JP2000147668A - Lenticular lens sheet and its manufacture - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lenticular lens sheet with which a clear image whose contrast is high is obtained by markedly reducing external light reflection. SOLUTION: This is lenticular lens sheet possesses plural lenticular lenses on one surface of a light transmissive substrate and possesses a convex lens part 2 at the condensing position of light from each lenticular lens on the other surface of the light transmissive substrate, and possesses a convex external light-absorbing part 3 that is provided with an external light-absorbing layer 4 at an apical part, at a position different from the condensing position of the light from each lenticular lens on the other surface and the external light- absorbing layer 6 is provided at a concave part 5 between the convex lens part 2 and the convex external light-absorbing part 3. The external light- absorbing layer 4 of the external light absorbing part 3 may be provided at not only the apical part of the external light-absorbing part 3 but also at one part near the summit part on the side surface of the external light-absorbing part.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lenticular lens sheet for a transmission screen used in a rear projection television or the like, and a method for producing the same.

[0002]

2. Description of the Related Art A transmission screen used in a rear projection television or the like generally has a structure in which two lens sheets are superimposed. That is, on the light source side, a Fresnel lens sheet that narrows down the image light from the CRT or the image light transmitted through the liquid crystal so as to be within a certain angle range is arranged, and on the observer side, the light passes through the Fresnel lens sheet. A lenticular lens sheet having a function of spreading the image light in an appropriate angle range is provided.

FIG. 12 is a schematic perspective view of a conventional lenticular lens sheet. As shown in FIG. 12, the lenticular lens sheet 11 has a lenticular lens 12 formed on a surface on which image light is incident. Of the lenticular lens sheet 11 from which the image light is emitted, it is general to form the condensing portion 13 for condensing light from the lenticular lens 12 formed on the incident side surface into a convex lens shape. The reason why the condensing portion 13 is formed in a convex lens shape is to improve the diffusion performance of the image light in the horizontal direction. In a lenticular lens sheet used in combination with a three-tube CRT light source, it is necessary to form the condensing portion 13 in a convex lens shape, in particular, to correct color misregistration of three colors. The non-light-collecting portion 14 (the portion other than the light-collecting portion 13) formed on the incident-side surface where light from the lenticular lens 12 does not converge is formed in a convex shape having a top parallel to the lenticular lens sheet. . Then, an external light absorbing layer 15 made of a black paint or the like is provided on a top portion of the convex portion and a portion (upper side surface) near the top portion of the side surface of the convex portion by means of roll coating, screen printing, transfer printing, or the like. An external light absorbing portion 16 having a shape of is formed. Thus, of the external light incident on the lenticular lens sheet, light reflected on the exit surface of the lenticular lens sheet and returning to the observer side is reduced, and the image contrast is improved.

[0004]

However, in order to obtain high image contrast in an environment where external light is present, an external light absorbing layer is formed on the top and the upper side of the convex external light absorbing portion of the lenticular lens sheet. Is not sufficient just to provide the reflection, and there is a problem to further reduce the reflection of external light.

Therefore, it has been proposed to provide an external light absorbing layer not only on the top and upper side of the external light absorbing portion of the lenticular lens sheet, but also on the entire side surface (Japanese Utility Model Application Laid-Open No. 59-59).
-87042). According to this method, the area for absorbing external light can be increased, and the ratio of absorbed external light can be increased. However, since the convex lens-shaped condensing portion protrudes from the lower side surface of the external light absorbing portion, the external light of the lenticular lens sheet is formed by a conventional external light absorbing layer forming means such as roll coating, screen printing, and transfer printing. Even if the material for forming the external light absorbing layer is applied to not only the top portion but also the entire side surface of the absorbing portion, the external light absorbing layer forming material is not attached to the convex lens portion (condensing portion), and the external light absorbing material is not attached. It is extremely difficult to apply the external light absorbing layer forming material to the lower end of the bottom of the portion. It is difficult to manufacture a lenticular lens sheet in which a material for forming an external light absorbing layer is applied to all side surfaces of a convex external light absorbing portion by a practical production process.

