JP2006208593A - Diffusion optical sheet, transmission type screen, and back projection display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a diffusion optical sheet which is prevented from curving owing to environmental change in temperature, humidity, etc., to cause deterioration in picture quality and can prevent fragments of a substrate from scattering when the substrate is broken owing to an accident such as a collision, and is high in flatness and safe, and a transmission type screen and a back projection type display device using the same. <P>SOLUTION: A lenticular lens sheet 120 of the present invention has second and fourth scatter preventive layers 123 and 122 laminated integrally on both surfaces of a second glass substrate 121 and the fourth scatter preventive layer provided on an incidence side is provided with a lenticular lens portion 122a to solve the problem. Further, this lenticular lens sheet 120 is combined with a Fresnel lens sheet 110 as a different body to form one transmission type screen 100, which is used for a rear projection television 1. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a diffusing optical sheet used for a transmissive screen that emits image light projected from a light source to an emission side, a transmissive screen using the diffusing optical sheet, and a rear projection display device.

In a rear projection type display device that projects and displays image light from behind the screen, a transmissive screen is used as a screen for displaying the image light in an enlarged manner. Generally, this transmissive screen is a sheet having a diffusion effect such as a Fresnel lens sheet that refracts image light projected from a light source so as to be substantially parallel light toward the observation surface, and a lenticular lens that diffuses image light. Are used in combination.
Conventionally, a lenticular lens sheet and a Fresnel lens sheet used for such a transmission type screen are formed by laminating optical elements such as lenses on a plastic substrate such as an acrylic resin or a polycarbonate resin.

However, the thickness and size of a plastic substrate is likely to change due to environmental changes such as temperature and humidity. For this reason, the sheet is warped, and a float may be generated between the Fresnel lens sheet and the lenticular lens sheet. When image light is projected onto the transmissive screen in such a state, there is a problem in that the image quality is remarkably lowered, such as defocusing, color reproduction deterioration, double image, and image distortion.
In particular, in a thin rear projection television, since the incident angle of the image light to the transmissive screen is large, there is a problem that slight warping or floating generated on the screen has a great influence on the image quality.
Further, when the transmission type screen is enlarged, there is a problem that image deterioration due to warping and floating caused by environmental changes becomes more conspicuous than a small one, and there is a problem that it is easily bent due to its own weight.

In view of this, a transmission screen using a glass substrate that hardly warps due to changes in the environment such as temperature and humidity has been developed. Examples of the transmission screen using a glass substrate include, for example, Patent Document 1 to Patent Document 4 as shown below.
In Patent Document 1, a Fresnel lens sheet (described as “Fresnel lens plate” in Patent Document 1) and a lenticular lens layer (described as “lenticular lens sheet” in Patent Document 1) are laminated on one side of a glass substrate. An example of a transmission screen combined with a lenticular lens sheet (described as “lenticular lens plate” in Patent Document 1) is disclosed.
However, since the frontmost surface (most observed side surface) on the light exit side of the screen is a glass substrate, there is a problem that glass fragments are scattered when the glass substrate is damaged due to an accident or the like.
Patent Document 1 discloses an example in which a diffusing material is mixed with a glass substrate to give a diffusing effect. However, it is not easy to mix a diffusing material with a glass substrate, and the production cost is high. In addition, there is a problem that the glass substrate becomes brittle and easily breaks by mixing the diffusing material.

Patent Document 2 discloses a structure in which a lenticular lens sheet and a Fresnel lens sheet are supported in close contact with each other in a shape in which concave and convex curvatures are provided in opposite directions by heat treatment and a glass substrate is sandwiched therebetween.
However, the method disclosed in Patent Document 2 is possible with a Fresnel lens sheet in which a Fresnel lens shape is provided on the incident side of the Fresnel lens sheet, but the Fresnel lens shape on the exit side (glass substrate side) of the Fresnel lens sheet. However, the glass substrate and the lens surface are in close contact with each other, and the lens surface is rubbed.

Furthermore, Patent Document 3 discloses an example of forming a screen by directly forming a Fresnel lens on one plane of a glass substrate and integrally laminating a plastic sheet on which the lenticular lens is molded on the other plane. is doing.
However, forming a Fresnel lens directly on a glass substrate is technically not easy and has a problem of high production costs. Also, since only one side of the glass substrate is protected by the plastic sheet, the plane on the side where the Fresnel lens is formed is not protected, and if the glass substrate breaks due to an accident etc., the fragments will be There was a problem of scattering and scratches and dirt on the lens. Further, the valley portion of the Fresnel lens shape has a problem that stress is easily concentrated and is easily broken.

In Patent Document 4, an ultraviolet curable resin is applied to the surface of a glass substrate, a lens layer is adhered, an ultraviolet curable resin is applied to the surface of the lens layer as a protective layer, and the incident side and the emission side are completely flat Fresnel lens sheets. Further, an example is disclosed in which a glass substrate is further bonded on the protective layer to increase environmental resistance.
However, the technique disclosed in Patent Document 4 has a problem that the outermost surface is a glass substrate, so that fragments are scattered when the glass substrate is broken.

JP 2002-357868 A JP 2001-154274 A JP-A-2-183241 JP-A-2-44001

  The object of the present invention is to prevent warpage caused by changes in the environment such as temperature and humidity, and inferior image quality, and to prevent the fragments from scattering when the substrate is damaged due to an accident or the like. To provide a high and safe diffusing optical sheet, a transmissive screen and a rear projection display device using the same.

The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to the Example of this invention is attached | subjected and demonstrated, it is not limited to this.
The invention of claim 1 is a diffusion optical sheet used for a transmission type screen that emits image light projected obliquely from the incident side to the emission side, and has a high rigidity and a high rigidity substrate with high light transmission Layers (121, 221, 311, 421, 521) and anti-scattering layers (122, 123, 222, 223, 312, 313, 422, 423, 522) integrally laminated on both surfaces of the high-rigidity substrate layer 523) and a diffusion optical sheet (120, 220, 300, 420, 520) comprising a diffusion optical element (122a, 222a, 313a, 422a, 522a) provided on at least one surface of the anti-scattering layer It is.

  According to a second aspect of the present invention, there is provided the diffusion optical sheet according to the first aspect, wherein the high-rigidity substrate layers (121, 221, 311, 421, 521) are made of glass. It is a sheet (120, 220, 300, 420, 520).

  According to a third aspect of the present invention, in the diffusing optical sheet according to the first or second aspect, the diffusing optical element has a unit optical shape having a refracting surface that refracts at least part of incident light in a horizontal or vertical direction. A plurality of lenticular lenses (122a, 222a) arranged in a diffusing optical sheet (120, 220).

  According to a fourth aspect of the present invention, in the diffusing optical sheet according to the first or second aspect, the diffusing optical element has a plurality of unit optical shapes each having a total reflection surface that totally reflects at least a part of incident light. A diffusion optical sheet (300, 420, 520) characterized by being made.

  The invention according to claim 5 is the diffusion optical sheet according to any one of claims 1 to 4, further comprising a diffusion part for diffusing light, wherein the diffusion optical sheet (120, 220, 300, 420, 520).

  According to a sixth aspect of the present invention, in the diffusing optical sheet according to the fifth aspect, the diffusion portions are provided on the incident side and the emission side from the high-rigidity substrate layers (121, 221, 311, 421, 521), respectively. These are diffusion optical sheets (120, 220, 300, 420, 520) characterized by the following.

  The invention according to claim 7 is the diffusion optical sheet according to any one of claims 1 to 6, wherein the scattering prevention layer (122, 123, 222, 223, 312, 313, 422, 423, 522) is provided. , 523) has at least one function of diffusion, antireflection, antiglare, coloring, dimming, ultraviolet absorption, antistatic, antifouling, sensor, and hard coat. It is a sheet (120, 220, 300, 420, 520).

  The invention according to claim 8 is the diffusion optical sheet according to any one of claims 1 to 7, wherein the high-rigidity substrate layer (121, 221, 311, 421, 521) and the scattering prevention layer are provided. (122, 123, 222, 223, 312, 313, 422, 423, 522, 523) and the joining layers (124-1, 124-2, 224-1, 244-2, 314-1) integrally joined together. , 314-2, 424-1, 424-2, 524-1, 524-2), a diffusing optical sheet (120, 220, 300, 420, 520).

  The invention of claim 9 is the diffusing optical sheet according to claim 8, wherein at least one of the bonding layers includes at least one of a diffusion material for diffusing light and an ultraviolet absorber for absorbing ultraviolet rays. A diffusing optical sheet is characterized.

  The invention of claim 10 is a transmission type screen (100, 200, 300, 300) comprising the diffusing optical sheet (120, 220, 300, 420, 520) of any one of claims 1 to 9. 400,500).

  The invention according to an eleventh aspect is projected from the transmissive screen according to the tenth aspect (100, 200, 300, 400, 500), a light source unit (21, 22) for projecting image light, and the light source unit. The rear projection display device (1, 2) includes a mirror unit (31, 32) for reflecting the image light (L) toward the transmission screen.

According to the present invention, the following effects can be obtained.
(1) The diffusing optical sheet has a light-transmitting and high-rigidity substrate layer having high rigidity, thereby preventing warpage caused by changes in the environment such as temperature and humidity, and bending due to its own weight.
In addition, since the diffusion optical sheet has an anti-scattering layer laminated on both sides of the high-rigidity substrate layer, the high-rigidity substrate layer may be accidentally damaged during operations such as handling the diffusion optical sheet alone. However, the debris does not scatter and is safe. Furthermore, when this diffusion optical sheet is used for a transmission screen of a rear projection type display device, even if a high-rigidity substrate layer breaks due to an accident such as a collision, the fragments do not scatter and are highly safe. A transmissive screen and a rear projection display device can be provided.

