KR20060033704A - Contrast improving sheet and rear projection screen provided with the same - Google Patents

Abstract

A contrast improving sheet disposed on the observation-side front surface of a display device, such as a rear projection display or a liquid crystal display, high in contrast and superior in directivity; and a rear projection screen having the same. A contrast improving sheet (11) is provided with a first optical element (1) and a second optical element (2) disposed on the observation side of the first optical element (1). The first optical element (1) has a plurality of ribs (3) arranged in one direction or planarly. Each rib (3) has a pair of mutually opposed total reflection surfaces (5) for totally reflecting image light (4) which substantially vertically falls thereon from the back side, and a flat surface (6) formed to connect these opposed total reflection surfaces (5) on the light outgoing side. Further, a light absorption layer (7) is formed in the V-shaped groove between ribs (3). The second optical element (2) has an optical path correcting layer (9) for correcting the optical path of image light totally reflected by the total reflection surface of each rib of the first optical element (1) so as to cause the image light to go out substantially perpendicularly to the observation side. The optical path correcting layer (9) has a plurality of inclined surfaces (8) disposed in zigzags in order to cause the image light (4) which is totally reflected by the total reflection surface (5) of each rib (3) of the first optical element (1) to go out substantially perpendicularly.

Description

CONTRAST IMPROVING SHEET AND REAR PROJECTION SCREEN PROVIDED WITH THE SAME}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a contrast enhancement sheet disposed on the front side of an observation side of a display display device such as a rear projection display, a liquid crystal display, a plasma display, a CRT display, and a rear projection screen having the same. As used herein, the "contrast enhancement sheet" refers to an optical element that improves contrast in a display display device in which it is assembled by suppressing a reduction in contrast due to external light, stray light, or the like.

BACKGROUND In display display devices such as a rear projection type display or a liquid crystal display, various methods have been proposed for enhancing the contrast so that an observer can fully recognize an image while achieving a viewing angle.

Specifically, the convex lens element is disposed as a light diffusing element on the rear side (image light source side) on which the image light is incident as the first optical element, and the observation side where the image light passing through the convex lens element does not pass. It is proposed to arrange | position a light absorption element in a non-transmissive part so that the external light which injects from an observation side may be absorbed by the said light absorption element.

Further, as the second optical element, a plurality of ribs (ribs having an inclined surface formed between the inclined surface and the inclined surface that totally reflects light) are formed on the observation side as the light diffusing element, and between the adjacent ribs. It is proposed that a light absorbing material is filled in a V-shaped groove of the light absorbing material so that external light incident on the observation side is absorbed by the light absorbing material (Japanese Patent Application Laid-Open No. 50-121753 and Japanese Patent Laid-Open No. 60-159733). See the Gazette publication.

However, in the first optical element described above, although a certain effect is obtained with respect to the enhancement of the contrast, parallel light incident perpendicularly to the optical element is diffused and emitted from the convex lens element which is the light diffusion element. However, it cannot be used for optical elements that require directivity. Moreover, in this optical element, since the convex lens element on the back side and the light absorbing portion on the observation side must cope one-to-one, there is a problem that manufacturing becomes remarkably difficult when the pitch of the lens is small.

On the other hand, also in the above-described second optical element, light emitted from the observation side is light in three directions (light in one direction that is not reflected from the inclined surface of the rib and exits from the emission surface in the front direction, and on each of the inclined surfaces opposite to the rib). After being totally reflected, the light is divided into two directions of light emitted at two specific angles from the emission surface. Therefore, in order to obtain a uniform image in this second optical element, a large amount of light diffusing agent must be added to the rib through which light passes. By virtue of the sharpness of the sharpness, it could not be used for optical elements that require directivity.

SUMMARY OF THE INVENTION The present invention has been invented in view of such a point, and in a contrast enhancement sheet disposed on the front side of an observation side of a display display device such as a rear projection type display or a liquid crystal display, a contrast enhancement sheet having high contrast and excellent directivity and a rear surface having the same It is an object to provide a projection screen.

The contrast enhancement sheet according to the first embodiment of the present invention for achieving the above object is a rear surface of the contrast enhancement sheet disposed on the front side of the observation side of a display display device such as a rear projection display, a liquid crystal display, or a plasma display. And stray light incident at an oblique angle from the back side while emitting image light incident vertically or substantially vertically from the side (hereinafter only referred to as " approximately vertical ") to the observation side regardless of the incident position. And an optical element for absorbing external light incident from the observation side.

In the contrast enhancement sheet according to the first embodiment of the present invention configured as described above, as shown in FIG. 15, (1) the image light 4 that is incident substantially perpendicularly from the rear side of the contrast enhancement sheet 11 is It is emitted to the viewing side substantially vertically (parallel to the granular light). In addition, (2) the external light 41 incident vertically or obliquely from the observation side of the contrast improving sheet 11 is absorbed or transmitted to the back side and is not returned to the observation side. (3) Light 42 made of stray light incident at an angle of about 30 ° or more from the rear side of the contrast improving sheet 11 is absorbed and is not transmitted to the observation side. By the above three operations (1) to (3), the image light incident on the rear side can be transmitted to the observation side with high directivity without loss, and can absorb stray light and external light. Therefore, unlike conventional lenticular lens sheets for improving contrast, the optical light and the imaging system have directivity because they hardly diffuse the image light and are transmitted to the observation side with high directivity. Can be used for optical elements, etc.). On the other hand, as shown in Fig. 16, in the conventional lenticular lens sheet 43, the image light 4 which enters substantially vertically from the rear side and enters at an angle of about 30 ° or more from the rear side Light 42 that becomes stray light is diffused and emitted to the observation side.