The present invention has been made in view of such circumstances, and provides a lenticular lens sheet capable of obtaining a high-contrast clear image by greatly reducing external light reflection, and a lenticular lens thereof. It is an object of the present invention to provide a method for manufacturing a sheet by simple means.

[0007]

A lenticular lens sheet according to the present invention for solving the above-mentioned problems has a plurality of lenticular lenses on one surface of a light-transmitting substrate and the above-mentioned lenticular lens on the other surface of the light-transmitting substrate. The light condensing position of the light from each of the lenticular lenses (here, the light condensing position includes both the case where the light converges on the light converging point and the case near the light converging point). Having a convex external light absorbing portion provided with an external light absorbing layer on the top, at a position different from the condensing position of light from each lenticular lens on the other surface, An external light absorbing layer is provided in a concave portion between the convex lens portion and the convex external light absorbing portion. The external light absorbing layer of the external light absorbing section can be provided not only on the top of the external light absorbing section but also on a part of the side surface of the external light absorbing section near the top.

The lenticular lens sheet of the present invention has a plurality of lenticular lenses on one surface and a convex lens portion on the other surface at a position where light from each of the lenticular lenses is condensed. The light-transmitting substrate having a convex external light absorbing portion on which an external light absorbing layer is to be provided at a position different from the light condensing position of the light from each of the lenticular lenses on the other surface. An external light absorbing material is filled between the convex lens portion and the convex external light absorbing portion, and then a portion other than the concave portion between the convex lens portion and the convex external light absorbing portion By removing the external light absorbing material, an external light absorbing layer is provided in the concave portion, and then the external light absorbing layer is provided on the top of the convex external light absorbing portion. Here, when the external light absorbing material is filled between the convex lens portion and the convex external light absorbing portion, a layer of the external light absorbing material is provided on the entire surface of the other surface of the light transmitting substrate. May be. When the external light absorbing layer is provided on the top of the convex external light absorbing section, the external light absorbing layer may be provided on a part of the side surface of the external light absorbing section near the top.

The lenticular lens sheet of the present invention has a plurality of lenticular lenses on one surface and a convex lens portion on the other surface at a position where light from each of the lenticular lenses is condensed. In the light-transmitting substrate having a convex external light absorbing portion at a position different from the light condensing position of the light from each of the lenticular lenses on the other surface, at the top of the convex external light absorbing portion. A first external light absorbing layer is provided, and then a layer of an external light absorbing material is laminated on the entire surface including the convex external light absorbing portion, or after the convex lens portion and the convex external light absorbing layer are laminated. After filling the external light absorbing material between the light absorbing portion, so that the second external light absorbing layer remains in the concave portion between the convex lens portion and the convex external light absorbing portion, Manufacture of lenticular lens sheet for removing external light absorbing material in portions other than the concave portions It is produced by law. Here, when the first external light absorbing layer is provided on the top of the convex external light absorbing portion, the external light absorbing material layer may be provided on a part of the side surface of the external light absorbing portion near the top. is there.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The lenticular lens sheet of the present invention has a plurality of lenticular lenses on one surface of a light-transmitting substrate, and transmits light from each lenticular lens on the other surface of the light-transmitting substrate. An external light absorbing layer is provided on the top at a position different from the light condensing position of light from each lenticular lens on the other surface, having a convex lens portion at the light condensing position (at or near the light condensing point). Having a convex external light absorbing portion. FIG. 1 is a schematic cross-sectional view of a light-emitting side surface of a first example of a lenticular lens sheet of the present invention. This lenticular lens sheet 1
It has a convex lens portion 2 and a convex external light absorbing portion 3 in which an external light absorbing layer 4 is provided on a part of the top and side surfaces on the top side. Light absorbing part 3
The external light absorbing layer 6 is also provided in the concave portion 5 in the middle of the above. Here, as shown in FIG. 1, the concave portion between the lens portion 2 and the external light absorbing portion 3 has a shape close to an inverted trapezoidal shape having a certain length parallel to the sheet surface. As shown in FIG. 2, there is a case where there is no valley-shaped portion parallel to the sheet surface.

