JP2012098525A - Reflection screen for stereoscopic image display, and stereoscopic image display system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reflection screen for stereoscopic image display and a stereoscopic image display system capable of displaying a clear stereoscopic image and having a high contrast and luminance.SOLUTION: A reflection screen 10 for stereoscopic image display reflects two polarized light beams L1 and L2 which are projected as video light beams and have mutually different polarizing directions, so as to observably display it. This reflection screen includes: a base material layer 12 having optical transparency; a resin layer 15 formed on the surface in the back side of the base material layer 12, and disposed with a plurality of light transmission parts 13 with optical transparency; and a reflective layer 17 formed at the back side with respect to the light transmission parts 13. The light transmission parts 13 are formed of ionizing radiation curable resin, and the base material layer 12 is defined to have an in-plane phase difference with little dispersion.

Description

  The present invention relates to a reflective screen for stereoscopic video display and a stereoscopic video display system.

Reflective screens that reflect image light and are observably displayed are widely used in conferences and home theaters for home use, and various reflective screens with improved contrast and brightness have been developed (for example, Patent Document 1).
In recent years, there has been an increasing demand for video display systems capable of displaying stereoscopic video (3D video), and various types of video display systems have been developed. Among these, there are wide-spread polarization display types that allow stereoscopic video to be observed by projecting left-eye video light and right-eye video light on the same screen and observing the video using polarized glasses. Are known.

JP 2008-40153 A

However, in the case of using the polarized light as the image light as described above, if the in-plane retardation of the layers constituting the reflection screen is large, the polarization state of the image light reflected and reaching the observer is changed within the screen. Uneven polarization unevenness occurs. If an image is observed in a state where this polarization unevenness has occurred, the stereoscopic image may be incomplete or unclear, and it may be difficult for the observer to observe the image.
In addition, there is a constant demand for a high-contrast and high-brightness image to be displayed even in a bright room environment where illumination light or the like is lit on the reflective screen.

  An object of the present invention is to provide a reflective screen and a stereoscopic image display system for displaying stereoscopic images that can display clear stereoscopic images and have high contrast and high brightness.

The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, it is not limited to this.
The invention according to claim 1 is a reflective screen for stereoscopic video display that reflects two polarized light beams (L1, L2) projected as video light and having different polarization directions so as to be observable, and is light transmissive. A resin layer (15) in which a plurality of light transmissive portions (13) having light transmissivity are arranged, and the light transmissive portion. A reflective layer (17) formed on the back side, wherein the light transmission part is formed of an ionizing radiation curable resin, and the base material layer has a small variation in in-plane retardation. A stereoscopic screen display reflective screen (10).
According to a second aspect of the present invention, in the reflective screen for stereoscopic image display according to the first aspect, the angle formed by the polarization directions of the two stacked polarizing plates is 0 at a position 1 m away from the observation surface of the reflective screen. A reflection screen for stereoscopic video display (10), characterized in that when the observation surface of the reflection screen is observed through the two polarizing plates while changing from ° to 90 °, uneven brightness is not visually recognized. is there.
According to a third aspect of the present invention, in the reflective screen for stereoscopic video display according to the first or second aspect, the light transmission portion (13) is observed in a cross section perpendicular to the screen surface, rather than the width on the back side. A substantially trapezoidal shape having a wider width on the surface side, arranged in a plurality along the screen surface, and the resin layer (15) is alternately formed with the light transmitting portion along the screen surface in the cross section, A reflective screen (10) for stereoscopic video display, comprising a light absorbing portion (14) having a refractive index lower than that of the light transmitting portion and absorbing light.

According to a fourth aspect of the present invention, in the reflective screen for stereoscopic image display according to any one of the first to third aspects, the reflective layer (17) reflects the image light substantially regularly. It is the reflective screen (10) for the stereoscopic video display characterized.
According to a fifth aspect of the present invention, in the reflective screen for stereoscopic video display according to any one of the first to fourth aspects, the light transmitting portion (13) is arranged so that the upper and lower sides of the screen when the reflective screen is in use. A reflective screen (10) for displaying a stereoscopic image, characterized by being arranged along a direction.

According to a sixth aspect of the invention, the stereoscopic image display reflective screen (10) according to any one of the first to fifth aspects and the first polarized light (L1) as the first video light. The first light source unit (P1) that projects the observation surface of the reflection screen for stereoscopic image display, and the second polarized light (L2) having a polarization direction different from the first polarized light as the second image light. A second light source unit (P2) that projects onto the observation surface of the stereoscopic image display reflecting screen, and the first polarized light reflected by the stereoscopic image display reflecting screen is transmitted and reflected for the stereoscopic image display. A first image transmission unit (51) that does not transmit the second polarized light reflected by the screen, and transmits the second polarized light reflected by the reflective screen for stereoscopic image display and transmits the second polarized light. The first deflection reflected by the reflection screen. A second image transmission part (52) that does not transmit the first image transmission part in front of one eye of the observer (O), and the second image transmission part is the other image of the observer. An observer puts on the eye so that the first polarized light transmitted through the first image transmission unit reaches one eye of the observer, and the second image transmission unit is A stereoscopic image display system comprising: polarized glasses (50) that allow the transmitted second polarized light to reach the other eye of the observer.
A seventh aspect of the present invention is the stereoscopic image display system according to the sixth aspect, wherein the first polarized light (L1) and the second polarized light (L2) are linearly polarized light and have polarization planes orthogonal to each other. This is a stereoscopic video display system characterized by that.