(2) Since the high-rigidity substrate layer is formed of glass or translucent ceramics, it is possible to provide a diffusing optical sheet with high flatness that is unlikely to warp due to environmental changes such as temperature and humidity.
In addition, if a substrate made of glass or translucent ceramics is broken due to an accident such as a collision, the fragments are scattered and dangerous. However, the high-rigidity substrate layer according to the present invention prevents both sides from scattering. It is in a form covered by a layer, and when it is cracked or cracked, its debris does not scatter and is safe.

(3) Since the diffusion unit diffuses light, effects such as reduction of scintillation (screen glare), expansion of viewing angle, and improvement of uniformity of diffusion can be expected.

(4) Since at least one of the scattering prevention layer has at least one function of diffusion, ultraviolet absorption, antireflection, antiglare, dimming, coloring, hard coat, antistatic, antifouling, sensor, etc., high rigidity In addition to the effect of preventing debris from scattering when the substrate layer breaks, it is possible to expect effects such as improved image quality, screen protection, and improved functionality.

(5) Since the bonding layer integrally bonds the high-rigidity substrate layer and the anti-scattering layer, when the high-rigidity substrate layer breaks due to an accident or the like, the effect of the anti-scattering layer that prevents the fragments from scattering To increase.
Further, at least one of the bonding layers includes at least one of a diffusing material that diffuses light and an ultraviolet absorber that absorbs ultraviolet rays. Therefore, even when the bonding layer cannot be mixed with the anti-scattering layer, it includes a diffusing material to diffuse light and reduce scintillation (screen glare), wide viewing angle, Improvement in uniformity of diffusion can be expected, and by including an ultraviolet absorber, yellowing of the screen due to ultraviolet rays can be prevented.

  The present invention is a diffusive optical sheet that is difficult to warp due to changes in the environment such as temperature and humidity or to be bent due to its own weight, and that does not scatter when a substrate breaks due to an accident or the like, and the diffusing optical sheet For the purpose of providing a transmissive screen and a rear projection display device using a glass substrate, a scattering prevention layer is integrally laminated on both surfaces of the glass substrate, and a lenticular lens portion is formed on the scattering prevention layer on the incident side. This was realized by using a lenticular lens sheet provided with Further, this lenticular sheet and a separate Fresnel lens sheet were combined to form a pair of transmission screens, which were used in a rear projection display device.

FIG. 1 is a view showing a transmission screen of Example 1 using a lenticular lens sheet according to the present invention.
FIG. 2 is a cross-sectional view of a rear projection television using the transmission screen according to the first embodiment.
As shown in FIG. 1, the transmissive screen 100 of Example 1 is provided on the Fresnel lens sheet 110 provided on the incident side (light source side) of the image light L and on the emission side (observation surface side) of the image light L. The lenticular lens sheet 120 is combined, and these are combined to form a set of screens, which are arranged on the image plane of the image light L.
As shown in FIG. 2, the rear projection television 1 is a rear projection display device including a light source unit 21, a mirror unit 31, a transmission screen 100, and the like. This rear projection television 1 uses a mirror unit to receive image light L projected from a single-tube light source unit 21 using DMD, which is provided on the side opposite to the observation surface side (outgoing side) of the transmissive screen 100. The light is reflected at 31 and projected onto the transmissive screen 100 for display.

FIG. 3 is a diagram schematically showing the layer structure of the transmission screen of Example 1 using the lenticular lens sheet according to the present invention.
The image light L is indicated by an arrow in the figure, and enters the transmissive screen 100 from the right side in the figure and exits from the left side in the figure. In the figure, the layer in which the white circles are distributed indicates that it includes a diffusing material that diffuses light.

(Fresnel lens sheet)
First, the Fresnel lens sheet 110 will be described.
As shown in FIG. 3, the Fresnel lens sheet 110 includes a first glass substrate 111, a first scattering prevention layer 112, a third scattering prevention layer 113, and bonding layers 114-1 and 114-2. It is arranged on the incident side of the mold screen 100.
The first glass substrate 111 is a high-rigidity substrate layer having high light transmittance and high rigidity, and is a glass plate having a thickness of 2 mm formed of silicate glass. The thickness of the glass plate used for the 1st glass substrate 111 should just be in the range of 1.5-3 mm, and was 2 mm in the present Example. The first glass substrate 111 has a light transmittance of 90% or more in a wavelength band of 400 to 700 nm.

  The bonding layers 114-1 and 114-2 are layers for integrally bonding the first glass substrate 111 and first and third scattering prevention layers 112 and 113, which will be described later, and irradiate ultraviolet rays. It is formed of an ultraviolet curable acrylic resin that is cured by this, and its thickness is 100 μm. The bonding layer 114-1 is provided between the first glass substrate 111 and the first scattering prevention layer 112, and the bonding layer 114-2 is formed between the first glass substrate 111 and the third scattering prevention layer. It is provided in between.

  The first scattering prevention layer 112 is integrally laminated on the incident side from the first glass substrate 111 via the bonding layer 114-1, and has a function of preventing scattering when the first glass substrate 111 is damaged. It is a member having. This first scattering prevention layer is a general-purpose antireflection sheet having an antireflection function formed of an acrylic resin or the like, and has a thickness of 80 μm.

The third scattering prevention layer 113 is laminated integrally on the emission side of the first glass substrate 111 via the bonding layer 114-2, and has a function of preventing scattering when the first glass substrate 111 is damaged. It is a member having.
The third scattering prevention layer 113 is obtained by previously laminating a Fresnel lens portion 113a using a UV curable resin on one surface of the Fresnel base portion 113b on the first glass substrate 111.

The Fresnel base portion 113b is a sheet-like member having a thickness of 200 μm that serves as a base of the third scattering prevention layer 113, and is formed of an acrylic resin mixed with glass beads as a diffusing material, and serves as a diffusing portion that diffuses light. It has the function of. Here, glass beads having a diameter of 1 μm or more are used so that diffusion does not depend on the wavelength of light.
Here, the diffusing part is kneaded with particles formed of an organic or inorganic compound to a member serving as a base material, or the surface thereof is coated with particles formed of an organic or inorganic compound, or It is a part having a function of diffusing light by providing a fine uneven shape on the surface.

The Fresnel lens portion 113a is integrally formed on the emission side of the Fresnel base material portion 113b, and functions as a Fresnel lens that refracts the image light L incident from the incident side in a predetermined direction and emits it as substantially parallel light to the emission side. To do.
The Fresnel lens portion 113a heats a Fresnel lens molding die (not shown) having a reverse shape of a Fresnel lens, applies an ultraviolet curable resin to the mold surface, and the temperature of the applied ultraviolet curable resin. The Fresnel base material portion 113b is pressure-laminated on the ultraviolet curable resin filled in the mold while the resin is being cured, and the resin is cured by irradiating the ultraviolet light, and then the Fresnel base material portion 113b is peeled off from the mold. Are integrally formed. The ultraviolet curable resin is not particularly limited, but urethane acrylate, epoxy acrylate and the like are preferable.

(Lenticular lens sheet)
Next, the lenticular lens sheet 120 according to the present invention will be described.
As shown in FIG. 3, the lenticular lens sheet 120 includes a second glass substrate 121, a second scattering prevention layer 123, a fourth scattering prevention layer 122, and bonding layers 124-1 and 124-2. A diffusing optical sheet that refracts and diffuses L, and is disposed on the exit side of the transmissive screen 100.

The second glass substrate 121 is a highly rigid substrate layer having light transmittance and high rigidity. Like the first glass substrate 111, the second glass substrate 121 is a glass plate having a thickness of 2 mm formed of silicate glass. is there. Similar to the first glass substrate 111, the second glass substrate 121 has a light transmittance of 90% or more in the wavelength band of 400 to 700 nm.
The bonding layers 124-1 and 124-2 are layers for integrally bonding the second glass substrate 121, the fourth scattering prevention layer 122, and the second scattering prevention layer 123, and are ultraviolet curable. It is a 100-micrometer-thick layer formed with the acrylic resin.

The fourth scattering prevention layer 122 is integrally laminated on the incident side of the second glass substrate 121 via the bonding layer 124-1, and has a function of preventing scattering when the second glass substrate 121 is damaged. Have.
In the fourth scattering prevention layer 122, a lenticular lens portion 122a is formed in advance on one surface of the lenticular base material portion 122b using a thermoplastic resin, and a light absorbing portion 122c that absorbs light is formed on the other surface. The formed one is stacked on the second glass substrate 121. In this embodiment, the example in which the lenticular lens portion 122a is formed using a thermoplastic resin has been shown. .
The lenticular base material part 122b is a sheet-like member having a thickness of 200 μm serving as a base of the fourth scattering prevention layer 122, and is formed of an acrylic resin in which glass beads are mixed as a diffusing material, and has a function as a diffusing part. .

The lenticular lens part 122a is a diffusing optical element formed integrally on the incident side surface of the lenticular base part 122b. The diffusion optical element is a lens or prism-shaped optical element having an effect of diffusing light.
The lenticular lens portion 122a is formed by arranging a plurality of unit lenses having a diffusion effect in the horizontal direction. The unit lens is a unit optical shape having a refracting surface that refracts at least a part of incident light, and has a shape that protrudes toward the emission side having a substantially elliptical cross section.
The light absorbing parts 122c are arranged in stripes in the vertical direction of the transmissive screen 100 in a region where the image light on the emission side surface of the lenticular base material part 122b does not pass.