By providing the external light absorbing layer in the concave portion between the lens portion 2 and the external light absorbing portion 3 as described above, external light is absorbed in this portion, and reduction in contrast due to external light is reduced. . The concave portion is a portion where the image light does not enter. Even if the external light absorbing layer is provided here, the optical performance of the lenticular lens sheet will not be reduced.

FIG. 3A shows a case where there is a concave portion having a substantially flat bottom surface between the lens portion and the external light absorbing portion, and FIG.
Indicates a case where there is no substantially flat portion on the bottom surface of the concave portion between the lens portion and the external light absorbing portion. Even when a lenticular lens sheet is formed by transferring the shape using a forming roll as shown in FIG. 4 or 5 later, the lens portion and the external light absorbing portion of the obtained lenticular lens sheet are formed. The boundaries between are not always clear. Therefore, the bottom of the external light absorbing section 3, the bottom of the lens section 2 or the flat bottom shown in FIG.
Generally, there is a rounded portion as shown in the partial enlarged view of FIG.

In the lenticular lens sheet according to the present invention, in order to obtain a higher contrast, the width of the external light absorbing layer provided in the concave portion between the lens portion 2 and the external light absorbing portion 3 is limited to the width of the lenticular lens sheet. It is preferable that the width is the largest as long as the optical performance is not reduced.
The preferred height of the external light absorbing layer will be described with reference to FIG. FIGS. 3 (a) in (b), W the width of the external light-absorbing layer in the hem of the skirt and lens portion of the external light absorption portions respectively _B and W
_Expressed by _L. Also, it expressed in FIG. 3 (a), the width of the flat bottom at _{W F.} Then, the height of the external light-absorbing layer from the lowest portion of the recess in the skirt side of the external light-absorbing portion by h _B, the height of the external light-absorbing layer from the lowest portion of the recess in the skirt side of the lens portion h
Each is represented by _L. Also, the height of the external light-absorbing portion from the most bottom of the recess in H _B, respectively represent the height of the lens portion from the most bottom of the recess in the H _L.

Here, the above H _L and h _L are 0.0
It is preferable to satisfy the relationship of 2 ≦ h _L / H _L ≦ 0.4. Being in this range provides higher contrast, and further reduces the influence of image light shading at the bottom of the lens portion, which causes a decrease in transmittance and causes coloring when observing an image from an oblique direction. Because you can. As the above range, 0.03 ≦ h _L / H _L ≦
It is more preferable to satisfy 0.3. In addition, the above H
_B and _{h B} preferably satisfies the _{0.01 ≦ h B / H B ≦} 0.3 the relationship. h _B / H _B can be obtained even higher contrast by 0.01 or more. The preferable upper limit of the value of h _B / H _B is not determined by the optical performance, but the light absorbing layer forming material adheres to the image light transmitting region of the lens portion, or the light absorbing layer forming material is attached to the image light transmitting region of the lens portion. This is determined from the viewpoint of manufacturing a lenticular lens sheet that an external light absorbing layer must be formed in the concave portion while preventing the remaining of the lens. As the above range, 0.02 ≦ h _B /
More preferably, H _B ≦ 0.25 is satisfied. The lenticular lens sheet of the present invention preferably satisfies both the above-mentioned preferable range of h _L / _{HL and} the preferable range of h _B / H _B.

Next, an example of a method for manufacturing a lenticular lens sheet according to the present invention will be described. First, a lenticular lens sheet substrate is manufactured by melt-extruding a light-transmitting thermoplastic resin. That is, the reverse shape of the lenticular lens is engraved on one side, and the reverse shape of the external light absorbing portion for providing the reverse shape of the convex lens portion and the external light absorbing layer having the top parallel to the sheet surface is formed on the other side. A light-transmitting thermoplastic resin is passed between a pair of metal forming rolls on which the mold shape is engraved, and the engraved shape is shaped to form a lenticular lens sheet substrate.

