JP2008089945A - Display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device which utilizes fluorescence and in which only a display section can be viewed during light emission without exposing a light source. <P>SOLUTION: The display device is composed of: a matrix LED 25 which emits ultraviolet light striking on a fluorescent material to excite fluorescent light; a first reflective thin-film layer 23 made of a dielectric reflective thin-film layer disposed in front of the matrix LED 25; and a transparent display screen plate 22 disposed in front of the first reflective thin-film layer 23 at a predetermined distance from the matrix LED 25 and containing the fluorescent material. The first reflective thin-film layer 23 transmits the exciting light, so fluorescent light is generated in the display screen plate 22 and visible light is reflected by the first reflective thin-film layer 23, so the matrix LED 25 is never viewed from outside. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a display device in which fluorescence is emitted in a fluorescent layer containing a fluorescent material by relatively high energy excitation light such as ultraviolet light and blue light.

2. Description of the Related Art Conventionally, there are various display devices that use a light emitting device as a medium to transmit information according to the purpose to the outside. For example, in Patent Document 1, display light is viewed through a display window 2 formed on a front panel 1a of a housing with a light source such as a liquid crystal display with a backlight or a fluorescent display tube. In addition to the display device that allows direct viewing of the light of the display device, a fluorescent paint containing a fluorescent material is applied to a transparent plastic substrate, and excitation light is emitted from the light source (excitation light emitting unit 1) to the transparent plastic substrate. There is a display device that uses fluorescence to display fluorescence on a substrate. Patent document 2 is given as an example of such a display device.
JP 2005-55887 A JP 2003-27057 A

However, since each of the conventional display devices uses an external light source, the light source is viewed through the display window 2 or a plastic substrate coated with a fluorescent paint. However, it is inevitable that the light source is visually observed in a display device such as Patent Document 1 that directly looks at the light of the display device, and at least in the light-emitting state, the light source is generally difficult to see due to diffusion of the luminescent color. I don't feel so uncomfortable.
However, in the fluorescent display device as in Patent Document 2, if the excitation light is ultraviolet light, it is not visually observed, and there is a distance from the light source to the plastic substrate serving as the display unit, and therefore the light source is sufficiently covered by the diffusion of the fluorescence. After all, the light source is exposed both in the light emission and non-light emission. For this reason, there has been a demand for a contrivance that allows only the display unit to be visually observed without exposing the light source particularly in a display device using this type of fluorescence.
The present invention has been made paying attention to such problems existing in the prior art. An object of the present invention is to provide a display device that allows only a display unit to be visually observed during light emission without exposing a light source in a display device using fluorescence.

As a first means for solving the above-described problem, at least an excitation light generation source that generates excitation light that excites fluorescence by colliding with a fluorescent material, and a dielectric disposed in front of the excitation light generation source A reflective thin film layer, and a transparent fluorescent layer containing a fluorescent material disposed at a predetermined distance from the excitation light source at the front surface of the dielectric reflective thin film layer, and the dielectric reflective thin film layer includes: The gist is that the excitation light is transmitted and the visible light is reflected.
In such a configuration, the excitation light emitted by the excitation light generation source passes through the dielectric reflective thin film layer and reaches the fluorescent layer. The excitation light collides with the fluorescent material in the fluorescent layer and excites the fluorescent material. The excitation light is absorbed by the fluorescent material, and the fluorescent material generates fluorescence based on the excitation light. The generated fluorescence is displayed in a predetermined display mode in the fluorescent layer.
Here, the optical characteristics of the dielectric reflective thin film layer are such that the wavelength range of the excitation light can be transmitted but the wavelength range of the visible light is reflected and cannot be transmitted. Therefore, the excitation light source is not visually observed from the fluorescent layer side through the dielectric reflective thin film layer.
More specifically, the dielectric reflective thin film layer sets the transmittance of light having a wavelength in the visible light range from about 380 nm to about 780 nm as low as possible (with high reflectivity), and emits a large amount of light that excites the fluorescent material. The transmittance of light with a wavelength of 380 nm or less is set as high as possible (reflectance is low). In the present invention, high-energy visible light wavelength light that can be both visible light and excitation light such as deep purple and blue is not regarded as visible light when used as excitation light. The dielectric reflective thin film layer is intended to prevent the excitation light source from being seen from the fluorescent layer side, and therefore the dielectric reflective thin film layer does not necessarily have to completely reflect all visible wavelengths. . It is sufficient to shield the wavelength in the visible range and to clear a certain reflectance. Similarly, the dielectric reflective thin film layer is preferably as high as the transmittance of the excitation light, but need not be 100%.

