JPH06194741A - Transparent screen - Google Patents

Abstract

PURPOSE:To reduce the reflection of the external light effectively, and to restrict the reduction of the transmittance of the projected light in a transparent screen of a back surface projection type display device. CONSTITUTION:The surface of one side of a transparent resin plate 11 is formed with plural projections 12 made of the transparent material. The surface of an inclined part 14 of each projection 12 except for the peak part 13 of the projection 12 is formed with a light absorbing layer 15. The projected light 21 enters the peak part 13 directly, or the projected light 21 is reflected by the inner surface of the inclined part 14 to enter the peak part 13, and goes out as the outgoing light 22. The external light 23, which entered the inclined part 14, is absorbed by the light absorbing layer 15.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmissive screen, and more particularly to a transmissive screen for a rear projection display device.

[0002] In recent years, with the spread of video devices, there is an increasing demand from general viewers who want to enjoy large-screen video more easily. Therefore, the enlargement of the screen has been developed by various methods, and in particular, the rear projection type display device using a CRT or a liquid crystal panel is becoming popular in general households because of its light weight and cost reduction.

Here, in the case of a rear projection type display device, a sufficient contrast is required under normal lighting in a room, so that the surface reflection light of the transmissive screen is reduced and the projection light from the rear surface of the transmissive screen is reduced. Improvements in transmittance are needed.

[0004]

2. Description of the Related Art FIG. 25 shows an example of a conventional transmissive screen. The screen 41 is originally a diffusion layer having a high screen gain (screen gain: 5 to 5).
A black (light absorbing) pigment is added to 15). Projection light 2
1 is diffused by the screen 41 and emitted as transmitted diffused light 25. The external light 23 is partially transmitted through the screen 41 as the transmitted light 26 and partially reflected as the external light reflected light 24. By adding a black (light absorbing) pigment to the screen 41, the reflectance of the external light 23 is reduced and the contrast is improved.

FIG. 26 is an explanatory view of a conventional transmissive screen in which a smoke plate is combined. As shown in FIG. 26, a light absorbing plate (smoke plate) 43 is arranged on the front surface of the diffusion layer screen 42. The projection light 21 is diffused by the screen 42 to become the transmitted diffused light 25, which is transmitted through the smoke plate 43 and emitted. Outside light 23 is a smoke plate 43
After passing through, the light is reflected by the screen 42 and again passes through the smoke plate 43.

The external light 23 is transmitted through the smoke plate 43 twice at the time of incidence and reflection, whereas the projection light 21 is diffused by the screen 42 and is transmitted through the smoke plate 43 only once. The outside light 23 and the projection light 21 are different. Therefore, the contrast can be improved. In addition,
As a method similar to the method of combining a smoke plate, there is a method of using a polarizing plate and a quarter wave plate.

FIG. 27 is an explanatory view of a conventional transmissive screen using a lenticular lens. A large number of lenticular lenses 45 are provided on the lenticular lens plate 44, and a light absorption band 46 is arranged between the lenses of the lenticular lens 45. The projection light 21 is condensed and diffused by the lenticular lens 45 and is emitted as transmitted diffused light 25 to improve the transmittance. On the other hand, the reflection area of the external light 23 is reduced due to the light absorption band 46. Therefore, the contrast can be improved.

[0008]

However, in the conventional method of adding the black pigment to the diffusion layer of the screen and the method of controlling the transmittance of the external light and the projection light by combining the smoke plate and the like, the contrast is improved. Can be realized, but the transmittance of projection light is inevitably reduced, and the screen is inevitably darkened. Therefore, there is a problem that it is necessary to increase the amount of projection light, and the efficiency of the rear projection display device decreases.

Further, in the method of arranging the light absorption band on the lenticular lens plate, the pitch of the lenticular lens, the pitch of the light absorption band, etc. cannot be made sufficiently fine, and the resolution limit is compared. It is in a rough place. For this reason, there will be a problem in achieving higher definition of the screen in the future.

The present invention has been made in view of the above points, and a reflection type screen having a high resolution and a high contrast is obtained by effectively reducing the reflection of external light and suppressing the reduction of the transmittance of projection light. The purpose is to provide.

[0011]

In order to solve the above problems, the present invention is characterized by taking the following means.

According to the first aspect of the present invention, a plate-shaped or film-shaped transparent member and a plurality of transparent members are formed on one surface of the transparent member, and a light absorption layer is formed on an inclined portion other than the top. The present invention is characterized in that a transmissive screen is constituted by convex projections made of a material.

According to the invention of claim 7, a lenticular lens formed of a transparent body having a lenticular portion formed on at least one surface thereof and a light absorbing layer formed on the lenticular portion of the lenticular lens are transparent. It is characterized in that a screen is constructed.

Further, in the invention according to claim 10, a lenticular lens formed of a transparent body having a lenticular portion formed on at least one surface, and a lenticular lens formed on or near the top of the lenticular portion and incident on the inside of the lenticular lens. It is characterized in that the transmission type screen is constituted by the light shielding portion for blocking the traveling of the outside light.

[0015]

The above-mentioned means operate as follows.

According to the first aspect of the invention, the convex projection group is provided, and the light absorbing layer is provided on the inclined portion other than the apex thereof to reduce reflection of external light and to transmit projection light. It is possible to suppress the reduction of the rate and thus improve the contrast.

