JPH01161393A - Variable color display - Google Patents

Abstract

PURPOSE: To make a stereoscopic display by arranging a display plate which has a dichroic filter layer on a surface type light emitting display element. CONSTITUTION: The variable color display device is equipped with a case 1, the display plate 5 which is held in the case 1 and has the dichroic layer 31, a let light source 2 which is held in the case 1 and irradiates the top side of the display plate 5 to emit reflected light, and a 2nd light source 4 which is held in the case 1 and irradiates the reverse side of the display plate 5 to emit transmitted light; and the 2nd light source 4 is the surface light emitting display element and the display plate 5 is arranged on the surface light emitting display element. Consequently, a stereoscopic variable color display is made.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a variable color display device, and more specifically, a variable color display device that enables a three-dimensional display using a display board having a dichroic filter. Related to display devices.

[Prior Art] As a conventional variable color display device, as shown in FIG.
A case 1A, a display plate 3A held in the middle of the case 1Δ and having a dichroic filter layer, a first light source 2A held in the case 1A and emitting reflected light by illuminating the front side of the display plate 3A, and a case. This display board 3A is held at 1A.
A second light source 4A that emits transmitted light by illuminating the back side of the
Publication No. 9).

Furthermore, a display device having the same configuration as that shown in FIG. 4 except that a colored transparent material is used as the substrate of the display board is also known (Japan Institute of Invention and Innovation Technical Report, Branch No. 85-4281).

[Problems to be Solved by the Invention] In the two display devices, the second light source 4A is connected to the display panel 3.
It is installed at the back of A. Therefore, in this display device, the optical path difference between the optical path length from the first light source 2A (text 1 + λ0) and the optical path length from the second light source 4A (g20, Ro) is insufficient, so it is not necessarily possible to have an excellent three-dimensional effect. In addition, there was a problem that the entire display device became bulky.

The present invention has been made to overcome the above-mentioned problems, and it is an object of the present invention to provide a variable color display device that is not bulky and enables display with a three-dimensional effect superior to that of the prior art.

[Means for Solving the Problems] A variable color display device of the present invention includes a case, a display board held in the case and having a dichroic filter layer, and a display board held in the case that irradiates the front side of the display board. A variable color display device comprising a first light source that emits reflected light and a second light source that is held in the case and that illuminates the back side of the display board and emits transmitted light, wherein the second light source has a planar shape. It is a light emitting display element, and the display plate is arranged on the planar light emitting display element.

The case holds the display board, the first light source, and the second light source.

The display board has a dichroic filter layer. This dichroic filter layer has an optical interference film formed on a transparent substrate, and has the property of reflecting light of a certain wavelength and transmitting light of other wavelengths.

This optical interference film is usually composed of a multilayer film in which layers with a high refractive index and layers with a low refractive index are alternately laminated.

Then, the film thickness of each layer is determined by the optical film thickness of 1/4 wavelength in the direction of the wavelength of the light to be reflected (the optical film thickness is the refractive index
(displayed using actual film thickness), the light reflected by each layer is mutually intensified, and light of that wavelength is strongly reflected.

Specifically, titanium dioxide films and silicon dioxide films are layered alternately on the surface of a transparent glass plate. For example, the thickness of the titanium dioxide film is 690 mm and the thickness of the silicon dioxide film is 1 mm
This can be obtained by setting the number to 130 people. As a result, 60% or more of light with a wavelength of 560 to 750 nm can be reflected, and 80% or more of light with a wavelength of 560 nm or less can be transmitted. Note that figures, patterns, and characters may be drawn on the display board.

Further, this dichroic filter layer may be formed directly on the surface of a transparent substrate for a display panel, or as shown in FIG. It may be formed on a layer. That is, the former uses a substrate different from that of the planar light emitting display element, as shown in FIG. 3, and the superior uses a display board and a display element that are integrally combined.

The display board is placed on a planar light emitting display element, which is a second light source, which will be described below. The display plate can therefore be placed closely on the surface of the element, or it can be placed on top of and in close proximity to the element. first or second
In order to increase the optical path difference between the light source and the eyepoint,
The former is preferred. As mentioned above, if the two substrates are different, the display plate can be placed closely on the surface of the display element or fixed by adhesive, or it can be placed close to each other with a predetermined gap. You can also do that.