According to the present invention, the following effects can be obtained.
(1) The reflection screen for stereoscopic image display of the present invention reflects and displays two polarized light beams having different polarization directions projected as image light, and has a base layer having light transparency, The resin layer is formed on the back surface of the base material layer, and includes a resin layer in which a plurality of light transmitting portions having light transmittance are arranged, and a reflective layer formed on the back side from the light transmitting portion. The base material layer is formed of a radiation curable resin, and variation in in-plane retardation is small. Therefore, it is possible to reduce as much as possible the occurrence of unevenness in the polarization state of the two polarized lights (image light) reflected due to variations in the in-plane retardation of the base material layer. Therefore, a clear stereoscopic image can be displayed to an observer who wears polarized glasses and observes.

(2) Two reflective screens for displaying a stereoscopic image are displayed at a position 1 m away from the observation surface of the reflective screen while changing the angle formed by the polarization directions of the two stacked polarizing plates from 0 ° to 90 °. When the observation surface of the reflection screen is observed through the polarizing plate, unevenness in brightness is not visually recognized. Therefore, the reflection screen for stereoscopic video display has a small variation in the in-plane retardation of the base material layer, and can reduce the occurrence of unevenness in the polarization state of the two reflected polarized lights (video light) as much as possible.

(3) The light transmissive portion has a substantially trapezoidal shape in which the width on the observation surface side is wider than the width on the back surface side in a cross section orthogonal to the screen surface, and a plurality of the light transmission portions are arranged along the screen surface. In the cross section, a light absorbing portion is formed alternately with the light transmitting portion along the screen surface, and has a refractive index lower than that of the light transmitting portion and absorbs light. Accordingly, the reflective screen for stereoscopic image display can reflect the image light efficiently and display a high-luminance image, and absorbs unnecessary external light such as illumination light by the light absorption part, and in a bright room environment. Can display images with high contrast.

(4) Since the reflection layer reflects the image light substantially regularly, the polarization state of the two image lights can be maintained and a clear image can be displayed.

(5) Since the light transmission portions are arranged along the vertical direction of the screen in the usage state of the reflection screen for displaying stereoscopic images, generally, the light transmission portion generally efficiently absorbs external light incident from above the reflection screen. The contrast improvement effect can be enhanced.

(6) The video display system of the present invention includes a reflective screen for stereoscopic video display according to the present invention, a first light source unit that projects a first polarized light as the first video light, and a second light as the second video light. A second light source that projects a second polarized light having a polarization direction different from the first polarized light, and the first polarized light reflected by the reflective screen for stereoscopic video display and transmitted by the reflective screen for stereoscopic video display The first image transmitting unit that does not transmit the second polarized light, and the first polarized light that is transmitted by the second polarized light reflected by the reflective screen for stereoscopic video display and reflected by the reflective screen for stereoscopic video display A second image transmitting portion that does not transmit the first image transmitting portion, and the first image transmitting portion is disposed in front of one eye of the observer, and the second image transmitting portion is disposed in front of the other eye of the observer. And the first polarized light transmitted through the first image transmitting portion is viewed by the observer. To reach one eye of persons, in which and a polarization glasses to reach the observer's other eye a second polarized light transmitted through the second image transmitting unit. Therefore, a clear stereoscopic image can be displayed to the observer, and an image with high contrast and brightness can be displayed even in a bright room environment.

It is a figure which shows the three-dimensional video display system of embodiment. It is a figure which shows the reflective screen of embodiment. It is a figure which shows an example of the deformation | transformation form of a reflective screen.

Embodiments of the present invention will be described below with reference to the drawings.
In addition, each figure shown below including FIG. 1 is the figure shown typically, and the magnitude | size and shape of each part are exaggerated suitably for easy understanding.
In addition, the terms “plate”, “sheet”, “film” and the like are used, but these are generally used in the order of thickness, “plate”, “sheet”, “film”. I am using it. However, there is no technical meaning for such use. Accordingly, the terms “sheet”, “plate”, and “film” can be appropriately replaced.
Furthermore, numerical values such as dimensions and material names of each member described in the present specification are examples of the embodiment, and the present invention is not limited thereto, and may be appropriately selected and used.