Further, according to the invention of claim 7, the light absorbing layer is formed in the lenticular portion of the lenticular lens, so that the external light entering the light absorbing layer is generated in the light absorbing layer having a shape along the lenticular portion. Since the light travels, the optical path length of the external light traveling in the light absorption layer can be lengthened, the reflection of the external light can be reduced, and the contrast of the transmissive screen can be improved.

Further, according to the invention of claim 10, the light-shielding portion formed on or near the top of the lenticular portion blocks the propagation of the external light incident on the inside of the lenticular lens, so that the reflection of the external light is reduced. Therefore, the contrast of the transmissive screen can be improved.

[0019]

1 is a sectional view of a first embodiment of the present invention, and FIG. 2 is a perspective view of the first embodiment of the present invention. The transparent resin plate 11 which is a transparent member is a transparent resin such as acrylic or polycarbonate, and the lower surface thereof has a flat plate shape. Transparent resin plate 1
On the upper surface of 1 is a convex projection 1 made of the same material as the transparent resin plate 11.
2 are formed at a plurality of equal pitches. This convex protrusion 1
As shown in FIG. 2, 2 has a shape in which the top portion of the cone is cut to form a flat surface.

The surface of the inclined portion 14 of the convex projection 12 and
Bottom 11a left between the convex protrusions 12 of the transparent resin plate 11
A light absorbing layer 15 (thick solid line in FIG. 1) is formed on the surface of (see FIG. 2). The light absorption layer 15 is formed by applying a black paint, adhering a black pigment, blackening the surface of the transparent resin by a chemical means, or the like. It should be noted that a light absorbing layer is not formed on the tops 13 of the convex projections 12 and is light transmissive.

The transmissive screen of the first embodiment uses the external light 2
When 3 is incident on the inclined portion 14 of the convex protrusion 12, most of the light is absorbed by the light absorption layer 15 at the incident point. A part of the light is reflected, but due to the inclination of the convex protrusions, the light is further reflected toward the bottom of the convex protrusions 12 and again enters the light absorption layer 15. As a result, of the outside light 23, that incident on the inclined portion 14 of the convex protrusion 12 is absorbed by the light absorption layer 15.

Of the outside light 23, the top 1 of the convex projection 12
The light incident on 3 is reflected by the top 13 and becomes the external light reflected light 24. However, the area of the top 13 and the area covered by the light absorption layer 15 when the screen is viewed from the front. By appropriately setting the ratio of
Can be sufficiently reduced.

On the other hand, the projection light 21 from the back of the screen
Is incident on the transparent resin plate 11 from the plane of the lower part of the screen and then directly reaches the top 13 to be emitted as the emitted light 22 or is reflected on the inner surface side of the inclined portion 14 of the convex protrusion 12 to be reflected from the top 13. It is emitted as emitted light 22.

The emitted light 22 reflected from the inner surface side of the inclined portion 14 of the convex projection 12 and emitted from the top 13 has a larger angle with respect to the normal line of the screen surface than the original projected light 21. Therefore, the convex protrusions 12 can increase the degree of diffusion of light.

In order to efficiently project the projection light 21 from the top 13, the incident angle of the projection light 21 and the convex projection 1
The angle or the like of the second inclined portion 14 is appropriately set.

Next, the design method of the first embodiment will be described. FIG. 3 shows a sectional view for explaining the first embodiment, and FIG. 4 shows a plan view of the first embodiment. As a prerequisite, projection light 2
1 is incident from the lower side of FIG. 3, and the chief ray of the projection light 21 is incident on the screen surface in the normal direction.
Further, at this time, the angular width of the projection light 21 focused on one point on the screen is ± θ °. In the figure, the principal ray is a thin solid line, the ray from the right side θ ° is a thin dash-dotted line, and the ray from the left θ ° is a thin dash-dotted line to show their paths.

Here, the angle β of the inclined portion 14 with respect to the screen normal direction will be considered. The smaller the angle β, the larger the inclination of the inclined portion 14,
Since the incident light reflected by the inner surface of the above is incident on the inner surface of the apex 13 at an angle closer to vertical, the emission efficiency of the light reflected by the inner surface of the inclined portion 14 is increased. However, when the angle β is decreased, the ratio B / A between the diameter B of the top 13 and the diameter A of the bottom of the convex protrusion 12 increases, and the absorption area of the external light 23 decreases.

On the other hand, the larger the angle β, the B
The value of / A decreases, and the absorption area of the external light 23 increases. However, the amount of light that is incident so as to be reflected on the inner surface of the inclined portion 14 is larger than the amount of light that is directly incident on the top 13. Further, if the angle β is too large, the light reflected on the inner surface of the inclined portion 14 does not enter the apex 13 and cannot hit the inclined portion 14 on the opposite side to be emitted. The incident efficiency is reduced due to the incident light having an angle exceeding 100 ° C and being totally reflected.

[0029] Therefore, as shown in FIG. 3, of the light incident with a width of ± theta °, as in the incident light a _1, the light incident from the right side in FIG. 3 at maximum amplitude theta, inclined portion 14 When the light is reflected by the slope on the slightly right side of the bottom of 14 and is incident on the right end of the top 13 at a critical angle (the same is true for light incident from the left side), B /
It is considered to be a condition that optimizes the value of A and the emission efficiency of the light reflected by the inclined portion 13. Therefore, the relational expression between the incident angle θ and the value of B / A is derived based on this condition.