Here, the dielectric reflective thin film layer is a film that selectively transmits and reflects light in a predetermined wavelength range, and the dielectric reflective thin film layer generally has a multilayer structure. Become. Each constituent film layer of the multilayer film is a dielectric made of a metal oxide or a metal fluoride. For example, TiO ₂ (titanium dioxide), Ta ₂ O ₅ (tantalum pentoxide), ZrO ₂ (zircon oxide), Al ₂ O ₃ (aluminum oxide), Nb ₂ O ₅ (niobium pentoxide), SiO ₂ (silicon oxide), MgF ₂ (magnesium fluoride), ZnO ₂ (zinc oxide) HfO ₂ (hafnium oxide), CaF ₂ (fluorination) Calcium) et al.
The dielectric film of the present invention is preferably composed of alternating layers in which at least two kinds of dielectrics selected from these nine kinds are alternately laminated with a low refractive index material and a high refractive index material in the light transmitting direction. The number of the multilayer film comprised is not specifically limited. A dielectric optical film can be configured by selecting and combining compounds in order to exhibit reflection performance or transmission performance for a desired wavelength. The method for forming the dielectric reflective thin film layer is not particularly limited, but it is generally preferable to form the film by a vapor deposition method or a sputtering method.

Alternatively, the fluorescent layer may be formed by dispersing a fluorescent material in a solvent and applying a sol solution on a transparent substrate and drying it to form a film body, or by dispersing the fluorescent material in a plastic material. The transparent substrate itself may be configured as a fluorescent layer by molding. In particular, since a fluorescent layer having a thickness can be constructed by forming the fluorescent layer by molding as described above, it is possible to emit three-dimensional fluorescence in the fluorescent layer. Translucent includes translucent.
The fluorescent material is not particularly limited. The RGB fluorescent material used depending on the fluorescent color can be freely selected. For example red fluorescent as the material _{6MgO · As 2 O 5: Mn} , 3.5MgO0.5MgF 2 · GeO 2: Mn, YVO: Eu 3+, SrY 2 S 4: Eu 3+, SrY 2 S 4: Mn or the like, Green fluorescent materials include SrAl ₂ O ₄ : Eu ²⁺ , SrGa ₂ S ₄ : Eu ²⁺ Y ₃ Al ₅ O ₁₂ : Ce ³⁺ , ZnS: Cu, ZnS: Cu, Cl, ZnS: Cu, Cl, Al As the blue fluorescent material, Sr ₁₀ (PO ₄ ) ₆ Cl ₂ : Eu ²⁺ , BaMgAl ₁₀ O ₁₇ : Eu ²⁺ , Sr ₃ MgSi ₂ O ₈ : Eu ²⁺ , Ba ₃ MgSiO ₈ : Eu ²⁺ , ZnS: Ag, Cl, ZnS: Ag, Al, etc. are assumed. Of course, other fluorescent materials can be used.