The second scattering prevention layer 123 is integrally bonded to the emission side of the second glass substrate 121 via the bonding layer 124-2, and prevents the scattering when the second glass substrate 121 breaks. It is a member which has.
This second scattering prevention layer 123 is a sheet-shaped member having a thickness of 188 μm formed by mixing glass beads as a diffusing material in polyethylene terephthalate resin or the like, and functions as a diffusing portion for diffusing light. Have

By combining the lenticular lens sheet 120 and the Fresnel lens sheet 110 according to the present invention into a set of transmission screens 100, the following effects can be obtained.
The Fresnel lens sheet 110 and the lenticular lens sheet 120 use the first and second glass substrates 111 and 121 as substrates. Accordingly, it is possible to provide a transmissive screen that is unlikely to be warped or floated due to changes in the environment such as temperature and humidity, or to bend due to its own weight, can prevent image distortion, and can obtain a high-quality image due to high flatness.

  Further, the Fresnel lens sheet 110 and the lenticular lens sheet 120 are respectively provided with first and third scattering prevention layers 112 and 113, second and fourth scattering on both surfaces of the first and second glass substrates 111 and 121, respectively. Since the prevention layers 123 and 122 are integrally laminated, the first and second glass substrates 111 and 121 are damaged due to an accident or the like while the Fresnel lens sheet 110 and the lenticular lens sheet 120 are handled alone. In addition, it is possible to prevent debris from being scattered and to be safe.

  Further, the transmissive screen 100 uses such a Fresnel lens sheet 110 and a lenticular lens sheet 120, so that the most incident side surface and the most emitted side surface of the transmissive screen 100 are covered with a scattering prevention layer. Therefore, the transmissive screen 100 is safe because it can prevent the broken pieces from scattering when the first and second glass substrates 111 and 121 are cracked or broken due to an accident such as a collision.

  Since the first scattering prevention layer 112 is an antireflection sheet having an antireflection function, when the image light L is incident on the transmissive screen 100, the first scattering prevention layer 112 is on the most incident side surface (side surface of the most light source part) of the transmissive screen 100. Reduce stray light caused by reflection. Therefore, it is possible to reduce the occurrence of double images (ghosts) caused by stray light generated in such a manner being reflected again by the mirror unit 31 and entering the transmission screen 100, thereby improving the image quality.

  The lenticular base material part 122b and the second scattering prevention layer 123 are substantially uniformly mixed with glass beads as a diffusing material to provide a function as a diffusing part, thereby widening the viewing angle and improving diffusion uniformity. In addition to the above effects, it is possible to reduce scintillation (glare of the screen) that is likely to occur when the light source unit 21 is a single-tube light source such as DMD, and a high-quality image can be provided to the observer.

  Moreover, the Fresnel base material part 113b and the lenticular base material part 122b do not provide a diffusion layer having a diffusion effect as a separate layer by mixing glass beads as a diffusion material substantially uniformly to give a function as a diffusion part. In addition, the total number of layers of the transmissive screen 100 can be reduced. Therefore, the transmission screen 100 can be made thin and light, and the process can be simplified.

(Modification of Example 1)
(1) FIG. 4 is a diagram schematically showing a layer configuration of a modified example of the Fresnel lens sheet in the transmission screen of the first embodiment.
In the figure, a layer in which white circles are distributed indicates that a diffusion material that diffuses light is included. In addition, a layer whose boundary portion is indicated by a fine curve indicates that a fine uneven shape is provided on the surface of the layer.
In this embodiment, the Fresnel lens sheet 110 is mixed with the Fresnel base material portion 113b substantially uniformly as a diffusing material and imparts a function as a diffusing portion, but imparts a function as a diffusing portion. The number of layers and the number thereof are not particularly limited. Although the example of the layer which provides the function as a spreading | diffusion part below is shown, it is not this limitation.
The Fresnel lens sheet 110 does not mix a diffusing material with the Fresnel base material portion 113b (Fresnel base material portion 113b-2), and as shown in FIG. 4A, the first glass substrate 111 and the first scattering prevention The diffusion layer (bonding layer 114-1-2) may be mixed with the bonding layer 114-1 provided between the layer 112 and the diffusion layer (bonding layer 114-1-2), or as shown in FIG. A diffusion material (bonding layer 114-2-2) may be formed by mixing a diffusion material substantially uniformly with the bonding layer 114-2 provided between the glass substrate 111 and the third scattering prevention layer 113.

  As shown in FIG. 4 (c), the Fresnel lens sheet 110 does not mix a diffusing material in the Fresnel base material portion 113b, but has a diffusing effect by providing a fine uneven shape on the incident side surface thereof. It is good also as (Fresnel base material part 113b-3). At this time, it is preferable that the difference in refractive index between the Fresnel base material portion 113b-3 and the bonding layer 114-2 is larger when a diffusion effect is imparted. In addition to this example, when a fine uneven shape is provided on the surface of a layer to provide a function as a diffusion portion, the difference in refractive index between two layers in contact with the surface provided with the uneven shape should be as large as possible. The diffusion effect is increased and preferable.

  As shown in FIG. 4D, the Fresnel lens sheet 110 does not mix the diffusing material with the Fresnel base material portion 113b (Fresnel base material portion 113b-2), and is perpendicular to the first scattering prevention layer 112-2. You may provide the lenticular lens part 112a-2 and the lenticular base material part 112b-2 which have the effect of diffusing light in a direction. In addition, although not shown, the first scattering prevention layer 112-2 may be arranged in a plurality of prism shapes that protrude toward the emission side, have a substantially triangular cross section, and have an effect of diffusing light in the vertical direction.

  Further, as shown in FIG. 4 (e), the Fresnel lens sheet 110 does not mix the diffusing material with the Fresnel base material portion 113b (Fresnel base material portion 113b-2), and the first scattering prevention layer 112 is made of polyethylene. A layer having a thickness of 188 μm formed by mixing glass beads as a diffusing material with terephthalate resin in a substantially uniform manner may be laminated to form a diffusion portion (first scattering prevention layer 112-3). It is good also as a diffused part by laminating. Although not shown, the first scattering prevention layer 112 may be provided with a fine uneven shape on the incident side surface to serve as a diffusion portion.

(2) FIG. 5, FIG. 6, and FIG. 7 are diagrams schematically showing a layer configuration of a modification of the transmission screen of Example 1 of the lenticular lens sheet according to the present invention.
In the present embodiment, the lenticular sheet 120 has shown an example in which glass beads as a diffusing material are mixed substantially uniformly into the lenticular base material portion 122b and the second scattering prevention layer 123 to provide a function as a diffusing portion. However, there are no particular limitations on the number of layers and the number of layers that provide the function as the diffusion portion. The layer configuration in the case where two diffusion portions are provided is shown below, but this is not restrictive.

As an example in which a diffusing portion is provided on each of the incident side and the emitting side of the second glass substrate 121, the lenticular lens sheet 120 does not mix a diffusing material with the lenticular base portion 122b (lenticular base portion 122b-2). As shown in FIG. 5 (a), a diffusion layer 125-1 having a thickness of 188 μm formed by mixing a polyethylene terephthalate resin with a diffusion material such as glass beads substantially uniformly is mixed with the second glass substrate 121 and the fourth scattering. You may laminate | stack between the prevention layer 122 through bonding layer 124-3, 124-4.
Further, the lenticular lens sheet 120 is provided with the diffusion layer 125-1 as described above, and as shown in FIG. 5 (b), the second scattering prevention layer 123 is not mixed with a diffusion material (second scattering prevention). Layer 123-2), a diffusion material is mixed with the bonding layer 124-2 provided between the second glass substrate 121 and the second scattering prevention layer 123-2, and the diffusion portion (124-2-2). Alternatively, as shown in FIG. 5 (c), the lenticular lens sheet 120 is not mixed with the diffusing material in the second scattering prevention layer 123, and a fine uneven shape is provided on the surface thereof, so that the diffusing portion ( It is good also as a 2nd scattering prevention layer 123-3).

The lenticular lens sheet 120 does not mix a diffusing material with the second scattering prevention layer 123 (second scattering prevention layer 123-2), and as shown in FIG. A diffusion layer 125-2 similar to the diffusion layer 125-1 may be stacked between the two scattering prevention layers 123-2 via bonding layers 124-5 and 124-6.
Further, a diffusion layer 125-2 is provided, and as shown in FIG. 5E, the lenticular base material portion 122b is not mixed with the diffusion material (lenticular base material portion 122b-2), and the second glass substrate 121 and the second glass substrate 121 are formed. The diffusion layer (bonding layer 124-1-2) may be obtained by mixing the diffusion material substantially uniformly with the bonding layer 124-1 provided between the four scattering prevention layers 122.
Further, the lenticular lens sheet 120 is provided with a diffusion layer 125-2, and as shown in FIG. 5 (f), the lenticular base material portion 122b is not mixed with a diffusing material, and a fine uneven shape is provided on the surface to diffuse. It is good also as a part (lenticular base material part 122b-3).

  When the diffusion layer is not provided as a separate layer, the lenticular lens sheet 120 is provided with a fine uneven shape on the surface thereof without mixing the diffusion material with the second scattering prevention layer 123 as shown in FIG. The diffusion part (second scattering prevention layer 123-3) may be used. Further, as shown in FIG. 6H, the lenticular lens sheet 120 does not mix the diffusing material in the second scattering prevention layer 123 (second scattering prevention layer 123-2), and the second glass substrate 121. The diffusion layer (bonding layer 124-2-2) may be formed by mixing the diffusion material substantially uniformly with the bonding layer 124-2 provided between the second scattering prevention layer 123 and the diffusion layer. Although not illustrated, at this time, the lenticular base material part 122b may be provided with a fine uneven shape on the surface thereof without mixing the diffusing material to serve as a diffusing part.

