It is explanatory drawing showing the relationship between a chromaticity diagram and color temperature. It is explanatory drawing showing the relationship between the angle visually recognized in the 1st organic EL panel and 2nd organic EL panel of FIG. 1, and color temperature. It is explanatory drawing showing the appearance when the organic electroluminescent light emission system of FIG. 1 is seen from the normal line (0 degree) of the light emission plane. It is explanatory drawing showing the appearance when the organic electroluminescent light emission system of FIG. 1 is seen from an angle of 30 degrees with respect to the normal line of the light emission plane. It is explanatory drawing showing the appearance when the organic electroluminescent light emission system of FIG. 1 is seen from an angle of 50 degree | times with respect to the normal line of the light emission plane. It is explanatory drawing showing the appearance when the organic electroluminescent light emission system of FIG. 1 is seen from an angle of 70 degree | times with respect to the normal line of the light emission plane. It is explanatory drawing showing the appearance when the organic electroluminescent light emission system of FIG. 1 is seen from an angle of 80 degree | times with respect to the normal line of the light emission plane. It is explanatory drawing showing distribution of the color temperature of each organic EL panel in the organic EL light emission system of the state of FIG. It is explanatory drawing showing distribution of the color temperature of each organic EL panel in the organic EL light emission system of the state of FIG. It is a schematic diagram of the layer structure of the organic EL panel of the present invention.

Hereinafter, embodiments of the present invention will be described in detail.
In the following description, unless otherwise specified, the vertical / left / right positional relationship of the organic EL light emitting system 1 will be described with reference to the posture of FIG. That is, the organic EL light emitting system 1 is set parallel to the ceiling 20 and the light extraction side (light emission plane 21 side) surface of the organic EL light emitting system 1 faces the living space side (user side). The following color temperature values are values calculated according to JIS Z 8725: 1999 unless otherwise specified.

The organic EL light emitting system 1 of the present embodiment is used as a single lighting device in which a plurality of organic EL panels 2 are arranged in parallel as shown in FIG. That is, the organic EL light emitting system 1 is formed by laying a plurality of organic EL panels 2 in a planar shape.
In the present embodiment, a total of 25 organic EL panels 2, 5 in the row direction l and 5 in the column direction w, are laid out in a grid pattern to form one light emission plane 21.

Further, in the organic EL light emitting system 1 of the present embodiment, two types of organic EL panels 2a and 2b having different viewing angle dependencies are spread and formed. That is, the organic EL light emitting system 1 intentionally includes an organic EL panel (hereinafter also referred to as the first organic EL panel 2a) having a large variation in color temperature depending on the viewing angle (the viewing angle dependency is large), Compared with the first organic EL panel 2a, an organic EL panel (hereinafter also referred to as a second organic EL panel 2b) in which the variation in color temperature is small (the viewing angle dependency is small) depending on the viewing angle is mixed.
Then, the organic EL light emitting system 1 lays out the first organic EL panel 2a in a desired graphic shape, so that the graphic shape emerges only within a predetermined viewing angle range with respect to the second organic EL panel 2b. It has a configuration.
Specifically, the first organic EL panel 2a is laid on the center side, and the second organic EL panel 2b is laid on the outside, so that the color represented on the black body trajectory shown in the chromaticity diagram of FIG. The configuration is such that the figure of the first organic EL panel 2a is raised depending on the difference in temperature.
In the present embodiment, the five first organic EL panels 2a are arranged in a cross on the center side, and the twenty second organic EL panels 2b are arranged in the periphery thereof so that a cross pattern emerges. Is laid.

  The characteristics of the first organic EL panel 2a and the second organic EL panel 2b will be described. As shown in FIG. 3, the first organic EL panel 2a and the second organic EL panel 2b are both viewed at an angle (light emission). The color temperature tends to increase as the angle with respect to the normal line 21 with respect to the normal line increases, and takes a peak bottom on the normal line n (0 degree), and 70 degrees (− Take the peak top at 70 degrees. That is, the color temperature of the first organic EL panel 2a and the second organic EL panel 2b increases as the angle formed in the direction inclined from the normal line toward the light emission plane 21 increases.

Paying attention to the characteristics of the first organic EL panel 2a, the maximum color temperature of the first organic EL panel 2a from 0 degree (on the normal line n) to 80 degrees (10 degrees with respect to the light emission plane 21) with respect to the normal line n And the minimum color temperature difference (difference between peak top and peak bottom) is 1200K or more, and preferably 1300K or more.
Further, when paying attention to the characteristics of the second organic EL panel 2b, the maximum of the second organic EL panel 2b from 0 degree (on the normal line n) to 80 degrees (10 degrees with respect to the light emission plane 21) with respect to the normal line n as a reference. The difference between the color temperature and the minimum color temperature (the difference between the peak top and the peak bottom) is 700K or less, and preferably 600K or less.