Further, as a second means for solving the above-described problem, at least an excitation light generation source that generates excitation light that excites fluorescence by colliding with a fluorescent material and a front surface of the excitation light generation source are disposed. The wavelength selective absorption layer is composed of a wavelength selective absorption layer and a transparent fluorescent layer containing a fluorescent material disposed at a predetermined distance from the excitation light source at the front of the wavelength selective absorption layer, and the wavelength selective absorption layer is excited. The gist is to transmit light and selectively absorb visible light.
In such a configuration, the excitation light emitted by the excitation light generation source passes through the wavelength selective absorption layer and reaches the fluorescent layer. The excitation light collides with the fluorescent material in the fluorescent layer and excites the fluorescent material. The excitation light is absorbed by the fluorescent material, and the fluorescent material generates fluorescence based on the excitation light. The generated fluorescence is displayed in a predetermined display mode in the fluorescent layer.
Here, although the wavelength selective absorption layer can transmit the wavelength range of excitation light, the wavelength range of visible light is absorbed and cannot be transmitted. Therefore, the excitation light generation source is not visually observed from the fluorescent layer side through the wavelength selective absorption layer.
More specifically, the wavelength selective absorption layer sets the absorption rate of light having a wavelength in the visible light range from about 380 nm to about 780 nm as high as possible, and has a wavelength of 380 nm or less that becomes a light beam having a large energy that excites the fluorescent substance. Set the light absorptance as low as possible. In the present invention, high-energy visible light wavelength light that can be both visible light and excitation light such as deep purple and blue is not regarded as visible light when used as excitation light. Since the wavelength selective absorption layer is intended to prevent the excitation light generation source from being viewed from the fluorescent layer side, the wavelength selective absorption layer is not necessarily required to completely absorb all visible wavelengths. For example, it is possible to selectively reflect only a desired wavelength range and absorb a different wavelength range to cause predetermined color development. Similarly, the wavelength selective absorption layer is preferably as high as the transmittance of the excitation light, but need not be 100%.
In addition, the wavelength selective reflection thin film layer is disposed between the wavelength selective absorption layer and the fluorescent layer, and the wavelength selective reflection thin film layer transmits excitation light and selectively reflects visible light. preferable. As a result, the light in the selected wavelength range is reflected when viewed from the fluorescent layer side, and the remaining visible wide range is absorbed by the wavelength selective absorption layer, thereby preventing the excitation light source from being viewed. However, the desired selected color tone can be visually observed as the background of the fluorescent layer.

  Here, the wavelength selective absorption layer is a film that selectively transmits and absorbs light in a predetermined wavelength range, and contains and disperses a dye of a predetermined color in the visible light range, In the light region, it is possible to apply and form a thin film layer that can exhibit its absorption characteristics by containing and dispersing organic compounds such as benzophenone and benzotriazole, and metal oxides such as zinc oxide cerium oxide and titanium oxide silicon oxide. is there. In general, when a thin film layer is used, it is not always necessary to use a multilayer as in the case of a wavelength selective reflection thin film layer. Alternatively, the dye or metal oxide may be dispersed in a transparent base material such as acrylic to constitute the base material itself as a wavelength selective absorption layer.

In general, ultraviolet light and blue light can be considered as excitation light that can cause the fluorescent material to fluoresce. Since ultraviolet light has higher energy than blue light, high-intensity fluorescent light emission can be expected, and excitation light is not visually observed.
When ultraviolet light is used as excitation light, a second reflective thin film layer for reflecting ultraviolet light outward from the fluorescent layer is formed in order to block ultraviolet light leaking forward from the fluorescent layer without exciting the fluorescent material. It is preferable to arrange.
As an application of such a display device, for example, it is assumed that the display device is used for a main display screen or a sub display screen of a mobile information processing device such as a mobile terminal device such as a mobile phone, a mobile personal computer, or an electronic notebook. It is also possible to configure a large display device by enlarging the phosphor layer.

  In the inventions of the above claims, since the excitation light source cannot be seen from the fluorescent layer side by the wavelength selective dielectric reflective thin film layer or the wavelength selective absorption layer, only fluorescence is emitted to the fluorescent layer without exposing the excitation light source. It is possible to realize the display.