Moreover, the lenticular lens sheet 120 does not mix a diffusing material with the lenticular base material portion 122b (lenticular base material portion 122b-2), and as shown in FIG.
It is good also as a diffusion part (bonding layer 124-1-2) by mixing a diffusion material with 24-1, or, as shown in FIG.6 (j), a diffusion material is mixed with the bonding layer 124-1, and a diffusion part. (Bonding layer 124-1-2), a diffusing material is not mixed in the second scattering prevention layer 123, and a minute concavo-convex shape is provided on the surface thereof as a diffusion portion (second scattering prevention layer 123-3). Also good.
Furthermore, the lenticular lens sheet 120 does not mix a diffusing material in the lenticular base material portion 123b and the second scattering prevention layer 123 as shown in FIG. 6 (k) (lenticular base material portion 122b-2, second scattering). Diffusion layer is mixed into the bonding layers 124-1 and 124-2, which integrally laminate the prevention layer 123-2), the second glass substrate 121, and the fourth and second scattering prevention layers 122 and 123. It is good also as a part (bonding layer 124-1-2, 124-2-2).

  As an example in which two diffusing portions are provided on the incident side from the second glass substrate 121, the lenticular lens sheet 120 is not mixed with a diffusing material in the second scattering prevention layer 123 as shown in FIG. A diffusion layer 125-2 may be provided between the second scattering prevention layer 123-2) and the second glass 121 and the fourth scattering prevention layer 122. At this time, although not shown, the lenticular base material portion 122b may be formed as a diffusion portion by providing a fine uneven shape on the surface thereof without mixing the diffusion material.

  Using the above-described method, if the function as a diffusing portion having a diffusing effect is given to two or more non-adjacent layers on the exit side from the Fresnel lens portion 113b as a whole, the viewing angle is increased. In addition, effects such as improvement in uniformity of diffusion and reduction in scintillation can be expected, and image quality can be improved.

(3) In the present embodiment, the lenticular lens portion 122a is an example of a lenticular lens in which a plurality of unit lenses having a substantially elliptical cross section are arranged and has a horizontal diffusion effect. However, the present invention is not limited thereto. For example, a microlens array or the like may be used.

(4) In this embodiment, the lenticular lens sheet 120 is provided with the lenticular lens portion 122a and the lenticular base material portion 122b is provided on the fourth scattering prevention layer 122. m), a lenticular lens part 123a-4 and a lenticular base material part 123b-4 may be provided on the second scattering prevention layer 123-4.
In FIG.7 (m), although the lenticular lens sheet 120 has shown the example which mixes a diffusing material substantially uniformly with the lenticular base-material part 123b-4 and the 4th scattering prevention layer 122-2, and makes it a diffusion part. The number of layers and the number of layers that provide the function as the diffusion portion are not particularly limited as in the case of the above-described modification.

FIG. 8 is a view showing a transmission screen of Example 2 using the diffusion optical sheet according to the present invention.
The transmissive screen 400 of Example 2 includes a Fresnel lens sheet 410 provided on the incident side of the image light L and a diffusion optical sheet 420 provided on the output side of the image light L. Like the transmissive screen 100 shown in the first embodiment, the screen is formed as a set of screens and used in the rear projection television 1 shown in FIG.

FIG. 9 is a diagram schematically showing the layer structure of the transmission screen of Example 2 using the diffusion optical sheet according to the present invention.
The image light L is indicated by an arrow in the figure, and enters the transmissive screen 400 from the right side in the figure and exits from the left side in the figure. In addition, a layer in which white circles are distributed in the drawing indicates that it includes a diffusing material that diffuses light.

Here, the Fresnel lens sheet 410 includes a first glass substrate 411, a first scattering prevention layer 412, a third scattering prevention layer 413, and bonding layers 414-1 and 414-2. The same member as the Fresnel lens sheet 110.
Therefore, the first glass substrate 411, the first scattering prevention layer 412, the third scattering prevention layer 413, and the bonding layers 414-1 and 414-2 in the Fresnel lens sheet 410 of this example are each of Example 1. This corresponds to the first glass substrate 111, the first scattering prevention layer 112, the third scattering prevention layer 113, and the bonding layers 114-1 and 114-2 in the Fresnel lens sheet 110, and has the same function. Therefore, the overlapping description is omitted.

(Diffusion optical sheet)
The diffusion optical sheet 420 is provided on the emission side of the transmissive screen 400, and includes a second glass substrate 421, a second scattering prevention layer 423, a fourth scattering prevention layer 422, and bonding layers 424-1 and 424-2. And an optical sheet that diffuses by totally reflecting at least part of incident video light.
The second glass substrate 421 is a highly rigid substrate layer having optical transparency and high rigidity. The second glass substrate 421 is a 3 mm thick glass plate formed of silicate glass, and has a light transmittance of 90% or more in the wavelength band of 400 to 700 nm.

  The bonding layers 424-1 and 424-2 are layers for integrally bonding the second glass substrate 421 and fourth and second scattering prevention layers 422 and 423 described later, and are adhesive by pressure. Is formed of a pressure-sensitive adhesive acrylic resin, and its thickness is 20 μm. In this embodiment, the thickness of the bonding layers 424-1 and 424-2 is 20 μm, but is not particularly limited as long as it is in the range of 20 to 30 μm.

The fourth scattering prevention layer 422 is a member integrally laminated on the incident side of the second glass substrate 421 via the bonding layer 424-1, and when the second glass substrate 421 is cracked, It has a function to prevent the scattering.
The fourth scattering prevention layer 422 is obtained by previously forming the diffusion optical element 422a on one surface of the diffusion optical element base part 422b using an ultraviolet curable resin in the same manner as the Fresnel lens part 113a shown in the first embodiment. Is stacked on the second glass substrate 421.
The diffusion optical element base material part 422b is a sheet-like member having a thickness of 200 μm serving as a base of the fourth scattering prevention layer 422, and is formed of an acrylic resin mixed with a diffusion material such as glass beads, and serves as a diffusion part. It has the function of.

FIG. 10 is a cross-sectional view of the diffusing optical element.
The diffusing optical element 422a has a plurality of unit optical shapes 422c formed on the emitting side surface of the diffusing optical element base 422b by the same ultraviolet curable resin as the Fresnel lens 113a shown in the first embodiment. Projected and arranged.
As shown in FIG. 10, the unit optical shape 422c is a shape whose cross section protrudes toward a substantially trapezoidal emission side, and absorbs light in a portion where the cross section between adjacent unit optical shapes is triangular. A light absorbing portion 422d is formed. The light absorbing portion 422d is formed of a material having a lower refractive index than the optical shape 422c.
The diffusing optical element 422a has an effect of diffusing at least a part of the light incident from the lower bottom portion of the unit optical shape 422c in a predetermined direction by the hypotenuse portion 422e of the unit optical shape 422c to be emitted from the upper bottom portion. Have.

As shown in FIG. 9, the second scattering prevention layer 423 is a layer laminated integrally on the emission side of the second glass substrate 421 via the bonding layer 424-2, and the second glass substrate. When 421 is damaged, it has a function of preventing scattering.
The second scattering prevention layer 423 is a sheet-like member having a thickness of 188 μm formed by mixing glass beads with polyethylene terephthalate resin or the like as a diffusing material, and has a function as a diffusing portion.

By including the diffusing optical sheet 420 and the Fresnel lens sheet 410 according to the present invention, the transmissive screen 400 according to the second embodiment is similar to the transmissive screen 100 according to the first embodiment in the environment such as temperature and humidity. A transmissive screen with high flatness that hardly warps or floats due to change, or bends due to its own weight, and can provide a high-quality image.
Moreover, the transmission type screen 400 of Example 2 can prevent scattering of fragments when the first and second glass substrates 411 and 421 are cracked, like the transmission type screen 100 shown in Example 1. , Safe.
Further, the diffusion optical element 422a used for the diffusion optical sheet 420 is easy to manufacture and can produce a high-definition one. Therefore, the diffusion optical sheet and the transmission type can obtain a high-quality image at low cost. Can provide a screen.

  Furthermore, since the diffusing optical sheet 420 can be fine pitch, the transmission type screen 400 of Example 2 has higher definition than the transmission type screen 100 using the lenticular lens sheet 120 shown in Example 1. Can provide high-quality images.

(Modification of Example 2)
(1) The Fresnel lens sheet 410 of the present embodiment is the same member as the Fresnel lens sheet 110 shown in the first embodiment. Therefore, the Fresnel lens sheet 410 of the present embodiment can use a modification of the Fresnel lens sheet 110 shown in Embodiment 1 as a modification thereof.
(2) The diffusing optical sheet 420 of the present embodiment has a substantially triangular shape with a cross-section projecting to the incident side on the incident side surface of the diffusing optical element substrate 422b, and diffuses light vertically or horizontally (not shown). A plurality of prism shapes may be arranged, or a fine uneven shape (not shown) may be provided on the incident-side surface of the diffusing optical element substrate portion 422b. By providing such a prism shape or uneven shape, external light incident from the observation surface side (outgoing side) of the transmission screen 400 is reflected at the incident side interface of the prism shape or uneven shape, and is absorbed by the light absorbing portion 422d. Since the light is absorbed, deterioration in image quality such as a decrease in contrast due to external light can be reduced.

