JP2021099515A - Reflection screen and video display device - Google Patents

Abstract

To provide a reflection screen that has high transparency and can display a video with high video contrast, and a video display device including the same.SOLUTION: A screen 10 comprises: a first optical shape layer 12 in which a plurality of unit optical shapes 121 having light transmissive properties and having a first surface 121a on which video light is incident and a second surface 121b opposite thereto are arranged on a surface on the back side; and a reflection layer 13 that is formed on the back side of the unit optical shapes 121 along the first surface 121a and the second surface 121b, has a rough surface having an irregular rugged shape on its surface, and has a function to diffuse and reflect part of incident light with the rugged shape and transmit part of the light. A plane passing through a point t located closest to the back side on the second surface 121b and a point v located closest to a video source side on the second surface 121b has a form that intersects the normal direction of a screen surface of the screen 10.SELECTED DRAWING: Figure 2

Description

The present invention relates to a reflective screen and an image display device including the reflective screen.

Conventionally, various reflective screens have been developed that reflect and display the image light projected from the image source (see, for example, Patent Document 1). Among them, the translucent transflective reflective screen has the advantage that the scenery on the other side of the screen can be seen through when not in use, which does not project image light, and is in demand due to its high design. Is increasing.

Japanese Unexamined Patent Publication No. 9-114003

However, when the reflection screen as described above is provided with a light diffusion layer containing diffuse particles or the like that diffuses light, the scenery on the other side of the screen is observed to be whitish and blurry, and the design is deteriorated. Therefore, improving transparency has been an issue.
Further, it is also required to suppress a decrease in contrast of an image due to external light and display a bright and clear image with respect to the above-mentioned reflective screen.
The above-mentioned Patent Document 1 proposes a screen that can be used for both a transmissive type and a reflective type, and can transmit light from the back surface side. However, Patent Document 1 does not disclose anything about improving the transparency of the screen.

An object of the present invention is to provide a reflective screen capable of displaying an image having high transparency and high contrast of an image, and an image display device including the reflective screen.

The present invention solves the above problems by the following solutions. In addition, in order to facilitate understanding, the description will be given with reference numerals corresponding to the embodiments of the present invention, but the present invention is not limited thereto.
The first invention is a reflective screen having transparency, reflecting at least a part of the image light projected from an image source to display an image, and transmitting a part of the image light. The unit optical shape (121,221) having transparency and having a first surface (121a, 221a) on which image light is incident and a second surface (121b, 221b) facing the first surface (121a, 221a) is on the back side. A plurality of optical shape layers (12, 22) arranged on the surface and the back side of the unit optical shape are formed along the first surface and the second surface, and the surface thereof has an irregular uneven shape. It is a rough surface having, and includes a reflection layer (13, 23) having a function of diffusing and reflecting a part of incident light by the uneven shape and transmitting a part of the incident light, and is provided with a reflection layer (13, 23) having a function of transmitting a part of the incident light. The plane (M) passing through the point (t) located at and the point (v) located closest to the image source side in the second surface intersects the normal direction of the screen surface of the reflective screen. The plane passing through the point (t) located on the backmost side on the second surface (121b, 221b) and the point (v) located on the image source side on the second surface is the screen of the reflective screen. When the angle formed in the direction parallel to the surface is θ2, the angle θ2 is a reflection screen (10, 20) characterized in that 25 ° ≦ θ2 ≦ 65 ° is satisfied.
According to the second invention, in the reflective screen of the first invention, the optical shape layer (12, 22) is a circular in which a plurality of the unit optical shapes (121,221) are concentrically arranged on the back surface side. A reflective screen (10, 20) characterized by having a Fresnel lens shape.
The third invention is characterized in that the reflective screen of the first invention or the second invention does not include a light diffusing layer containing diffusing particles having an action of diffusing light (10, 20).
The fourth invention has light transmittance in any of the reflective screens from the first invention to the third invention, is provided on the back surface side of the reflective layer (13, 23), and has the unit optical shape. The second optical shape layer (14, 24) which is laminated so as to fill the valley portion of the unevenness according to (121,221) and has a small refractive index difference which is equal to or can be regarded as equal to the optical shape layer. It is a reflective screen (10, 20) characterized by being provided.
A fifth invention is an image display device including any of the reflective screens (10, 20) from the first invention to the fourth invention, and an image source (LS) for projecting image light onto the reflective screen. (1).

According to the present invention, it is possible to provide a reflective screen capable of displaying an image having high transparency and high contrast of an image, and an image display device including the reflective screen.

It is a figure which shows the image display device 1 of 1st Embodiment. It is a figure explaining the layer structure of the screen 10 of 1st Embodiment. It is a figure which looked at the 1st optical shape layer 12 of 1st Embodiment from the back side (−Z side). It is a figure explaining the unit optical shape 121 and the reflection layer 13 of 1st Embodiment. It is a figure explaining the relationship between an angle θ2 and outside light. It is a figure which shows the state of the image light and the outside light on the screen 10 of 1st Embodiment. It is a figure explaining the screen 20 of the 2nd Embodiment. It is a figure explaining the unit optical shape 221 and the reflection layer 23 of the 2nd Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings and the like. It should be noted that each of the figures shown below, including FIG. 1, is a diagram schematically shown, and the size and shape of each part are exaggerated as appropriate for easy understanding.
In the present specification, terms that specify a shape or a geometric condition, for example, terms such as parallel and orthogonal, have the same optical function in addition to their strict meanings, and can be regarded as parallel or orthogonal. It shall also include the state having the error of.
In the present specification, numerical values such as dimensions of each member and material names described are examples of embodiments, and the present invention is not limited to these, and may be appropriately selected and used.

In this specification, terms such as board and sheet are used. Generally, the plates, sheets, and films are used in the order of thickness, and are used in the same manner in the present specification. However, since there is no technical meaning in such proper use, these words can be replaced as appropriate.
In the present specification, the screen surface indicates a surface in the plane direction of the screen when viewed as the entire screen, and is assumed to be parallel to the screen (display surface) of the screen.