Consider the incident light a ₁ incident from the right side of FIG. 3 at an angle of θ with the normal to the screen. When the refractive index of the screen material is n, γ is calculated as follows.

Sin θ = n · sin γ ∴γ = sin ⁻¹ (sin θ / n) ----- (1) When the critical angle is δ, β is calculated as follows from FIG.

Δ = α + β, α = γ + β ∴β = (δ−γ) / 2 = (δ−sin ⁻¹ (sin θ / n)) / 2 −− (2) The height of the convex protrusion 12 is C. Then, A and B can be expressed as follows.

A = C · (tan δ + tan β) −−− (3) B = A−2 · Ctan β −−− (4) Substituting the equation (4) into the equation (3), B can be represented by the following equation. .

B = C · (tan δ-tan β) ----- (5) From equations (3) and (5), B / A can be expressed by the following equation.

B / A = C · (tan δ−tan β) / (C · (tan δ + tan β)) = sin (δ−β) / sin (δ + β) −−− (6) Substituting, B / A can be expressed as follows.

B / A = sin ((δ + γ) / 2) / sin ((3δ−γ) / 2) = √ ((1-cos (δ + γ)) / (1-cos (3δ−γ))) − -(7) The critical angle δ is calculated as follows.

Sin 90 ° = n · sin δ ∴ δ = sin ⁻¹ (1 / n) −−− (8) Substituting equation (1) and equation (8) into equation (7), B / A is It can be expressed as follows.

[0038]

[Equation 1]

As described above, when the incident angle is θ, the angle β of the inclined portion 14 is obtained by the equation (2), and the value of B / A is obtained by the equation (9).

Next, as a specific example, a case of θ = 10 ° will be described. In FIG. 3, when light ray a ₁ is incident on the screen from the direction of 10 ° to the right, if acrylic is used as the screen, the refractive index is 1.492, so from equation (1), γ = 6.7 °. , 6.7 ° with respect to the screen normal direction. This light ray a ₁ is totally reflected in the vicinity of the bottom of the convex projection 12 on the exit surface side, and as shown in FIG.
The angle β of the inclined portion 14 of the convex projection 12 is set so that the light enters the end of the top 13 of the convex projection 12 that is the exit window at a critical angle.
To design.

As a result, of the projection light 21, the bottom 11
All incident light other than a (see FIG. 2) is directly incident on the apex 13 or is reflected by the inclined portion 14 of the convex projection 12 and is incident on the apex 13 at an angle equal to or less than the critical angle. become. Acrylic / air surface critical angle δ = 42.1 °,
Since a movement angle gamma = 6.7 ° of light a _1, (2) the β from the equation, is determined as follows.

Β = (42.1 ° −6.7 °) /2=17.7° That is, the angle β of the inclined portion 14 of the convex protrusion 12 is 17.7 ° with respect to the screen normal direction. Should be Further, A and B are obtained from the equations (3) and (4) as follows.

A = C · (tan 42.1 ° + tan 17.7 °) = 1.223 · C B = A−2 · Ctan 17.7 ° = 0.585 · C From this, B / A = 0.478 obtain.

The light whose principal ray is directly incident on the apex 13 (rays b ₀ , b ₁ , b _{2 in} FIG. 3) is emitted from the apex 13 at an angle of ± 10 ° and the principal ray is apex 13. Light that travels so as to form an image in other areas (rays d ₀ , d ₁ , d _{2 in} FIG. 3)
Is reflected by the inclined portion 14 of the convex projection 12, refracted at the top 13 and emitted at an angle other than ± 10 °. Therefore, even if the top portion 13 does not have a light diffusing property, the projection light 21 is diffused and emitted, which has the effect of widening the viewing angle.

In FIG. 3, the light beam d ₂ is the light beams d ₀ and d.
_{Although the} light is emitted from the tops 13 adjacent to ₁ , if the arrangement interval of the tops 13 is sufficiently smaller than the resolution of the human eyes to be observed or the resolution of the image, the image quality does not deteriorate.

Next, reduction of external light reflection will be described.
The cross-sectional view of FIG. 3 corresponds to the cross section taken along the alternate long and two short dashes line ff of FIG. Of the projection light 21, the projection light 21 that has entered the bottom portion 11a (hatched portion) in FIG. 4 does not reach the top portion 13 and repeatedly disappears due to repeated internal reflection. The ratio of the amount of light reaching 13 is the ratio of the area of the regular hexagon circumscribing the diameter A to the area of the circle of the diameter A, and is calculated as follows.

Π · (A / 2) ² / ((A / 2) × (A /
2) · tan 30 ° × 6) = 0.907 The above ratio value indicates that about 90% of the projection light 21 can be used.

On the other hand, if the outside light 23 is completely absorbed by the inclined portion 14 of the screen surface and the bottom portion 11a, the ratio of the area of the regular hexagon circumscribing the diameter A to the area of the circle of the diameter B is obtained. The incident light is incident on the apex 13 and becomes reflected light, which causes a reduction in contrast. This ratio is calculated as follows.