The inverted shape provided on the forming roll is generally formed by engraving a copper-plated portion of the surface of the forming roll with a lathe. From the viewpoint of optical performance, the forming roll used for forming the lens portion and the external light absorbing portion has a shape in which the lens portion and the external light absorbing portion are in close contact as shown in FIG. Is ideal.
However, in the case of an inverted shape as shown in FIG. 4, the pointed portion of the tip of the forming roll may fall down due to the resin pressure during sheet forming, and a predetermined shape may not be obtained. In order to avoid such tipping of the forming roll, a flat portion may be provided at the tip of the reverse engraved portion as shown in FIG. When such a forming roll is used, a concave portion having a substantially flat bottom surface is formed between the lens portion of the formed lenticular lens sheet and the external light absorbing portion, as shown in FIG.

That is, the concave portion having a substantially flat bottom surface between the lens portion and the external light absorbing portion is provided because there is a restriction in forming the sheet. This concave portion does not affect the optical function of the lenticular lens sheet. Even if an external light absorbing layer is provided in this concave portion, the image light is not damaged. In addition, there is no problem even if the external light absorbing layer is provided on a part (hem) of the side surface of the lens portion on the concave side as long as it does not affect the image light. FIG. 4 described above.
The lenticular lens sheet of the present invention shaped by the forming roll shown in FIG. 2 has a shape as shown in FIG.

Next, an external light absorbing layer is provided in a concave portion between the lens portion of the light transmitting lenticular lens sheet substrate and the external light absorbing portion. The external light absorbing layer in the concave portion is formed by filling an external light absorbing material between the lens portion and the external light absorbing portion, and removing unnecessary external light absorbing material in a portion other than the concave portion.

As the external light absorbing material, a known ink composition or paint such as a solvent type, a two-part reactive type, or an ultraviolet (UV) curable type containing a vehicle selected in consideration of the material of the light transmitting substrate is used. A composition prepared by adding a light-absorbing black pigment, a matting agent such as silica or calcium carbonate to the composition is used.

As a method for filling the concave portion with the external light absorbing material, a method such as screen printing, curtain coater, roll coater, spray coating, or the like is used. At this time, the external light absorbing material may be filled only between the lens part and the external light absorbing part, or the external light absorbing material may be applied to the entire surface of the lenticular lens sheet substrate on the emission side.

As a method of removing the unnecessary external light absorbing material other than the concave portion, a method of scraping with a spatula or a blade made of a rubber elastic material such as urethane rubber or silicone rubber, or a method of scraping with a rotating brush-like material And the like. In order to leave the ink outside the lens portion and to leave the external light absorbing material uniformly in the concave portion, it is preferable to scrape in the direction along the concave portion. Further, the scraping may be repeated twice or more. FIG. 6 schematically shows a method of scraping with a spatula-shaped rubber called “squeegee” used in screen printing. FIG. 7 schematically shows a method in which an external light absorbing material is linearly poured into the inside of the edge of the lenticular lens sheet, and the material is applied to the front with a spatula rubber or the like, and is simultaneously scraped off.

After providing the external light absorbing layer in the concave portion as described above, an external light absorbing layer is provided on the top of the convex external light absorbing portion, or the top of the external light absorbing portion and the top of the side surface thereof. An external light absorbing layer is provided on a part of the side. This external light absorbing layer is applied with ink or paint on the top or the like, and then heated,
It is formed by curing the coating film by a method such as irradiating ultraviolet rays. Here, the material of the external light absorbing layer formed on the top of the external light absorbing portion and the material of the external light absorbing layer formed on the concave portion may be the same or different. .

In the method of manufacturing a lenticular lens sheet of the present invention, the order of forming the external light absorbing layer in the concave portion and the external light absorbing layer such as the top of the external light absorbing portion may be reversed from the above description. That is, a first external light absorbing layer is provided on the top of the convex external light absorbing portion, and then a layer of an external light absorbing material is laminated on the entire surface including the convex external light absorbing portion, or After filling an external light absorbing material between the convex lens portion and the convex external light absorbing portion, a concave portion between the convex lens portion and the convex external light absorbing portion is filled. The lenticular lens sheet of the present invention may be manufactured by removing the external light absorbing material other than the concave portion so that the second external light absorbing layer remains.