Embodiments in which the present invention is applied to a camera-equipped mobile phone will be described below with reference to the drawings.
(Example 1)
As shown in FIGS. 1A and 1B, the camera-equipped mobile phone 10 has an outer shape in which a first housing 11 and a second housing 12 are connected by a hinge portion 13. The first and second casings 11 and 12 can be opened and closed by a hinge portion 13, and are folded as shown in FIG. 1 (a) in a portable state and can be used as a telephone as shown in FIG. 1 (b). It will open and the inside will be exposed.
A sub display screen 15 and a lens 16 for taking an image are disposed on the outer surface of the first housing 11. The lens 16 is provided with an imaging device, but illustration and description thereof are omitted. A main display screen 17 composed of a liquid crystal display device is disposed on the inner surface of the first housing 11. An operation unit 18 including a numeric keypad and various menu keys is disposed on the inner surface of the second housing 12. The camera-equipped mobile phone 10 includes a normal mechanism as a mobile phone, for example, a modem, a microphone, a receiver, a transmission / reception unit, an antenna, and the like.

As shown in FIGS. 2 and 3, a display screen plate 22 as a fluorescent layer constituting the sub display screen 15 is fitted in a through hole 21 formed in the first housing 11. In the first embodiment, the display screen plate 22 is a transparent square plastic plate made of polycarbonate. The display screen plate 22 contains RGB (red, green, and blue) fluorescent materials in a dispersed manner, and generates red, green, and blue fluorescence using ultraviolet light as excitation light. These fluorescent colors are mixed to generate white light.
A first reflective thin film layer 23 is formed on the back surface (inside the first housing 11) of the display screen plate 22. An example of the characteristics of the first reflective thin film layer 23 is shown in Table 1. In Table 1, the solid line indicates the transmittance, and the broken line indicates the reflectance. The first reflective thin film layer 23 is set to an average transmittance of about 98% (an average reflectance of about 2%) for light of 250 nm to 350 nm, which is the wavelength region of near ultraviolet light, and has a large visible light range. For light of 450 nm to 780 nm occupying a portion, the reflectance is set to about 95% on average (transmittance of about 5% on average). That is, the first reflective thin film layer 23 has a very high reflectance for visible light and a very low reflectance for near-ultraviolet light.

A second reflective thin film layer 24 is formed on the surface of the display screen plate 22 (external side of the first housing 11). An example of the characteristics of the second reflective thin film layer 24 is shown in Table 2. In Table 2, the solid line indicates the transmittance, and the broken line indicates the reflectance. The second reflective thin film layer 24 is set to have an average reflectance of about 98% (average transmittance of about 2%) for light of 250 nm to 350 nm, which is the wavelength region of near ultraviolet light, and has a large visible light range. For light of 450 nm to 780 nm occupying a portion, the transmittance is set to about 95% on average (reflectance of about 5% on average). That is, the second reflective thin film layer 24 has a very high reflectance with respect to ultraviolet rays and a very low reflectance with respect to visible light.
In the first housing 11 and on the bracket 26, a matrix LED 25 made of ultraviolet light-emitting diode elements arranged 10 × 10 is disposed. The matrix LED 25 irradiates ultraviolet light toward the first reflective thin film layer 23 based on control by a control unit (not shown). The display screen plate 22, the first reflective thin film layer 23, and the second reflective thin film layer 24 constitute a sub display screen 15, and a matrix LED 25 is added to this to form a fluorescent display mechanism 27.

In the camera-equipped mobile phone 10 having such a configuration, the following operation is performed on the sub display screen 15. In the following description, FIG. 4 is prepared for easy understanding of the configuration and operation in the vicinity of the sub display screen 15, and the thickness of each layer is shown regardless of the actual ratio.
As shown in FIG. 4, when the matrix LED 25 emits ultraviolet light as excitation light from a predetermined ultraviolet light emitting diode element, the ultraviolet light passes through the first reflective thin film layer 23 and enters the display screen plate 22. When an RGB fluorescent material is encountered, it is excited to generate fluorescence (trajectory A). As a result, predetermined characters, numbers, and the like are displayed as fluorescence on the display screen plate 22 as the sub display screen 15. The fluorescent light passes through the second reflective thin film layer 24 as a bright band which is a lumpy light lump generated by the fluorescent light like the elongated egg shape in the display screen plate 22 which is thick in the front-rear direction and is visually observed by the viewer. It will be. On the other hand, since the visible light is almost blocked by the first reflective thin film layer 23, the viewer will recognize the first reflective thin film layer 23 as a mirror surface.
Here, not all ultraviolet light encounters the RGB fluorescent material in the display screen plate 22 and excites it, and a part may pass through the display screen plate 22 as it is. In that case, the ultraviolet light is reflected (that is, blocked) by the second reflective thin film layer 24 and returns toward the display screen plate 22 (trajectory B). Part of the reflected ultraviolet light contributes to excitation, and part of it is attenuated in the display screen plate 22.