Π · (B / 2) ² / ((A / 2) × (A /
2) · tan 30 ° × 6) Here, when this ratio is calculated for the above example of θ = 10 °, B = 0.478A, and thus it is obtained as follows.

Π · (0.478 A / 2) ² / ((A / 2) ×
(A / 2) · tan 30 ° × 6) = 0.207 The above ratio value indicates that about 80% of the external light 23 is absorbed.

As described above, in the first embodiment, it is possible to reduce the loss of the amount of projection light and to significantly reduce the reflected light of external light. Further, the convex protrusion 12 can increase the degree of diffusion of light.

As shown in FIG. 5, the convex projections 12 are closely contacted so that the boundary between the cones is a regular hexagon when viewed from the screen surface. If the ratio of the diameter B of 13 is designed to be equal to the ratio of A and B of FIG. 4, the bottom portion 11a is eliminated, so that in the ideal state, the projection light 21 reaches 100% of the top portion 13. .

FIG. 6 shows a sectional view of the second embodiment of the present invention. In the second embodiment, in order to further increase the effect of absorbing the external light 23, the inclination of the inclined portion 14 of the convex protrusion 12 is increased, and the inclination of the inclined portion 14 is improved in order to improve the diffusion of the emitted light. The cross-sectional shape is a convex curve.

FIG. 7 shows an explanatory sectional view of the second embodiment.
As described in the first embodiment, when the angle width of the projection light 21 focused on one point on the screen is ± 10 °, the angle of the inclined portion 14 with respect to the screen normal is 17.7 °.
Must be: In the second embodiment, in order to further increase the effect of absorbing the external light 23, the inclination of the inclined portion is increased and this angle is made smaller than 17.7 °. In FIG. 7, 16 indicates a case where the inclined portion is a straight line with an angle of 10 °, and 14 indicates a case where the inclined portion is a curved line convex upward.

When the inclined portion is a straight line with an angle of 10 °,
The light beam b ₁ incident at 10 ° to the right travels inside the acrylic plate 11 at an angle of 6.7 °, is reflected by the inclined portion 16 at an angle of 10 °, and exits from the top 13 at an angle of 41.9 °. That is, when the inclined portion is a straight line with an angle of 10 °, when it is incident from the same direction as the light beam b ₁ and is reflected inside the inclined portion 16, regardless of its position, the peak is always 41.9 °. The light is emitted from the portion 13.

On the other hand, when the curved inclined portion is formed, the angle of the inclined portion near the top 13 is set to 1 as shown in FIG.
If it is set to 7.7 °, the light rays reflected in this vicinity (Fig. 7
Inside, the light ray a ₁ ) is incident on the apex 13 at an angle close to the critical angle, so that an output light ray at an angle of about 90 ° with respect to the normal is obtained. Further, the angle of incidence on the top 13 varies depending on the position reflected by the inclined portion 14. For this reason, it is more effective in widening the viewing angle than when the inclined portion is a straight line with an angle of 10 °.

Of the external light 23, that incident on the inclined portion 14 of the convex protrusion 12 is absorbed by the light absorption layer 15. Of the external light 23, that incident on the top 13 of the convex projection 12 is reflected by the top 13 to become external light reflected light 24. However, when the screen is viewed from the front, the top 13
By appropriately setting the ratio of the area of 1 to the area of the portion covered by the light absorption layer 15, the reflected light of external light can be sufficiently reduced.

FIG. 8 shows a sectional view of the third embodiment of the present invention. In the third embodiment, in order to increase the amount of emitted light, the inclination of the inclined portion 14 of the convex protrusion 12 is increased, and the cross-sectional shape of the inclined portion 14 is convex downward in order to improve the diffusion of the emitted light. And the curve.

FIG. 9 shows an explanatory sectional view of the third embodiment.
In the third embodiment, the inclination of the inclined portion 14 is increased to increase the ratio of the area of the top 13 to the area of the screen viewed from the front in order to increase the amount of emitted light. In this case, the angle of the inclined portion with respect to the screen normal of the inclined portion is 17.7.
Less than °. In FIG. 9, 16 indicates a case where the inclined portion is a straight line having an angle of 10 °, and 14 indicates a case where the inclined portion is a downward convex curve.

When the inclined portion is a straight line with an angle of 10 °,
The light beam b ₁ incident at 10 ° to the right travels inside the acrylic plate 11 at an angle of 6.7 °, is reflected by the inclined portion 16 at an angle of 10 °, and exits from the top 13 at an angle of 41.9 °. That is, when the inclined portion is a straight line with an angle of 10 °, when it is incident from the same direction as the light beam b ₁ and is reflected inside the inclined portion 16, regardless of its position, the peak is always 41.9 °. The light is emitted from the portion 13.

On the other hand, in the case where the inclined portion is formed by a curved line, as shown in FIG. 9, if the angle of the inclined portion near the bottom of the inclined portion 14 is set to 17.7 °, the light rays reflected in this vicinity ( In FIG. 9, the light ray a ₁ ) is at the top 1 at an angle close to the critical angle.
Since the light beam is incident on the beam No. 3, an output light beam having an angle of about 90 ° with respect to the normal is obtained. Further, the angle of incidence on the top 13 varies depending on the position reflected by the inclined portion 14. For this reason, it is more effective in widening the viewing angle than when the inclined portion is a straight line with an angle of 10 °.