(3) In the present embodiment, the diffusion optical sheet 420 has a function as a diffusion portion by mixing glass beads with the second scattering prevention layer 423 and the diffusion optical element base portion 422b substantially uniformly as a diffusion material. Although the example to provide was shown, the layer to which the function as a spreading | diffusion part is provided and the number thereof are not specifically limited. Examples are shown below, but are not limited thereto.
When the diffusing optical sheet 240 is mixed with the diffusing optical element base material portion 422b to form a diffusing portion, the diffusing material is not applied to the bonding layer 424-1 or the bonding layer 424-2, but to the second scattering prevention layer 423. It is good also as a spreading | diffusion part.
Further, in the case where the second scattering prevention layer 423 has a function as a diffusion portion, the diffusion optical sheet 420 has a diffusion material on the bonding layer 424-1 or the bonding layer 424-2, not on the diffusion optical element base material portion 422b. It is good also as a diffusion part by mixing.
Further, the diffusion optical sheet 420 is formed by, for example, mixing a diffusion material into the diffusion optical element base material part 422b or the like to form a diffusion part, and laminating a general-purpose antireflection sheet or the like on the second scattering prevention layer 423, and a polyethylene terephthalate resin. A diffusion layer (not shown) formed by mixing the diffusion material substantially uniformly with the second glass substrate 421 and the second scattering prevention layer 423 or between the second glass substrate 421 and the fourth scattering layer. You may laminate | stack between the prevention layers 422. At this time, the second scattering prevention layer 423 may use an antiglare sheet or the like.

(4) FIG. 11 is a diagram schematically showing a layer configuration of a modified example of the diffusion optical sheet according to the present invention.
In this embodiment, the diffusion optical sheet 420 has an example in which the diffusion optical element 422a and the diffusion optical element base material portion 422b are provided in the fourth scattering prevention layer 422. However, the present invention is not limited to this example. As shown to a), you may provide the diffusion optical element 423a-2 and the diffusion optical element base-material part 423b-2 in the 2nd scattering prevention layer 423-2. At this time, the transmissive screen 400 is provided with the light absorbing portion of the diffusing optical portion 423b-2 on the most emission side, and an effect of improving the contrast of the image can be expected.
In FIG. 11 (a), the diffusion optical sheet 420 is a mixture of a diffusion material in the diffusion optical element base material portion 423b-2 and the fourth scattering prevention layer 422-2 provided in the second scattering prevention layer, Although an example of the diffusion unit is shown, the number and the layer to which the function as the diffusion unit is given are not limited to this and are not particularly limited.
At this time, as shown in FIG. 11B, the diffusion optical sheet 420 has a diffusion layer 425 formed by mixing a diffusion material with polyethylene terephthalate resin or the like on the emission side of the diffusion optical element 423a-2. Further, by integrally stacking the layers via the bonding layer 424-3, diffusion may be made uniform and image quality may be improved. Further, instead of the diffusion layer 425, a general-purpose diffusion sheet or the like may be laminated.

FIG. 12 is a diagram showing a transmission screen of Example 3 using the lenticular lens sheet according to the present invention.
FIG. 13 is a cross-sectional view of a rear projection television using the transmission screen of the third embodiment.
As shown in FIG. 12, the transmissive screen 200 according to the third embodiment includes a prism sheet 210 on the light source unit 22 side, a lenticular lens sheet 220 on the observation surface side, and a combination of these. , Used in the rear projection television 2 shown in FIG.
As shown in FIG. 13, the rear projection television 2 is a rear projection display device including a light source unit 22, a mirror unit 32, and a transmissive screen 200. The light source unit 22 is a single tube type light source using DMD, and projects the image light L from below the transmissive screen 200. Therefore, the incident angle at which the image light L enters the transmissive screen 200 is larger than that of the rear projection television 1.

FIG. 14 is a diagram schematically showing the layer structure of the transmission screen of Example 3 using the lenticular lens sheet according to the present invention.
The image light L is indicated by an arrow in the figure, and enters the transmissive screen 200 from the right side in the figure and exits from the left side in the figure. In addition, a layer in which white circles are distributed in the drawing indicates that a diffusing material that diffuses light is mixed.
The lenticular lens sheet 220 is provided on the exit side of the transmission screen 200, and includes a second glass substrate 221, a fourth scattering prevention layer 222, a second scattering prevention layer 223, and bonding layers 224-1 and 224-2. It is the diffusion optical sheet which has. This lenticular lens sheet 220 is the same member as the lenticular lens sheet 120 of Example 1, and the respective layers are the first glass substrate 121, the fourth scattering prevention layer 122, and the second scattering of Example 1. It corresponds to the prevention layer 123 and the bonding layers 124-1 and 124-2 and has the same function. Therefore, the overlapping description is omitted.

(Prism sheet)
As shown in FIG. 14, the prism sheet 210 includes a first glass substrate 211, a first scattering prevention layer 212, a third scattering prevention layer 213, and bonding layers 214-1 and 214-2, and is a transmission type. It is provided on the incident side of the screen 200.
The first glass substrate 211 is a highly rigid substrate layer that has optical transparency and high rigidity. The first glass substrate 211 is a 3 mm thick glass plate formed of silicate glass, and has a light transmittance of 90% or more in a wavelength band of 400 to 700 nm.
The bonding layers 214-1 and 214-2 are layers for integrally bonding the first glass substrate 211, the first scattering prevention layer 212, and the third scattering prevention layer 213, and are adhesive by pressure. Is formed of a pressure-sensitive adhesive acrylic resin, and its thickness is 20 μm.

The first scattering prevention layer 212 is a member that is integrally laminated on the incident side of the first glass substrate 211 via the bonding layer 214-1, and is scattered when the first glass substrate 211 is damaged. It has the function to prevent.
In the first scattering prevention layer 212b, the prism portion 212a is previously formed on one surface of the prism base material portion 212b using an ultraviolet curable resin in the same manner as the Fresnel lens portion 113a shown in the first embodiment. The glass substrate 211 is laminated.
The prism base member 212b is a sheet-like member having a thickness of 200 μm that serves as a base for the first scattering prevention layer 212, and is formed of an acrylic resin in which glass beads are mixed as a diffusing material, and has a function as a diffusing portion. .

FIG. 15 is a cross-sectional view of the prism portion.
As shown in FIG. 15, the prism unit 212a has a plurality of unit prisms 212e having an incident surface 212c on which the image light L is incident and a total reflection surface 212d that totally reflects at least a part of the light incident from the incident surface 212c. 12 are arranged concentrically from the center P of the concentric circle outside the prism sheet 210, as shown in FIG.

As shown in FIG. 14, the third scattering prevention layer 213 is a member that is integrally laminated on the emission side of the first glass substrate 211 via the bonding layer 214-2, and the first glass substrate. It has a function of preventing scattering when 211 is damaged.
The third scattering prevention layer 213 is a sheet-like member having a thickness of 188 μm, which is formed by mixing polyethylene terephthalate resin or the like with glass beads or the like as a diffusion material, and has a function as a diffusion portion.

The transmissive screen 200 of the second embodiment including the lenticular lens sheet 220 and the prism sheet 210 according to the present invention improves the image quality by improving the flatness, and the first and second glass substrates 211 and 221 break. In addition to the effect of preventing debris from scattering, the following effects can be obtained.
In the rear projection television 2, since the light source unit 22 is provided below the transmission screen 200, the incident angle of the image light projected from the light source unit 22 is large. However, by providing the prism portion 212a on the incident side of the transmissive screen 200, the incident video light can be totally reflected and emitted to the observation surface side (outgoing side) as substantially parallel light. can do.

  Further, since the rear projection television 2 has a large incident angle of the image light L, the influence of image degradation caused by slight warping or floating of the transmission screen 200 is much higher than that of the rear projection television 1 of the first embodiment. Big. In particular, the farther from the light source unit 22, such as the upper side of the transmissive screen, the greater the influence on the image quality due to the floating of the transmissive screen.

  However, the prism sheet 210 and the lenticular lens sheet 220 according to the present invention are integrally laminated on the first glass substrate 211 and the second glass substrate 221, respectively. Since warpage and floating due to environmental changes such as humidity and humidity, bending due to its own weight hardly occur, and flatness is improved, even when the incident angle of the image light L is large as in the case of the rear projection television 2, it is high for the observer. Can provide high quality images.

(Modification of Example 3)
(1) Since the lenticular lens sheet 220 of this embodiment is the same member as the lenticular lens sheet 120 shown in Embodiment 1, the lenticular lens sheet 220 is a modification of the lenticular lens sheet 120 as a modification thereof. It is possible to use.

FIG. 16 is a diagram schematically illustrating a layer configuration of a modified example of the prism sheet in the transmission screen of the third embodiment.
(2) In the prism sheet 210 of the present embodiment, an example in which a diffusion material such as glass beads is mixed substantially uniformly into the prism base portion 212b and the third scattering prevention layer is shown as a diffusion portion. In addition, in the prism sheet 210, the number of layers and the number of layers imparting a function as a diffusion portion are not particularly limited.
For example, as shown in FIG. 16, the prism sheet 210 does not mix the diffusing material into the prism base material portion 212b (prism base material portion 212-b) and mixes the diffusing material into the bonding layer 214-1 substantially uniformly. The diffusion portion (bonding layer 214-1-2) may be used, or although not shown, a diffusion material may be mixed with the bonding layer 214-2 to form the diffusion portion.
In addition, although not illustrated, the prism sheet 210 may be used as a diffusing portion by providing a fine uneven shape on the surface of the third scattering prevention layer 213 without mixing a diffusing material in the prism base portion 212b. A general-purpose diffusion sheet or the like may be used for the scattering prevention layer 213, or an optical sheet or the like on which a lenticular lens that diffuses light in the vertical direction of the transmission screen 200 and has a weak diffusion effect is formed. Good.

