JP5064709B2 - Reflective screen for bright room - Google Patents

Description

  The present invention relates to a reflective screen, and more particularly, to a reflective screen for a projector capable of reflecting and projecting an image projected from a projector in a bright room.

  As a reflective screen for projectors that reflects color images projected from a projector, a multilayer interference reflection film that selectively reflects blue light and a multilayer interference reflection that selectively reflects red light on a light-absorbing substrate. Patent Document 1 discloses a configuration in which a film and a multilayer interference reflection film that selectively reflects green light are arranged so as to overlap each other and a light diffusion layer is arranged thereon. Since this reflective screen can reflect only the three primary color lights projected from the projector and transmit the other light to be absorbed by the base material, it can display a high-contrast image regardless of the projection environment.

In Patent Document 1, a multilayer film in which high refractive index layers and low refractive index layers made of a thermoplastic resin are alternately stacked is used as a blue, green, and red multilayer interference reflection film. As the multilayer interference reflection film, those formed of an inorganic material are widely known.
JP 2005-352237 A

  The multilayer interference reflection film is designed by using a material having two or more different refractive indexes depending on the wavelength to be reflected, and considering the film thickness and the order of construction. The multilayer interference reflection film of the reflective screen is designed to reflect a specific wavelength of vertically incident light because it is required to reflect image light projected from a projector disposed almost in front of the screen. Yes.

  However, when a reflective screen is used in a bright room, not only image light from the projector but also external light such as illumination light enters from an oblique direction. The external light incident from an oblique direction has a shorter optical path difference in the multilayer interference reflection film than the vertically incident video light, and therefore, light having a shorter wavelength than the originally set reflection wavelength is reflected. For example, in the case of a multilayer interference reflection film designed to reflect red image light, as the incident angle increases (as it approaches the horizontal direction from the vertical direction to the film surface), the color changes from red to green or even blue. And reflected light changes. Such reflected light of outside light has a wavelength different from that of the image light, so that the image is damaged.

  An object of the present invention is to provide a reflective screen using a multilayer interference reflective film, which can display a clear image even when external light is incident from an oblique direction.

  In order to achieve the above object, the present invention provides the following reflective screen. That is, a reflective screen having first, second, and third films sequentially stacked on a light absorbing film, wherein the first, second, and third films each correspond to three primary colors in advance. It has the property of reflecting the defined first, second, and third wavelength band light and transmitting visible light other than the reflected light. A fourth film that transmits the first wavelength band light and absorbs light having a shorter wavelength than the first wavelength band light is disposed between the first and second films, and the second and third films A fifth film that transmits the second wavelength band light and absorbs light having a shorter wavelength than the second wavelength band light is disposed between the films. Thereby, even when external light is incident from an oblique direction and the reflection characteristics of the first, second, and third films are shifted to the short wavelength side, the fourth and fifth films and the light absorption Since it can be absorbed by the film, reflection of external light can be suppressed.

  Of the first, second, and third wavelength bands, it is possible to set the wavelength of the first wavelength band to be the longest and the wavelength of the third wavelength band to be the shortest. The first, second, and third films can be multilayer interference reflection films.

  For the fourth and fifth films, filters in which color materials are dispersed in a resin can be used.

  On the third film, the reflectance of the third wavelength band light for the first to fifth films as a whole is matched with at least one of the reflectances of the first and second wavelength band lights. It is possible to arrange a reflectance adjusting film. Thereby, since the reflectance of the 1st thru | or 3rd wavelength band light as a reflection type screen can be made equivalent, the visibility of a white display can be improved and an easy-to-see screen can be implement | achieved.

  The reflection type screen of the present invention displays a clear image without damaging the image because the reflection of the incident external light can be suppressed even when the external light is incident from an oblique direction and the reflection wavelength of the reflective film changes. can do.

An embodiment of the present invention will be described with reference to the drawings.
First, the configuration of the reflective screen according to the present embodiment will be described with reference to FIG. As shown in FIG. 1, the reflective screen has a red multilayer interference reflection film 12, a red filter 13, a green multilayer interference reflection film 14, a yellow filter 15, a blue multilayer interference reflection film 16, a reflectance on the light absorption film 11. In this configuration, the adjustment films 17 are sequentially stacked. However, the reflectance adjusting film 17 may be configured not to be used. A diffusion layer 18 and a protective layer (not shown) are disposed on the reflectance adjustment film 17 as necessary.