The display board may be held and fixed on one inner surface of the case via a display element as shown in FIG. 1, or one end of the display board may be held on the case as shown in FIG. , the entire display board may be held and fixed so as to be fixed.

The first light source is held in the case so as to illuminate the front side of the display board. The light from the first light source is irradiated onto the front side of the display board, and reflected light is emitted by the interference film of the display board. This first light source does not necessarily have to be a light source such as a small lamp; it may be a light source provided elsewhere and sent from this light source by a reflecting mirror, or it may be a planar light emitter, etc. good.

The second light source is held in the case and irradiates light from the back side of the display board, and the light transmitted through the display board has a specific color. For example, when red and blue dichroic filters are used in a display board, the transmitted light becomes, for example, green, and the display board emits green light.

This second light source is a planar light emitting element. This element can be an EL element.

This E element includes, for example, a transparent substrate, a transparent electrode layer formed on the substrate, a light-emitting layer containing a fluorescent material integrally formed on the surface of the transparent electrode layer, and a light-emitting layer formed on the top surface of the light-emitting layer. and a transparent electrode layer formed by vapor deposition. The light emitting layer can be a dispersed type light emitting layer or a vapor deposited thin film type light emitting layer in which a fluorescent substance is dispersed in a resin. As the fluorescent substance, a conventionally known fluorescent substance such as one activated by adding copper or the like to zinc sulfide or the like can be used. Note that in addition to the fluorescent substance, a high dielectric substance may be dispersed in the resin. Furthermore, an insulating layer made of a high dielectric material may be formed between the N-pole layer and the light-emitting layer.

This light-emitting layer can be formed by a doctor blade method, a screen printing method, a physical vapor deposition method, or the like.

The color of the light emitted by each of the first light source and the second light source can also be used as a red lamp or a green lamp. In this case, since absorption by the dichroic filter can be reduced, the efficiency of light emitted from the display panel is increased. Also, one light source can be made stronger than the other light source. 1st light source, 2nd light source
The light sources may be turned on individually, or both the first light source and the second light source may be turned on.

[Function] The function of the variable color display device of the present invention will be explained with reference to FIG.

This display device includes a display plate having a dichroic filter layer 31. Since this filter layer 31 has the property of reflecting light of a certain wavelength and transmitting light of other wavelengths, the visible color of the reflected light and the transmitted light of this filter layer are different. Moreover, when the first light source 2 and the second light source 4 are turned on at the same time, it is also possible to visually recognize the color corresponding to the mixed light of the reflected light and the transmitted light.

Further, in this display device, the second light source is a planar light emitting display element, and the display plate (in the figure, the dichroic filter layer 3
1) is placed on this planar light emitting display element. Therefore,
The optical path length between the first light source 2 and the eye point is [λ++Rol
It is expressed as On the other hand, the optical path length between the second light source 4 and the eye point is expressed as [20 λ0].

The length of this il is significantly smaller than the length of prong 1.

Therefore, the difference in optical path length between the two is approximately i+.

On the other hand, in the conventional display device, as shown in FIG. 4, the difference in optical path length between il and pattern 2 is small or almost non-existent.

Therefore, is the difference in optical path length between the two up to the eye point small?
Or almost none.

[Effects of the Invention] As described above, in the variable color display device of the present invention, since a display plate having a dichroic filter layer is used, as described in the above operation, reflected light of this filter, transmitted light, or a mixture of both light It can display variable colors corresponding to light. Furthermore, in this display device, as described in the above-mentioned operation, since the difference in optical path length between the first light source or the second light source and the eye point is large, it is also possible to display a display with excellent three-dimensional effect compared to the conventional display device.

[Example〕 The present invention will be explained below with reference to Examples.

Example 1 An explanatory cross-sectional view of a variable color display device of this example is shown in FIG.

This variable color display device is composed of a case 1, a first light source 2, a light emitting/display plate 5, switches 61, 62, and a power source 7.

The case 1 has a container shape with an open front, and the inner surface of the front edge 11 is a curved reflective surface. The tip of the front edge 11 is bent downward to block the light from the first light source 2 so that the light from the first light source 2 does not directly leak into the opening. The first light source 2 is a red display element (red bean lamp) that produces a remarkable reflection projection, and is disposed in front of the case 1.