With such a configuration, the following effects are achieved in the first embodiment.
(1) The matrix LED 25 is not viewed by a viewer, and is displayed in a display mode in which a bright band appears in the display screen plate 22, thereby providing a new sub-display screen that has not existed before. Is possible.
(2) Even if the ultraviolet light emitted from the matrix LED 25 is not excited in the display screen plate 22, the leaked ultraviolet light is shielded by the second reflective thin film layer 24 and does not reach the viewer, so the adverse effect due to the ultraviolet light. Does not reach the viewer.

(Example 2)
Example 2 uses a high-luminance blue light-emitting diode element instead of an ultraviolet light-emitting diode element as the matrix LED 25 in Example 1. The description of the same configuration as in the first embodiment is omitted.
As shown in FIG. 5, unlike Example 1, Example 2 does not use ultraviolet light, so the second reflective thin film layer 24 is not formed on the outer surface of the display screen plate 22. As the RGB fluorescent material, a material corresponding to the blue light emitting diode is selected.
An example of the characteristics of the first reflective thin film layer 23 of Example 2 is shown in Table 3. In Table 3, the solid line indicates the transmittance, and the broken line indicates the reflectance. The first reflective thin film layer 23 is set to an average transmittance of about 95% (average reflectance of about 5%) for light of 430 to 460 nm which is the wavelength range of blue light, and most of the visible light range. With respect to the light of 500 nm to 780 nm occupying, the reflectance is set to about 95% on average (transmittance of about 5% on average). That is, the first reflective thin film layer 23 is set to have a very high reflectivity with respect to visible light except blue, and a very low reflectivity with respect to blue light.

In the camera-equipped mobile phone 10 having such a configuration, the following operation is performed on the sub display screen 15. In the following description, FIG. 6 is created for easy understanding of the configuration and operation in the vicinity of the sub display screen 15, and the thickness of each layer is shown irrespective of the actual ratio.
As shown in FIG. 6, when the matrix LED 25 emits blue light as excitation light from a predetermined blue light emitting diode element, the blue light passes through the first reflective thin film layer 23 and enters the display screen plate 22. When an RGB fluorescent material is encountered, it is excited to generate fluorescence (trajectory A). As a result, predetermined characters, numbers, and the like are displayed as fluorescence on the display screen plate 22 as the sub display screen 15. The fluorescent light passes through the second reflective thin film layer 24 as a bright band which is a lumpy light lump generated by the fluorescent light like the elongated egg shape in the display screen plate 22 which is thick in the front-rear direction and is visually observed by the viewer. It will be. On the other hand, since the visible light is almost blocked by the first reflective thin film layer 23, the viewer will recognize the first reflective thin film layer 23 as a mirror surface.
By adopting such a configuration, the same effect as the effect (1) of the first embodiment is achieved in the second embodiment. Moreover, since it is not necessary to provide the 2nd reflective thin film layer 24 like Example 1, it can contribute to cost reduction.

(Example 3)
In the third embodiment, an absorbing thin film layer 28 is used as shown in FIG. 8 instead of the first reflective thin film layer 23 in the first embodiment. In the following description, the description of the same configuration as that of the first embodiment is omitted.
An absorption thin film layer 28 is formed on the rear surface of the display screen plate 22 (inside the first housing 11). An example of the characteristics of the absorption thin film layer 28 is shown in Table 4. In Table 4, the solid line indicates the transmittance, and the broken line indicates the absorption rate. The first reflective thin film layer 23 is set to an average transmittance of about 98% (an average reflectance of about 2%) for light of 250 nm to 350 nm, which is the wavelength region of near ultraviolet light, and has a large visible light range. For light of 450 nm to 780 nm that occupies a portion, the average absorptance is set to about 95% (average transmittance of about 5%). That is, the absorption thin film layer 28 is set to have an extremely high absorption rate for visible light and an extremely low absorption rate for near-ultraviolet light (high transmission rate).