On the other hand, in the contrast enhancing sheet according to the first embodiment of the present invention, the optical element is a first optical element having a plurality of ribs arranged in one direction or planarly, wherein each of the ribs is incident substantially perpendicularly from the rear side. A first optical element having a light absorbing layer formed between the ribs, and having a total reflection surface facing each other that totally reflects the image light, and a flat surface formed so as to connect the opposite reflection total reflection surfaces to each other at the emission surface; And a second optical element stacked on the observation side of the first optical element, the optical path correction layer for correcting the optical path of the image light totally reflected by the total reflection surface of each rib to emit the image light approximately perpendicular to the observation side. It is preferred to have a second optical element. The optical path correction layer of the second optical element may have a plurality of inclined surfaces formed to be different from each other so that the image light totally reflected by the total reflection surface of each rib of the first optical element is emitted substantially vertically. Do.

In the contrast enhancement sheet according to the first embodiment of the present invention configured as described above, the total reflection surface of each rib of the first optical element is totally reflected from the rear side and passes through the flat surface. One image light is refracted at each inclined plane included in the optical path correction layer of the second optical element and is emitted substantially perpendicularly from the second optical element. Also, among the image light incident on the back side substantially vertically, the image light passing through the flat surface without being reflected by the total reflection surface of each rib of the first optical element is used at each inclined surface included in the optical path correction layer of the second optical element. After being totally reflected, it is refracted on the inclined surface opposite thereto and exits approximately vertically from the second optical element. Accordingly, the light absorption layer of the first optical element absorbs stray light and external light, and corrects the optical path of the image light totally reflected on the total reflection surface of each rib of the first optical element by the optical path correction layer of the second optical element. Since the light is emitted substantially perpendicular to the observation side, and the image light passing through the flat surface without being reflected at the total reflection surface of each rib of the first optical element is also emitted perpendicularly perpendicular to the observation side, problems of opacity of the image, etc. It is possible to improve the contrast and to achieve high directivity by preventing the occurrence of?

Here, in the contrast enhancement sheet according to the first embodiment of the present invention, each of the inclined surfaces included in the optical path compensation layer of the second optical element is the first optical element of the image light which is incident substantially perpendicularly from the rear side. Light that passes through a flat surface without being reflected at the total reflection surface of each of the ribs, is totally reflected at each of the inclined surfaces, and is refracted and emitted from the inclined surface opposite thereto, and each of the ribs of the first optical element of the image light It is preferable that the light that is totally reflected at the total reflection surface of and passes through the flat surface is refracted and emitted from the respective inclined surfaces so as to be substantially parallel.

Further, in the contrast enhancing sheet according to the first embodiment of the present invention, the light absorbing layer of the first optical element includes light absorbing particles in a transparent material having a lower refractive index than the material forming the rib of the first optical element. It is preferable to contain. The light absorbing layer of the first optical element is preferably made of colored material having a lower refractive index than the material forming the rib of the first optical element. Accordingly, the light absorbing layer having the above structure effectively absorbs not only external light incident from the observation side, but stray light incident from the rear side at an angle of about 30 ° or more, without total reflection on the total reflection surface of the first optical element. The contrast can be further improved.

According to the contrast improving sheet according to the first embodiment of the present invention, the inclination angle (angle with respect to the direction orthogonal to the sheet surface of the second optical element) of the inclined surfaces of the optical path compensation layer of the second optical element is determined. θ ₂ , the refractive index of the material of the portion of the optical path compensation layer located on the side of the first optical element with respect to the respective inclined surfaces is n ₂ And n ₃ / n ₂ = cos (3θ ₂ ) / cosθ ₂ when the refractive index of the material of the portion of the optical path compensation layer positioned on the opposite side of the first optical element is n ₃ at the boundary. It is desirable to satisfy. Accordingly, the image light which passes through the flat surface without being reflected from the total reflection surface of each rib of the first optical element and is incident substantially perpendicularly from the rear side, is emitted more reliably vertically (ie parallel to the incident light) to the viewing side. You can do it. As a result, high directivity can be realized.

According to the contrast improving sheet according to the first embodiment of the present invention, the inclination angle (angle with respect to the direction orthogonal to the sheet surface of the first optical element) of the total reflection surface of each rib of the first optical element is θ ₁ A refractive index of the material forming the rib of the first optical element n ₁ , and an inclination angle of each inclined surface of the optical path compensation layer of the second optical element (an angle with respect to a direction orthogonal to the sheet surface of the second optical element) N ₂ · sin (2θ ₂ ) = n ₁ · sin when θ ₂ and the refractive index of the material of the portion located on the side of the first optical element with respect to the respective inclined surfaces of the optical path compensation layer are n ₂ . It is preferable to satisfy the relationship of (2θ ₁ ). Accordingly, the image light incident on the rear surface side and vertically reflected on the total reflection surface of each rib of the first optical element and passing through the flat surface is refracted on each inclined surface of the optical path compensation layer of the second optical element for more reliable observation. It can be emitted perpendicularly to the side (that is, parallel to the incident light). As a result, high directivity can be realized.

On the other hand, in the contrast enhancing sheet according to the first embodiment of the present invention, when the ribs constituting the second optical element are arranged in one direction, the ribs constituting the second optical element are oriented in one direction so as to be parallel thereto. When arranged in a planar arrangement, it is preferable that the planar arrangement so as to be parallel to it.

The rear projection screen according to the second embodiment of the present invention is a rear projection type screen for displaying an image by emitting the image light projected from the rear side to the observation side, wherein the image light projected from the rear side is approximately perpendicular to the observation side. And a contrast enhancement sheet according to the first embodiment of the present invention described above, which is disposed on the observation side of the Fresnel lens sheet.

According to the rear projection screen according to the second embodiment of the present invention as described above, the Fresnel lens sheet for deflecting the image light projected from the rear side substantially vertically toward the observation side, and the first embodiment of the present invention described above By combining the contrast enhancing sheet according to the present invention, it is possible to provide a rear projection screen having high contrast and excellent directivity.

In addition, the rear projection screen according to the third embodiment of the present invention is a rear projection screen for displaying an image by emitting the image light projected from the rear side to the observation side, the image light projected from the rear side toward the observation side A fresnel lens sheet for deflecting substantially vertically, a lenticular lens sheet disposed on an observation side of the Fresnel lens sheet and diffusing image light, and the present invention described above disposed on an observation side of the lenticular lens sheet. It is characterized by comprising a contrast enhancing sheet according to the first embodiment of the present invention.