In order to efficiently manufacture the lenticular lens sheet of the present invention by the method described above, the boundary between the side surface of the convex external light absorbing portion 3 and the concave portion 5 and the side surface of the convex lens portion 2 are required. It is preferable that the shape changes discontinuously at the boundary between the groove and the concave portion 5 and that the boundary be clear. FIG. 8 shows an example of a lenticular lens sheet according to the present invention in which a concave portion having a substantially rectangular cross section, such as a deep groove, is provided so that a clear boundary is provided between the external light absorbing portion, the concave portion, and the lens portion. It is a sectional view (however,
Since the slope of the light absorbing portion 3 has a large inclination, the boundary between the side surface of the external light absorbing portion 3 and the concave portion 5 becomes a slightly unclear boundary. ). The external light absorbing layer formed in the concave portion by coating or the like is shown in FIG.
As shown in FIG. 8B, the shape may be along the groove shape of the concave portion, or may be such that it fills the entire groove of the concave portion as shown in FIG. 8C. Here, as for the depth of the concave portion, the height h _L of the external light absorbing layer from the bottom of the concave portion on the bottom side of the lens portion and the height of the lens portion from the bottom of the concave portion are H _L. As long as the relationship of 0.02 ≦ h _L / H _L ≦ 0.4 is satisfied, h _L is preferably 2 μm or more, and more preferably h _L is 3 μm or more.

[0025]

The present invention will be described below in detail with reference to examples. Black ink is applied to the entire surface including the convex lens portion 2, the convex external light absorbing portion 3 and the concave portion 5 on the emission side of the extruded lenticular lens sheet substrate having the shape shown in FIG. Apply. FIG. 10 is a schematic cross-sectional view of the sheet substrate after the black ink is applied. Next, excess ink is scraped off with a squeegee rubber for screen printing, and an external light absorbing layer is provided in the recess as shown in FIG. Then, a black ink is applied to the top of the external light absorbing portion and a part of the side near the top by a screen printing method, and an external light absorbing layer is provided to obtain a lenticular lens sheet having a cross-sectional shape shown in FIG.

The lenticular lens sheet of the present invention and the conventional lenticular lens sheet in which the external light absorbing layer is not provided in the recess are respectively combined with a Fresnel lens sheet, each of which is set in a projection television, the contrast is measured, and the both are measured. A comparison was made. The basic form such as the lens pitch of both lenticular lens sheets is the same. Here, the white image light luminance is W,
Assuming that the black image light luminance is B and the external light reflection luminance is X, the contrast C is expressed by the following equation. C = (W + X) / (B + X)

The illuminance on the screen surface was set to 250 lx using the external light as a fluorescent lamp in the room. The luminance of the image light and the reflection luminance of the external light were measured at a position 3 m away from the front of the center of the screen and under the condition of a 2 ° visual field. Table 1 shows the measurement results. The specifications of the lenticular lens of the lenticular lens sheet for which the measurement results of Table 1 were obtained are as shown in Table 2.

[0028]

[Table 1]

[Table 2]

As shown in Table 1, the lenticular lens sheet of the present invention improved the contrast by 18%. Further, the difference in blackness of the black screen was obvious even by visual observation, and reflection of external light was greatly reduced by the lenticular lens sheet of the present invention.

Next, in forming the external light absorbing layer in the concave portion by the method of the present embodiment, as shown in Table 3, three types of lenticular lens sheets in which the application range of the external light absorbing layer in the concave portion was changed were used. After being manufactured, each optical performance and contrast were evaluated.