(First Embodiment)
FIG. 1 is a diagram showing a video display device 1 of the first embodiment. FIG. 1A is a perspective view of the image display device 1, and FIG. 1B is a side view of the image display device 1.
The image display device 1 has a screen 10, an image source LS, and the like. The screen 10 of the present embodiment can reflect the image light L projected from the image source LS and display the image on the screen (display surface) on the image source side. Details of the screen 10 will be described later.

Here, in order to facilitate understanding, in each of the following figures including FIG. 1, an XYZ Cartesian coordinate system is appropriately provided and shown. In this coordinate system, the horizontal direction (horizontal direction) of the screen in the used state of the screen 10 is the X direction, the vertical direction (vertical direction) is the Y direction, and the thickness direction of the screen 10 is the Z direction. The screen of the screen 10 is parallel to the XY plane, and the thickness direction (Z direction) of the screen 10 is orthogonal to the screen of the screen 10. The screen of the screen 10 is parallel to the screen surface.
Further, when viewed from the observer O1 located in the front direction of the image source side of the screen 10, the direction toward the right side in the left-right direction of the screen is the + X direction, the direction toward the upper side in the vertical direction of the screen is the + Y direction, and the back side in the thickness direction ( The direction from the back side) to the image source side is the + Z direction.
Further, in the following description, the screen vertical direction, the screen horizontal direction, and the thickness direction are the screen vertical direction (vertical direction), the screen horizontal direction (horizontal direction), and the screen vertical direction (vertical direction) in the usage state of the screen 10, unless otherwise specified. It is assumed that the thickness direction (depth direction) is parallel to the Y direction, the X direction, and the Z direction, respectively.

The image source LS is an image projection device (projector) that projects the image light L onto the screen 10. The image source LS of this embodiment is a short focus type projector.
This image source LS is a screen 10 when the screen (display area) of the screen 10 is viewed from the front direction (normal direction of the screen surface) of the image source side (+ Z side) in the state of use of the image display device 1. It is located at the center of the screen in the left-right direction of the screen 10 on the lower side (−Y side) in the vertical direction with respect to the screen of the screen 10.
The image source LS can project the image light L diagonally from a position in the depth direction (Z direction) from a position where the distance from the surface of the image source side (+ Z side) of the screen 10 is significantly closer than that of the conventional general-purpose projector. .. Therefore, as compared with the conventional general-purpose projector, the image source LS has a shorter projection distance to the screen 10, a large incident angle at which the projected image light is incident on the screen 10, and a large change in the incident angle.

The screen 10 is a reflective screen that displays a part of the image light L projected by the image source LS toward the observer O1 side located on the image source side (+ Z side) and displays the image light. This is a translucent reflective screen having transparency that allows the scenery on the other side of the screen 10 to be observed when the screen is not used.
The screen (display area) of the screen 10 has a substantially rectangular shape in which the long side direction is the left-right direction of the screen when viewed from the observer O1 side on the image source side (+ Z side) in the used state.
The screen size of the screen 10 is about 40 to 100 inches diagonally, and the aspect ratio of the screen is 16: 9. Not limited to this, for example, the screen size of the screen 10 may be 40 inches or less, and the size and shape thereof can be appropriately selected according to the purpose of use, the environment of use, and the like.

In general, the screen 10 is a laminated body of thin layers made of resin or the like, and in many cases, the screen 10 alone does not have sufficient rigidity to maintain flatness. Therefore, the screen 10 may be integrally joined (or partially fixed) to the support plate (not shown) via a joining layer (not shown) having light transmission on the back surface side thereof to maintain the flatness of the screen.
This support plate is a flat plate-shaped member having light transmittance and high rigidity, and a plate-shaped member made of a resin such as an acrylic resin or a PC resin or made of glass can be used.
The video display device 1 of the present embodiment is applied to, for example, a shop window of a store. At this time, it is preferable that the screen 10 has a form in which the glass of the show window is fixed as the above-mentioned support plate.

FIG. 2 is a diagram illustrating a layer structure of the screen 10 of the first embodiment. In FIG. 2, the screen 10 passes through a point A (see FIG. 1), which is the center of the screen (geometric center of the screen) on the image source side (+ Z side) of the screen 10, and is parallel to the vertical direction (Y direction) of the screen. A part of the cross section perpendicular to the screen surface (parallel to the Z direction, which is the thickness direction) is shown in an enlarged manner.
FIG. 3 is a view of the first optical shape layer 12 of the first embodiment as viewed from the back surface side (−Z side). For ease of understanding, the reflective layer 13, the second optical shape layer 14, the protective layer 15, and the like of the screen 10 are omitted.
FIG. 4 is a diagram illustrating the unit optical shape 121 and the reflective layer 13 of the first embodiment. In FIG. 4, a part of the cross section of the screen 10 shown in FIG. 2 is enlarged and shown. Further, in FIG. 4, only the first optical shape layer 12, the reflection layer 13, and the second optical shape layer 14 are shown for easy understanding.
As shown in FIG. 2, the screen 10 includes a base material layer 11, a first optical shape layer 12, a reflection layer 13, a second optical shape layer 14, and a protective layer 15 in this order from the image source side (+ Z side). ing.

The base material layer 11 is a sheet-like member having light transmission. The base material layer 11 is integrally formed with the first optical shape layer 12 on the back surface side (back surface side, −Z side). The base material layer 11 is a layer serving as a base material (base) for forming the first optical shape layer 12.
The base material layer 11 is, for example, a polyester resin such as PET (polyethylene terephthalate) having high light transmittance, an acrylic resin, a styrene resin, an acrylic styrene resin, a PC (polycarbonate) resin, an alicyclic polyolefin resin, and a TAC (triacetyl). Cellulose) It is formed of resin or the like.

The first optical shape layer 12 is a light-transmitting layer formed on the back surface side (−Z side) of the base material layer 11. A plurality of unit optical shapes (unit lenses) 121 are arranged and provided on the back surface (−Z side) of the first optical shape layer 12.
As shown in FIG. 3, the unit optical shape 121 is a partial shape (arc shape) of a perfect circle, and a plurality of units are arranged concentrically around a point C located outside the screen (outside the display area) of the screen 10. Has been done. That is, the first optical shape layer 12 has a so-called offset structure circular Fresnel lens shape with the point C as the Fresnel center on the back surface side.
As shown in FIG. 3, this point C is located at the center of the screen (display area) of the screen 10 in the left-right direction and at the lower side of the screen. A is located on the same straight line parallel to the Y direction.