According to the rear projection screen according to the third embodiment of the present invention configured as described above, in the second embodiment of the present invention described above, since the lenticular lens sheet is further provided, a rear projection screen having a wide viewing angle can be provided. Will be.

On the other hand, in the rear projection screen according to the third embodiment of the present invention, the lenticular lens sheet has a light absorption layer on the observation side, and the contrast enhancement sheet is at least on the lenticular lens sheet in the light absorption layer. It is preferable to adhere | attach. Accordingly, even when the lenticular lenses of the lenticular lens sheet are arranged at a short pitch, it is possible to provide a rear projection screen having excellent rigidity.

The rear reflection type screen according to the fourth embodiment of the present invention is a rear projection type screen which displays an image by emitting the image light projected from the rear side to the observation side, and the observation side of the image light projected at an oblique angle from the rear side. A Fresnel lens sheet which is deflected substantially vertically toward the front side, wherein the total reflection Fresnel lens is formed on the rear side thereof, and the Fresnel lens sheet having the contrast enhancement sheet according to the first embodiment of the present invention described above on the observation side; And a lenticular lens sheet disposed on an observation side of the Fresnel lens sheet to diffuse image light.

According to the rear projection type screen according to the fourth embodiment of the present invention configured as described above, in the rear projection type screen having the Fresnel lens sheet having the total reflection Fresnel lens on the rear side, the double image due to stray light or mirror reflection can be greatly reduced. Will be.

1 is a partial cross-sectional view showing a contrast improving sheet according to an embodiment of the present invention;

2 is a ray tracing diagram for explaining an optical path of light in the contrast enhancement sheet shown in FIG. 1;

3 is a view showing an example of the arrangement of the ribs of the first optical element in the contrast enhancement sheet according to the embodiment of the present invention;

4 is a view showing another example of the arrangement form of the ribs of the first optical element in the contrast enhancement sheet according to the embodiment of the present invention;

FIG. 5 is a view showing an example of a lamination form of a first optical element and a second optical element in a contrast enhancing sheet according to an embodiment of the present invention; FIG.

6 is a view showing another example of a lamination form of a first optical element and a second optical element in the contrast enhancement sheet according to the embodiment of the present invention;

7 is a view showing another example of a lamination form of a first optical element and a second optical element in the contrast enhancement sheet according to the embodiment of the present invention;

8 is a perspective view showing one example of a rear projection screen having a contrast enhancing sheet according to one embodiment of the present invention;

9 is a perspective view showing another example of a rear projection screen having a contrast enhancing sheet according to one embodiment of the present invention;

10 is a partial cross-sectional view showing a contrast improving sheet according to another embodiment of the present invention;

11 is a perspective view showing one example of a rear projection screen having a contrast enhancing sheet according to another embodiment of the present invention;

12 is a perspective view showing another example of a rear projection screen having a contrast enhancing sheet according to another embodiment of the present invention;

13 is a ray tracing diagram of a contrast improving sheet according to Example 1,

14 is a view showing light distribution characteristics of a contrast improving sheet according to Example 1,

15 is a view for explaining the optical characteristics of the contrast improving sheet according to the present invention;

16 is a view for explaining the optical characteristics of the conventional lenticular lens sheet.

EMBODIMENT OF THE INVENTION Hereinafter, the Example of this invention is described with reference to drawings.

(Contrast improvement sheet)

As shown in FIG. 1, the contrast enhancement sheet 11 according to an embodiment of the present invention is used by being assembled to a display device such as a rear projection display, a liquid crystal display, or a plasma display, and includes a first optical element 1. And a second optical element 2 laminated on the observation layer of the first optical element 1.

Among them, the first optical element 1 has a plurality of ribs 3 having a substantially trapezoidal cross section arranged in one direction or planarly, as shown in FIGS. 1 and 2. Each of the ribs 3 includes a pair of total reflection surfaces 5 facing each other that totally reflects the image light 4 incident on the back side (image light source side) approximately vertically, and a pair of opposing ones. The total reflection surface 5 is provided with a flat surface 6 formed so as to be connected to each other on the surface (emission surface) of the second optical element 2 side of each rib 3. Further, a V-shaped light absorbing layer 7 made of a light absorbing material is formed in the V-shaped groove between each rib 3. On the other hand, the total reflection surface 5 of each rib 3 corresponds to the inclined surface which comprises the substantially trapezoidal cross section of each rib 3, and is between the rib 3 and the light absorption layer 7 corresponding to it. It is located at the boundary of.

Here, as shown in FIG. 3, the first optical element 1 has a shape in which a plurality of ribs 3 are arranged in a vertical direction therewith in a state in which the ridges 12 of the ribs 3 extend in one direction. In addition to this, as shown in FIG. 4, the ribs 3 forming a square pyramid shape may take the form of a plurality of vertically and horizontally aligned ribs.

On the other hand, the second optical element 2, as shown in Figs. 1 and 2, the exit surface of the first optical element 1 (that is, the flat surface 6 of the rib 3 and the light absorbing layer adjacent thereto) Surface (7). The second optical element 2 corrects the optical path of the image light 4 totally reflected by the total reflection surface 5 of each rib 3 of the first optical element 1 so that the image light 4 is observed on the viewing side. The optical path correction layer 9 which emits substantially vertically is provided. Here, the optical path correction layer 9 is formed of ribs 15 and 16 made of two kinds of transparent materials having different refractive indices, and the boundary surface thereof is arranged in a cross-sectional triangle shape to form the inclined surface 8. . Here, the inclined surfaces 8 are formed differently as shown in FIG. 1, that is, the image light totally reflected by the total reflection surface 5 of each rib 3 of the first optical element 1. 4) is refracted to emit substantially vertically.