Of the external light 23, that incident on the inclined portion 14 of the convex protrusion 12 is absorbed by the light absorption layer 15. Of the external light 23, that incident on the top 13 of the convex projection 12 is reflected by the top 13 to become external light reflected light 24. However, when the screen is viewed from the front, the top 13
By appropriately setting the ratio of the area of 1 to the area of the portion covered by the light absorption layer 15, the reflected light of external light can be sufficiently reduced.

Next, the manufacturing process of the first, second and third embodiments will be described. FIG. 10 is an explanatory view of the manufacturing process of the transmission screen of the above embodiment. Figure 10
(A) In the compression molding step, the lower mold 52 which is usually a flat plate
A large number of convex protrusions 12 are formed on the transparent resin plate 11 by sandwiching the transparent resin plate 11 between the upper mold 51 and the upper mold 51 having the concave recesses formed therein, and heating and pressing the transparent resin plate 11. The lower surface of the transparent resin plate 11 is usually a flat surface, but it may be a Fresnel surface or a lenticular surface in order to realize other optical effects.

(B) In the light absorption layer forming step, the surface of the convex protrusions 12 of the transparent resin plate 11 after molding and the convex protrusions 12 are formed.
This is a step of forming the light absorption layer 15 on the bottom 11a (see FIG. 2) in between. In order to form the light absorption layer 15, a method of applying a black paint, a method of soaking the surface of the transparent resin plate 11 with a pigment, a method of changing the composition of the surface of the transparent resin plate to blacken it, and the like are used.

(C) In the top polishing (dissolution) step, in order to remove the light absorption layer 15 on the top of the convex protrusion 12,
As shown by the dotted line h in FIG. 3, the top portion is removed to form a transparent light-transmitting top portion 13 as shown in.

To remove the top portion, there is a method of scraping off the top portion by polishing to form the top portion 13, or a method of dissolving or making the light absorption layer 15 transparent only in the top portion. In the method of polishing the top portion, roughening of the top portion 13 can be performed at the same time, so that the diffusion degree of light on the emission surface of the top portion 13 can be increased.

FIG. 11 is a view showing a method of using a roller for molding the transparent resin plate 11. A concave recess group is formed on one roller (upper die roller 53 in FIG. 11), and the transparent resin plate 11 or the resin film is formed in the gap between the upper and lower rollers (upper die roller 53, lower die roller 54). It is formed by passing (pressurizing) the material while heating it. This method is suitable when the area of the resin plate 11 is large or when molding a material having a small thickness.

FIG. 12 shows an example of steps for molding into another shape. As shown in FIG. 12, during the (a) molding step,
By forming the top 13 in a planar shape, workability in the step (c) top polishing (melting) step can be improved.

FIG. 13 shows a sectional view of the fourth embodiment of the present invention. In the fourth embodiment, the light reflection layer 1 is provided inside the light absorption layer 15.
6 is formed. In the fourth embodiment, when the projection light 21 reaches the inclined portion 14 of the convex protrusion 12 inside the transparent resin plate 11, it is reflected (diffuse reflection) on the surface of the light reflection layer 16,
Since the light travels in the direction of the top 13, the emission efficiency from the top 13 can be increased as compared with the case where the light reflection layer 16 is not provided.

On the other hand, of the external light 23, that incident on the inclined portion 14 of the convex projection 12 is absorbed by the light absorption layer 15. Of the external light 23, that incident on the top 13 of the convex projection 12 is reflected by the top 13 to become external light reflected light 24. However, when the screen is viewed from the front, the top 13
By appropriately setting the ratio of the area of 1 to the area of the portion covered by the light absorption layer 15, the reflected light of external light can be sufficiently reduced.

FIG. 14 is an explanatory view of the manufacturing process of the fourth embodiment. (A) After forming the convex protrusions 12 in the molding step,
(B) In the light reflecting layer forming step, the light reflecting layer 16 is formed on the surface of the convex projection 12. As a method for forming the light reflecting layer, there are a method of applying white or silver paint, a method of depositing a surface-reflective metal such as aluminum, and the like. (C) In the light absorption layer forming step, the light absorption layer 15 is formed on the upper surface of the light reflection layer 16. (D) In the top polishing step, the light absorption layer 15 and the light reflection layer 16 on the top of the convex projection 12 are removed to form the transparent top 13.

FIG. 15 shows a sectional view of the fifth embodiment of the present invention, and FIG. 16 shows a perspective view of the fifth embodiment. 15, 16
As shown in, in the fifth embodiment, the convex protrusion 12 is composed of the high refractive index layer 17 in the central portion and the bottom refractive index layer 18 in the peripheral portion. In the fifth embodiment, the projection light 21 has a convex projection 1
When incident on 2, the total reflection is repeated at the boundary between the high-refractive index layer 17 and the low-refractive index layer 18 to proceed, and the light is emitted from the apex 13 as outgoing light 22. Therefore, the projection light 21 can be efficiently emitted from the top 13.