As shown in FIGS. 2 and 4, the unit optical shape 121 is parallel to the direction orthogonal to the screen surface (Z direction), and the cross-sectional shape in the cross section parallel to the arrangement direction of the unit optical shape 121 is substantially triangular. The shape.
The unit optical shape 121 is convex toward the back surface side (-Z side), and has a first surface (lens surface) 121a on which image light is incident and a second surface (non-lens surface) 121b facing the first surface (lens surface) 121a. Have. In one unit optical shape 121, the second surface 121b is located on the lower side (−Y side) of the first surface 121a with the apex t of the unit optical shape 121 interposed therebetween.
The angle formed by the first surface 121a with the surface parallel to the screen surface is θ1. The angle formed by the second surface 121b with the surface parallel to the screen surface is θ2. The angles θ1 and θ2 satisfy the relationship of θ2> θ1.

The first surface 121a and the second surface 121b of the unit optical shape 121 have a fine and irregular uneven shape on the surface thereof, and have a rough surface shape.
This uneven shape is formed by irregularly arranging fine convex shapes and concave shapes in a two-dimensional direction, and the size, shape, height, etc. of the convex and concave shapes are irregular.

The arrangement pitch of the unit optical shape 121 is P, and the height of the unit optical shape 121 (the dimension from the apex t in the thickness direction to the point v which is the valley bottom between the unit optical shapes 121) is h.
For ease of understanding, FIG. 2 shows an example in which the arrangement pitch P and the angles θ1 and θ2 of the unit optical shape 121 are constant in the arrangement direction of the unit optical shape 121. However, in the unit optical shape 121 of the present embodiment, although the arrangement pitch P is actually constant, the angle θ1 gradually increases as the angle θ1 moves away from the point C which becomes the Fresnel center in the arrangement direction of the unit optical shape 221. ..
The angles θ1, θ2, the arrangement pitch P, etc. are the projection angle of the image light from the image source LS (angle of the image light incident on the screen 10), the size of the pixels of the image source LS, and the screen of the screen 10. It may be appropriately set according to the size, the refractive index of each layer, and the like. For example, the arrangement pitch P may change along the arrangement direction of the unit optical shape 121, and the angles θ1 and θ2 may change.

The first optical shape layer 12 is formed of an ultraviolet curable resin such as urethane acrylate-based, polyester acrylate-based, epoxy acrylate-based, polyether acrylate-based, polythiol-based, and butadiene acrylate-based, which have high light transmittance.
In the present embodiment, as the resin constituting the first optical shape layer 12, an ultraviolet curable resin will be described as an example, but the present invention is not limited to this, and for example, other ionizing radiation such as an electron beam curable resin is used. It may be formed of a curable resin.

Returning to FIG. 2 and the like, the reflective layer 13 is a semi-transmissive reflective layer (so-called half mirror) having a function of reflecting a part of the incident light and transmitting a part of the incident light, and is on the unit optical shape 121 (so-called half mirror). It is formed on the first surface 121a and the second surface 121b).
The reflective layer 13 is formed following the fine and irregular uneven shape formed on the first surface 121a and the second surface 121b of the unit optical shape 121, and is opposite to the unit optical shape 121 side. A film is also formed on the surface of the surface in a state where this fine and irregular uneven shape is maintained. Therefore, the reflective layer 13 has fine and irregular uneven shapes on both sides thereof, and is a rough surface.
The reflective layer 13 diffuses and reflects a part of the incident light due to a fine and irregular uneven shape, and transmits other non-reflected light without diffusing it.
As for the fine and irregular uneven shape of the reflective layer 13, the size and shape of the unevenness may be appropriately selected according to the desired optical performance and the like.

The reflective layer 13 is formed of a dielectric multilayer film capable of achieving higher transparency and reflectance than a metal vapor-deposited film or the like. In the dielectric multilayer film, a plurality of dielectric films having a high refractive index (hereinafter referred to as a high refractive index dielectric film) and a dielectric film having a low refractive index (hereinafter referred to as a low refractive index dielectric film) are alternately laminated. Is formed.
The high refractive index dielectric film is formed of, for example, TiO ₂ (titanium dioxide), Nb ₂ O ₅ (niobium pentoxide), Ta ₂ O ₅ (tantalum pentoxide), or the like. The refractive index of the high refractive index dielectric film is about 2.0 to 2.6.
The low refractive index dielectric film is formed of, for example, SiO ₂ (silicon dioxide), MgF ₂ (magnesium fluoride), or the like. The refractive index of the low refractive index dielectric film is about 1.3 to 1.5.
The film thickness of the high-refractive index dielectric film and the low-refractive index dielectric film is about 5 to 100 nm, and these are formed by alternately laminating about 2 to 10 layers, and the total thickness of the dielectric multilayer film is , 10 to 1000 nm.

The reflective layer 13 of the present embodiment has a reflectance of 5 to 45% and a transmittance of 55 to 85% with respect to light having a wavelength range of 400 to 800 nm.
Further, as an example of the reflective layer 13 of the present embodiment, a high refractive index dielectric film formed of a metal oxide film such as _{TiO 2} (titanium dioxide) and a low refractive index dielectric film formed of _{SiO 2 are used.} It is formed by laminating a plurality of layers, and the reflectance is about 20% and the transmittance is about 70%.

The reflective layer 13 formed of the dielectric multilayer film has higher transparency than the reflective layer formed of a metal vapor deposition film such as aluminum, and has a small light absorption loss and high reflection. The rate can be achieved.
Further, the reflective layer 13 of the present embodiment is formed by depositing or sputtering a dielectric multilayer film as described above on the unit optical shape 121 (on the first surface 121a and the second surface 121b). , Formed to a predetermined thickness.
The reflective layer 13 is not limited to this, and for example, a metal having high light reflectivity such as aluminum, silver, and nickel is vapor-deposited, a metal having high light reflectivity is sputtered, and a metal foil is transferred. It may be formed by such as.