Here, each of the inclined surfaces 8 of the optical path compensation layer 9 in the second optical element 2 is formed corresponding to the formation of each rib 3 of the first optical element 1. Specifically, for example, when the ridges 12 of the ribs 3 are arranged in the horizontal direction, as shown in Fig. 5, the ribs 15 and 16 are also arranged in the horizontal direction, The inclined surface 8 formed by the ribs 15 and 16 is also arranged in a state extending in the horizontal direction so as to be parallel to the ridgeline 12 of the rib 3. In addition, when the ridges 12 of the ribs 3 are arranged in the vertical direction, as shown in Fig. 6, the ribs 15, 16 are also arranged in the vertical direction, and the ribs 15 , The inclined surface 8 formed by 16 is also arranged in a state extending in the vertical direction parallel to the ridgeline 12 of the rib (3). When the ribs 3 having a rectangular pyramid shape are arranged in a vertically and horizontally aligned state, as shown in FIG. 7, the ribs 15 and 16 are also formed in a square pyramid shape, and the ribs 15 and 16 are formed. The inclined surface 8 formed by) is also arranged to be substantially parallel to the total reflection surface 5 of the rib 3.

On the other hand, the pitch P ₁ of the rib 3 of the first optical element 1 and the pitch P ₂ of the inclined surface 8 of the optical path compensation layer 9 of the second optical element ₂ are P _1. / P ₂ > 3.5, more preferably, it is preferable to select both pitch ratios so as to satisfy the relationship that P ₁ / P ₂ > 3.5 and P ₁ / P ₂ is non-integer. By adjusting the pitch of both to satisfy such a relationship, it is difficult to observe the moire generated by the arrangement period of both.

Next, the optical path of the light in the contrast enhancement sheet 11 according to the present embodiment will be described with reference to FIG. 2.

In Fig. 2, the light A is image light incident vertically from the back side. Here, in the contrast enhancing sheet 11 according to the present embodiment, the inclination angle of each inclined surface 8 of the optical path compensation layer 9 of the second optical element 2 (orthogonal to the sheet surface of the second optical element 2). The refractive index of the material of the portion (rib 16) located on the side of the first optical element 1 on the side of each inclined surface 8 of the optical path compensation layer 9 as θ ₂ , and n _2. When the refractive index of the material of the portion (rib 15) located on the opposite side of the first optical element 1 with respect to each inclined surface 8 of the optical path compensation layer 9 is n ₃ , the following equation (1) ) , In other words

n ₃ / n ₂ = cos (3θ ₂ ) / cosθ ₂

It is configured to satisfy the relationship. On the other hand, as can be seen from this relation, in the optical path compensation layer 9 of the second optical element 2, θ ₂ < 30 ° and n ₃ 〈 n ₂ .

Therefore, the light of the sign A incident perpendicularly from the back side is not reflected by the total reflection surface 5 of each rib 3 of the first optical element 1 and passes through the flat surface 6 without being reflected by the second optical. After total reflection at each inclined plane 8 of the optical path compensation layer 9 of the element 2, it is refracted at the inclined plane opposite thereto and emitted vertically (ie parallel to the incident light) at the second optical element 2.

Luminous intensity of code B Similar to the light of code A, it is video light which is incident vertically from the back side. Here, in the contrast enhancement sheet 11 according to the present embodiment, the inclination angle of the total reflection surface 5 of each rib 3 of the first optical element 1 (perpendicular to the sheet surface of the first optical element 1) The angle with respect to the direction), θ ₁ , the refractive index of the material forming the ribs 3 of the first optical element ₁ , n ₁ , and each inclined surface 8 of the optical path compensation layer 9 of the second optical element 2. ), The angle of inclination of the second optical element 2 in the direction orthogonal to the sheet surface of the second optical element 2 is set at θ ₂ and the first optical element 1 side with respect to each inclined surface 8 of the optical path compensation layer 9. When the refractive index of the material of the portion (rib 16) located at is n ₂ , the following equation (2), namely

n _{2 · Sin (2θ 2) = n} 1 · sin (2θ 1)

It is configured to satisfy the relationship.

Therefore, the light having the sign B perpendicularly incident from the rear side is totally reflected at the total reflection surface 5 of each rib 3 of the first optical element 1 and passes through the flat surface 6, then the optical path correction layer. It is refracted at each inclined surface 8 of 9 and exits perpendicularly (ie parallel to incident light) at the second optical element 2. In this case, the light of the sign A and the sign B emitted from the second optical element 2 may be parallel to each other.

On the other hand, one solution for satisfying the equation (1) and the equation (2) together, θ ₁ = θ ₂ and n ₁ = n ₂ Equation (2) becomes meaningless by the following, and the refractive index n ₂ to satisfy only the condition of the equation (1) And it may be selected for the ratio of the refractive index n _3. In addition, the refractive indices of each material n ₁ , n ₂ , n ₃ And the relationship between the inclination angles θ ₂ of the inclined surfaces 8 of the optical path compensation layer 9 are slightly different from the above Equation 1 and / or Equation 2, thereby exiting from the second optical element 2. The light of code A and the light of code B may be made non-parallel so as to have a weak diffusion effect on the contrast improving sheet 11 according to the present embodiment.

Here, in the first optical element 1, the refractive index n ₄ of the material (transparent resin) forming the light absorption layer 7 is lower than the refractive index n ₁ of the material forming the rib 3, and each rib 3 The inclination angle θ ₁ of the total reflection surface 5 of), the refractive index n ₁ of the material forming the rib 3 and the refractive index n ₄ of the material forming the light absorption layer 7 are given by the following equation (3), namely

θ ₁ = cos ^-1 (n ₄ / n ₁ )-sin ^-1 (1/2 n ₁ )

It is configured to satisfy the relationship.

Accordingly, the light of the sign A and the sign B incident perpendicularly from the rear side is the total reflection surface 5 located at the interface between each rib 3 of the first optical element 1 and the respective light absorption layer 7 corresponding thereto. ) Is totally reflected.

On the other hand, the light having the sign C inclined at an angle of incidence θ ₃ of about 30 ° on the back side is formed between each rib 3 of the first optical element 1 and the corresponding light absorption layer 7. In the total reflection surface 5 located at the boundary surface, the light absorption layer 7 enters and is absorbed without being totally reflected. On the other hand, the light of symbol C is a light (slightly different light) having a different light exit position from the image light transmitted through the normal optical path, and is mainly the cause of the double phase.