FIG. 17 is a diagram showing a transmission screen of Example 4 using the diffusion optical sheet according to the present invention.
The transmissive screen 500 according to the fourth embodiment of the present invention includes a prism sheet 510 provided on the light source unit 22 side (incident side) and a diffusion optical sheet 520 provided on the observation surface side (exit side). It is formed as a set of screens.
Further, this transmissive screen 500 is used in the rear projection television 2 shown in FIG. 13 in the same manner as the transmissive screen 200 of the third embodiment.
FIG. 18 is a diagram schematically showing the layer configuration of the transmission screen of Example 4. As shown in FIG.
The image light L is indicated by an arrow in the figure, and enters the transmissive screen 500 from the right side in the figure and exits from the left side in the figure. Further, in the figure, a layer in which white circles are distributed is shown to include a diffusing material.

  The prism sheet 510 is the same member as the prism sheet 210 shown in Example 3, and the first glass substrate 511, the first scattering prevention layer 512, and the third scattering prevention layer in the prism sheet 510 of this example. 513 and bonding layers 514-1 and 514-2 are the first glass substrate 211, the first scattering prevention layer 212, the third scattering prevention layer 213, and the bonding layer 214-1 in the prism sheet of Example 3, respectively. , 214-2, and has the same function. Therefore, the overlapping description is omitted.

  The diffusion optical sheet 520 is the same member as the diffusion optical sheet 420 shown in Example 2, and the second glass substrate 521, the second scattering prevention layer 523, and the fourth member in the diffusion optical sheet 520 of the present example. The scattering prevention layer 522 and the bonding layers 524-1 and 524-2 are respectively the second glass substrate 421, the second scattering prevention layer 423, and the fourth scattering prevention layer 422 in the diffusion optical sheet 420 of Example 2. It corresponds to the bonding layers 424-1 and 424-2 and has the same function. Therefore, the overlapping description is omitted.

The transmissive screen 500 according to the fourth embodiment including the diffusing optical sheet 520 and the prism sheet 510 according to the present invention is warped due to changes in the environment such as temperature and humidity, like the transmissive screen 100 illustrated in the first embodiment. A transmissive screen with high flatness, which is less likely to float and bend due to its own weight, and can provide a high-quality image to an observer.
In addition, the transmission type screen 500 of Example 4 has a configuration in which the most incident side surface and the most emission side surface are covered with the first and second scattering prevention layers 512 and 523, and the first and second side surfaces are caused by an accident or the like. When the glass substrate 511 or 521 is damaged, the fragments are not scattered and are safe.

Furthermore, the transmission screen 500 according to the fourth embodiment has the prism sheet 510 provided on the incident side, so that the image light can be obtained even when the incident angle of the image light L to the transmission screen is large as shown in FIG. Since L can be emitted as substantially parallel light to the emission side, the depth of the rear projection television can be reduced and made thinner.
Furthermore, the diffusing optical element 522a used for the diffusing optical sheet 520 is easy to manufacture and can be manufactured with high definition, so that a transmission screen capable of obtaining a high-quality image can be provided at low cost.

  As in the case of the rear projection television 2 shown in FIG. 13, when the incident angle of the image light on the transmissive screen is large, the outer peripheral portion of the transmissive screen undergoes chromatic dispersion due to wavelength dispersion of the refractive index, resulting in color unevenness. Is a problem. However, such a prism sheet 510 and the diffusing optical sheet 520 reflect and emit light, so that chromatic dispersion does not occur and color unevenness can be reduced.

(Modification of Example 4)
The prism sheet 510 used in the transmission screen 500 of the present embodiment is the same member as the prism sheet 210 shown in the third embodiment. Therefore, the prism sheet 510 can use a modification of the prism sheet 210 as a modification thereof.
Further, the diffusing optical sheet 520 used in the transmissive screen 500 of this example is the same member as the diffusing optical sheet 420 shown in Example 2. Therefore, the diffusion optical sheet 520 can use a modification of the diffusion optical sheet 420 as a modification thereof.

FIG. 19 is a diagram showing a transmission screen of Example 5 using the diffusion optical sheet according to the present invention.
The transmission type screen 300 of Example 5 using the diffusion optical sheet according to the present invention has a diffusion optical element 313 a similar to the diffusion optical element 422 a shown in Example 2 in the second scattering prevention layer 313.
The image light L is indicated by an arrow in the figure, and enters the transmission screen 300 from the right side in the figure and exits from the left side in the figure. In the drawing, a layer in which white circles are distributed indicates that a diffusion layer that diffuses light is included.
However, the transmission screen 300 of Example 5 is not provided with a separate prism sheet on the incident side, and is implemented on the incident side of the glass substrate 311 on which the second scattering prevention layer 313 having the diffusion optical element 313a is laminated. A prism portion 312 a similar to the prism portion 212 a shown in Example 3 is integrally laminated to form a single transmission screen 300.
Further, the transmissive screen 300 of the present embodiment is used in the rear projection television 2 as shown in FIG. 13 in the same manner as the transmissive screen 200 shown in the third embodiment.

FIG. 20 is a diagram schematically showing the layer configuration of the transmission screen of Example 5 using the diffusing optical sheet according to the present invention.
The transmission screen 300 of Example 5 is a diffusion optical sheet having a glass substrate 311, a first scattering prevention layer 312, a second scattering prevention layer 313, and a bonding layer 314-1.314-2.
The glass substrate 311 is a highly rigid substrate layer having light transmittance and high rigidity. The glass substrate 311 is a 3 mm thick glass plate formed of silicate glass, and has a light transmittance of 90% or more in the wavelength band 400 to 700.

  The bonding layers 314-1 and 314-2 are layers for integrally bonding the glass substrate 311 and the first and second scattering prevention layers 312 and 313, and are made of a pressure-sensitive adhesive acrylic resin or the like. Formed, and its thickness is a layer of 20 μm.

The first scattering prevention layer 312 is a layer integrally laminated on the glass substrate 311 via the bonding layer 314-1 on the incident side of the glass substrate 311, and prevents scattering when the glass substrate 311 is broken. It has the function to do.
The first scattering prevention layer 312 is obtained by integrally forming the prism portion 312a with an ultraviolet curable resin in advance on one surface of the prism base material portion 312b in the same manner as the Fresnel portion 113a shown in the first embodiment. The glass substrate 311 is laminated.

The prism base material portion 312b is a sheet-like member having a thickness of 200 μm that serves as a base of the first scattering prevention layer 312. The prism base portion 312b is formed of an acrylic resin in which glass beads are mixed substantially uniformly as a diffusing material, and has a function as a diffusing portion.
The prism portion 312a has the same shape as the prism portion 212b shown in the third embodiment, and totally reflects the incident surface on which light is incident and at least part of the light from the incident surface and emits the light toward the emitting side. A plurality of unit prisms having a surface are arranged and formed.

The second scattering prevention layer 313 is a layer integrally laminated on the emission side of the glass substrate 311 via the bonding layer 314-2, and has a function of preventing scattering when the glass substrate 311 is broken. .
In the second scattering prevention layer 313, the diffusion optical element 313a was previously formed on one surface of the diffusion optical element base material part 313b by using an ultraviolet curable resin in the same manner as the Fresnel lens part 113a shown in Example 1. Things are stacked on the glass substrate 311.

The diffusing optical element substrate portion 313b is a sheet-like member having a thickness of 200 μm serving as a base for the second scattering prevention layer 313, and is formed of an acrylic resin mixed with glass beads as a diffusing material, and functions as a diffusing portion. Have
The diffusing optical element 313a is formed on the exit-side surface of the diffusing optical element substrate 313b, has the same shape as the diffusing optical element 422a shown in Example 2, and has a convex shape with a substantially trapezoidal cross section. These unit optical shapes are arranged so as to protrude to the emission side.

By setting it as such a layer structure, the transmission type screen 300 of Example 5 is the following in addition to the improvement in flatness shown in Example 1, and the effect of preventing scattering of fragments when the glass substrate 311 is broken. Such an effect is obtained.
The transmission type screen 300 of the fifth embodiment can be used as a transmission type screen without combining a separate prism sheet and diffusion optical sheet, so that the transmission type screen can be made thinner and lighter. And the production cost can be reduced.

  In addition, a transmission type screen combining a separate prism sheet and a diffusing optical sheet causes floating between the sheets even if only one of the sheets is warped. There is a problem that deterioration occurs. However, the transmissive screen 300 of this embodiment can be used as a transmissive screen by itself, and its flatness is high, so that floating or the like occurs and deterioration of image quality can be prevented.

  The rear projection television 2 has a large incident angle of the image light L projected from the light source unit 22. However, since the transmissive screen 300 is provided with the prism portion 312a on the incident side, the image light can be emitted as substantially parallel light to the observation surface side (outgoing side), so that the depth of the rear projection television 2 is reduced and the thickness is reduced. it can.

(Modification of Example 5)
(1) In the present embodiment, the second scattering prevention layer 313 has an example having the diffusing optical element 313a in which a plurality of unit optical shapes each having a substantially trapezoidal cross section are arranged. Not limited to this, a lenticular lens portion (not shown) in which a plurality of unit lenses having a substantially elliptical cross section may be provided, and the shape thereof is not particularly limited. Moreover, not only a lenticular lens part but a diffusion layer having a strong diffusion effect, a general-purpose diffusion sheet, or the like may be used.