(Embodiment)
FIG. 1 is a diagram illustrating a stereoscopic video display system according to the present embodiment. FIG. 1A is a perspective view of a stereoscopic video display system, and FIG. 1B is a diagram of the stereoscopic video display system viewed from above.
In FIG. 1, the interior illumination (external light source) G, the image sources P1 and P2, the reflective screen 10 for stereoscopic image display, etc. are schematically shown together, and therefore there are portions where the arrangement relationship is different from the actual, In addition, the incident angle of each light beam includes a portion different from the magnitude relationship in the description below.
The video display system includes a reflective screen 10 and video sources P1 and P2. The video lights L1 and L2 projected from the video sources P1 and P2 are reflected by the reflective screen 10, and an observation surface (video source) of the reflective screen 10 is displayed. P1 and P2 side) are displayed in an overlapping manner. Note that FIG. 1 shows an example in which the two video sources P1 and P2 are arranged in separate housings. However, the present invention is not limited to this. For example, two video sources are housed in one housing. You may use what is.

In the stereoscopic video display system of the present embodiment, video sources P1 and P2 that project video lights L1 and L2 are installed below a normal line passing through the center of the observation surface of the reflective screen 10 for stereoscopic video display, As shown in FIG. 1, the video light L <b> 1 and L <b> 2 are mainly projected in the front direction or obliquely upward. However, the present invention is not limited to this, and a video display system in which video sources P1 and P2 are arranged at positions where video light is projected horizontally with respect to the center of the reflective screen 10 may be used.
As shown in FIG. 1, the room illumination G is disposed above the interior of the room such as the ceiling. Unnecessary outside light emitted from the room illumination G is incident on the reflection screen 10 mainly from above. . The video display system and the reflective screen 10 according to the present embodiment are made in consideration of an environment in which ambient light or the like is incident mainly from above the reflective screen 10.

The video sources P1 and P2 are light source units that project the video lights L1 and L2 from the observer O side to the observation surface of the reflection screen 10, respectively. The video source P1 is a projector that projects left-eye video light L1, and the video source P2 is a projector that projects right-eye video light L2. Video lights L1 and L2 emitted from the video sources P1 and P2 are both linearly polarized light, and their polarization directions are orthogonal to each other. The left-eye video light L1 and the right-eye video light L2 have different viewing angles. The video source P1 may be a projector that projects right-eye video light, and the video source P2 may be a projector that projects left-eye video light.
As the video sources P1 and P2, for example, a liquid crystal projector may be used, or a CRT projector or the like provided with a polarizing plate (not shown) or the like at a video light emitting portion may be used.

The observer O wears the polarizing glasses 50 and observes the reflective screen 10. The polarizing glasses 50 include a left-eye transmission unit 51 and a right-eye transmission unit 52.
The left-eye transmission unit 51 transmits the left-eye video light L <b> 1 reflected by the reflection screen 10, and does not transmit the right-eye video light L <b> 2 reflected by the reflection screen 10. The right-eye transmission unit 52 transmits the right-eye video light L2 reflected by the reflection screen 10 and does not transmit the left-eye video light L1 reflected by the reflection screen 10. Each of the left-eye transmission unit 51 and the right-eye transmission unit 52 is a polarizing plate, and the polarization directions of polarized light that can be transmitted through each are orthogonal to each other.
By wearing the polarizing glasses 50, the right eye video light L2 reaches the right eye of the observer O, and the left eye video light L1 reaches the left eye of the observer O. Since the right eye of O observes only the image for the right eye reflected on the reflection screen 10, and the left eye of the observer O observes only the image for the left eye reflected on the reflection screen 10, the observer O In this case, an image displayed on the reflection screen 10 is observed as a stereoscopic image.

FIG. 2 is a diagram showing the reflective screen of the present embodiment. FIG. 2A shows an enlarged part of a cross section orthogonal to the screen surface of the reflective screen 10 and parallel to the vertical direction of the screen when the reflective screen 10 is used. FIG. 2B is a diagram of the reflective screen 10 viewed from the back side, and a back surface protective layer 18 described later is omitted.
Here, the screen surface indicates a surface in the plane direction of the reflection screen 10 when viewed as the reflection screen 10 as a whole, and the same definition is used in the present specification and claims. Used.
Further, in this specification, the screen vertical direction and the screen horizontal direction are the screen vertical direction (vertical direction) and the screen horizontal direction (horizontal direction) when the reflective screen 10 is used unless otherwise specified. .
Further, in this specification, the cross section of the reflective screen 10 in the vertical direction of the screen is perpendicular to the screen surface and is in the vertical direction of the screen when the reflective screen 10 is used, as shown in FIG. Parallel cross section.

The reflective screen 10 of this embodiment includes a resin layer 15 having a surface functional layer 11, a base material layer 12, a light transmission part 13, and a light absorption part 14 in order from the image sources P 1 and P 2 side (observation surface side). A shape layer 16, a reflective layer 17, and a back surface protective layer 18 are provided.
The surface functional layer 11 is a layer provided on the image sources P1 and P2 side (observation surface side) of the reflective screen 10. The surface functional layer 11 of the present embodiment has an anti-glare function and has a function of reducing the reflection (hot spot) of the image source.