  The light absorption film 11 is a film that acts to absorb visible light that has passed through the films 12 to 18 above, and for example, a black polyethylene terephthalate (PET) film can be used. There is no particular limitation on the material, and it can be manufactured by applying and drying a black paint on the opposite surface of the red multilayer interference reflection film 12. Moreover, a flexible thing can be used on the assumption that the applicability to a roll screen etc. is improved. In addition to the PET film described above, plastic films such as polyethylene, polypropylene, polyacrylate, polyvinyl chloride, and polyvinylidene chloride can be used. These may contain a coloring material as appropriate. As the coloring material to be contained, a dye or a pigment can be used. Moreover, it is possible to mix and use 2 or more types of color materials. The light absorption film 11 only needs to absorb the light transmitted through the films 12 to 18 described above. Note that it is desirable that the reflectance and transmittance be extremely low.

  The red multilayer interference reflection film 12 has a property of reflecting red light contained in an image irradiated from the projector and transmitting other visible wavelength light. That is, the red multilayer interference reflection film 12 has a configuration in which a high refractive index resin layer and a low refractive index resin layer are alternately laminated in multiple layers, and the film thickness and refractive index of the high refractive index resin layer and the low refractive index resin layer. Is set to a predetermined value to reflect predetermined red band light with high efficiency. The predetermined red band light is set so as to include the wavelength of red light of the three primary colors constituting the image irradiated from the projector. Further, assuming that the projector is disposed substantially in front of the reflective screen, the film thickness and refraction of each layer constituting the red multilayer interference reflection film 12 are set with the incident angle of light being substantially zero (perpendicular incidence). The rate is fixed.

  Similarly, the green and blue multilayer interference reflection films 14 and 16 have reflection wavelength bands set so as to reflect green and blue light of the three primary colors emitted from the projector, and transmit other visible wavelength light. It has the property to do. That is, the film thicknesses of the high-refractive index resin layer and the low-refractive index resin layer constituting each of the films 14 and 16 so as to reflect green light and blue light having a predetermined wavelength perpendicularly incident on the films 14 and 16 with high efficiency The refractive index is set to a predetermined value.

  For example, when the wavelengths of the three primary colors emitted from the projector are blue 457 ± 25 nm, green 532 ± 25 nm, and red 642 ± 25 nm, the reflection wavelength bands of the blue, green, and red multilayer interference reflection films 16, 14, and 12 are The wavelength is set to 400 nm or more and less than 500 nm, 500 nm or more and less than 600 nm, and 600 nm or more and less than 700 nm, respectively, and the wavelength of the three primary colors from the projector and the band in the vicinity thereof are set.

  The red filter 13 has a property of absorbing visible light having a shorter wavelength than the red light emitted from the projector. For example, the red filter 13 having the property of absorbing light having a wavelength of less than 600 nm and transmitting light having a wavelength of 600 nm or more is used.

  The yellow filter 15 has a property of absorbing visible light having a shorter wavelength than the green light emitted from the projector. For example, a yellow filter 15 having a property of absorbing light having a wavelength of less than 500 nm and transmitting light having a wavelength of 500 nm or more is used.

  The reflectance adjustment film 17 is a film for equalizing the reflectance of blue light, red light, and green light as the entire reflective screen. For example, in consideration of the action of the other films 11 to 16, if the reflectance of blue light is higher than that of other red light and green light, the blue light is absorbed at a predetermined absorption rate and other visible light is absorbed. A transmitting filter is used as the reflectance adjustment film 17. Conversely, if the reflectance of blue light is lower than that of other red light and green light, a filter that absorbs red light and green light at a predetermined absorption rate and transmits blue light is used as the reflectance adjustment film 17. . On the contrary, if the reflectance of blue light, red light, and green light as the whole reflective screen is equal, the reflectance adjustment film 17 may not be provided.

  The reflection type screen having such a configuration is disposed in the bright room, and the three primary colors of blue, green, and red constituting the color image are irradiated from the diffusion layer 18 side from the projector disposed almost in front. In addition to the primary color light from the projector entering the main plane almost perpendicularly to the main plane, external light such as illumination also enters the reflective screen from an oblique direction.