On the other hand, in the low refractive index material (transparent resin) for forming the light absorption layer 7, it is preferable to disperse the light-absorbing fine particles or to include a dye having a light absorption effect to color it. It can be improved.

The light of the code | symbol D is image light which obliquely enters in incidence angle (theta) ₄ smaller than the light of the code | symbol C at the back side. The light of the sign D, like the light of the sign B, is totally reflected at the total reflection surface 5 of each rib 3 of the first optical element 1 and passes through the flat surface 6 before the optical path correction layer 9 It is refracted by each inclined surface 8 of and is emitted from the second optical element 2 at an angle (emission angle) θ _{5 which} is twice the incident angle θ ₄ . Therefore, by injecting diffused light into the contrast enhancement sheet 11 according to the present embodiment at an incidence angle θ ₄ of about 5 ° to 10 °, the emission angle θ ₅ of the light emitted to the observation side can be widened by about twice. Therefore, the angle of exit of the light with directivity can be enlarged for a while.

Light of symbol E is external light incident on the observation side vertically. The light of this symbol E is refracted by each of the inclined surfaces 8 of the optical path compensation layer 9 of the second optical element 2 at the interface between the second optical element 2 and the first optical element 1. Each light absorption layer 7 of the first optical element 1 enters and is absorbed without being totally reflected. Although not shown, for the external light incident on the observation side at an angle of, for example, 50 ° or more, the optical path is formed by the respective inclined surfaces 8 of the optical path correction layer 9 of the second optical element 2. Since it is bent in the thickness direction, when it enters each of the light absorbing layers 7 of the first optical element 1 from the optical path compensation layer 9 of the second optical element 2, it enters without total reflection as in the case described above. As a result, the light absorption layer 7 absorbs the light.

As described above, in the contrast improving sheet 11 according to the present embodiment, since the first optical element 1 and the second optical element 2 configured to satisfy the relationship of the above formulas 1 to 3 are stacked, The light (image light) of code A and code B incident on the first optical element 1 side, which is on the side, can be emitted substantially perpendicularly to the observation side, regardless of the incident position, and on the back side of the first optical element 1 side. The light (light stray) of the sign C incident at an angle on the side of the first optical element 1 and the light (external light) of the sign E incident on the side of the second optical element 2 which is the observation side are subjected to the first optical element 1. Each light absorption layer 7 can be absorbed. Therefore, the contrast can be improved and the image light incident from the rear side can be transmitted to the observation side with high directivity without loss.

On the other hand, in the contrast enhancement sheet 11 according to the present embodiment, the first optical element 1 disposed on the rear side and the second optical element 2 disposed on the observation side are formed separately, respectively. It can be manufactured by bonding. In that case, in this embodiment, the pitch P ₁ of the rib 3 of the first optical element 1 and the pitch P of the inclined surface 8 of the optical path compensation layer 9 of the second optical element 2 are described. ₂ ) is different, the pitch ratio of both is satisfied so as to satisfy the relationship that P ₁ / P ₂ > 3.5, more preferably P ₁ / P ₂ > 3.5 and P ₁ / P ₂ is non-integer between them Since it is selected, it is not necessary to carry out both alignment, and the contrast enhancement sheet 11 according to the present embodiment can be easily manufactured.

On the other hand, when the first optical element 1 is made, a plurality of ribs 3 are formed by duplicating with a molding mold using a known method such as a heating press method, a thermal polymerization method or a radiation curing method, and then each rib 3 is formed. The light absorbing material 7 is formed by filling a V-shaped groove between the light absorbing materials by wiping or the like.

Similarly, when making the second optical element 2, one of the portion (rib 15) located on the exit surface side or the portion (rib 16) located on the incident surface side of the first optical element 1 described above is described. After forming the rib 3 in the same manner as the method of forming the rib 3, the V-shaped groove of the formed one portion (the rib 15 or the rib 16) is filled with a curable radiation-curable resin or the like to harden the other. Form part (rib 16 or rib 15). At that time, the part on the exit surface side (rib 15) is first formed with a molding mold, and the resin for the incident surface side part (rib 16) is filled into the V-shaped groove of the exit surface side portion (rib 15). The first optical element 1 may be laminated thereon, and then the incident surface side portion (rib 16) of the second optical element 2 may be hardened. Accordingly, the first optical element 1 and the second optical element 2 can be bonded to each other in the process of making the second optical element 2. On the other hand, the rib 3 of the first optical element 1 or the optical path correction layer 9 of the second optical element 2 is formed on a substantially transparent film or sheet, and then both are formed through the adhesive layer. May be adhered to.

On the other hand, in the present embodiment, the ribs 15 and 16 of the material forming the ribs 3 of the first optical element 1 and the optical path correction layer 9 of the second optical element 2 are manufactured from the viewpoint of manufacture. At least one of the two kinds of materials to be formed is preferably a radiation curable resin. Here, as radiation-curable resin, what is generally used in the said field can be mentioned, For example, ultraviolet curable resin, such as an acryl-type, epoxy-type, urethane type, electron beam curable resin, etc. can be used suitably. Moreover, also about the transparent film or sheet | seat which supports the rib 3 of the 1st optical element 1, and the optical path correction layer 9 of the 2nd optical element 2, general things, such as a polyester film and a polycarbonate film, You can use it properly.

In addition, the light absorption layer 7 of the first optical element 1 is formed by dispersing light absorbing fine particles in a transparent resin having a low refractive index or by containing a dye having a light absorption effect and coloring the same. The color of the light absorbing layer 7 is preferably achromatic, such as black or gray, but is not limited thereto. A material that selectively absorbs a specific wavelength in accordance with the characteristics of the image light may be used. On the other hand, as the light absorbing fine particles, in addition to metal salts such as carbon black, graphite, and black iron oxide, colored organic fine particles, colored glass beads, and the like can be used. As the dye for coloring, xanthene-based organic dyes such as acid red and organic acid neodymium such as neodymium carboxylate can be used.