  The base material layer 12 is a layer that becomes a base material necessary for forming the light transmitting portion 13 and is a sheet-like member having light transmittance. The base material layer 12 is provided on the back side of the surface functional layer 11 (on the side opposite to the image source side in the thickness direction of the reflective screen 10). The base material layer 12 preferably has a small variation in in-plane retardation, that is, a substantially uniform in-plane retardation within the screen of the reflective screen, from the viewpoint of displaying a clear stereoscopic image. Therefore, for example, the base layer 12 has substantially the same phase difference at the center of nine regions formed by dividing the base layer into three parts in the vertical direction of the screen and three parts in the horizontal direction of the screen. And it is preferable that the value of the phase difference is small.

The base material layer 12 of this embodiment is a sheet-like member created by extruding a polycarbonate (PC) resin, and the thickness thereof can be appropriately selected within a range of 100 to 188 μm. The base material layer 12 is not limited to this, and for example, an unstretched TAC sheet, unstretched PET (polyethylene terephthalate), unstretched PP (polypropylene), unstretched PE (polyethylene), unstretched A sheet made of stretched vinyl chloride or the like can be used. In addition, as a method for forming the sheet-like member used for the base material layer 12, a method in which molecular orientation and density distribution tend to be uniform, such as an extrusion coating method and an extrusion molding method, can be appropriately selected and used.
The base material layer 12 may be colored (tinted) with a dye or pigment such as gray that reduces the transmittance to a predetermined transmittance as necessary. In this case, since there is a possibility that a scattering effect is caused by particles such as dyes, the addition amount of the dyes and the like is not so large that the dispersion of the retardation of the base material layer affects the polarization state of the image. It is preferable to do. In addition, the base material layer 12 having a smaller phase difference is more preferable from the viewpoint of maintaining the polarization state of the image light.

The resin layer 15 is a layer having a light transmission part 13 and a light absorption part 14, and is provided integrally on the back side (back side) of the base material layer 12.
The light transmitting portion 13 has light transmittance, and has a substantially trapezoidal shape in which the width on the observation surface side is wider than the width on the back surface side in the cross section shown in FIG. (In FIG. 2, in the vertical direction of the screen) a plurality are arranged.
The light transmission part 13 of this embodiment is formed using the ultraviolet curable resin (refractive index 1.54) containing urethane acrylate and epoxy acrylate. The light transmitting portion 13 is not limited to an ultraviolet curable resin, but other ionizing radiation curable resins such as an electron beam curable resin, a photocurable resin that is effective when irradiated with light of a predetermined wavelength, and the like. May be used.

The light absorbing portion 14 is a portion having an action of absorbing light formed in a valley portion between adjacent light transmitting portions 13, and a cross-sectional shape in a cross section in the vertical direction of the screen is a substantially wedge shape. The substantially wedge shape includes a substantially triangular shape and a substantially trapezoidal shape. Accordingly, the cross-sectional shape of the cross section in the vertical direction of the screen of the light absorber 14 may be a substantially triangular shape or a substantially trapezoidal shape. The refractive index of the light absorbing portion 14 is smaller than the refractive index of the light transmitting portion 13.
As illustrated in FIG. 2A, the light transmission unit 13 and the light absorption unit 14 are alternately arranged in the vertical direction of the screen along the screen surface.
The light absorbing portion 14 of the present embodiment is an ultraviolet curable resin (for example, urethane acrylate, epoxy acrylate, etc.) containing light absorbing particles containing black pigment having an average particle diameter of about 6 μm as fine beads that absorb light. It is formed by wiping (squeezing) a tripropylene glycol diacrylate, methoxytriethylene glycol acrylate, etc. (refractive index of about 1.49) and curing. The ultraviolet curable resin used for the light absorbing portion 14 has a lower refractive index than the ultraviolet curable resin used for the light transmitting portion 13.

Further, the light absorbing portion 14 of the present embodiment has a slope angle (angle formed by the interface with the light transmitting portion 13 and the normal direction of the screen surface) of 9 °, and the top of the head has a plane having a width of 2 μm. The height of the light absorbing portion 14 (dimension in the thickness direction of the reflective screen 10) is 117 μm, the width of the light absorbing portion 14 on the most back side is 39 μm, and the light absorbing portion 14 and the light transmitting portion The arrangement pitch of the portions 13 is 65 μm. And the thickness (dimension in the thickness direction of the reflective screen 10 of the light transmissive part 13) of the resin layer 15 of this embodiment can be selected within the range of 120-180 micrometers.
In this embodiment, the average particle diameter of the light absorbing particles containing the black pigment is about 6 μm, but the average particle diameter is preferably about 1 to 10 μm. If it is smaller than that, scraping by wiping becomes difficult, and if it exceeds 10 μm, it becomes difficult to fill the gap between the light transmission parts 13.