The light-emitting/display board 5 is composed of an EL element 4 and a dichroic filter layer 31 formed on the surface of the display element 4, and is held and fixed on the inner surface of the case 1 on the back side by means of adhesive or the like. There is. That is, this includes a transparent conductive layer 42, a light emitting WJ43, a transparent conductive ff1144 on a glass substrate 41.
, the dichroic filter layer 31 is made up of WA layers in sequence. The transparent conductive layers 42 and 44 are made of ITO (indium-tin-oxide) and emit light I! ! 243 is composed of a fluorescent substance made of zinc sulfide (ZnS) activated with terbium (Tb). This EL element 4 has an emission wavelength corresponding to green. On the other hand, the dichroic filter layer 31 had a cutoff wavelength of 600 nIIl, and was made of about 10 layers of titanium dioxide and silicon dioxide laminated alternately. This dichroic filter layer 31 has the ability to pass green light emitted from the EL element 4 and reflect red light. Note that each of the layers described above is formed by a vapor deposition method. The first light source 2 and the second light source 4 are electrically connected to a power source 7 via a first switch 61 and a second switch 62, respectively.

When the first switch 61 is turned on and the second switch 62 is turned off, only the first light source 2 shines. This light source illuminates the front side of the issue/display board 5, and the reflected light becomes the color of the issue/display board. It reflects more than 560 nlll of light and 56
Since light of 0 nil or less is transmitted, the reflected light becomes red, and the light emitting/display plate 5 shines in red.

When the first switch 61 is turned off and the second switch 62 is turned on, the second light source 4 emits light, and this transmitted light passes through the light emitting/display plate 5. At this time, the light emitting display plate 5 has a wavelength of 5
Since light of 60 nm or less is transmitted and light of 560 nm or more is reflected, green light of 560 nm or less is emitted.
released from. Therefore, the light-emitting display panel 5 glows green. When both the switches 61 and 62 are turned on, the transmitted green light and the reflected red light interfere to produce yellowish red to yellowish green light.

In this way, the variable color display device of this embodiment shines in five colors: red, green, yellow-red, yellow, and yellow-green.

Further, in this display device, the distance between the first light source 2 and the eyepoint is expressed as 1+λ0. - The distance between the power tube 2 light source 4 and the eye point is io+Rt. Here, io is about 4Qcm, l + is 15CIIl, and ff12 is 1/1
000 cm or less, the optical path length difference is as large as about 15 cm. Therefore, this display device was able to provide display with excellent three-dimensional effect.

Example 2 A cross-sectional view of the variable color display device of this embodiment is shown in FIG.

This display device has the following features: (1) The display plate 3a and the EL element 4a have different substrates, and the dichroic filter layer is formed on the surface of the display plate transparent substrate; (2) the display plate 3a
and the EL element 4a are bonded via an adhesive;
(3) This is the same as in Example 1 except that the outer peripheral ends of the display plate 3a and the EL element 4a are held and fixed to the case 1a.

This display device also has the same effects as the first embodiment.

[Brief explanation of the drawing]

FIG. 1 is an explanatory cross-sectional view of a variable color display device according to Example 1, FIG. 2 is an explanatory cross-sectional view of a light-emitting display board in which a dichroic filter layer is formed on the surface of an El element, and FIG. 3 is an explanatory cross-sectional view of a variable color display device according to Example 2. FIG. 4 is an explanatory sectional view of a conventional variable color display device. 1... Case 2... First light source 3...
Display board 4...Second light source 5...Light emission-Display board 61.62...Switch 7...Power source 8...Reflector Patent applicant Toyota Motor Corporation Agent
Patent attorney Hiroshi Okawa

Claims (5)

[Claims] (1) a case, a display board held in the case and having a dichroic filter layer, a first light source held in the case that illuminates the front side of the display board and emits reflected light; A variable color display device comprising: a second light source that illuminates the back side of a display board to emit transmitted light; the second light source is a planar light emitting display element; and the display board is a planar light emitting display element. A variable color display device, characterized in that the variable color display device is disposed on the top. (2) The planar light emitting display element uses electroluminescence (
The variable color display device according to claim 1, which is an EL) element. (3) The variable color display device according to claim 2, wherein the display plate is integrally formed on the surface of the planar light emitting display element. (4) The variable color display device according to claim 2, wherein the planar light emitting display element is held on one inner surface of the case. (5) The variable color display device according to claim 1, wherein one of the first light source and the second light source is a red light source, and the other is a green light source.