In the camera-equipped mobile phone 10 having such a configuration, the following operation is performed on the sub display screen 15. In the following description, FIG. 6 is created for easy understanding of the configuration and operation in the vicinity of the sub display screen 15, and the thickness of each layer is shown irrespective of the actual ratio.
When the matrix LED 25 emits ultraviolet light as excitation light from a predetermined ultraviolet light-emitting diode element, the ultraviolet light passes through the absorption thin film layer 28 and enters the display screen plate 22. When an RGB fluorescent material is encountered, it is excited to generate fluorescence. As a result, predetermined characters, numbers, and the like are displayed as fluorescence on the display screen plate 22 as the sub display screen 15. The fluorescent light passes through the second reflective thin film layer 24 as a bright band which is a lumpy light lump generated by the fluorescent light like the elongated egg shape in the display screen plate 22 which is thick in the front-rear direction and is visually observed by the viewer. It will be. On the other hand, since most of the visible light is absorbed by the absorption thin film layer 28, the viewer recognizes the absorption thin film layer 28 as a black background in which all visible light regions are absorbed.
By adopting such a configuration, the same effects as the effects (1) and (2) of the first embodiment are achieved in the third embodiment.

Example 4
A large display device for installation in the outdoors or public space will be described based on the fourth embodiment.
As shown in FIG. 7, an acrylic transparent plate 32 is disposed in a large opening 31 formed on the side surface of a building S such as a building. A first reflective thin film layer 33 is formed on the inner surface of the transparent plate 32. Facing the large opening 31, a matrix LED 34 composed of ultraviolet light emitting diode elements and an optical system for enlarging and projecting the light emission pattern image are disposed in the building S.
A large panel 35 is erected on the ground at an outer position facing the large opening 31 of the building S. The panel 35 of Example 4 is a transparent plastic plate made of polycarbonate. The panel 35 contains RGB (red, green, and blue) fluorescent materials in a dispersed manner, and generates red, green, and blue fluorescence using ultraviolet light as excitation light. These fluorescent colors are mixed to generate white light. A space is formed between the panel 35 and the building S. In addition, it is preferable to provide a fence that prevents people from passing in the space. A second reflective thin film layer 36 is formed on the surface of the panel 35. The first reflective thin film layer 33 and the second reflective thin film layer 36 in Example 4 have the same optical characteristics as those of the first reflective thin film layer 23 and the second reflective thin film layer 24 in Example 1 (Tables 1 and 2). ).

In the large display device having such a configuration, the following operation is performed.
When the matrix LED 34 emits ultraviolet light as excitation light from a predetermined ultraviolet light emitting diode element, the ultraviolet light passes through the first reflective thin film layer 33 and enters the panel 35. When an RGB fluorescent material is encountered, it is excited to generate fluorescence. As a result, predetermined characters, numbers, and the like are displayed as fluorescence as a large display device. The fluorescent light passes through the second reflective thin film layer 36 as a bright band generated by fluorescent light such as an elongated egg shape in the panel 35 having a thickness in the front-rear direction and is visually observed by a viewer. On the other hand, since the visible light is almost blocked by the first reflective thin film layer 33, the viewer recognizes the first reflective thin film layer 33 as a mirror surface.
Here, not all ultraviolet light encounters the RGB fluorescent material in the panel 35 and excites it, and a part may pass through the panel 35 as it is. In this case, the ultraviolet light is reflected by the second reflective thin film layer 36 and is not emitted forward.

With such a configuration, the following effects are achieved in the fourth embodiment.
(1) The matrix LED 34 is not viewed by the viewer, and is displayed in a display mode in which a bright band appears in the panel 35. Thus, it is possible to provide an unprecedented new large display device. It becomes.
(2) Even when the ultraviolet light emitted from the matrix LED 34 is not excited in the panel 35, the leaked ultraviolet light is shielded by the second reflective thin film layer 36 and does not reach the outside of the panel 35. There is no adverse effect from light.