The shaping layer 16 is a light-transmitting layer provided between the resin layer 15 and the reflective layer 17 and has a lenticular structure in which unit surface shapes 161 are arranged on the surface on the back side (the reflective layer 17 side). It has a lens shape.
As shown in FIG. 2B, the unit surface shape 161 is a partial shape of a substantially elliptical column shape that is convex on the back side, and a plurality of unit surface shapes 161 are arranged in the horizontal direction of the screen with the longitudinal direction being the vertical direction of the screen. . Accordingly, the unit surface shape 161 has a shape in which a cross-sectional shape of a cross section orthogonal to the screen surface and parallel to the horizontal direction of the screen extends in the vertical direction of the screen while maintaining the same shape.
The shaping layer 16 is formed by performing UV molding on the back surface of the resin layer 15 using an ultraviolet curable resin. In addition, the shaping layer 16 is not limited to the lenticular lens shape in which the unit lens shape (unit surface shape) is a partial shape of an elliptical cylinder, and the unit surface shape may be a substantially sine wave shape or have a different curvature. It is good also as a shape which consists of one curved surface, and it is good also as a shape which combined the plane and the curved surface like the waveform which is a substantially triangular waveform and the top part becomes a curved surface.
By appropriately selecting the shape on the back side of the shaping layer 16, the diffusibility of the reflected light in the horizontal direction can be made more preferable according to the position of the light source, the observation position, and the like. In order to give the reflected light directivity, the unit surface shape may be asymmetric in the left-right direction of the screen.

The reflection layer 17 is provided on the back side of the shaping layer 16, that is, on the surface of the unit surface shape 161, and the reflection surface has a shape along the shape of the lenticular lens of the shaping layer 16. The reflection layer 17 is formed by vapor-depositing a metal having high reflectivity such as aluminum, silver, or chromium, and has a function of substantially regular reflection (specular reflection) of the image light reaching the reflection layer 17. Yes. In the present embodiment, the reflective layer 17 is formed of an aluminum vapor deposition film.
Since the reflection layer 17 reflects the image light substantially regularly, the polarization plane of each irradiated image light can be maintained during reflection.
In addition, since the reflection layer 17 substantially reflects image light substantially regularly, it is combined with the shaping layer 16 having the shape of the lenticular lens in which the unit surface shapes 161 are arranged so that the diffusion action in the horizontal direction of the screen is diffused in the vertical direction of the screen It can be made larger than the action. Therefore, the viewing angle in the horizontal direction can be widened.
Since the reflective screen 10 can control the shape of the reflective surface by the shape of the shaping layer 16 on the back side, the viewing angle of the reflective screen 10 in the left-right direction of the screen can be controlled more finely.
The arrangement direction of the unit surface shapes 161 may be a vertical direction, a direction that forms an angle with respect to the horizontal direction, or a unit surface according to the environment in which the reflective screen 10 is used, desired optical characteristics, and the like. The cross-sectional shape of the shape 161 can also be selected as appropriate, such as a sine wave shape, a triangular wave shape, or an arc shape.

The back surface protective layer 18 is a layer provided on the most back side (back side) of the reflective screen 10 and is a layer that protects the back surface of the reflective screen 10 from scratches and the like. The back surface protective layer 18 may be formed by using a sheet-like member such as PET resin, or by applying an ultraviolet curable resin to the back side of the reflective layer 17 of the reflective screen 10 and curing it by irradiating ultraviolet rays. May be.
In addition, this back surface protective layer 18 provides a light absorbing action by using a sheet-like member containing a black pigment or the like, or by laminating a black cloth or the like on the back side, thereby providing a reflective screen. The incidence of external light from the back surface side of 10 can be prevented.
The back surface protective layer 18 of the present embodiment uses a sheet-like member containing a black pigment, and is affixed to the back side of the reflective layer 17 by a bonding layer (not shown).

As shown in FIG. 2A, the image light projected from the image sources P 1 and P 2 enters the reflection screen 10, passes through the surface functional layer 11 and the base material layer 12, and proceeds to the resin layer 15. In FIG. 2A, the refractive index of the surface functional layer 11, the base material layer 12, the light transmitting portion 13, and the shaping layer 16 is shown to be equal for easy understanding.
Part of the image light (light L3) having a small incident angle with respect to the screen surface is transmitted through the light transmitting portion 13 and the shaping layer 16, is substantially regularly reflected by the reflective layer 17, and is directed to the observer O side as an observable light beam. move on. Further, a part of the image light (light L4) incident on the screen surface at an incident angle larger than the light L3 is totally reflected at the interface between the light transmitting portion 13 and the light absorbing portion 14 to form the shaping layer 16. The light passes through the reflection layer 17 side, is reflected by the reflection layer 17, and is totally reflected again at the interface between the light transmission unit 13 and the light absorption unit 14.

On the other hand, the external light G1 from the room lighting G provided above the reflection screen 10 has a larger incident angle with respect to the reflection screen 10 (resin layer 15) than the image lights L3 and L4. The incident angle at the interface between the light absorbing portion 13 and the light absorbing portion 14 becomes small, and there are many components that do not exceed the critical angle, so that a large amount of light enters the light absorbing portion 14 and is absorbed without being totally reflected. As a result, the rate at which external light is reflected and reaches the observation position can be greatly reduced, and the reduction in contrast due to external light can be greatly reduced.
Moreover, since the back surface protective layer 18 also absorbs external light G2 from the back surface side of the reflective screen 10, the effect of improving contrast can be enhanced.