The second optical shape layer 14 is a light-transmitting layer provided on the back surface side (−Z side) of the reflective layer 13. The second optical shape layer 14 is formed so as to fill the valley portion of the unevenness due to the unit optical shape 121, and the surfaces of the first optical shape layer 12 and the reflection layer 13 on the back surface side (−Z side) are flat. .. Therefore, the surface of the second optical shape layer 14 on the image source side (+ Z side) is formed by arranging a plurality of substantially inverted shapes of the unit optical shape 121 of the first optical shape layer 12.
By providing such a second optical shape layer 14, the reflective layer 13 can be protected. Further, by providing the second optical shape layer 14, the protective layer 15 and the like can be easily laminated on the back surface of the screen 10, and further, the bonding to the support plate and the like can be facilitated.

It is desirable that the refractive index of the second optical shape layer 14 is equal to or substantially equal to the refractive index of the first optical shape layer 22 (the difference in refractive index is small enough to be regarded as equal). Further, the second optical shape layer 14 is preferably formed by using the same ultraviolet curable resin as the first optical shape layer 12 described above, but may be formed by a different material.
The second optical shape layer 14 of the present embodiment is formed of the same material (ultraviolet curable resin) as the first optical shape layer 12, and its refractive index is equal to the refractive index of the first optical shape layer 12.

The protective layer 15 is a light-transmitting layer formed on the back surface side (−Z side) of the second optical shape layer 14, and has a function of protecting the back surface side of the screen 10.
As the protective layer 15, a resin sheet-like member having high light transparency is used. As the protective layer 15, for example, a sheet-like member formed by using the same material as the base material layer 11 may be used.
The protective layer 15 may not be provided when the surface on the back surface side of the screen 10 is joined to a support plate or the like (not shown).
As described above, the screen 10 of the present embodiment does not include a light diffusing layer containing a diffusing material such as particles having a diffusing action of diffusing light, and the image light is fine and irregular in the reflective layer 13. Diffuse reflection is caused by the uneven shape.

The screen 10 is formed by, for example, the following manufacturing method.
A UV base layer 11 is prepared, and one surface thereof is laminated with an ultraviolet curable resin filled in a molding mold that forms a unit optical shape 121, and is irradiated with ultraviolet rays to cure the ultraviolet curable resin. The first optical shape layer 12 is formed by a molding method.
At this time, fine and irregular uneven shapes are formed on the surfaces forming the first surface 121a and the second surface 121b of the molding die that shape the unit optical shape 121. This uneven shape can be formed by performing surface processing a plurality of times on the surfaces forming the first surface 121a and the second surface 121b of the molding die. This surface processing includes, for example, plating processing, etching processing, blasting processing, and the like. Further, the surface processing may be performed a plurality of times by changing various conditions and the like.
After the first optical shape layer 12 is formed on one surface of the base material layer 11, the reflective layer 13 is formed by depositing a dielectric multilayer film on the first surface 121a and the second surface 121b.

After that, from above the reflective layer 13, an ultraviolet curable resin is applied so that the valley portion of the unevenness due to the unit optical shape 121 is filled and the surface on the back surface side becomes flat, the protective layer 15 is laminated, and ultraviolet rays are emitted. The ultraviolet curable resin is cured by irradiation to integrally form the second optical shape layer 14 and the protective layer 15. After that, the screen 10 is completed by cutting it to a predetermined size or the like.
The base material layer 11 and the protective layer 15 may have a single-wafer shape or a web-like shape. Further, when the screen 10 does not have the protective layer 15, the ultraviolet curable resin may be cured without laminating the protective layer 15.

As a method of forming a fine uneven shape on the surface of the reflective layer 13, for example, diffusion particles or the like are coated on the first surface 121a and the second surface 121b to form the reflective layer 13 on the first surface 121a and the second surface 121b. 1 There is conventionally known a method of performing blasting once on the first surface 121a and the second surface 121b after forming the optical shape layer 12.
However, with such a manufacturing method, stable manufacturing cannot be performed due to large variations in diffusion characteristics, quality, and the like on the individual screens 10. On the other hand, as described above, even when a large number of screens 10 are manufactured by shaping the uneven shape of the first surface 121a and the second surface 121b of the unit optical shape 121 by a molding die. There is an advantage that there is little variation in quality and stable production is possible.

Here, in the present embodiment, as shown in FIGS. 2 and 4, the second surface 121b is planar, and the point (that is, the apex t) on the backmost side of the second surface 121b and the most image. The angle at which the plane passing through the source-side point (that is, the valley bottom point v between adjacent unit optical shapes 121) is parallel to the screen surface is such that the second surface 121b is parallel to the screen surface. It is equal to the angle formed with respect to the direction and is an angle θ2. At this time, the surface of the reflective layer 13 formed on the second surface 121b on the observer side (+ Z side) also has an angle θ2 with respect to the direction parallel to the screen surface.
From the viewpoint of improving the transparency of the screen 10, suppressing the decrease in contrast due to external light, and displaying a high-contrast image, the second surface 121b intersects the normal direction of the screen surface (that is, on the screen surface). It is preferable that the angle θ2 is not orthogonal to the parallel direction), and it is more preferable that the angle θ2 satisfies 25 ° ≦ θ2 ≦ 65 °.
In the screen 10 of the present embodiment, the second surface 121b intersects the normal direction of the screen surface, and the angle θ2 satisfies 25 ° ≦ θ2 ≦ 65 °.

Further, it is desirable that the angle θ2 satisfies θ2 ≧ 2 × (θ1) while satisfying the above-mentioned conditions. If θ2 <2 × (θ1), a part of the image light is incident on the second surface 121b and reflected by the reflection layer 13, and does not reach the observer located in the front direction on the image source side. It may go in an unnecessary direction, or it may become stray light and cause deterioration of image quality.
Therefore, it is desirable that the angle θ2 satisfies θ2 ≧ 2 × (θ1) while satisfying the above conditions.