(Example 5)
Another example in which both the reflective thin film layer and the wavelength selective absorption thin film layer are arranged on the fluorescent layer based on Example 5 will be described. The fifth embodiment can be applied to, for example, the camera-equipped mobile phone and the large display device of the first to fourth embodiments.
As shown in FIG. 9, a fluorescent layer 41 and a matrix LED 42 that irradiates the fluorescent layer 41 with ultraviolet light as excitation light are arranged at a predetermined interval. A reflective thin film layer 43 is formed on the rear surface (matrix LED 42 side) of the fluorescent layer 41. Further, an absorption thin film layer 44 is laminated on the reflective thin film layer 43 by coating. The fluorescent layer 41 corresponds to the display screen plate 22 or the panel 35 in the above embodiment.
An example of the characteristics of the reflective thin film layer 43 is shown in Table 5. The reflective thin film layer 43 is selectively set to have a high reflectance (average reflectance of about 90%) with respect to light of 500 nm to 570 nm which is a green wavelength region. Further, the reflectance is set to an average of about 5% (average transmittance of about 95%) for light of 250 nm to 350 nm, which is the wavelength region of near ultraviolet light. That is, the reflective thin film layer 43 has a very high reflectance for green light in visible light, and has a very low absorptance for other wavelength regions, particularly near-ultraviolet light that is excitation light, so that it almost transmits. Is set to
An example of the characteristics of the absorption thin film layer 44 is shown in Table 6. In Table 6, the solid line indicates the transmittance, and the broken line indicates the absorption rate. The absorption thin film layer 44 is set to an average transmittance of about 98% (an average reflectance of about 2%) for light of 250 nm to 350 nm, which is the wavelength region of near ultraviolet light, and occupies most of the visible light region. For light of 450 nm to 780 nm, the average absorptance is set to about 98% (average transmittance of about 2%). That is, the absorption thin film layer 44 has an extremely high absorption rate for visible light, an extremely low absorption rate for near-ultraviolet light, and is set so as to be almost transmitted.

By adopting such a configuration, the following operation is performed.
When the matrix LED 42 emits ultraviolet light as excitation light from a predetermined ultraviolet light emitting diode element, the ultraviolet light passes through the reflective thin film layer 43 and the absorption thin film layer 44 and enters the fluorescent layer 41 as shown by a locus C in FIG. . When an RGB fluorescent material is encountered, it is excited to generate fluorescence. As a result, predetermined characters, numbers, and the like are displayed as fluorescence as a large display device. The fluorescent light is visually recognized by the viewer as a bright band generated by the fluorescent light like an elongated egg shape in the fluorescent layer 41 having a thickness in the front-rear direction.
Now, external light (natural light) is irradiated from the fluorescent layer 41 side with the characteristics shown in Table 7. Here, since the visible light is reflected on the reflective thin film layer 43 around the green wavelength region as shown by the locus D in FIG. 9, the viewer sees green as the background of the fluorescent layer 41. . Further, since visible light wavelengths other than green are absorbed by the absorption thin film layer 44 as shown by the locus E, the absorption thin film layer 44 is recognized as a dark color by the viewer, so the absorption thin film layer 44 serves as a shielding layer. The matrix LED 42 is not visually observed. At this time, the absorption thin film layer 44 reaches a wavelength range other than the green wavelength range as shown in Table 8.
If the absorption thin film layer 44 is not present, not only green is visually recognized as the background of the fluorescent layer 41, but also when the external light of the fluorescent layer 41 is bright when the excitation light source is extinguished, the matrix LED 42 is visually observed. In addition, when the external light is weak and dark at the time of lighting, there is a possibility that it may be visually observed by fluorescent light emission, but such a problem is caused by the two-layer structure of the reflective thin film layer 43 and the absorption thin film layer 44. Can be resolved.