The reflective screen 10 has a structure in which layers made of resin or the like are laminated. In addition, the image light emitted from the image sources P1 and P2 is linearly polarized light. Accordingly, when a phase difference is caused by each layer while entering the reflecting screen 10, being reflected by the reflecting layer 17, and again emitted from the reflecting screen 10, this phase difference affects the display of a stereoscopic image.
Here, even if a phase difference is caused by the reflection screen 10, the phase difference is uniform in the screen, and the polarization states of the reflected light of the right-eye video light and the left-eye video light are aligned. There is no problem in displaying stereoscopic images.
However, if the phase difference greatly varies in the screen of the reflective screen 10, the polarization state of the observed image light varies, and the observer O cannot see the stereoscopic image or the stereoscopic image is partially displayed. It becomes incomplete.
The light transmitting portion 13 and the shaping layer 16 of the reflective screen 10 are formed of an ultraviolet curable resin or the like, and are not stretched at the time of molding, so that in-plane retardation is unlikely to occur. However, when a film or the like stretched on the base material layer 12 is used, the in-plane retardation of the base material layer 12 varies in the screen depending on the stretching direction, the chamfering method of the base material layer 12, and the like. Cheap. This variation in the in-plane phase difference causes the aforementioned incomplete stereoscopic image. Therefore, the base material layer 12 preferably has a small variation in in-plane retardation.

Here, the reflection screen 10 of the present embodiment and the reflection screen of the comparative example (not shown) are prepared, the phase difference variation is evaluated, and the image light is actually projected from the image sources P1 and P2 to form a three-dimensional image. The images were observed to evaluate the quality of the images.
The reflective screen of the comparative example has substantially the same form as the reflective screen of the present embodiment except that the base material layer is different from the reflective screen 10 of the present embodiment. The base material layer of the reflective screen of the comparative example is a sheet-like member made of PET resin, and is formed into a sheet by being biaxially stretched at the time of molding. Therefore, the substrate layer of the reflective screen of the comparative example has a variation in in-plane retardation, and the variation of the in-plane retardation is larger than that of the substrate layer 12 of the reflective screen 10 of the embodiment.

(Evaluation of phase difference variation)
The image light of the white screen is projected from the image source located in the front direction of the screen surface to the reflection screen 10 of the embodiment and the reflection screen of the comparative example, and the two polarizing plates are changed in the polarization direction. The screen was observed through the polarizing plate, and the in-plane phase difference variation was evaluated based on whether or not unevenness in the brightness (light intensity) of the observed image was generated.
The in-plane phase difference variation is evaluated at a position 1 m away from the center of the screen of each reflecting screen, the front direction of the screen (normal direction of the screen surface) is 0 degree, and the horizontal direction of the screen is + 60 ° to −60 °. (In the horizontal direction of the screen, the right side is the + direction) every 5 °, and in the vertical direction of the screen, in the range of + 15 ° to −15 ° (the upper direction in the vertical direction is the + direction) every 5 °. Went to.

The evaluator observes the screen through two stacked polarizing plates at each evaluation position. At this time, the evaluator changes the angle formed by the polarization directions of the two polarizing plates from 0 ° to 90 ° by rotating one polarizing plate or the like.
And when the unevenness of the brightness (light intensity) does not occur on the screen surface observed through the two polarizing plates, the reflection screen has no in-plane phase difference variation or the variation is small, It evaluates that it is favorable as a reflective screen which does not have polarization unevenness and projects polarized light to display a stereoscopic image. In addition, when unevenness in brightness occurs on the screen surface observed through two polarizing plates, the reflective screen has uneven polarization due to variations in in-plane phase difference, and polarized light is projected to display a stereoscopic image. It is evaluated that it is not suitable for use as a reflective screen.

The reflective screen of the comparative example has uneven brightness on the screen surface observed through the two polarizing plates at most evaluation positions, the in-plane variation of the retardation of the base material layer is large, and polarized light is projected. It was not suitable for use as a reflective screen for displaying stereoscopic images.
On the other hand, the reflective screen 10 of the embodiment has a brightness unevenness on the screen surface observed through the two polarizing plates at any evaluation position, and displays a stereoscopic image by projecting polarized light. As good.

(Video evaluation)
Next, the reflective screen 10 of this embodiment and the reflective screen of the comparative example were placed in a bright room environment, image light was projected from the image sources P1 and P2, and the image was observed from the front direction of the screen.
In the reflective screen of the comparative example, the phase difference of the polarization of the image light varies, and a portion of the stereoscopic image is incomplete or unclear. This also made it difficult for the observer to observe the video.
On the other hand, the reflection screen 10 of the present embodiment has a small variation in the polarization of the image light, a clear and clear stereoscopic image is observed, and the observer does not feel difficult to observe the image.