Hereinafter, how the user sees each angle at normal angles to the normal line n of the light emitting plane 21 of the organic EL light emitting system 1 will be described.
First, the appearance when the light emission plane 21 of the organic EL light emission system 1 is viewed from the normal line n (0 degree) (when the light emission plane 21 is viewed from the front) will be described as shown in FIGS. There is almost no difference in color temperature between the first organic EL panel 2a and the second organic EL panel 2b. Specifically, at 0 degree, the color temperature of the first organic EL panel 2a that is the maximum color temperature in the light emission plane 21 and the color temperature of the second organic EL panel 2b that is the minimum color temperature in the light emission plane 21 The difference Dv is 300K or less, preferably 250K or less.
Here, the color temperature is the relative intensity of the blue-violet light and the red light, and represents the corresponding color on the black body locus shown in FIG. 2 or the color in the vicinity of the black body locus. As the value increases, the difference in the appearance of the luminescent color (darkness difference) increases, and as the value decreases, the difference in the appearance of the luminescent color (darkness difference) decreases.
Therefore, when viewed from the normal n (0 degree), there is almost no difference between the emission color of the first organic EL panel 2a and the emission color of the second organic EL panel 2b as shown in FIG. The light emission color of the organic EL panel 2a and the second organic EL panel 2b look almost the same color. Therefore, the light emission plane 21 of the organic EL light emitting system 1 appears to emit light in the same manner.

Next, the appearance when the organic EL light emitting system 1 is viewed from an angle of 30 degrees from the normal n (when viewed from an angle of 60 degrees from the light emitting plane 21) will be described. As shown in FIG. Although there is a difference in color temperature as compared with the case of viewing from the front, there is no great difference in color temperature between the first organic EL panel 2a and the second organic EL panel 2b. Specifically, at 30 degrees, the color temperature of the first organic EL panel 2a that is the maximum color temperature in the light emission plane 21 and the color temperature of the second organic EL panel 2b that is the minimum color temperature in the light emission plane 21 The difference is 400K or less, preferably 350K or less.
Therefore, as shown in FIG. 5, there is not much difference between the emission color of the first organic EL panel 2a and the emission color of the second organic EL panel 2b, and the emission color of the first organic EL panel 2a and the second organic EL panel. 2b looks almost the same color. Therefore, the light emission plane 21 of the organic EL light emitting system 1 appears to emit light in the same manner.

  Thus, in the range of 0 to 30 degrees with respect to the normal line n, the color temperature of the first organic EL panel 2a that is the maximum color temperature in the light emission plane 21 and the minimum color temperature in the light emission plane 21 are The difference in color temperature of the second organic EL panel 2b is within 400K, and the emission color of the first organic EL panel 2a and the emission color of the second organic EL panel 2b appear to be almost the same color. That is, the organic EL light emitting system 1 functions as an illumination device for the same light in the range of 0 degrees to 30 degrees with respect to the normal line n.

Next, how the organic EL light emitting system 1 is viewed from an angle of 50 degrees from the normal line n (when viewed from an angle of 40 degrees from the light emitting plane 21) will be described. As shown in FIG. There is a clear difference in color temperature as compared to the case of viewing from 0 to 30 degrees. That is, there is a difference in color temperature between the first organic EL panel 2a and the second organic EL panel 2b. Specifically, when the viewing angle is 50 degrees, the color temperature of the first organic EL panel 2a that is the maximum color temperature in the light emission plane 21 and the second organic EL panel that is the minimum color temperature in the light emission plane The difference from the color temperature of 2b is 500K or more, and preferably 600K or more.
Therefore, as shown in FIG. 6, there is a difference between the light emission color of the first organic EL panel 2a and the light emission color of the second organic EL panel 2b, and the light emission surface of the first organic EL panel 2a and the second organic EL panel. There is a difference in appearance between the light emitting surfaces of 2b. That is, the light emitting surface of the first organic EL panel 2a and the light emitting surface of the second organic EL panel 2b are shaded, and the light emitting surface of the first organic EL panel 2a is different from the light emitting surface of the second organic EL panel 2b. It appears to be white. In other words, the first organic EL panel 2a has a higher ratio of blue-violet light to red light than the second organic EL panel 2b. Therefore, the light emission plane 21 of the organic EL light emitting system 1 seems to have a figure (a cross shape in this embodiment) represented by the first organic EL panel 2a.