FIG. 5 is a diagram for explaining the relationship between the angle θ2 and the outside light. 5 (a) to 5 (c) show a cross section corresponding to the cross section shown in FIG. Further, in FIGS. 5A to 5C, the reflective layer 13 is shown in a simplified manner.
As shown in FIG. 5A, when the angle θ2 is θ2 = 90 °, that is, when the second surface 121b is orthogonal to the direction parallel to the screen surface, from the image source side (+ Z side). Even if the external light G17 incident on the screen 10 at a large incident angle is reflected by the reflection layer 13 on the second surface 121b, it is emitted upward on the image source side, and the observer located in the front direction on the image source side. It does not reach O1. Further, the external light G18 incident on the screen 10 from the back surface side (−Z side) at a large incident angle passes through the reflection layer 13 on the first surface 121a and is reflected by the reflection layer 13 on the second surface 121b. Even so, it may be emitted upward on the image source side of the screen 10, or depending on the incident angle of the external light G18, it may be totally reflected at the interface between the surface of the screen 10 on the image source side and the air and proceed upward in the screen 10. Therefore, it does not reach the observer O1 located in the front direction on the image source side.

However, a part of the external light G15 incident on the screen 10 from the back surface side at a small incident angle passes through the reflection layer 13 on the first surface 121a and is incident on the reflection layer 13 on the second surface 121b. It may be diffusely reflected and reach the observer O1 located in the front direction on the image source side. Further, a part of the external light G16 incident on the screen 10 from the image source side at a small incident angle is incident on the reflection layer 13 on the second surface 121b and diffusely reflected, and the observation is located in the front direction on the back side. It may reach the person.
As a result, when the image light is not projected, the scenery on the other side of the screen 10 becomes blurred or white for the observer O1 located in the front direction on the image source side and the observer located in the front direction on the back side. It is observed to be blurred, and the transparency of the screen 10 is reduced. Further, when the image light is projected, the external light G15 causes a decrease in the contrast of the image.
Therefore, from the viewpoint of improving the transparency of the screen 10 and improving the contrast of the image, the second surface 121b intersects the normal direction of the screen surface (that is, the angle θ2 is not 90 °). Is preferable.

Further, as shown in FIG. 5B, a case where the angle θ2 is 65 ° <θ2 <90 ° will be described. In this case, a part of the external light G19 incident from above the image source side (+ Z side) is reflected by the reflection layer 13 formed on the second surface 121b and the first surface 121a, and is reflected by the image source of the screen 10. It may reach the observer O1 because it is emitted upward on the side, or depending on the incident angle of the external light G19, it is totally reflected at the interface between the surface of the screen 10 on the image source side and the air and travels upward in the screen 10. Therefore, it does not interfere with the visibility of the image.
Further, a part of the external light G20 incident on the screen 10 from the image source side at a small incident angle is incident on the reflection layer 13 on the second surface 121b, reflected, and emitted upward on the back surface side of the screen 10. , It does not reach the observer O1 located in the front direction on the image source side. Although not shown, most of the external light incident on the screen 10 from the back surface side (−Z side) at a small incident angle is transmitted through the reflection layer 13 and temporarily reflected by the reflection layer 13 on the second surface 121b. However, it does not reach the observer O1 or the like on the image source side because it is emitted downward on the back side of the screen 10.

However, in this case, a part of the external light G21 incident on the screen 10 from above the back surface side (−Z side) at a large incident angle passes through the reflection layer 13 on the first surface 121a and passes through the reflection layer 13 on the first surface 121a, and the second surface 121b. It is incident on the upper reflection layer 13 and diffusely reflected, and reaches the observer O1 located in the front direction on the image source side, which may cause a decrease in the contrast of the image.

Further, as shown in FIG. 5C, a case where the angle θ2 is 0 ° <θ2 <25 ° will be described. In this case, the external light G22 incident on the screen 10 from above the back surface side (−Z side) at a large incident angle passes through the reflection layer 13 on the first surface 121a and is emitted downward on the image source side of the screen 10. Therefore, it does not reach the observer O1 located in the front direction on the image source side, and does not interfere with the visual recognition of the image.
Further, a part of the external light G23 incident on the screen 10 from the image source side (+ Z side) at a small incident angle is incident on the reflection layer 13 on the second surface 121b and reflected, and is reflected on the image source side of the screen 10. It does not reach the observer O1 located in the front direction of the image source side because it emits upward or is totally reflected at the interface between the surface of the screen 10 on the image source side and air and advances inside the screen 10 upward. .. Further, although not shown, most of the external light incident on the screen 10 from the back surface side at a small incident angle passes through the reflection layer 13 and is reflected by the reflection layer 13 on the second surface 121b, but on the screen 10. It does not reach the observer O1 or the like because it emits light downward on the back side.

However, in this case, a part of the external light G24 incident on the screen 10 from above the image source side (+ Z side) at a large incident angle is incident on the reflection layer 13 on the second surface 121b and diffusely reflected, resulting in an image. It may reach the observer O1 located in the front direction on the source side, resulting in a decrease in the contrast of the image.
Further, in this case, in the unit optical shape 121, the area occupied by the second surface 121b becomes too large, and the area of the first surface 121a that reflects the image light toward the observer side becomes small. Therefore, the amount of image light reaching the observer O1 is reduced, and the image becomes dark and unclear, which is not preferable.

On the other hand, as shown in FIG. 4, when the angle θ2 is 25 ° ≤ θ2 ≤ 65 °, a part of the external light G13 and G14 incident on the screen 10 at a small incident angle is second. Even if it is reflected by the reflective layer 13 on the surface 121b, it does not reach the observer O1 on the image source side or the observer on the back side by emitting light upward or downward on the image source side of the screen 10. In addition, most of the external light G13 and G14 pass through the reflective layer 13 on the second surface 121b. Therefore, the background through the screen 10 is not blurred or blurred white when the image light is not projected, and is not visible to the observer located on the image source side or the back side, and has high transparency. The screen 10 can have high image contrast and brightness.
Further, regarding the external light G11 and G12 that are incident on the screen 10 at a large incident angle from the upper side of the back surface and the upper side of the image source side, even if a part of the external light G11 and G12 are reflected by the reflection layer 13 on the second surface 121b, the image source side. It emits upward or downward, and does not reach the observer O1 located in the front direction on the image source side. Therefore, it is possible to suppress a decrease in the contrast of the image due to external light, and it is possible to display an image having a high contrast.
Further, in the unit optical shape 121, the area of the first surface 121a that reflects the image light toward the observer side can be sufficiently secured, and the image light incident on the second surface 121b can be sufficiently reduced, so that the image light is bright and clear. Can display various images.
From the above, it is more preferable that the angle θ2 satisfies 25 ° ≦ θ2 ≦ 65 °.