From the above, according to the present embodiment, a clear and clear stereoscopic image can be displayed.
Moreover, according to this embodiment, since the resin layer 15 includes the light transmission part 13 and the light absorption part 14, it is possible to display an image with high contrast and high brightness even in a bright room environment.
Furthermore, according to the present embodiment, no special material or the like is used, and since the base material layer 12 using a relatively inexpensive PC resin is used as the resin material used for the optical product, the production cost is reduced. It is possible to provide a reflective screen and a stereoscopic image display apparatus that can suppress, inexpensive, and display clear stereoscopic images.
In addition, not only when displaying a stereoscopic image, but also by projecting image light not intended for stereoscopic image display onto a reflective screen 10 from a general-purpose projector or the like, and displaying a two-dimensional image as a conventional general reflective screen. It is possible to display an image having high contrast and brightness even in a bright room environment.

(Deformation)
The present invention is not limited to the embodiment described above, and various modifications and changes are possible, and these are also within the scope of the present invention.
(1) In the present embodiment, the reflection layer 17 is formed by vapor-depositing a metal having a high reflectance such as aluminum, silver, chromium, but the present invention is not limited thereto. You may form by carrying out the gravure coating of the silver type (metallic) paint which has high reflectivity so that the whole back surface (back surface of the resin layer 15) may be covered. At this time, the reflective layer 17 is not limited to the gravure coating, and a forming method such as gravure reverse coating, screen printing, and inkjet coating can be used. At this time, the thickness of the reflective layer is about 20 μm. The reflective layer may be coated with metal powder such as aluminum.
In general, a reflective screen is also known in which the reflective layer is formed using a white paint that diffusely reflects image light and no shaping layer is provided. The reflection layer formed using such a white paint has a longer penetration length for the image light to enter the reflection layer than the reflection layer 17 of the present embodiment, and therefore there is a phase shift due to internal diffusion. As a result, the variation in the in-plane phase difference is increased, and the polarization state of each reflected light is uneven. For this reason, as shown in the present embodiment, the reflective layer is preferably made of a metal vapor-deposited film or silver-based paint that is substantially specularly reflected (specularly reflected).

(2) In the present embodiment, the image lights L1 and L2 projected from the image source are linearly polarized light whose polarization directions are orthogonal to each other. However, the present invention is not limited to this. For example, the image light is elliptically polarized light. Alternatively, circularly polarized light having a different rotation direction may be used.

(3) In the present embodiment, the reflective screen 10 may be a reflective screen that can be wound and stored on a winding core in a storage unit (not shown) provided at the top or bottom of the reflective screen when not in use.
Further, when the reflective screen 10 is a fixed reflective screen that cannot be wound, the reflective screen 10 may be attached to a support plate, a white board, a wall surface, or the like (not shown). Note that the back surface protective layer 18 may be omitted when the support plate or the like is black or when it is not necessary to consider the influence of external light from the back surface side.

(4) In this embodiment, as shown in FIG. 2, the light absorption unit 14 and the light transmission unit 13 have a cross-sectional shape perpendicular to the screen surface and parallel to the screen vertical direction. (The arrangement direction of the portion 13 and the light absorption portion 14) is a symmetrical shape, but may be an asymmetric shape, or the interface between the light transmission portion 13 and the light absorption portion 14 along the arrangement direction and the screen surface. It is good also as a shape etc. in which the angle which the normal line direction makes changes gradually or in steps. Moreover, the shape of the light transmission part 13 is good also as a shape which combined the curved surface and the plane.

(5) In the present embodiment, the back side surface of the light transmission unit 13 is an example of a substantially smooth surface. However, the present invention is not limited to this. For example, the back side surface (upper bottom surface) of the light transmission unit 13 may be used. A plurality of fine lines extending in the arrangement direction (up and down direction of the screen) of the light transmission part 13 and the light absorption part 14 may be provided (hairline processing). Such a streak can be formed by rubbing the back side surface of the light transmission part 13 with sandpaper or the like, for example.
By setting it as such a form, even if it does not provide a shaping layer, the spreading | diffusion effect | action of the screen left-right direction can be improved, and the viewing angle of a horizontal direction can be expanded.

(6) In this embodiment, although the resin layer 15 showed the example provided with the light transmissive part 13 and the light absorption part 14, it is not restricted to this, For example, the resin layer 15 is ultraviolet-rays based on the base material layer 12 It is good also as a form which has the linear Fresnel lens shape etc. in which the unit lens 251 formed with the curable resin etc. was arranged in multiple numbers on the back side.
FIG. 3 is a diagram illustrating an example of a modification of the reflective screen.
The reflective screen 20 in a modified form includes a surface functional layer 11, a base material layer 12, a resin layer 25, a reflective layer 27, and a back surface protective layer 28 in order from the observation surface side. The reflective screen 20 in this modified form reflects the image light projected from above by the reflective layer 27 and displays it on the observation surface.
The resin layer 25 has a linear Fresnel shape in which a plurality of unit lenses 251 are arranged on the back side of the resin layer 25 in the vertical direction of the screen. The reflection layer 27 has a function of substantially regular reflection of image light, and is formed on the lens surface of the unit lens. In the reflective screen 10, the back surface protective layer 28 provided on the back side of the reflective layer 27 may be black and may have a function of absorbing external light from the back side.
The shape is not limited to the linear Fresnel lens shape, and for example, a circular Fresnel lens shape in which unit lenses are arranged concentrically may be used. Moreover, it is good also as what arrange | positions the up-down direction of the reflective screen 20 of said deformation | transformation reversely, projects image light from below, and uses it.