On the other hand, of the external light 23, that incident on the inclined portion 14 of the convex projection 12 is absorbed by the light absorption layer 15. Of the external light 23, what is incident on the apex 13 of the convex protrusion 12 is reflected by the apex 13 to become external light reflected light, and the area of the apex 13 when the screen is viewed from the front, By appropriately setting the ratio of the area covered by the light absorption layer 15, the reflected light from outside light can be sufficiently reduced.

As a method of forming the high refractive index layer 17 and the low refractive index layer 18, the convex protrusions 1 having a high refractive index are formed on the transparent resin plate 11.
After forming 2, the surface of the convex projection 12 is coated with a low refractive index resin, or when the convex projection 12 is formed of a glass material, the surface of the convex projection 12 is made to have a low refractive index by an ion exchange method. There are methods such as rationalization.

FIG. 17 shows a sectional view of the sixth embodiment of the present invention. As shown in FIG. 17, in the sixth embodiment, the convex protrusion 12
The light diffusing layer 1 is formed inside the light reflecting layer 15 and near the top 13.
9 is formed. Therefore, in the sixth embodiment, the projection light 2
1 is diffused in the diffusion layer near the top 13 and emitted as outgoing light 22. Therefore, the degree of diffusion of the light emitted from the top 13 can be increased.

On the other hand, of the external light 23, that incident on the inclined portion 14 of the convex projection 12 is absorbed by the light absorption layer 15. Of the external light 23, what is incident on the apex 13 of the convex protrusion 12 is reflected by the apex 13 to become external light reflected light, and the area of the apex 13 when the screen is viewed from the front, By appropriately setting the ratio of the area covered by the light absorption layer 15, the reflected light from outside light can be sufficiently reduced.

FIG. 18 is an explanatory view of the manufacturing process of the sixth embodiment. As shown in (a), the transparent resin plate 11 used in the sixth embodiment has a light diffusion layer 19 containing a light diffusion substance on one side surface of the transparent resin plate 11. (B) In the molding process,
The convex protrusions 12 are formed by compression molding. Even after this molding, the light diffusion layer 19 is located on the surface portion of the convex protrusion 12. (C) In the light absorption layer forming step, the light absorption layer 15 is formed on the surface of the convex projection 12. (D) Top polishing (dissolution)
In the process, the light absorption layer 15 on the surface of the top 13 is removed.
At the time when the polishing (melting) step is completed, the light diffusion layer 19 is formed inside the light absorption layer 15 and near the top 13.

FIG. 19 shows a sectional view of the seventh embodiment of the present invention. As shown in FIG. 19, in the seventh embodiment, the light absorption layer 1
After the formation of 5, the light diffusion layer 20 is formed by applying a light diffusion material or the like, and the light diffusion layer 20 is formed near the top 13. After the projection light 21 is incident on the convex protrusion 12, it is diffused by the light diffusion layer 20 in the vicinity of the top 13 and emitted as emission light 22. Therefore, the degree of diffusion of the light emitted from the top 13 can be increased. In addition, in order to suppress the reflection of the external light 23 on the top portion 13, a slight amount of the light absorbing pigment may be added to the light diffusing substance.

On the other hand, of the external light 23, that incident on the inclined portion 14 of the convex protrusion 12 is absorbed by the light absorption layer 15. Of the external light 23, what is incident on the apex 13 of the convex protrusion 12 is reflected by the apex 13 to become external light reflected light, and the area of the apex 13 when the screen is viewed from the front, By appropriately setting the ratio of the area covered by the light absorption layer 15, the reflected light from outside light can be sufficiently reduced.

By combining the light reflecting layer of the fourth embodiment and the light diffusing layer of the sixth and seventh embodiments,
A screen with desired characteristics can be realized. Further, the convex protrusion 12 shown in each of the above-mentioned embodiments is not limited to the conical shape, and may be a pyramid shape. Further, the transparent member 11 is not limited to the transparent resin plate, but may be a transparent resin film.

FIG. 20 shows a sectional view of the eighth embodiment of the present invention. In the figure, 30 is a lenticular lens, which is made of transparent acrylic resin or glass. The lenticular lens 30 has a flat surface 33 on one surface and a lenticular portion 31 on which the other surface is formed with a plurality of semi-cylindrical lenses. In addition, a light absorption layer 32 (shown by hatching in the drawing), which is a feature of this embodiment, is formed in the lenticular portion 31 with a predetermined film thickness. In the transmissive screen having the configuration shown in the figure, the projection light 21 travels from the bottom to the top in the figure, and the external light 23 enters from the upper part of the lenticular lens 30 toward the flat surface 33.

Here, the optical path of the external light 23 when the external light 23 enters the lenticular lens 30 will be considered with reference to FIG. In the lenticular lens 30 shown in FIG. 21, the light absorption layer 32 is not provided in order to clearly show the optical path of the external light 23. However, the light absorption layer 32 is provided. However, the optical path of the external light 23 in the lenticular lens 30 is the same as that in which the light absorption layer 32 is not provided.

As shown in the figure, when the lenticular lens 30 is arranged so that the external light 23 is incident on the flat surface 33 and the projection light 21 is incident on the lenticular portion 31,
Most of the external light 23 that has entered from the flat surface 33 is repeatedly totally reflected by the lenticular portion 31, and passes through the path indicated by the arrow in FIG. That is, the external light 23 passes through a predetermined depth range portion along the outer surface of the lenticular portion 31. Further, since the external light 23 incident on the lenticular lens 30 is repeatedly totally reflected as described above, its optical path length becomes long.