FIG. 6 is a diagram showing the state of image light and external light on the screen 10 of the first embodiment. FIG. 6 shows an enlarged part of a cross section of the unit optical shape 121 in a cross section parallel to the arrangement direction (Y direction) and the thickness direction (Z direction) of the screen. Further, in FIG. 6, in order to facilitate understanding, it is shown that there is no difference in refractive index at the interface of each layer in the screen 10.
Of the image light L1 projected from the image source LS located below the screen 10 and incident on the screen 10, a part of the image light L2 is incident on the first surface 121a of the unit optical shape 121 and is a reflection layer. It is diffusely reflected by 13 and emitted to the observer O1 side.

Of the video light incident on the first surface 121a, the other video light L3 that has not been reflected passes through the reflection layer 13 and is emitted from the back surface side (−Z side) of the screen 10. At this time, the image light L3 is emitted above the screen 10 and does not reach the observer O2 located in the front direction on the back side of the screen 10.
Further, of the image light L1 projected from the image source LS, a part of the image light L4 is reflected on the surface of the screen 10 and heads upward to the screen 10, so that the image light L1 of the observer O1 is not hindered from being visually recognized.
In the present embodiment, the image source LS is located below the screen 10, the image light L1 is projected from below the screen 10, and the image light is rarely directly incident on the second surface 121b. The second surface 121b has a small effect on the reflection of image light.

Next, light from the outside world such as sunlight (hereinafter referred to as external light) other than the image light incident on the screen 10 from the back surface side (−Z side) or the image source side (+ Z side) will be described.
As shown in FIG. 6, of the external light G1 and G5 incident on the screen 10, some of the external light G2 and G6 are reflected by the surface of the screen 10 and head toward the lower side of the screen. Further, some of the external light G3 and G7 are reflected by the reflective layer 13, and for example, the external light G3 is totally reflected on the surface of the screen 10 on the image source side (+ Z side) and heads downward inside the screen 10. The external light G7 is emitted to the upper side outside the screen on the back side (−Z side). Further, the other external light G4 and G8 that are not reflected by the reflection layer 13 pass through the reflection layer 13 and are emitted downward on the back surface side and the image source side, respectively.
At this time, the external light G2, G3, G8 emitted to the image source side does not reach the observer O1, and a part of the external light incident on the screen 10 is on the image source side and the back side of the screen 10. Since it is totally reflected on the surface of the screen and attenuates toward the lower side inside the screen, it is possible to suppress a decrease in contrast of the image.
Further, in the screen 10, since the angle θ2 satisfies 25 ° ≦ θ2 ≦ 65 °, the reflective layer is formed on the second surface 121b by being incident on the screen 10 from above the image source side or the back surface side. As described above, the external light reflected by the surface of the image source side of 13 does not reach the observer O1 on the image source side.

Most of the external light G9 and G10 incident at a small incident angle pass through the reflection layer 13 and are emitted to the back surface side and the image source side, respectively. In the screen 10, since the angle θ2 satisfies 25 ° ≦ θ2 ≦ 65 °, a part of the external light incident at such a small incident angle is formed on the second surface 121b as a reflection layer 13. Even if it is reflected on the surface of the image source side or the like, it does not reach the observers O1 and O2 on the image source side or the back side.
Further, since the screen 10 does not contain a diffusing material or the like containing diffusing particles, the external light G9 and G10 transmitted through the screen 10 are not diffused.
Therefore, when the observers O1 and O2 observe the scenery on the other side of the screen 10 through the screen 10, the scenery on the other side of the screen 10 is not blurred or blurred in white, and has high transparency. Can be observed.

In a semi-transmissive reflective screen provided with a light diffusing layer containing diffusing particles that diffuse light, the image light is diffused twice before and after reflection by the reflective layer, so that a good viewing angle can be obtained. On the other hand, there is a problem that the resolution of the image is lowered. In addition, since external light is also diffused by the diffused particles, the scenery on the other side of the screen is observed to be blurred or bleeding white, and the transparency is lowered.

However, the screen 10 of the present embodiment does not include the light diffusion layer, and the image light is diffused only when it is reflected by the reflection layer 13. Further, in the screen 10 of the present embodiment, only the light reflected by the reflective layer 13 is diffused, and the light transmitted through the reflective layer 13 is not diffused. Therefore, the screen 10 of the present embodiment can display an image having a good viewing angle and resolution, and the scenery on the other side of the screen 10 is not blurred or blurred, and is well visible to the observer O1. And high transparency can be achieved.
Further, in the screen 10 of the present embodiment, the observer O1 can partially see the scenery on the other side (back side) of the screen 10 even when the image light is projected on the screen 10. Further, in the screen 10 of the present embodiment, the observer O2 located on the back side has high transparency in the scenery on the image source side (+ Z side) through the screen 10 regardless of the presence or absence of projection of image light. Can be visually recognized well.

Further, in the screen 10 of the present embodiment, since the angle θ2 formed by the second surface 121b with the surface parallel to the screen surface satisfies 25 ° ≦ θ2 ≦ 65 °, from the upper side of the image source side and the upper side of the back side. The external light incident at a large incident angle is diffusely reflected by the reflection layer 13 on the second surface 121b, and the unnecessary external light does not reach the observer O1 located in the front direction on the image source side. Further, in the screen 10 of the present embodiment, since the angle θ2 satisfies 25 ° ≦ θ2 ≦ 65 °, the external light incident at a small incident angle is diffusely reflected by the reflection layer 13 on the second surface 121b. It is possible to suppress a decrease in the transparency of the screen 10 due to the above.
Therefore, according to the present embodiment, the screen 10 and the image display device 1 capable of displaying a bright image with high transparency and high contrast can be obtained.