[0031]

[Table 3]

As shown in Table 3, the evaluation results show that
Of the external light absorbing layer from the bottom of the concave portion on the bottom side of
_BAnd the height H of the external light absorbing portion from the bottom of the concave portion_BRatio h
_B/ H_BIs 0.007 for lenticular lens
No. 2, the above ratio h _B/ H_BExceeds 0.01
Lenticular lens sheet No. 1 and No. 1
The contrast is slightly inferior to 3. Also the lens
Of the external light absorbing layer from the bottom of the concave part on the skirt side of the part
h_LAnd the height H of the lens portion from the bottom of the concave portion_LRatio h_L
/ H_LLenticular lens sheet N where is 0.5
o. 3, the above ratio h_L/ H_LIs 0.4 or less
Chicular lens sheet No. 1 and No. 1 Than 2
Also, the transmittance was somewhat low. Lenticular lens sheet
No. When the image of No. 3 is observed from an oblique direction,
Was slightly observed.

[0033]

According to the lenticular lens sheet of the present invention, reflection of external light is greatly reduced, and a clear image with high contrast can be obtained.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view showing an emission surface of a lenticular lens sheet of the present invention.

FIG. 2 is a cross-sectional view showing an emission surface of a second example of the lenticular lens sheet of the present invention.

FIG. 3 is a diagram for explaining a preferable height of an external light absorbing layer formed in a concave portion.

FIG. 4 is a cross-sectional view illustrating an example of a shape of a forming roll for shaping an emission surface shape.

FIG. 5 is a cross-sectional view illustrating another example of the shape of a forming roll for shaping the shape of an emission surface.

FIG. 6 is a diagram illustrating an example of a method of removing an external light absorbing material other than a concave portion.

FIG. 7 is a diagram showing another example of a method of removing an external light absorbing material other than a concave portion.

FIG. 8 is a cross-sectional view showing an example of a lenticular lens sheet of the present invention provided with a concave portion such as a deep groove.

FIG. 9 is a cross-sectional view showing an emission surface of an extruded lenticular lens sheet substrate.

FIG. 10 is a cross-sectional view showing an emission surface of a lenticular lens sheet substrate on which an external light absorbing material is applied on the entire surface.

FIG. 11 is a cross-sectional view showing an emission surface of a lenticular lens sheet substrate from which external light absorbing materials other than concave portions have been removed.

FIG. 12 is a schematic perspective view of a conventional lenticular lens sheet.

[Explanation of symbols]

 1: Lenticular lens sheet 2: Lens part 3: External light absorbing part 4, 6: External light absorbing layer 5: Concave part

Claims (14)