In this embodiment, the lenticular lens 30 is used.
Paying attention to the above-mentioned optical path of the external light 23 that has penetrated into, the light absorbing layer 32 is formed in the region of the lenticular portion 31 through which the external light 23 passes. As a method of forming the light absorbing layer 32, for example, a method of forming a light absorbing material on the lenticular portion 31 by a film forming method such as sputtering or plating, and a method of impregnating the lenticular portion 31 with the light absorbing material can be considered. . Note that FIG. 20 shows a structure in which the light absorption layer 32 is formed by a sputtering method.

With this structure, the external light 23 that has entered the lenticular lens 30 passes through the light absorption layer 32 having a high light absorption rate, and its path is long, so that the external light 23
Most of the light is absorbed in the light absorption layer 32, and the amount of the external light 23 emitted from the flat surface 33 to the outside again decreases. Thereby, the reflection of external light can be reduced, and the contrast of the transmissive screen can be improved.

On the other hand, as shown in FIG.
Unlike the external light 23, 1 passes through the light absorption layer 32 so as to traverse the light absorption layer 32, so that the projection light 21 is absorbed by the light absorption layer 32 in a small proportion. Therefore, it is possible to suppress the reduction of the transmittance of the projection light, which also improves the contrast. Now, assuming that the ratio of the distance that the projection light 21 passes through the light absorption layer 32 and the distance that the outside light 23 passes through the light absorption layer 32 is 1:10, the light absorption rate of the projection light 21 in the light absorption layer 32 is It is about 11%, the light absorption rate of the external light 23 is about 80%, and the contrast of the transmissive screen can be improved to about 65.

FIG. 22 shows a modification of the above eighth embodiment. The structure shown in the figure is formed by impregnating the lenticular portion 31 with a light absorbing material. The light absorption layer 34 of this modified example is the lenticular portion 31.
The entire light-absorbing material is impregnated into the whole of the semi-cylindrical lens portion formed on the. Even with this configuration, the outside light 23 is compared with the distance that the projection light 21 passes through the light absorption layer 34.
The distance that the light passes through the light absorption layer 34 can be set to be long, and the contrast of the transmissive screen can be improved.

FIG. 23 shows a ninth embodiment of the present invention. In the figure, 35 is a lenticular lens,
It is made of transparent acrylic resin or glass. This lenticular lens 30 also has a flat surface 3
6 and the other surface is a lenticular portion 37 in which a plurality of kamaboko-shaped lenses are formed. Further, a light shielding portion 40 is formed at the tip of the lenticular portion 31. The light shielding portion 40 includes a groove portion 38 formed at the tip of the lenticular portion 31 and a light absorbing member 39 (shown by hatching in the figure) arranged inside the groove portion 38.
It is composed of and. Even in the transmissive screen having the configuration shown in the figure, the projection light 21 travels from the bottom to the top in the figure, and the external light 23 enters from the upper part of the lenticular lens 35 toward the flat surface 33.

As described above, the lenticular lens 3
When the outside light 23 enters into the inside 5, the outside light 23 travels in a predetermined area along the lenticular portion 37. Therefore,
By disposing the light absorbing member 39 in the optical path of the external light 23, it is possible to prevent the external light 23 from traveling.

By providing the light-shielding portion 40 in the lenticular portion 37 as described above, the traveling of the external light 23 is blocked, and the amount of the external light 23 emitted from the flat surface 36 to the outside can be reduced again. On the other hand, the light absorbing member 39
By setting the width dimension (shown by the arrow L in the figure) of the projector to be sufficiently small, the projection light 21 is not blocked by the light blocking section 40, and therefore, the contrast can be improved also by this configuration. .

The projection light 21 is generally incident on the lenticular lens 35 perpendicularly, and the light shield 40 is narrow and vertically long, so that the light shield 40 is practically used. Due to this, the projection light 21 is hardly blocked. Further, the formation position of the light shielding portion 40 is
The present invention is not limited to the apex of the lenticular portion 37, and the effect of this embodiment can be obtained if it is on the optical path of the external light 23.

FIG. 24 is an external view of the transmissive screen 45 mounted in the eighth and ninth embodiments. Generally, the transmissive screen 45 using a lenticular lens is
Two lenticular lenses 46 and 47 are used, and the extending directions of the lenses of the lenticular portions 48 and 49 are set to 9 degrees relative to each other.
It is configured so as to face each other with 0 ° difference. The reason why the extending directions of the lenses of the lenticular portions 48 and 49 are different from each other by 90 ° and they are arranged to face each other is that the lenticular lenses 46 and 47 have directivity in the light diffusion direction. In the example shown in the figure, the lenticular lens 46 diffuses light in the arrow Y direction in the figure, and the lenticular lens 47 diffuses light in the arrow X direction in the figure. Therefore, the two lenticular lenses 46 and 47
By combining the above, light can be diffused in both the arrow X direction and the arrow Y direction, and a transmissive screen capable of viewing an image from a wide range can be realized.