  The three primary colors of video light enter the reflective screen substantially perpendicularly, pass through the reflectance adjustment film 17 located closest to the light incident side among the three types of multilayer interference reflection films 12, 14, and 16, and are reflected by the blue multilayer interference reflection. The light enters the film 16 almost perpendicularly. Of the image light, blue light is reflected by the blue multilayer interference reflection film 16. The reflected blue light is transmitted again through the reflectance adjusting film 17 so that its intensity is adjusted, and then diffused and emitted by the diffusion layer 18.

  Red light and green light other than blue light are transmitted through the blue multilayer interference reflection film 14 and then incident on the yellow filter 15. The yellow filter 15 has a property of transmitting light of 500 nm or more, and therefore, red light and green light. Any light passes through the yellow filter 15. The red light and green light transmitted through the yellow filter enter the green multilayer interference reflection film 14 almost perpendicularly, and the green light is reflected. The reflected green light again passes through the yellow filter 15, the blue multilayer interference reflection film 16, and the reflectance adjustment film 17, and then is diffused and emitted by the diffusion layer 18.

  The red light passes through the green multilayer interference reflection film 14 and enters the red filter 13, but the red filter 13 has a property of transmitting light of 600 nm or more, and thus passes through the red filter 13. The red light transmitted through the red filter 13 enters the red multilayer interference reflection film 12 almost perpendicularly and is reflected. The reflected light again passes through the red filter 13, the green multilayer interference reflection film 14, the yellow filter 15, the blue multilayer interference reflection film 16, and the reflectance adjustment film 17, and then is diffused and emitted by the diffusion layer 18.

  As described above, since the three primary color image lights are all reflected by the multilayer interference reflection films 12, 14, 16, a color image is displayed.

  On the other hand, external light such as illumination mostly enters the reflective screen from an oblique direction due to the positional relationship between the light source and the reflective screen. The incident external light passes through the reflectance adjustment film 17 and then enters the blue multilayer interference reflection film 16. For this incident light, the blue multilayer interference reflection film 16 reflects light having a shorter wavelength than blue because the reflection wavelength is shifted to the shorter wavelength side than the original reflection wavelength (blue). Light having a wavelength shorter than that of the reflected blue light easily enters an invisible region (ultraviolet light), so that the image is hardly damaged. However, a filter that absorbs light of less than 430 nm may be provided on the blue multilayer interference reflection film 16 in order to make it more ideal. In that case, by adding this function to the reflectance adjustment film 17, it is possible to also serve as a filter that absorbs less than 430 nm.

  Of the external light incident on the blue multilayer interference reflection film 16, light having a wavelength longer than the shifted reflection wavelength (blue, green, red light, etc.) passes through the blue multilayer interference reflection film 16 and then enters the yellow filter 15. Incident. Since the yellow filter 15 has a property of absorbing light of less than 500 nm and transmitting light of 500 nm or more, most of the blue light transmitted through the blue multilayer interference reflection film 16 is absorbed by the yellow filter 15. The green light and the red or higher wavelength light transmitted through the blue multilayer interference reflection film 16 pass through the yellow filter 15 and enter the green multilayer interference reflection film 14.

  The green multilayer interference reflection film 14 shifts a slight blue light transmitted through the yellow filter 15 to the incident light because the reflection wavelength is shifted to the shorter wavelength (blue) side than the original reflection wavelength (green). Reflects and transmits green light and light of wavelengths longer than red. Since the reflected blue light is incident on the yellow filter 15 again and absorbed, the rate at which the blue light included in the external light is emitted from the reflective screen is suppressed as low as possible.

  The green and red wavelength light transmitted through the green multilayer interference reflection film 14 is incident on the red filter 13. Since the red filter 13 has a property of absorbing light of less than 600 nm and transmitting light of 600 nm or more, most of the green light transmitted through the green multilayer interference reflection film 14 is absorbed by the red filter 13. Red or higher wavelength light transmitted through the green multilayer interference reflection film 14 passes through the red filter 13 and enters the red multilayer interference reflection film 12.

  The red multi-layer interference reflection film 12 shifts a slight green light transmitted through the red filter 13 to the incident light because the reflection wavelength is shifted to the shorter wavelength (green) side than the original reflection wavelength (red). Reflects and transmits light having a wavelength of red or higher. Since the reflected green light is incident on the red filter 13 again and absorbed, the rate at which the green light included in the external light is emitted from the reflective screen is suppressed as low as possible.