(2) FIGS. 21 and 22 are diagrams schematically showing a layer configuration of a modified example of the transmission screen of Example 5. FIG.
In the present embodiment, the transmissive screen 300 shows an example in which glass beads are mixed as a diffusing material into the prism base material portion 312b and the diffusing optical element base material portion 313b, and a function as a diffusing portion is given. There are no particular limitations on the number of layers and the number of layers that provide the function as a part. An example is shown below, but this is not restrictive.
For example, as shown in FIG. 21A, the transmission type screen 300 includes a diffusion layer 315-1 having a thickness of 188 μm formed by mixing a diffusion material such as glass beads with polyethylene terephthalate resin or the like. A new layer may be laminated on the emission side from the scattering prevention layer 313 via the bonding layer 314-3 to improve the uniformity of diffusion. For the diffusion layer 315-1, a general-purpose diffusion sheet or the like may be used.
In addition, the transmissive screen 300 is, for example, as described above with the bonding layers 314-4 and 314-5 interposed between the first scattering prevention layer 312 and the glass substrate 311 as shown in FIG. A diffusion layer 315-2 similar to the diffusion layer 315-1 may be newly stacked.

A modification of the transmission screen 300 of Example 5 shown in FIG. 22 is similar to the diffusion optical element 313a and the diffusion optical element base part 313b shown in Example 5, and the diffusion optical element base part 316b. This is an example in which a diffusion optical layer 316 having s is integrally bonded between the first scattering prevention layer 313 and the glass substrate 311.
As shown in FIG. 22C, the transmissive screen 300 is formed by bonding a diffusion optical layer 316 that functions as a diffusion unit that diffuses light between the first scattering prevention layer 312 and the glass substrate 311. You may laminate | stack through the layers 314-6 and 314-7. At this time, the second scattering prevention layer 313-2 may be a diffusion portion (second scattering prevention layer 313-2-2) by mixing a diffusing material.
Although not shown, the transmissive screen 300 is a reflection having an antireflection function on the second scattering prevention layer 313-2 integrally laminated on the emission side of the glass substrate 311 via the bonding layer 314-8. An anti-glare sheet or an anti-glare sheet having an anti-glare function may be laminated. Further, although not shown, the transmissive screen 300 may be formed as a diffusing portion by mixing a diffusing material substantially uniformly with the bonding layer 314-8 instead of the second scattering prevention layer 312-2.

As shown in FIG. 22D, the transmissive screen 300 includes a diffusion layer 315-having a diffusion effect between the diffusion optical layer 316 and the glass substrate 311 via bonding layers 314-9 and 314-10. 3 may be laminated, and an antireflection sheet having an antireflection function, an antiglare sheet having an antiglare function, or the like may be laminated on the second scattering prevention layer 313-2.
At this time, the bonding layer 314-8 between the glass substrate 311 and the second scattering prevention layer 313-2 may be formed as a diffusion portion (bonding layer 314-8-2) by mixing the diffusing material substantially uniformly. .

  Further, as shown in FIG. 22E, the transmission screen 300 includes a diffusion layer 315-3, and a bonding layer 314-11 is interposed between the second scattering prevention layer 313-2 and the glass substrate 311. The diffusion layer 315-4 may be laminated via 314-12. At this time, the second scattering prevention layer 313-2 may be laminated with a general-purpose antireflection sheet, an antiglare sheet, or the like.

(Modification common to Example 1 to Example 5)
The present invention is not limited to the embodiments described above, and various modifications and changes are possible, and these are also within the equivalent scope of the present invention.
(1) FIG. 23 is a diagram schematically showing a layer configuration of a modified example of the transmission screen using the lenticular lens sheet according to the present invention.
In the first embodiment, the Fresnel lens sheet 110 used for the transmissive screen 100 is an example in which the first glass substrate 111 is used. However, the present invention is not limited to this, and a plastic formed of a plastic resin as shown in FIG. You may use the Fresnel lens sheet 130 which formed the Fresnel lens part 132 of the substantially same shape as the Fresnel lens part 113a on the surface of the board | substrate 131 with the ultraviolet curable resin.
The plastic substrate 131 is a plate-like member having a thickness of 2 mm formed of, for example, acrylic resin, polystyrene resin, methyl methacrylate styrene copolymer resin (MS resin), methyl methacrylate butadiene styrene copolymer resin (MBS resin), or the like. . As shown in FIG. 23, the plastic substrate 131 may be provided with a function as a diffusion portion by mixing a diffusion material such as glass beads. It is technically easy to mix the diffusion material with the plastic substrate 131, and the production cost can be reduced.

At this time, since the Fresnel lens sheet 130 uses the plastic substrate 131, it is possible to reduce the weight of the transmissive screen, but warpage or floating due to environmental changes or the like is likely to occur. In order to prevent this, the Fresnel lens sheet 130 may be provided with a convex curvature on the lenticular lens sheet 120 side to form a set of transmission screens. By providing in this way, the Fresnel lens sheet 130 can maintain its flatness.
Similarly, the Fresnel lens sheet 410 shown in Example 2 and the prism sheets 210 and 510 shown in Examples 3 and 4 are not cured with glass, but UV-cured on the surface of a plastic substrate. A Fresnel lens sheet and a prism sheet in which a Fresnel lens part and a prism part are integrally formed of a mold resin may be used.

(2) In each embodiment, as a method for imparting a function as a diffusing portion for diffusing light, Fresnel base portions 113b and 413b, prism base portions 212b, 312b and 512b, lenticular base portions 122b and 222b, diffusion Glass beads as a diffusing material are mixed almost uniformly into the optical element base material portions 313b, 422b, 522b, the second scattering prevention layers 123, 223, 423, 523, and the third scattering prevention layers 213, 513, and the diffusion effect. An example in which a function as a diffusion part is given by giving the above is shown. However, the present invention is not limited to this, and for example, the bonding layers 114-1, 114-2, 124-1, 124-2, 214-1, 214-2, 224-1, 244-2, 314-2, 314-2. , 414-1, 414-2, 424-2, 424-2, 514-1, 514-2, 524-1, 524-1 etc. are mixed almost uniformly to give a function as a diffusion part. May be.
Further, by providing a fine uneven shape on the surface of these layers, a diffusion effect may be given and a function as a diffusion portion may be given. At this time, it is preferable that the two layers adjacent to each other through the surface on which the fine concavo-convex shape is provided have a larger difference in refractive index because the diffusion effect is increased.
Furthermore, the diffusing material is not limited to glass beads, and may be, for example, particles formed of an organic compound such as plastic as long as it does not depend on the wavelength of light.

(3) In each embodiment, if the diffusing portion having the diffusing effect is provided as a whole in the non-adjacent layers as the whole of the transmissive screens 100, 200, 300, 400, 500, in addition to the effect such as widening the viewing angle In addition, a reduction effect of scintillation (screen glare) can be expected. Moreover, the amount of the diffusing material to be mixed can be reduced by providing the diffusing portion in two or more layers.
In addition, although the layer which provides the function as a diffusion part is not particularly limited, the first and second glass substrates 111, 121, 211, 221, 311, 411, 421, 511, and 521 are mixed with a diffusion material. It is not preferable because it becomes brittle and easily breaks.

(4) In each of the embodiments, the light source units 21 and 22 are examples of a single tube type light source using DMD. However, the present invention is not limited to this. For example, a single tube type light source using an LCD or the like may be used. Good. In the first embodiment, the light source unit 21 may be a three-tube type light source using a CRT.

(5) In each embodiment, the Fresnel base portions 113b and 413b, the prism portions 212b, 312b, and 512b, the lenticular base portions 122b and 222b, and the diffusing optical element base portions 313b, 422b, and 522b are formed of an acrylic resin. However, the present invention is not limited to this. For example, it may be formed of a polyester resin, a polyethylene resin, a polycarbonate resin, or the like, and the material is not particularly limited.
In addition, when the light source parts 21 and 22 are light sources having polarization dependency such as LCD, these base material parts are sheet-like members formed of a cellulose-based resin such as triacetyl cellulose or unstretched polycarbonate. A member having low birefringence such as a plate may be used to reduce stray light and improve image quality.

(6) In each embodiment, the Fresnel lens portions 113a and 413a, the diffusing optical elements 313a, 422a and 522a, and the prism portions 212a, 312a and 512a are made of ultraviolet curable resin, respectively, and the Fresnel base material portions 113b and 413b are diffused. An example in which the optical element base material portions 313b, 422b, and 522b and the prism base material portions 212b, 312b, and 512b are integrally formed is shown. In the embodiment, the lenticular lens portions 122a and 222a are made of thermoplastic resin, and are Although the example formed integrally with the material parts 122b and 222b was shown, you may form using not only this but a thermosetting resin. Moreover, the molding method may be integrally molded with each base material portion by extrusion molding or the like, and is not particularly limited.

(7) In Examples 1 to 4, the second scattering prevention layers 123, 223, 423, and 523 are examples in which glass beads are mixed as a diffusion material and have a function as a diffusion part. For example, it is only necessary to have at least one function such as antireflection, antiglare, coloring, dimming, ultraviolet absorption, antistatic, antifouling, sensor, hard coat, etc. Can be expected.
Since the second scattering prevention layers 123 and 223 are laminated on the most emission side (most observation surface side), when having an antireflection function, there is an effect of preventing reflection of external light. In the case of having an ultraviolet absorbing function, there is an effect of preventing yellowing of the lenticular base material portions 123b, 222b and the like by ultraviolet rays contained in external light. In the case of having an antiglare function, glare on the screen can be suppressed. In the case of having a hard coat function, there is an effect of preventing the screen from being scratched and increasing the strength of the screen. In the case of having an antistatic function, static electricity generated on the transmission screen can be removed and adhesion of dust or the like can be prevented. In the case of having an antifouling function, it is possible to prevent the screen surface from being stained. In the case of having a coloring and dimming function, contrast can be improved and image quality can be improved. When it has a sensor function, it can be used for a touch sensor or the like.