By applying the eighth and ninth embodiments to the lenticular lens 46 of the transmissive screen 45 having the above-mentioned structure, an image can be seen from a wide range and a transmissive screen having good contrast can be obtained. Can be realized.

[0094]

As described above, according to the present invention, the reflection of external light is reduced and the reduction of the transmittance of projection light is suppressed, so that the contrast can be improved.

[Brief description of drawings]

FIG. 1 is a sectional view of a first embodiment of the present invention.

FIG. 2 is a perspective view of the first embodiment of the present invention.

FIG. 3 is a sectional view for explaining a first embodiment of the present invention.

FIG. 4 is a plan view of the first embodiment of the present invention.

FIG. 5 is a plan view of a modified example of the first embodiment of the present invention.

FIG. 6 is a sectional view of a second embodiment of the present invention.

FIG. 7 is a sectional view for explaining a second embodiment of the present invention.

FIG. 8 is a sectional view of a third embodiment of the present invention.

FIG. 9 is a sectional view for explaining a third embodiment of the present invention.

FIG. 10 is an explanatory diagram of a manufacturing process.

FIG. 11 is a diagram showing a method of using a roller.

FIG. 12 is a diagram showing a process example in the case of molding into another shape.

FIG. 13 is a sectional view of a fourth embodiment of the present invention.

FIG. 14 is an explanatory diagram of the manufacturing process of the fourth example of the present invention.

FIG. 15 is a sectional view of a fifth embodiment of the present invention.

FIG. 16 is a perspective view of a fifth embodiment of the present invention.

FIG. 17 is a sectional view of a sixth embodiment of the present invention.

FIG. 18 is an explanatory diagram of the manufacturing process of the sixth embodiment of the present invention.

FIG. 19 is a sectional view of a seventh embodiment of the present invention.

FIG. 20 is a sectional view of an eighth embodiment of the present invention.

FIG. 21 is a diagram for explaining an optical path of external light that has entered the lenticular lens.

FIG. 22 is a diagram showing a modification of the eighth embodiment of the present invention.

FIG. 23 is a sectional view of a ninth embodiment of the present invention.

FIG. 24 is an external view of a transmissive screen to which the eighth or ninth embodiment of the present invention can be applied.

FIG. 25 is an explanatory diagram of an example of a conventional screen.

FIG. 26 is an explanatory diagram of a conventional screen in which a smoke plate is combined.

FIG. 27 is an explanatory diagram of a conventional screen using a lenticular lens.

[Explanation of symbols]

 11 Transparent Resin Plate 12 Convex Protrusion 13 Top 14 Slope 15 Light Absorption Layer 16 Light Reflection Layer 17 High Refractive Index Layer 18 Low Refractive Index Layer 21 Projected Light 22 Emitted Light 23 External Light 24 External Light Reflected Light 30, 35, 46,47 Lenticular lens 31,37,48,49 Lenticular part 32,34 Light absorbing layer 38 Groove part 39 Light absorbing member 40 Light shielding part 45 Transmissive screen

 ─────────────────────────────────────────────────── ─── Continued Front Page (72) Inventor Kazuhiro Okamoto 1015 Kamiodanaka, Nakahara-ku, Kawasaki-shi, Kanagawa Fujitsu Limited

Claims (11)

[Claims] 1. A plate-shaped or film-shaped transparent member (11), and a plurality of light-absorbing layers formed on one side surface of the transparent member (11) and on the inclined portion (14) other than the top (13). (15)
A transmissive screen comprising a convex projection (12) made of a transparent material in which is formed. 2. The convex protrusions (12) are inclined portions (1).
The transmissive screen according to claim 1, wherein the inclination of 4) is a straight line. 3. The convex protrusions (12) are provided with inclined portions (1).
The transmissive screen according to claim 1, wherein the slope of 4) is a curve. 4. The transmissive screen according to claim 1, wherein a light reflection layer (16) is provided inside the light absorption layer (15). 5. The transmissive screen according to claim 1, wherein the convex protrusions (12) are composed of a high refractive index layer (17) at a central portion and a low refractive index layer (18) at a peripheral portion. . 6. The apex (13) of the convex projection (12)
The transmissive screen according to claim 1, wherein a light diffusion layer (19, 20) is provided in the vicinity. 7. The lenticular portion (3) on at least one surface.
1) A lenticular lens (30) formed of a transparent body and a light absorption layer (32, 34) formed in the lenticular portion (31) of the lenticular lens (30). Is a transmissive screen. 8. The transmissive screen according to claim 7, wherein the light absorption layer (32) is formed on the lenticular portion (31) of the lenticular lens (30) by coating. 9. The transmissive screen according to claim 7, wherein the light absorbing layer (34) has a structure in which a lenticular portion (31) of the lenticular lens (30) is impregnated with a light absorbing material. . 10. A lenticular lens (35) formed of a transparent body having a lenticular portion (37) formed on at least one surface, and a lenticular lens (35) formed on or near the top of the lenticular portion (37). 35) A transmissive screen, characterized in that it is constituted by a light shielding part (40) which blocks the propagation of external light entering inside. 11. The light shielding portion (40) includes a groove portion (38) formed at or near the top of the lenticular portion (37), and a light shielding member (3) interposed in the groove portion (39).
The transmissive screen according to claim 10, which is constituted by 9) and