Here, the material forming the ribs 3 of the first optical element 1, the two kinds of materials forming the ribs 15, 16 of the optical path compensation layer 9 of the second optical element 2, Coloring materials may be incorporated into at least one of the transparent film or sheet supporting the ribs 3 of the first optical element 1 or the optical path compensation layer 9 of the second optical element 2. The contrast can be further improved.

On the other hand, in the contrast improvement sheet 11 which concerns on a present Example, you may further laminate | stack an ultraviolet absorbing layer (including a film, a sheet, etc.) which has an ultraviolet absorbing effect on the observation side of the 2nd optical element 2. As shown in FIG. Further, at least one of a hard coat layer, an antireflection layer, an antiglare layer, an antistatic layer and the like may be laminated on the most observed side of the contrast improving sheet 11 according to the present embodiment.

The contrast enhancing sheet 11 according to the present embodiment is disposed on the front side of the observation side which is the image forming surface in a display display device such as a rear projection display or a direct view flat display (liquid crystal display, plasma display, EL display, etc.). Can be used. In particular, when the contrast enhancement sheet 11 is used for a rear projection type display, the contrast to external light can be improved, and a ghost caused by a Fresnel lens or a rear mirror assembled during the rear projection type display can be achieved. Image disturbance light such as a rainbow and the like can be effectively absorbed, so that a very good image can be obtained.

(Rear projection screen)

Next, a rear projection type screen provided with the contrast enhancement sheet 11 according to the present embodiment described above will be described. On the other hand, the rear projection screen is suitably used in a rear projection display and the like.

Fig. 8 is a diagram showing one example of the rear projection type screen provided with the contrast enhancement sheet 11 according to the present embodiment. As shown in Fig. 8, the rear projection screen 2lA emits the image light projected from the rear side to the observation side to display an image, and deflects the image light projected from the rear side toward the observation side approximately vertically. The Fresnel lens sheet 22 and the contrast improvement sheet 11 arrange | positioned at the observation side of this Fresnel lens sheet 22 are provided. On the other hand, the contrast enhancement sheet 11 is provided with a layer 19 such as an ultraviolet absorbing layer on the observation side in addition to the first optical element 1 and the second optical element 2 described above.

In the rear projection screen 21A shown in Fig. 8, a lenticular lens sheet or the like which is an optical element for diffusing image light is not used. However, in the contrast enhancement sheet 11 according to the present embodiment, if the video light incident from the rear side is diffused light, its diffusion angle (see θ ₄ in FIG. 2) can be enlarged by about twice. Therefore, in the rear projection type screen 21A shown in Fig. 8, for example, when a light diffusing agent having a degree of diffusion of about 10 ° is incorporated into the emission light emitted from the Fresnel lens sheet 22, the rear projection type screen ( 21A) As a whole, it is possible to give a diffusion effect of about 10 ° in the vertical direction and about 20 ° in the horizontal direction.

9 is a view showing another example of the rear projection type screen having the contrast enhancement sheet 11 according to the present embodiment. As shown in Fig. 9, the rear projection screen 21B includes a Fresnel lens sheet 22 in which the image light projected from the rear side is deflected substantially vertically toward the observation side, and the Fresnel lens sheet 22 A screen composed of three sheets having a lenticular lens sheet 23 arranged on an observation side and diffusing image light, and a contrast enhancement sheet 11 arranged on an observation side of the lenticular lens sheet 23. On the other hand, the contrast enhancing sheet 11 has a layer 19 such as an ultraviolet absorbing layer on the observation side in addition to the first optical element 1 and the second optical element 2 described above.

Even in this case, in the contrast enhancement sheet 11 according to the present embodiment, since the video light incident from the rear side can be enlarged at about twice the diffusion angle, it should be incorporated into the lenticular lens sheet 23. Since the amount of the light diffusing agent can be reduced, a clearer image can be obtained as compared with a conventional rear projection screen.

Here, the contrast enhancing sheet 11 and the lenticular lens sheet 23 may be bonded through an adhesive layer. In particular, in the case where the lenticular lens sheet 23 has a high fineness and is a thin plate, the contrast enhancement sheet 11 and the lenticular lens sheet 23 are formed on the observation side of the lenticular lens sheet 23. It is preferable to adhere to the light absorbing layer 23b (black stripe). Thereby, the rigidity as a sheet can be improved. On the other hand, when the image source of the rear-projection display is a single tube light source such as LCD or DLP, and the exit surface of the lenticular lens sheet assembled to the rear projection screen 21B is flat, the lenticular lens sheet It may be made to adhere to the contrast improving sheet 11 on the whole side of the observation side.

As shown in Fig. 9, the lenticular lens sheet 23 is formed with a plurality of lenticular lenses 23a extending in the vertical direction on the rear side thereof, and the lenticular lens on the rear projection screen 21B. The ridgeline of the lenticular lens 23a of the lens lens 23 and the rib 3 of the contrast enhancement sheet 11 are arranged to be orthogonal to each other.

Meanwhile, in the rear projection screen 21A shown in FIG. 8 and the rear projection screen 21B shown in FIG. 9, the contrast enhancement sheet 11 according to the present embodiment is provided separately from the Fresnel lens sheet 22. However, the present invention is not limited thereto, and the function of the contrast enhancement sheet according to the present embodiment may be incorporated as part of the Fresnel lens sheet, such as the total reflection Fresnel lens sheet 31 shown in FIG. 1A.

As shown in FIG. 10, the total reflection Fresnel lens sheet 31 deflects the image light projected obliquely from the rear side toward the observation side substantially vertically, and the total reflection Fresnel lens 32 is formed on the rear side. On the observation side, the first optical element 1 and the second optical element 2 constituting the contrast enhancing sheet are integrally formed.