(Second Embodiment)
FIG. 7 is a diagram illustrating the screen 20 of the second embodiment. FIG. 7 shows a cross section of the screen 20 corresponding to the cross section shown in FIG. 2 of the screen 10 of the first embodiment.
The screen 20 of the second embodiment is the same as the screen 10 of the first embodiment described above, except that the shape of the reflective layer 13 is different. Therefore, the same reference numerals or the same reference numerals are given to the parts that perform the same functions as those of the first embodiment described above, and duplicate description will be omitted as appropriate.
The screen 20 of the second embodiment includes a base material layer 11, a first optical shape layer 22, a reflection layer 23, a second optical shape layer 24, and a protective layer 15 in this order from the image source side (+ Z side). These layers are laminated integrally. The first optical shape layer 22, the reflection layer 23, and the second optical shape layer 24 correspond to the first optical shape layer 12, the reflection layer 13, and the second optical shape layer 14, respectively, of the first embodiment. This screen 20 can be applied to the image display device 1 shown in the first embodiment described above.

The first optical shape layer 22 has a circular Fresnel lens shape with an offset structure on the back surface side, similarly to the first optical shape layer 12 of the first embodiment.
FIG. 8 is a diagram illustrating the unit optical shape 221 and the reflective layer 23 of the second embodiment.
As shown in FIG. 8, the unit optical shape (unit lens) 221 has a gentle curved surface shape at least a part of the first surface (lens surface) 221a and the second surface (non-lens surface) 221b. The valley portion between the unit optical shapes 221 and the top of the unit optical shape 221 are also formed by curved surfaces.
Further, the unit optical shape 221 is a rough surface having a fine and irregular uneven shape on the surface thereof.

As shown in FIGS. 7 and 8, the reflective layer 23 is formed in a curved shape in the cross section of the unit optical shape 221 in the arrangement direction and the thickness direction of the screen surface, and is formed as a surface on the image source side and a surface on the back surface side. Is at least partly curved in the arrangement direction of the unit optical shape 221. Further, the reflective layer 23 has a rough surface having a fine and irregular uneven shape corresponding to the uneven shape of the unit optical shape 221.
The region serving as the second surface 221b in the present embodiment is a region from the point v to the apex t, which is the valley bottom, in the cross section shown in FIG. On the second surface 221b, a plane passing through a point on the backmost side (that is, apex t) and a point on the most image source side (that is, a point v that is a valley bottom between adjacent unit optical shapes 221). Assuming M, the angle formed by this plane M in the direction parallel to the screen surface is the angle θ2.
Further, as shown in FIG. 8, on the second surface 221b, the angle formed by the tangent line S of the second surface 221b in the direction parallel to the screen surface is the angle θ3. This angle θ3 gradually changes along the arrangement direction of the unit optical shape 221 in one second surface 221b.

In the screen 20 of the present embodiment, the above-mentioned plane M intersects the normal direction of the screen surface, and the angle θ2 satisfies 25 ° ≦ θ2 ≦ 65 °.
Further, in the screen 20 of the present embodiment, the sum of the area of the region where the angle θ3 is 0 ° ≦ θ3 <25 ° and the area of the region where the angle θ3 is 65 ° <θ3 ≦ 90 ° on the second surface 221b is , 25 ° ≤ θ3 ≤ 65 °, which is smaller than the area of the region. With such a form, the transparency of the screen 10 is improved, and the contrast and clarity of the image are improved.
Even in such a form, the screen 20 and the image display device 1 having high transparency and high image contrast can be obtained as in the first embodiment described above.

(Transformed form)
Not limited to each of the embodiments described above, various modifications and changes are possible, and these are also within the scope of the present invention.
(1) In each embodiment, a hard coat layer may be provided on the image source side (+ Z side) of the screens 10 and 20 for the purpose of preventing scratches. As the hard coat layer, for example, an ultraviolet curable resin having a hard coat function (for example, urethane acrylate or the like) is applied to the surface of the screens 10 and 20 on the image source side (the surface of the base material layer 11 on the image source side). It is formed by forming the film.
Further, not limited to the hard coat layer, a layer having appropriate necessary functions such as an antireflection function, an ultraviolet absorption function, an antifouling function, an antistatic function, etc., depending on the usage environment and purpose of use of the screens 10 and 20. May be provided by selecting one or more. Further, a touch panel layer or the like may be provided on the image source side (+ Z side) of the base material layer 11.
For example, when an antireflection layer is provided on the surface of the screens 10 and 20 on the image source side, in addition to suppressing the reflection of the image light when it is incident on the screen and increasing the amount of incident light of the image light, the reflection layer 13 A part of the light reflected by the screen is reflected on the surface of the screen on the image source side and emitted from the back side (-Z side), so that the observer O2 located on the back side can see a part of the image. Can also be prevented.

(2) In the first embodiment, the unit optical shape 121 shows an example in which the first surface 121a and the second surface 121b are formed by a flat surface, and in the second embodiment, the unit optical shape 221 is the first. The first surface 121a and the second surface 121b of the unit optical shape 121 and the unit optical shape 221 are not limited to the example in which the surface 221a and the second surface 221b of the unit optical shape 121 are formed by a curved surface. The first surface 221a and the second surface 221b may have a form in which a curved surface and a flat surface are combined, or may have a folded surface shape.
Further, in each embodiment, the unit optical shapes 121 and 221 may be polygonal shapes formed by a plurality of three or more surfaces.

(3) In each embodiment, the reflective layers 13 and 23 have been shown to be formed on the entire surfaces of the first surfaces 121a and 221a and the second surfaces 121b and 221b, but the present invention is not limited to this, and for example, the first surface. It may be formed on at least a part of the two surfaces 121b and 221b and the entire surface of the first surfaces 121a and 221a.
Further, in each embodiment, the first surfaces 121a and 221a and the second surfaces 121b and 221b are rough surfaces in which fine and irregular uneven shapes are formed, but the present invention is not limited to this. A form in which only the first surfaces 121a and 221a are rough surfaces may be used.

(4) In each embodiment, the screens 10 and 20 have a base material layer when the first optical shape layers 12 and 22 and the second optical shape layers 14 and 24 have sufficient thickness and rigidity. The form may not include the 11 and the protective layer 15, or may not include either one.
Further, in each embodiment, the screens 10 and 20 may have at least one of the base material layer 11 and the protective layer 15 as a plate-shaped member having light transmission such as a glass plate. At this time, the first optical shape layers 12, 22 and the like may be bonded to the glass plate and the like via the adhesive layer and the like.

(5) In each embodiment, the first optical shape layers 12 and 22 have linear Fresnel lens shapes in which unit optical shapes 121 and 221 extend in the left-right direction of the screen and are arranged in the vertical direction of the screen on the back side (-). It may be in the form of having it on the surface (Z side).