[Claims] 1. A lenticular lens having a plurality of lenticular lenses on one surface of a light-transmitting substrate, and a convex lens portion on the other surface of the light-transmitting substrate at a position where light from each of the lenticular lenses is condensed. Having, at a position different from the condensing position of light from each lenticular lens on the other surface,
It has a convex external light absorbing portion provided with an external light absorbing layer on the top, and a concave portion between the convex lens portion and the convex external light absorbing portion also has an external light absorbing layer. A lenticular lens sheet, characterized by comprising: 2. The lenticular lens sheet according to claim 1, wherein the external light absorbing layer of the external light absorbing section is also provided on a part of the side surface of the external light absorbing section near the top. 3. The method according to claim 1, wherein the concave portion between the convex lens portion and the convex external light absorbing portion has a substantially trapezoidal shape having a flat portion substantially parallel to the lenticular lens sheet surface. Lenticular lens sheet. 4. The lenticular according to claim 1, wherein the concave portion between the convex lens portion and the convex external light absorbing portion has a valley shape having no flat portion parallel to the lenticular lens sheet surface. Lens sheet. 5. A concave portion between the convex lens portion and the convex external light absorbing portion has a flat portion substantially parallel to the lenticular lens sheet surface and a flat portion substantially perpendicular to the lenticular lens sheet surface. The lenticular lens sheet according to claim 1, wherein the lenticular lens sheet has a substantially rectangular shape having a wall portion. 6. A concave portion on a skirt side of a convex lens portion.
The height of the provided external light absorbing layer is h_LAt the bottom of the recess
From the height to the top of the convex lens portion is H _LIn each
H_LAnd h_LIs 0.02 ≦ h_L/ H_L≤
The lenticular according to claim 1, which satisfies a relationship of 0.4.
-Lens sheet. In 7. hem side of the convex external light absorbing portion, the height of the external light absorption layer provided in a recess in the h _B, the top of the external light-absorbing portion from the bottom-most convex shape of the recess when representing each up to a height _{H B, H B} and _{h B} is, 0.01 ≦ h _B /
2. The lenticular lens sheet according to claim 1, wherein a relationship of H _B ≦ 0.3 is satisfied. 8. A concave portion on a skirt side of a convex lens portion.
The height of the provided external light absorbing layer is h_LAt the bottom of the recess
From the height to the top of the convex lens portion is H _LAnd convex
The external light absorbing portion provided in the concave portion at the foot of the external light absorbing portion
The height of the reservoir is h_BThe convex external light from the bottom of the concave portion
The height to the top of the absorber is H_B, H
_L, H_L, H_BAnd h_BIs 0.02 ≦ h_L/ H_L≤
0.4 and 0.01 ≦ h_B/ H_B≦ 0.3
2. The lenticular lens system according to claim 1, wherein the relationship is satisfied.
To 9. A lenticular lens having a plurality of lenticular lenses on one surface, and a convex lens portion at a condensing position of light from each of the lenticular lenses on the other surface; The convex lens portion and the convex portion in a light transmitting substrate having a convex external light absorbing portion on which an external light absorbing layer is to be provided on the top at a position different from the light condensing position of light from each lenticular lens. Between the convex external light absorbing portion and the convex external light absorbing portion, and then filling the external light absorbing material except for the concave portion between the convex lens portion and the convex external light absorbing portion. A method for manufacturing a lenticular lens sheet, characterized by providing an external light absorbing layer in the concave portion by removing the concave portion, and thereafter providing an external light absorbing layer on the top of the convex external light absorbing portion. 10. The lenticular lens according to claim 9, wherein when the external light absorbing layer is provided on the top of the convex external light absorbing section, the external light absorbing layer is also provided on a part of the side surface of the external light absorbing section near the top. Sheet manufacturing method. 11. When the external light absorbing material is filled between the convex lens portion and the convex external light absorbing portion, a layer of the external light absorbing material is formed on the entire surface of the other surface of the light transmitting substrate. Claim 9
A method for producing the lenticular lens sheet as described above. 12. A lenticular lens having a plurality of lenticular lenses on one surface, and a convex lens portion at a condensing position of light from each of the lenticular lenses on the other surface. A first external light absorbing layer is provided on a top of the convex external light absorbing portion in a light transmitting substrate having a convex external light absorbing portion at a position different from a light condensing position of light from each lenticular lens. Then, a layer of an external light absorbing material is laminated on the entire surface including the convex external light absorbing portion, and then a second external light absorbing material is formed in a concave portion between the convex lens portion and the convex external light absorbing portion. 2. A method for manufacturing a lenticular lens sheet, comprising removing an external light absorbing material other than the concave portion so that the external light absorbing layer 2 remains. 13. A lenticular lens having a plurality of lenticular lenses on one surface, a convex lens portion at a condensing position of light from each of the lenticular lenses on the other surface, and a lenticular lens on the other surface. In a light transmitting substrate having a convex external light absorbing portion at a position different from the condensing position of light from the lens, a first external light absorbing layer is provided on the top of the convex external light absorbing portion, An external light absorbing material is filled between the convex lens portion and the convex external light absorbing portion, and then the concave portion between the convex lens portion and the convex external light absorbing portion is filled. A method for manufacturing a lenticular lens sheet, comprising removing an external light absorbing material in a portion other than the concave portion so that a second external light absorbing layer remains. 14. The external light absorbing material layer according to claim 12, wherein when the first external light absorbing layer is provided on the top of the external light absorbing section, the external light absorbing material layer is also provided on a part of the side of the external light absorbing section near the top. Manufacturing method of lenticular lens sheet.