The second anti-scattering layers 123, 223, 423, and 523 are diffusion, antireflection, antiglare, coloring (Tint), dimming (ND), ultraviolet absorption, antistatic, antifouling, sensor, hard coat, etc. A general-purpose sheet having at least one of these functions may be used. For example, a sheet-like member formed of an acrylic resin or the like may be processed so as to have at least one of these functions. In addition, a plurality of sheets or the like having respective functions may be laminated, or processing may be performed so as to have a plurality of functions, and there is no particular limitation.
Furthermore, not only the second scattering prevention layers 123, 223, 423, and 523 but also other scattering prevention layers may have such a function as appropriate.

(8) In Example 1 to Example 3, the first glass substrates 111 and 411 and the second glass substrates 121 and 222 are examples of 2 mm thick glass plates formed of silicate glass. In Examples 2 to 5, the first glass substrates 211 and 511 and the second glass substrates 421, 521 and 311 are glass plates having a thickness of 3 mm formed of silicate glass. However, the material is not limited to this, and is a material having light transmittance and high rigidity. For example, alkali-free glass, phosphate glass, borate glass, soda-lime glass, potash glass, quartz glass, lead glass Further, a glass plate formed of barium glass, borosilicate glass, phosphate glass, or the like may be used, or a glass plate subjected to air cooling strengthening or chemical strengthening may be used. Moreover, you may use the plate-shaped member formed with the translucent ceramics etc. which have a light transmittance.
Furthermore, the thickness of the member used as a board | substrate will not be specifically limited if it exists in the range of 1.5-3 mm.

(9) In Example 1, the bonding layers 114-1, 114-2, 124-1, and 124-2 include the first and second glass substrates 111 and 121, and the first and third scattering prevention layers 112. , 113, and the second and fourth scattering prevention layers 123, 122 are shown as a layer for integrally joining, but the present invention is not limited thereto, and a diffusion material such as glass beads is mixed substantially uniformly as a diffusion portion. You may give the function of. Further, an ultraviolet absorber may be mixed with the bonding layer 124-2 provided in the vicinity of the most light emitting surface side of the transmissive screen 100 to prevent yellowing of the screen due to ultraviolet rays contained in external light.
Bonding layers 214-1, 214-2, 224-1, 244-2, 314-1, 314-2, 414-1, 414-2, 424-1, 424 shown in Example 2 to Example 5 The same applies to 2,514-1, 514-2, 524-1, and 524-2.

(10) In Example 1 to Example 3, the bonding layers 114-1, 114-2, 124-1, 124-2, 224-1, 244-2, 414-1, 414-2 are irradiated with ultraviolet rays. An example of a layer having a thickness of 100 μm formed of an ultraviolet curable acrylic resin that is cured by performing the steps shown in FIGS. 2 to 5, and bonding layers 214-1, 214-2, 314-1, 314-2, 424-1, 424-2, 514-1, 514-2, 524-1, 524-2 are formed of a pressure-sensitive adhesive type acrylic resin whose adhesiveness is manifested by pressure. Although the example which is a 20-micrometer-thick layer was shown, you may form with acrylic ester resin, a phenol resin, etc. not only this but it does not specifically limit. The bonding method is not particularly limited, for example, thermosetting, ultraviolet curable (UV curable), electron beam curable (EB curable), pressure sensitive adhesive (PSA), and the like. Furthermore, the thickness will not be specifically limited if it exists in the range of 5-200 micrometers.

It is the figure which showed the transmission type screen of Example 1 using the lenticular lens sheet | seat by this invention. 1 is a cross-sectional view of a rear projection television that uses a transmission screen according to Embodiment 1. FIG. It is the figure which showed typically the laminated constitution of the transmission type screen of Example 1 using the lenticular lens sheet | seat by this invention. 6 is a diagram schematically showing a layer configuration of a modified example of the Fresnel lens sheet in the transmission screen of Example 1. FIG. 6 is a diagram schematically illustrating a layer configuration of a modified example of the lenticular lens sheet in the transmission screen of Example 1. FIG. 6 is a diagram schematically illustrating a layer configuration of a modified example of the lenticular lens sheet in the transmission screen of Example 1. FIG. 6 is a diagram schematically illustrating a layer configuration of a modified example of the lenticular lens sheet in the transmission screen of Example 1. FIG. It is the figure which showed the transmission type screen of Example 2 using the diffusion optical sheet by this invention. It is the figure which showed typically the layer structure of the transmission type screen of Example 2 using the diffusion optical sheet by this invention. It is sectional drawing of a diffusion optical element. 6 is a diagram schematically showing a layer configuration of a modified example of the diffusion optical sheet in the transmission screen of Example 2. FIG. It is a figure which shows the transmission type screen of Example 3 using the lenticular lens sheet | seat by this invention. FIG. 6 is a cross-sectional view of a rear projection television using the transmission screen of Example 3. It is the figure which showed typically the laminated constitution of the transmission type screen of Example 3 using the lenticular lens sheet | seat by this invention. It is sectional drawing of a prism part. 6 is a diagram schematically illustrating a layer configuration of a modified example of the prism sheet in the transmission screen of Example 3. FIG. It is the figure which showed the transmission type screen of Example 4 using the diffusion optical sheet by this invention. It is the figure which showed typically the laminated constitution of the transmission type screen of Example 4 using the diffusion optical sheet by this invention. It is the figure which showed the transmission type screen of Example 5 using the diffusion optical sheet by this invention. It is the figure which showed typically the layer structure of the transmission type screen of Example 5 using the diffusion optical sheet by this invention. 10 is a diagram schematically showing a layer configuration of a modified example of the transmission screen of Example 5. FIG. 10 is a diagram schematically showing a layer configuration of a modified example of the transmission screen of Example 5. FIG. It is the figure which showed typically the layer structure of the modification of the transmission type screen using the diffusion optical sheet by this invention.

Explanation of symbols

1, 2 Rear projection television 21, 22 Light source unit 31, 32 Mirror unit 100, 200, 300, 400, 500 Transmission type screen 110, 410 Fresnel lens sheet 111, 411, 211, 511, 311 First glass substrate 112, 312, 412, 212, 512 First scattering prevention layer 113, 413, 213, 513 Third scattering prevention layer 113 a, 413 a Fresnel lens part 113 b, 413 b Fresnel base material part 114-1, 114-2, 124-1 , 124-2 Bonding layer 214-1, 214-2, 224-1, 244-2 Bonding layer 314-1, 314-2 Bonding layer 414-1, 414-2, 424-1, 424-2 Bonding layer 514 -1,514-2, 524-1,524-2 Bonding layer 120,220 Lenticular lens system 121, 221, 521 Second glass substrate 122, 222, 522 Fourth scattering prevention layer 122 a, 222 a Lenticular lens part 122 b, 222 b Lenticular base material part 123, 223, 313, 523 Second scattering prevention layer 210 , 510 Prism sheet 212a, 312a, 512a Prismatic part 212b, 312b, 512b Prism base part 220, 520 Diffusing optical sheet 222a, 313a, 522a Diffusing optical element 222b, 312b, 522b Diffusing optical element base part 311 Glass substrate 130 Fresnel Lens sheet 131 Plastic substrate 132 Fresnel lens part

Claims (11)

A diffusing optical sheet used for a transmission screen that emits image light projected from an incident side to an emission side,
A highly rigid substrate layer having light transparency and high rigidity;
An anti-scattering layer that is integrally laminated on both sides of the high-rigidity substrate layer and prevents the high-rigidity substrate layer from scattering;
A diffusing optical element provided on at least one of the anti-scattering layers;
A diffusing optical sheet comprising: The diffusing optical sheet according to claim 1,
The high-rigidity substrate layer is formed of glass or translucent ceramics;
A diffusion optical sheet characterized by the above. In the diffusion optical sheet according to claim 1 or 2,
The diffusing optical element is a lenticular lens in which a plurality of unit optical shapes having a refracting surface that refracts at least part of incident light are arranged in a horizontal or vertical direction;
A diffusion optical sheet characterized by the above. In the diffusion optical sheet according to claim 1 or 2,
The diffusing optical element has a plurality of unit optical shapes having a total reflection surface that totally reflects at least a part of incident light,
A diffusion optical sheet characterized by the above. In the diffusion optical sheet according to any one of claims 1 to 4,
Having a diffusion part for diffusing light;
A diffusion optical sheet characterized by the above. In the diffusion optical sheet according to claim 5,
The diffusion part is provided on the incident side and the emission side from the high-rigidity substrate layer,
A diffusion optical sheet characterized by the above. In the diffusion optical sheet according to any one of claims 1 to 6,
At least one of the anti-scattering layer has at least one function of diffusion, antireflection, antiglare, coloring, dimming, ultraviolet absorption, antistatic, antifouling, sensor, hard coat,
A diffusion optical sheet characterized by the above. In the diffusion optical sheet according to any one of claims 1 to 7,
Having a bonding layer that integrally bonds the high-rigidity substrate layer and the scattering prevention layer;
A diffusion optical sheet characterized by the above. In the diffusion optical sheet according to claim 8,
At least one of the bonding layers includes at least one of a diffusing material that diffuses light and an ultraviolet absorber that absorbs ultraviolet rays;
A diffusion optical sheet characterized by the above.   A transmissive screen comprising the diffusing optical sheet according to any one of claims 1 to 9. The transmissive screen according to claim 10;
A light source unit for projecting image light;
A mirror unit that reflects the image light projected from the light source unit toward the transmission screen;
A rear projection type display device.

Images