It should be noted that the present invention can be modified and embodied as follows.
In the above embodiment, the matrix LEDs 25 and 34 are used as the excitation light generation source, but the present invention is not limited to these as long as the excitation light can be emitted. For example, an image to be projected, a projection pattern, a photograph, or the like may be projected using an ultraviolet lamp. Moreover, it is good also considering a laser diode instead of LED as a light source. In that case, it is also possible to draw on the fluorescent layer by scanning the beam with a galvanometer or the like instead of the matrix array.
It is also possible to disperse phosphors in the panel 32 instead of the panel 35 to emit light.
In this case, instead of the ultraviolet light blocking film 36, the panel 35 may absorb only the ultraviolet light and transmit the aforementioned fluorescence.
In the fourth embodiment, the matrix LED 34 is projected as it is onto the panel 35, but a magnifying lens or the like may be disposed in the optical system to enlarge the projection light.
The thickness, size, and shape of the display screen plate 22 and the panel 35 as the phosphor layer can be changed as appropriate. You may make it form a fluorescent substance layer by means, such as vapor deposition and application | coating.
The first reflective thin film layers 23 and 33 may be directly formed on the surface of the excitation light source, for example, by coating a resin layer on the element surface.
In the fifth embodiment, the wavelength range with the green peak is reflected and used as the background. However, it is possible to freely set other colors as the background.
In addition, it is free to implement in a mode that does not depart from the spirit of the present invention.

(A) is a perspective view of the camera-equipped mobile phone according to the first and second embodiments of the present invention, and (b) is a side view of the same. FIG. 2 is a partially enlarged cross-sectional view of the vicinity of the sub display screen of the camera-equipped mobile phone according to the first embodiment. FIG. 2 is an exploded perspective view of the fluorescent display mechanism of the camera-equipped mobile phone according to the first embodiment. FIG. 3 is a schematic explanatory view for explaining the principle of the fluorescence display mechanism in the first embodiment. Similarly, the partial expanded sectional view of the sub display screen vicinity of the camera-equipped mobile phone according to the second embodiment. FIG. 6 is a schematic explanatory view for explaining the principle of the fluorescence display mechanism in the second embodiment. Similarly, the schematic sectional side view of the large sized display apparatus of Example 4. FIG. Similarly, the partial expanded sectional view of the sub display screen vicinity of the camera-equipped mobile phone according to the third embodiment. FIG. 6 is a schematic explanatory view for explaining the principle of the fluorescence display mechanism of the fifth embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Camera-equipped mobile phone, 22 ... Display screen plate as fluorescent layer, 23, 33 ... First reflective thin film layer as dielectric reflective thin film layer, 24, 36 ... Second reflective as dielectric reflective thin film layer Thin film layer, 25, 34, 42 ... matrix LED as excitation light generation source, 41 ... fluorescent layer, 43 ... reflective thin film layer as dielectric reflective thin film layer, 44 ... absorption thin film layer as wavelength selective absorption layer.

Claims (5)

At least an excitation light source that generates excitation light that excites fluorescence by colliding with a fluorescent material, a dielectric reflection thin film layer disposed in front of the excitation light generation source, and a front surface of the dielectric reflection thin film layer And a transparent fluorescent layer containing a fluorescent material disposed at a predetermined distance from at least the same excitation light generation source,
The dielectric reflection thin film layer transmits excitation light and reflects visible light. At least an excitation light source that generates excitation light that excites fluorescence by colliding with a fluorescent material, a wavelength selective absorption layer disposed in front of the excitation light generation source, and at least a front surface of the wavelength selective absorption layer A transparent fluorescent layer containing a fluorescent material arranged at a predetermined interval from the excitation light generation source,
The wavelength selective absorption layer transmits excitation light and selectively absorbs visible light. A dielectric reflective thin film layer is disposed between the wavelength selective absorption layer and the fluorescent layer, and the dielectric reflective thin film layer transmits excitation light and selectively reflects visible light. Item 3. The display device according to Item 2. The display device according to claim 1, wherein the excitation light is ultraviolet light. 5. The display device according to claim 4, wherein a second dielectric reflective thin film layer that reflects ultraviolet rays is disposed outside the fluorescent material.

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