  Red or higher wavelength light transmitted through the red multilayer interference reflection film 12 enters the light absorption film 11 and is absorbed. Therefore, the rate at which light having a wavelength of red or higher included in external light is emitted from the reflective screen is also suppressed to a low level.

  As described above, in the reflective screen according to the present embodiment, external light is incident from an oblique direction, and the reflection wavelengths of the green and red multilayer interference reflection films 14 and 12 are shifted to the short wavelength side, so that blue and green light respectively. Even when the light is reflected, the yellow light 15 and the red filter 13 can absorb the reflected light. Therefore, even when the screen is disposed in a bright room and external light is incident from an oblique direction, a high-contrast image can be clearly displayed. Note that even if the reflection wavelength of the blue multilayer interference reflection film 16 shifts to the ultraviolet region, it does not affect the visual recognition because it deviates from the visible region. Further, after the three primary color lights irradiated from the projector disposed almost in front are reflected by the blue, green, and red multilayer interference reflection films 16, 14, and 12, respectively, they are all diffused by the diffusion layer 18 and emitted from the projector. Can be projected.

  In the present embodiment, the red, green, and blue multilayer interference reflection films 12, 14, and 16 can be made of a thermoplastic resin. Any of these resin multilayer interference reflection films 12, 14, and 16 can be manufactured by a known multilayer extrusion stretching method. The multilayer extrusion stretching method is described in JP-A-2005-352237. In general, multilayer interference reflection films made of thermoplastic resin are superior in flexibility and inexpensive to manufacture compared to those made of inorganic materials. However, the optical multilayer film is not easily damaged, and there is an advantage that the manufacturing cost can be reduced.

  The yellow filter 15 and the red filter 13 are formed into a film by mixing a coloring material such as a dye or a pigment with a resin, and applying the resin on a transparent film as a base material by a coating method or the like, followed by drying. Alternatively, a resin in which a color material is mixed and formed into a film can be used. Alternatively, the yellow filter 15 or the red filter 13 can be formed by directly applying a resin mixed with a color material on the green multilayer interference reflection film 14 or the red multilayer interference reflection film 12. When using the coating method, a resin and a colorant soluble in an organic solvent or a solvent such as water are mixed to form a paint, and this is applied and dried to a predetermined film thickness using a wire bar or the like. It is also possible to use a thermosetting resin or the like in order to provide water resistance and solvent resistance. Further, by using a resin having an adhesive property as a resin mixed with the color material, the yellow filter 15 or the red filter 13 itself can be provided with an adhesive property, and the multilayer interference reflection films 12 and 14 to be laminated are laminated. , 16 can be bonded together by the adhesiveness of the red filter 13 or the yellow filter 15 itself.

  As the color material, a dye or a pigment can be used. Moreover, it is possible to mix and use 2 or more types of color materials. However, in any case, the visible light transmittance is important for extracting the contrast of the image. In the case of the red filter 13, the transmittance is 20% or less, preferably 10% or less at a wavelength of less than 600 nm, and the transmittance is 60% or more, preferably 70% or more at a wavelength of 600 nm or more. In the case of the yellow filter 15, the transmittance is 20% or less, preferably 10% or less at a wavelength of less than 500 nm, and the transmittance is 60% or more, preferably 70% or more at a wavelength of 500 nm or more. It is preferable that the transmittance change is steep in the vicinity where the transmittance changes. For example, the red filter 13 preferably has a characteristic that the transmittance changes from 20% or less to 60% or more in the range of 600 ± 30 nm. Similarly, the yellow filter 15 preferably has a characteristic that the transmittance changes from 20% or less to 60% or more in the range of 500 ± 30 nm.

  As shown in FIG. 1, the red, green, and blue multilayer interference reflection films 12, 14, and 16 may be arranged in such a manner that the reflection wavelength is shorter as the image light and the external light are closer to each other. desirable. This is because it is easy to remove unnecessary external light incident obliquely by arranging the yellow filter 15 and the red filter 13 between them as shown in FIG.

  As an example of the present invention, a reflective screen having the configuration shown in FIG. 1 was prepared. As the light absorption film 11, a black film (Lumirror X30 100 μm: Toray Industries, Inc.) was used.