In this case, in the total reflection Fresnel lens sheet 31, the light (image light) of the sign F which is incident on the incident surface 33 of the total reflection Fresnel lens 32 formed on the rear side and totally reflected on the total reflection surface 34 is Since it is incident substantially perpendicularly to the first optical element 1 formed on the observation side, even when exiting from the total reflection Fresnel lens sheet 31 passing through the first optical element 1 and the second optical element 2. It is emitted approximately vertically. On the other hand, the light of the sign G which is incident on the incident surface 33 of the total reflection Fresnel lens 32 formed on the rear side and is not totally reflected on the total reflection surface 34 to become stray light is the first optical element formed on the observation side. Since it is obliquely incident on (1), it is absorbed by the light absorption layer 7 and is not emitted to an observation side.

On the other hand, such a total reflection Fresnel lens sheet 31 is used in the rear projection screen 21C as shown in FIG. As shown in FIG. 11, the rear projection screen 21C has a lenticular lens sheet 24 disposed on the observation side of the total reflection Fresnel lens sheet 31 and the total reflection Fresnel lens sheet 31. . The total reflection Fresnel lens sheet 31 may also be used in the rear projection screen 21D as shown in FIG. As shown in FIG. 12, the rear projection type screen 21D has a total reflection lenticular lens sheet 25 disposed on the observation side of the total reflection Fresnel lens sheet 31 and the total reflection Fresnel lens sheet 31. It is.

detailed Example

Next, specific examples of the above-described embodiments will be described.

(Specific Example 1)

50㎛ of thickness on one surface of a PET film (refractive index: 1.6), the refractive index after curing (n _l) is to form the rib into a trapezoidal cross section by the 1.55 UV-curable resin. The pitch P ₁ of the rib was 0.3 mm, the height of the rib was 0.6 mm, the width of the flat surface at the tip was 0.169 mm, and the inclination angle θ ₁ of the total reflection surface as the inclined surface was 8 °. Thereafter, a V-shaped groove between the trapezoidal ribs is filled with a light absorbing material obtained by dispersing black beads having an average particle diameter of 6 μm in an acrylic paint having a refractive index (n ₄ ) of 1.49 to form a light absorbing layer. One optical element was created.

On the other hand, on one side of an acrylic styrene copolymer resin film (refractive index 1.53) having a thickness of 1.5 mm, acrylic ribs were modified to form ribs having a triangular cross section with a resin having a refractive index (n ₃ ) of 1.48. The pitch P ₂ of the ribs is 40 μm (ratio of pitches: P ₁ / P ₂ = 7.5) so that moiré generated between the ribs of the first optical element is not noticeable, and the height of the ribs is 135 μm. And the inclination angle θ ₂ were set to 8 ° similarly to the rib 3 of the first optical element. Subsequently, a second optical element was made by filling and curing a styrene-based EB cured resin having a refractive index (n ₂ ) of 1.6 in a V-shaped groove between the ribs.

Next, the first optical element and the second optical element made as described above were laminated and bonded in a state in which each rib faced each other, whereby a contrast improving sheet according to the specific example 1 was obtained.

(Evaluation results)

The contrast improvement sheet which concerns on the specific Example 1 was evaluated as follows.

First, a commercially available rear projection type TV (manufactured by Hitachi) having a conventional rear projection type screen consisting of three sheets of Fresnel lens sheet, lenticular lens sheet, and thinly colored transparent resin sheet (colored sheet) was prepared. . Instead of the colored sheet of this conventional rear projection screen, the contrast enhancement sheet according to Example 1 was placed to constitute a rear projection screen. And the television image at the time of using both rear projection screen was contrast-observed. On the other hand, in this case, the stacked form of the first optical element and the second optical element in the contrast enhancing sheet and the arrangement form when the contrast enhancing sheet is assembled into the rear projection screen are as shown in FIG. 9.

As a result, in the rear projection type screen equipped with the contrast enhancement sheet according to the specific example 1, the contrast of the image is improved compared to the conventional rear projection type screen equipped with the coloring sheet, and the image is displayed more clearly even in a bright indoor environment. there was. In addition, in the conventional rear projection type screen equipped with a coloring sheet, the rainbow caused by the Fresnel lens was observed thinly, but not at all in the rear projection type screen equipped with the contrast enhancement sheet according to the specific example 1.

13 is a ray tracing diagram of the contrast improving sheet according to the first embodiment, and FIG. 14 is a view showing light distribution characteristics of the contrast improving sheet according to the first embodiment. As can be seen from the results shown in these FIGS. 13 and 14, it was found that the contrast enhancement sheet according to the specific example 1 had excellent directivity. On the other hand, the gain shown in Fig. 14 measures the angular distribution of the luminance of the light coming forward when a parallel light beam is incident from the rear of the rear projection screen, and the &quot; gain G &quot; ) = Luminance / illuminance relation ".

(Specific Example 2)

The resin of the portion of the second optical element located on the rear side (the first optical element side) is the same resin as the rib of the first optical element (refractive index 1.55), and the resin of the observation side (the opposite side of the first optical element) is the refractive index 1.43. Contrast improvement sheet which concerns on Example 2 was produced with the material and the method similar to Example 1 except having been made into the phosphorus silicone resin.

(Evaluation results)

The contrast improvement sheet which concerns on the specific Example 2 was evaluated as follows.

First, a rear projection television (evaluation TV set) having a projection distance of 300 mm, a projection angle of 65 °, and a screen size of 60 inches was prepared. A conventional rear projection screen composed of a total reflection Fresnel lens sheet and a lenticular lens sheet is used for this rear projection television. Instead of the total reflection Fresnel lens sheet of the conventional rear projection type screen, the total reflection Fresnel lens sheet in which the contrast enhancement sheet according to Embodiment 2 is adhered to the observation side of the total reflection Fresnel lens sheet having the same optical characteristics The projection screen was constructed. And the television image in the case of using both rear projection screens was contrast-observed. On the other hand, in this case, the lamination form of the first optical element and the second optical element in the contrast enhancement sheet and the arrangement form when the contrast enhancement sheet is incorporated into the rear projection screen are as shown in FIG.