Next, how the organic EL light emitting system 1 is viewed from an angle of 70 degrees from the normal n (when viewed from an angle of 20 degrees from the light emitting plane 21) will be described as shown in FIGS. There is a further difference in color temperature compared to the case where the light emission plane 21 is viewed from 50 degrees. That is, there is a large difference in color temperature between the first organic EL panel 2a and the second organic EL panel 2b.
Specifically, when the viewing angle is 70 degrees, the color temperature of the first organic EL panel 2 a that is the maximum color temperature in the light emission plane 21 and the second organic EL that is the minimum color temperature in the light emission plane 21. The difference Dh from the color temperature of the panel 2b is 900K or more, preferably 1000K or more.
Therefore, a clear difference is seen between the emission color of the first organic EL panel 2a and the emission color of the second organic EL panel 2b as shown in FIG. 7, and the emission surface of the first organic EL panel 2a and the second organic EL panel 2a There is a great difference between the light emitting surfaces of the EL panel 2b. That is, the difference in shading is significant, and the light emitting surface of the first organic EL panel 2a appears to be clearly white with respect to the light emitting surface of the second organic EL panel 2b. In other words, the first organic EL panel 2a has a higher ratio of blue-violet light to red light than the second organic EL panel 2b. Therefore, the light emission plane 21 of the organic EL light emitting system 1 seems to have a clear figure represented by the first organic EL panel 2a.

Next, the appearance when the organic EL light emitting system 1 is viewed from an angle of 80 degrees from the normal n (when viewed from an angle of 10 degrees from the light emitting plane 21) will be described. As shown in FIG. The color temperature difference between the first organic EL panel 2a and the second organic EL panel 2b is smaller than when viewed from 70 degrees, but the difference is smaller than the range of 0 to 30 degrees. Still big.
Specifically, at 80 degrees, the color temperature of the first organic EL panel 2a that is the maximum color temperature in the light emission plane 21 and the color temperature of the second organic EL panel 2b that is the minimum color temperature in the light emission plane 21 The difference is 500K or more.
Therefore, as shown in FIG. 8, there is a difference between the emission color of the first organic EL panel 2a and the emission color of the second organic EL panel 2b, and the emission surface of the first organic EL panel 2a and the second organic EL panel. There is a difference in shading between the light emitting surfaces of 2b. That is, it appears that the light emitting surface of the first organic EL panel 2a is white with respect to the light emitting surface of the second organic EL panel 2b. Therefore, the light emission plane 21 of the organic EL light emitting system 1 seems to have a figure expressed by the first organic EL panel 2a.

Thus, in the range of 50 degrees to 70 degrees with respect to the normal n, as the component parallel to the light emission plane 21 becomes larger as the straight line connecting the user's eye line and the light emission plane 21 increases, in other words, As the vertical component with respect to the light emission plane 21 becomes smaller, the color temperature difference between the first organic EL panel 2a and the second organic EL panel 2b becomes larger. The first organic EL panel 2a and the second organic EL panel 2a are connected to the first organic EL panel 2a as the component parallel to the light emitting plane 21 decreases. The color temperature difference of the organic EL panel 2b becomes large.
In the range of 50 to 80 degrees with respect to the normal n, the color temperature of the first organic EL panel 2a that is the maximum color temperature in the light emission plane 21 and the second color temperature that is the minimum color temperature in the light emission plane. The difference in color temperature of the organic EL panel 2b is opened to 500K or more, and the emission color of the first organic EL panel 2a and the emission color of the second organic EL panel 2b appear to be different colors. Specifically, the first organic EL panel 2a looks whiter, and the second organic EL panel 2b appears white with a lighter orange color compared to the first organic EL panel 2a.

  In summary, in the case of the organic EL light emitting system 1 of the present embodiment, in the range of 0 to 30 degrees, it functions as a single color illumination as in the case of normal direct illumination, and in the range of 50 to 80 degrees. It functions as illumination of a plurality of colors, and a desired shape such as a figure emerges. Therefore, it is possible to obtain not only a function as illumination but also a decoration effect when the lamp is turned on, and the design can be improved.

Finally, the layer structure of the organic EL panel 2 will be described. In the present embodiment, the layer configurations of the first organic EL panel 2a and the second organic EL panel 2b are basically the same.
In the organic EL panel 2, an organic EL element 30 is laminated on a substrate 32 (base material) having translucency as shown in FIG.
The organic EL element 30 includes a functional layer 35 that actually emits light at least between the first electrode layer 33 and the second electrode layer 36 as shown in FIG. In the organic EL panel 2 of the present embodiment, a so-called “bottom emission type” organic EL panel 2 that extracts light from at least the substrate 32 side is employed, and the organic EL element 30 includes the first electrode layer 33 from the substrate 32 side. , The functional layer 35 and the second electrode layer 36 are laminated in this order.