(7) In the present embodiment, the light absorbing portion 14 is formed of an ultraviolet curable resin containing black beads. However, the present invention is not limited to this. For example, the light absorbing portion 14 is black in the gap portion between the light transmitting portions 13. In order to uniformly fill the beads and fix the black beads, a protective layer may be formed on the back side of the resin layer 15 using an ultraviolet curable resin or the like.
Alternatively, the light absorbing portion 14 may not be formed, and the groove portion between the light transmitting portions 13 may be left as a gap. In the reflection screen having such a configuration, external light incident on the reflection screen at an incident angle larger than that of the image light from above the screen is reflected by the reflection layer and emitted to the lower side of the screen, and the image light is transmitted through the light transmission unit 13. And is reflected back to the viewer side by total reflection at the interface between the gap and the gap.

(8) In the present embodiment, the example in which the surface functional layer 11 is provided on the observation surface side (image source side) of the base material layer 12 is shown, but not limited thereto, for example, the observation surface side of the base material layer 12 It may be formed by coating the surface directly.
Moreover, in this embodiment, although the surface functional layer 11 showed the example provided with an anti-glare function, it is not restricted to this, For example, an antireflection function, an antifouling function, an ultraviolet absorption function, a hard-coat function, an antistatic function Etc., etc. may be appropriately selected or combined. Thereby, the functionality and convenience of the reflective screen 10 can be improved.

  In addition, although this embodiment and modification can also be used in combination as appropriate, detailed description is abbreviate | omitted. Further, the present invention is not limited by the above-described embodiments and the like.

DESCRIPTION OF SYMBOLS 10 Reflective screen 11 Surface functional layer 12 Base material layer 13 Light transmission part 14 Light absorption part 15 Resin layer 16 Shaping layer 17 Reflection layer

Claims (7)

A reflective screen for stereoscopic image display that reflects two polarized light beams having different polarization directions projected as image light and displays the image in an observable manner,
A substrate layer having optical transparency;
A resin layer formed on the back side surface of the base material layer, in which a plurality of light transmitting portions having light transmittance are arranged;
A reflective layer formed on the back side from the light transmitting portion;
With
The light transmission part is formed of an ionizing radiation curable resin,
The base material layer has a small in-plane retardation variation,
Reflective screen for displaying stereoscopic images. The reflective screen for stereoscopic video display according to claim 1,
The observation surface of the reflection screen is passed through the two polarizing plates while changing the angle formed by the polarization directions of the two overlapping polarizing plates from 0 ° to 90 ° at a position 1 m away from the observation surface of the reflection screen. When observing, uneven brightness is not visible,
Reflective screen for displaying stereoscopic images. In the reflective screen for stereoscopic video display according to claim 1 or 2,
The light transmissive portion has a substantially trapezoidal shape in which the width on the observation surface side is wider than the width on the back surface side in a cross section orthogonal to the screen surface, and a plurality of the light transmission portions are arranged along the screen surface.
The resin layer is formed alternately with the light transmission portion along the screen surface in the cross section, and includes a light absorption portion that absorbs light with a lower refractive index than the light transmission portion;
Reflective screen for displaying stereoscopic images. In the reflective screen for stereoscopic video display according to any one of claims 1 to 3,
The reflective layer reflects the image light substantially regularly;
Reflective screen for displaying stereoscopic images. In the reflective screen for stereoscopic video display according to any one of claims 1 to 4,
The light transmissive portions are arranged along the vertical direction of the screen in the usage state of the reflective screen;
Reflective screen for displaying stereoscopic images. A reflective screen for stereoscopic video display according to any one of claims 1 to 5,
A first light source unit that projects first polarized light as first image light onto an observation surface of the reflective screen for stereoscopic image display;
A second light source unit that projects second polarized light having a polarization direction different from that of the first polarized light onto the observation surface of the stereoscopic image display reflecting screen as second image light;
A first video transmission unit that transmits the first polarized light reflected by the reflective screen for stereoscopic video display and does not transmit the second polarized light reflected by the reflective screen for stereoscopic video display; A second video transmission unit that transmits the second polarized light reflected by the reflective screen for displaying video and does not transmit the first polarized light reflected by the reflective screen for displaying stereoscopic images. The viewer wears the first image transmitting portion so that the first image transmitting portion is disposed in front of one eye of the observer and the second image transmitting portion is disposed in front of the other eye of the observer. Polarized glasses that cause the first polarized light transmitted through the first part to reach one eye of the observer and the second polarized light transmitted through the second image transmitting part to reach the other eye of the observer ,
3D image display system. The stereoscopic image display system according to claim 6,
The first polarized light and the second polarized light are linearly polarized light and have polarization planes orthogonal to each other;
3D video display system.

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