(6) In each embodiment, the screens 10 and 20 are colored with a dark colorant such as black or gray, and have a light absorbing layer (not shown) having a light absorbing property of absorbing a part of the incident light. You may have it. The light absorption layer may be located on the image source side (+ Z side) of the reflection layers 13 and 23, or may be located on the back side (−Z side) of the reflection layers 13 and 23. ..
By providing the light absorbing layers on the screens 10 and 20, stray light generated by external light incident on the screens 10 and 20 and traveling inside the screens 10 and 20 while being totally reflected at the interface between the surface of the screens 10 and 20 and the air. Can be absorbed, and the decrease in contrast of the image due to stray light can be suppressed.
Further, when the light absorption layer is located closer to the image source side than the reflection layers 13 and 23, the black brightness of the image can be reduced and the external light incident from the image source side can be absorbed to improve the contrast of the image. be able to. Further, when the light absorbing layer is located on the back side of the reflecting layers 13 and 23, it is possible to absorb the external light incident from the back side and improve the contrast of the image.
The above-mentioned light absorbing layer may be a transparent layer that does not contain a coloring material and has a light absorbing action.

(7) In each embodiment, the image source LS has been described with reference to an example in which the image source LS is located at the center of the screens 10 and 20 in the left-right direction of the screen and below the outside of the screen. , 20 may be arranged diagonally below the screens 10 and 20, and image light may be projected from the oblique light in the left-right direction of the screen with respect to the screens 10 and 20.
In each embodiment, the first optical shape layers 12 and 22 of the screens 10 and 20 have a circular Fresnel lens shape. Therefore, in the case of such a modified form, the position of the point C serving as the Fresnel center is shifted according to the position of the image source LS. When the first optical shape layers 12 and 22 of the screens 10 and 20 have a linear Fresnel lens shape, the unit optical shape is arranged in an inclined direction according to the position of the image source. Such a modified form can be applied.

(8) In each embodiment, the image source LS may project, for example, image light having a polarization component of a P wave.
At this time, the position and angle of the image source LS are set so that the image light is projected onto the screens 10 and 20 at an incident angle φ. This incident angle φ is (φb-10) ° or more when the incident angle (Brewster angle) at which the reflectance of the image light (P wave) projected on the screens 10 and 20 is zero is φb (°). It is set in the range of 85 ° or less. For example, when the incident angle φb at which the reflectance of the video light projected on the screens 10 and 20 becomes zero is 60 °, the incident angle φ of the video light is set in the range of 50 to 85 °.
In this way, by using the image source LS that projects the image light having the polarization component of the P wave, the specular reflection on the surface of the screens 10 and 20 is suppressed even when the incident angle φ to the screens 10 and 20 is large. This makes it possible to increase the degree of freedom in designing the projection system, such as the installation position of the image source LS. Further, by using such an image source LS, it is possible to reduce the reflection of the image light on the screen surface when it is incident on the screens 10 and 20, and it is possible to improve the brightness and sharpness of the image.
The angle φb (Brewster's angle) differs depending on the material of the surfaces of the screens 10 and 20 on which the image light is projected. Further, in such a form, a TAC sheet-like member is suitable as the base material layer 11 and the protective layer 15.

(9) In each embodiment, the screens 10 and 20 are joined (or partially fixed) to a support plate (not shown) to maintain their flatness, but the present invention is not limited to this, and for example, the screens 10 and 20 are shown. Reference numeral 20 denotes a form in which the four sides and the like are supported by a frame member (not shown) and the like, and the flatness thereof is maintained.

(10) In each embodiment, the image display device 1 is applied to a show window of a store or the like, but the present invention is not limited to this, and is not limited to this, for example, for indoor partitions, image display at exhibitions, and the like. Can also be applied. Further, the image display device 1 may be applied to an automobile head-up display (HUD: HEAD-Up Display) by attaching screens 10 and 20 to the windshield, or may be applied to vehicles other than automobiles. Good.

The embodiments and modifications can be used in combination as appropriate, but detailed description thereof will be omitted. Further, the present invention is not limited to the embodiments described above.

1 Video display device 10, 20 Screen 11 Base material layer 12, 22 First optical shape layer 121,221 Unit optical shape 121a, 221a First surface 121b, 221b Second surface 13,23 Reflective layer 14, 24 Second Optical shape layer 15 Protective layer LS image source

Claims (5)

A reflective screen that is transparent, reflects at least a part of the image light projected from the image source to display the image, and transmits a part of the image light.
An optical shape layer in which a plurality of unit optical shapes having light transmission and having a first surface on which image light is incident and a second surface facing the first surface and a second surface facing the first surface are arranged on the back surface side.
A rough surface formed on the back surface side of the unit optical shape along the first surface and the second surface, the surface of which has an irregular uneven shape, and a part of the incident light is the uneven shape. A reflective layer that has the function of diffuse-reflecting and partially transmitting
With
The plane passing through the point located on the backmost side of the second surface and the point located on the image source side of the second surface intersects with respect to the normal direction of the screen surface of the reflective screen.
The angle formed by the plane passing through the point located on the backmost side of the second surface and the point located closest to the image source side on the second surface in a direction parallel to the screen surface of the reflective screen is defined as θ2. When the angle θ2 is satisfied, 25 ° ≦ θ2 ≦ 65 ° is satisfied.
A reflective screen featuring. In the reflective screen according to claim 1,
The optical shape layer has a circular Fresnel lens shape in which a plurality of the unit optical shapes are concentrically arranged on the back surface side.
A reflective screen featuring. In the reflective screen according to claim 1 or 2.
Not having a light diffusing layer containing diffusing particles that have the effect of diffusing light,
A reflective screen featuring. In the reflective screen according to any one of claims 1 to 3.
It has light transmittance, is provided on the back surface side of the reflective layer, is laminated so as to fill the valley portion of the unevenness due to the unit optical shape, and is small enough to be regarded as having the same or equal refractive index as the optical shape layer. Provided with a second optical shape layer having a difference in refractive index,
A reflective screen featuring. The reflective screen according to any one of claims 1 to 4,
An image source that projects image light onto the reflective screen,
A video display device comprising.

Images