  The material of the substrate 32 is not particularly limited as long as it has transparency and insulation. In this embodiment, a glass substrate is employed.

  The first electrode layer 33 is a layer formed of a transparent conductive oxide, and for example, indium tin oxide (ITO) can be used.

As shown in FIG. 11, the functional layer 35 is provided between the first electrode layer 33 and the second electrode layer 36, and is a layer including at least one organic light emitting layer. Specifically, as shown in FIG. 16, the functional layer 35 has a structure in which, from the first electrode layer 33 side, a hole injection layer 40, a hole transport layer 41, an organic light emitting layer 42, an electron transport layer 43, and An electron injection layer 44 is provided.
The hole injection layer 40, the hole transport layer 41, the organic light emitting layer 42, the electron transport layer 43, and the electron injection layer 44 are all formed of a known organic material or the like.
In the present embodiment, the viewing angle dependency is controlled by the film thickness of the electron transport layer 43.
Specifically, the thickness of the electron transport layer 43 of the first organic EL panel 2a is 30 nm to 300 nm, and preferably 50 nm to 100 nm.
On the other hand, the film thickness of the electron transport layer 43 of the second organic EL panel 2b is 5 nm or more and 25 nm or less, and preferably 7 nm or more and 15 nm or less.
When the thickness of the electron transport layer 43 of the first organic EL panel 2a is 1, the thickness of the electron transport layer 43 of the second organic EL panel 2b is 1.5 or more and 10 or less, and is 2 or more and 7 or less. It is preferable that

  The second electrode layer 36 is not particularly limited as long as it forms an electrode with the first electrode layer 33 as a pair. For example, silver (Ag) or aluminum (Al) can be adopted.

  In the above-described embodiment, the organic EL panel in which the entire surface shines at the same time is adopted as the organic EL panel 2, but the present invention is not limited to this, and is like an organic EL panel having a passive matrix structure or an active matrix structure. The organic EL panel can emit light at a desired position.

  In the above-described embodiment, the viewing angle dependency is controlled by the film thickness of the electron transport layer of the organic EL panel 2, but the method for controlling the viewing angle dependency is not limited. For example, a viewing angle dependency may be controlled by attaching a polarizing film to the light emitting surface of the organic EL panel 2. That is, the viewing angle dependency may be controlled by the presence or absence of the polarizing film, or the viewing angle dependency may be controlled by the type of the polarizing film.

  In the above-described embodiment, a desired figure is displayed by the two types of the first organic EL panel 2a and the second organic EL panel 2b. However, the present invention is not limited to this, and three or more types of organic EL are displayed. You may display a figure etc. with a panel.

  In the above-described embodiment, the first organic EL panel 2a is laid in a cross shape in plan view as an example of a figure. However, the present invention is not limited to this, and the shape of the figure does not matter.

  In the above-described embodiment, the first organic EL panel 2a is provided on the center side, and the second organic EL panel 2b is provided on the outer side, so that the first organic EL panel 2a emerges. The second organic EL panel 2b may be laid on the center side, the first organic EL panel 2a may be laid on the outside, and the figure may be formed by the second organic EL panel 2b.

1 Organic EL light emitting system 2 Organic EL panel (Organic EL light emitting panel)
2a First organic EL panel (organic EL light-emitting panel)
2b Second organic EL panel (organic EL light-emitting panel)
21 Light emission plane 32 Substrate (base material)
33 First electrode layer (electrode)
35 Functional layer (organic light-emitting layer)
36 Second electrode layer (electrode)
42 Organic light emitting layer 43 Electron transport layer

Claims (1)

In an organic EL light emitting system in which a plurality of organic EL light emitting panels are laid out in a planar shape to form one light emitting plane,
The organic EL light-emitting panel has a cross-sectional structure in which two electrode layers and an organic light-emitting layer are sandwiched between the electrode layers on a substrate,
An angle formed between the light emission plane and a normal line to the light emission plane, and when the light emission plane is observed from a predetermined angle in a range of −30 degrees to 30 degrees with respect to the normal line,
Among the organic EL light emitting panels forming the light emitting plane, the color temperature difference between the organic EL light emitting panel having the maximum color temperature and the organic EL light emitting panel having the minimum color temperature is 400K or less,
An angle formed between the light emission plane and a normal to the light emission plane, and the light emission plane from a predetermined angle in a range of −80 degrees to −50 degrees or 50 degrees to 80 degrees with respect to the normal line. When observing
Among the organic EL light emitting panels forming the light emitting plane, the color temperature difference between the organic EL light emitting panel having the maximum color temperature and the organic EL light emitting panel having the minimum color temperature is 500K or more. Organic EL light emitting system.