  As the red multilayer interference reflection film 12, a film showing a reflection spectrum as shown in FIG. 3 with respect to perpendicular incident light was used. As the green multilayer interference reflection film 14, a film showing a reflection spectrum as shown in FIG. 4 was used. As the blue multilayer interference reflection film 16, a film showing a reflection spectrum as shown in FIG. 5 was used. However, each of FIGS. 3 to 5 uses a sample in which the red multilayer interference reflection film 12, the green multilayer interference reflection film 14, or the blue multilayer interference reflection film 16 is bonded to a black film (Lumirror X30 100 μm: Toray Industries, Inc.). Measured.

  The multilayer interference reflection films 12, 14, and 16 have a property that when the incident angle is 60 °, the peak of the reflection spectrum shifts to the short wavelength side by about 80 to 100 nm as shown in FIG. It was.

  As the red filter 13, a filter showing a transmission spectrum as shown in FIG. 7 was used. As the yellow filter 15, a filter showing a transmission spectrum as shown in FIG. 8 was used.

  A reflective screen having the structure shown in FIG. 1 was prepared by laminating the films 11 to 16 with an adhesive.

  As a comparative example, a reflective screen having the structure of FIG. 2 that does not include the red filter 13, the yellow filter 15, and the reflectance adjustment film 17 was produced. The multilayer interference reflection films 12, 14, 16 and the light absorption film 11 used are the same as in this embodiment.

  FIGS. 9 and 10 show the reflection characteristics of the reflective screens of the present example and the comparative example in the state where the diffusion layer 18 is not provided, for an incident angle of 5 ° and an incident angle of 60 °, respectively. The reflection type screen of this example had a low reflectance between 400 nm and 600 nm in the case of light having a larger incident angle than that of the comparative example. Therefore, it was verified that reflection of unnecessary external light having a large incident angle is reduced.

Explanatory drawing which shows the structure of the reflection type screen of one embodiment of this invention. Explanatory drawing which shows the structure of the reflection type screen of a comparative example. The graph which shows the reflection spectrum of the red multilayer interference reflection film 12 used for the reflective screen of the Example. The graph which shows the reflection spectrum of the green multilayer interference reflection film 14 used for the reflection type screen of an Example. The graph which shows the reflection spectrum of the blue multilayer interference reflection film 16 used for the reflection type screen of an Example. 6 is a graph showing a reflection spectrum of the multilayer interference reflection films 12, 14, and 16 shown in FIGS. 3, 4, and 5 at an incident angle of 60 °. The graph which shows the transmission spectrum of the red filter 13 used for the reflection type screen of an Example. The graph which shows the transmission spectrum of the yellow filter 15 used for the reflection type screen of an Example. The graph which shows the reflection spectrum in the incident angle of 5 degrees of the reflective screen of an Example and a comparative example. The graph which shows the reflection spectrum in the incident angle of 60 degrees of the reflection type screen of an Example and a comparative example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 ... Light absorption film, 12 ... Red multilayer interference reflection film, 13 ... Red filter, 14 ... Green multilayer interference reflection film, 15 ... Yellow filter, 16 ... Blue multilayer interference reflection film, 17 ... Reflectance adjustment film, 18 ... Diffusion layer.

Claims (5)

A reflective screen having first, second, and third films sequentially stacked on a light absorbing film;
Each of the first, second, and third films has a property of reflecting predetermined first, second, and third wavelength band lights corresponding to the three primary colors and transmitting visible light excluding them. Of the first, second and third wavelength bands, the wavelength of the first wavelength band is the longest, the wavelength of the third wavelength band is the shortest,
A fourth film that transmits the first wavelength band light and absorbs light having a shorter wavelength than the first wavelength band light is disposed between the first and second films,
A fifth film that transmits the second wavelength band light and absorbs light having a shorter wavelength than the second wavelength band light is disposed between the second and third films ,
On the third film, the reflectance of the third wavelength band light with respect to the entire first to fifth films is set to at least one of the reflectances of the first and second wavelength band lights. A reflection type screen, wherein a reflectance adjusting film for matching is disposed .   2. The reflection type screen according to claim 1, wherein the first, second and third films are multilayer interference reflection films. 3. The reflective screen according to claim 1, wherein each of the fourth and fifth films is a filter in which a color material is dispersed in a resin. The reflective screen according to any one of claims 1 to 3,
The reflective screen according to claim 1, wherein the reflectance adjusting film also serves as a filter that absorbs light having a wavelength shorter than that of the third wavelength band. The reflective screen according to any one of claims 1 to 4,
A reflective screen comprising a diffusion layer on the reflectance adjustment film.

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