As a result, in the rear projection type screen having the total reflection Fresnel lens sheet bonded with the contrast enhancement sheet according to the second embodiment, the contrast of the image is improved compared to the conventional rear projection type screen, and the image is sharper even in a bright indoor environment. Could display. In addition, in the conventional rear projection type screen, the dual phase due to the total reflection Fresnel lens and the dual phase due to the mirror reflection were observed, but in the rear projection type screen having the total reflection Fresnel lens sheet to which the contrast enhancement sheet according to Example 2 is adhered They have not been confirmed at all.

(Example 3)

The pitch P _l of the rib of the first optical element is 0.16 mm, the height thereof is 0.16 mm, and the pitch P ₂ of the second optical element is 18 μm (pitch ratio: P _l / P _2). = 3.5) and the contrast improvement sheet which concerns on the specific Example 3 was obtained like Example 2 except having made the height into 60 micrometers.

(Evaluation results)

The contrast improvement sheet which concerns on the specific Example 3 was evaluated as follows.

First, a 15-inch type liquid crystal monitor for a personal computer (PC) was prepared. The contrast improvement sheet which concerns on Example 3 was attached to this liquid crystal monitor, and the screen of the liquid crystal monitor was observed. In this case, the lamination form of the first optical element and the second optical element in the contrast enhancement sheet and the arrangement form when the contrast enhancement sheet is incorporated into the liquid crystal monitor are the same as those shown in FIG. 6.

As a result, even in a bright indoor environment, there is no reflection, and the contrast is high from the front of the screen, so that the image can be clearly observed, but no image is observed from the inclination of 25 ° or more in the horizontal direction. It could be confirmed.

Claims (12)

In the contrast enhancement sheet used to assemble the display It has an optical element which emits the image light incident on the back side substantially vertically to the observation side irrespective of the incidence position, and absorbs the stray light incident on the back side and the external light incident on the observation side. The contrast improvement sheet characterized by the above. The method of claim 1, wherein the optical element, A first optical element having a plurality of ribs arranged in one direction or planarly, each of which has a pair of total reflection surfaces facing each other that totally reflects the image light incident on the back side substantially vertically, and these facing sets A first optical element having a flat surface formed so as to be connected to each other with the total reflection surface of the light emitting surface side, wherein each of the ribs has a light absorption layer; A second optical element stacked on the observation side of the first optical element, the second optical element having an optical path correction layer for correcting the optical path of the image light totally reflected by the total reflection surface of each rib to emit the image light approximately vertically to the observation side; Contrast enhancement sheet comprising an optical element. 3. The plurality of inclined surfaces of claim 2, wherein the optical path correction layer of the second optical element comprises a plurality of inclined surfaces formed differently from each other to emit the image light totally reflected by the total reflection surface of each of the ribs of the first optical element. Contrast improvement sheet characterized by having. The inclined surface of the optical path correction layer of the second optical element is not reflected by the total reflection surface of each of the ribs of the first optical element among the image light incident substantially perpendicularly from the rear side. Light that is totally reflected and refracted on each inclined surface after passing through the flat surface, and is totally reflected in the total reflection surface of each of the ribs of the first optical element among the image light, and then refracted at each inclined surface after passing through the flat surface And the light emitted and configured to be substantially parallel to each other. The light absorbing layer according to any one of claims 2 to 4, wherein the light absorbing layer of the first optical element contains light absorbing particles in a transparent material having a lower refractive index than a material forming the rib of the first optical element. Contrast improvement sheet characterized by the above-mentioned. The light absorbing layer of any one of claims 2 to 4, wherein the light absorbing layer of the first optical element is made of a colored material having a lower refractive index than a material forming the rib of the first optical element. Contrast Enhancement Sheet. The inclination angle (angle with respect to the direction orthogonal to the sheet surface of the second optical element) of each inclined surface of the optical path compensation layer of the second optical element is θ ₂ , The refractive index of the material of the portion of the optical path compensation layer located on the side of the first optical element on the respective inclined surfaces is n _2. And n ₃ / n ₂ = cos (3θ ₂ ) / cosθ ₂ when the refractive index of the material of the portion of the optical path compensation layer positioned on the opposite side of the first optical element is n ₃ at the boundary. Contrast enhancement sheet characterized in that to satisfy. The inclination angle (angle with respect to the direction orthogonal to the sheet surface of the first optical element) of each of the ribs of the first optical element is θ ₁ , and the first The refractive index of the material forming the rib of the optical element is n ₁ , the inclination angle (angle with respect to the direction orthogonal to the sheet surface of the second optical element) of the inclined surface of the optical path compensation layer of the second optical element is θ ₂ when by the respective slopes of the optical path correction layer as a boundary hayeoteul the refractive index of the material located within the first optical element side portion to _{n 2, n 2 · sin (} 2θ 2) = n 1 · sin (2θ 1) Contrast enhancement sheet characterized in that to satisfy the relationship. In the rear projection screen which displays the image by emitting the image light projected from the rear side to the observation side, A Fresnel lens sheet for deflecting the image light projected from the rear side substantially vertically toward the observation side; The rear projection type screen provided with the contrast improvement sheet in any one of Claims 1-8 arrange | positioned at the observation side of this Fresnel lens sheet. In the rear projection screen which displays the image by emitting the image light projected from the rear side to the observation side, A Fresnel lens sheet for deflecting the image light projected from the rear side substantially vertically toward the observation side; A lenticular lens sheet disposed on an observation side of the Fresnel lens sheet to diffuse image light; The rear projection type screen provided with the contrast improvement sheet in any one of said Claims 1-8 arrange | positioned at the observation side of this lenticular lens sheet. The rear projection screen according to claim 10, wherein said lenticular lens sheet has a light absorbing layer on its observation side, and said contrast enhancing sheet is adhered to said lenticular lens sheet at least in said light absorbing layer. In the rear projection screen which displays the image by emitting the image light projected from the rear side to the observation side, A Fresnel lens sheet for deflecting image light projected obliquely from the rear side toward the observation side, wherein a total reflection Fresnel lens is formed on the rear side, and any of the above-mentioned items on the observation side. Fresnel lens sheet formed with the contrast enhancing sheet according to claim 1, A rear projection screen comprising a lenticular lens sheet disposed on an observation side of the Fresnel lens sheet to diffuse image light.

Images