WO2017146010A1

WO2017146010A1 - Laminated optical film

Info

Publication number: WO2017146010A1
Application number: PCT/JP2017/006241
Authority: WO
Inventors: 潔酒井; 昌利大鳥
Original assignee: サンテックオプト株式会社
Priority date: 2016-02-22
Filing date: 2017-02-20
Publication date: 2017-08-31
Also published as: JP6810126B2; JPWO2017146010A1

Abstract

Provided is a laminated optical film for preventing the occurrence of moire in a film on which a prism sheet is laminated on a diffusion sheet having linear protruding parts. In the laminated optical film in which upper and lower prism sheets having prism columns periodically arranged in parallel and the diffusion sheet are laminated via an adhesive layer, the upper and lower prism sheets are arranged such that the prism columns provided on the surface of the upper prism sheet and the prism columns provided on the surface of the lower prism sheet are orthogonal to each other, the linear protruding parts are periodically arranged in parallel on the surface of the diffusion sheet, the column direction of the linear protruding parts is not parallel on the same plane as the prism column direction of the upper prism sheet, and an angle is provided.

Description

Laminated optical film

The present invention relates to an optical film used for a liquid crystal panel or the like.

In recent years, there has been an increasing need for lighter and thinner smartphones, and the need for lighter and thinner liquid crystal panels has also increased.
A backlight unit used for a liquid crystal panel or the like generally has a structure in which a diffusion sheet, a prism sheet, and a light guide plate are physically stacked. That is, as shown in FIG. 9, there are a light guide plate 13 and a reflection plate 17 that guide light from the light source 18, a lower diffusion sheet 4 on the light guide plate 13, and vertical and horizontal prism filaments on the light diffusion plate 4. There are an upper prism sheet 2, a lower prism sheet 3, and an upper diffusion sheet 6, and these constitute the backlight unit 12. A panel portion 11 is provided on the upper and lower prism sheets (2, 3). The panel portion 11 has a configuration in which the liquid crystal cell 16 is sandwiched between polarizing plates 15 on the front surface side and the back surface side.

Since the prism sheet is provided with uneven prism rows on its surface, moire may occur due to the relationship with the liquid crystal cell when laminated on the panel unit 11. In addition, although the diffusion sheet 4 has random irregularities formed on the surface, linear protrusions are provided at a constant pitch in order to achieve adhesion with the lower prism sheet 3 laminated on the surface. In some cases, moire may occur due to the relationship between the prism filaments of the upper prism sheet 2 and the filament projections of the diffusion sheet 4. In addition, a linear protrusion here is a convex part extended in the linear provided in the diffusion sheet.
As a liquid crystal display device that prevents the occurrence of such moire, for example, the device of Patent Document 1 is known. This is to eliminate the moire by providing the pixel array direction of the liquid crystal display panel and the prism row direction of the prism sheet so as not to coincide with each other.
However, the liquid crystal display device disclosed in Patent Document 1 does not consider the case where the linear protrusion is provided on the surface of the diffusion sheet, and in such a case, the relationship between the prism sheet and the diffusion sheet. It is difficult to prevent the moiré generated in

JP 2008-32841 A

In view of the above situation, an object of the present invention is to provide a laminated optical film that prevents moiré that occurs in a film in which a prism sheet is laminated on a diffusion sheet having linear convex portions.

In order to solve the above-mentioned problems, the laminated optical film of the present invention is a laminated optical film in which an upper and lower prism sheet and a diffusion sheet in which prism rows are periodically arranged in parallel are laminated via an adhesive layer. The sheet is arranged so that the prism rows provided on the surface of the upper prism sheet and the prism rows provided on the surface of the lower prism sheet are orthogonal to each other. The portions are periodically arranged in parallel, and the row direction of the line projections is not parallel to the prism row direction of the upper prism sheet, but is provided with an angle. The row direction of the line projections of the diffusion sheet is not parallel on the same plane as the prism row direction of the upper prism sheet, and moire is reduced by integrally laminating at an angle in advance. In addition, although the cross section of a line | wire convex part is not specifically limited, The cross section is triangular shape, rectangular shape, polygonal shape, dome shape, semicircle shape, or semi-elliptical shape, for example.

The row direction of the line projections in the laminated optical film of the present invention is preferably in the range of an angle θ ± 2 ° (7 ° <θ <23 °) from the prism row direction of the upper prism sheet. By providing such an angle, the occurrence of moire can be effectively prevented.

In the laminated optical film of the present invention, the angle θ provided in the row direction of the line projections with respect to the prism row direction of the upper prism sheet is P ₁ , and the pitch of the prism row of the upper prism sheet is P ₁ . When the pitch of the strip convex section columns and P _2, it is preferable to satisfy the following formula 1. In the following formula 1, n is a natural number that satisfies 0.9205 <cos θ <0.9925, and P ₂ is a range that satisfies 5 to 10 times P ₁ .

(Equation 1)
cos θ = P ₂ / n · P ₁ (Formula 1)

In addition, in the laminated optical film of the present invention, the angle θ provided in the row direction of the linear protrusions with respect to the prism row direction of the upper prism sheet is set so that the pitch (P ₁ ) of the prism rows of the upper prism sheet is 20 When the pitch (P ₂ ) of the line projections of the diffusion sheet is 100 to 400 μm, it is 8 to 12 °.

In the laminated optical film of the present invention, the pitch (P ₂ ) of the linear projections of the diffusion sheet is made sufficiently larger than the pitch (P ₁ ) of the prisms of the upper prism sheet. This is because the linear projections of the diffusion sheet are partially embedded in the adhesive layer on the back surface of the lower prism sheet laminated on the diffusion sheet, resulting in a decrease in luminance performance. A preferred range of the above formulas 1 to n is determined. In other words, when Equation 1 is transformed to P ₁ · n · cos θ = P ₂ , the value of P ₂ is determined by the product of P ₁ , n, and cos θ. If 5 ≦ n · cos θ ≦ 10, n is a natural number, and cos θ is the minimum value 0.9205, the condition is not satisfied unless n is 6 or more. If cos θ is a maximum value of 0.9925, the condition is not satisfied unless n is 10 or less. Therefore, a preferable range of n is 6 ≦ n ≦ 10. It should be noted that the preferred range of n is also determined for Formula 2 described later, as with Formula 1.

In the laminated optical film of the present invention, the prism row of the lower prism sheet includes a first prism row having a first height and a second prism row having a second height lower than the first height. Is preferred.
Since the prism row of the lower prism sheet is embedded in the adhesive layer on the back surface of the upper prism sheet in the upper layer, the luminance performance may be lowered. Therefore, by providing two kinds of prism rows having different heights, it is possible to bond only the first prism row having a large height and not to bond the second prism row having a small height when bonded. Luminance performance can be improved. In addition, it is possible to prevent the occurrence of bleeding called wet out.

The laminated optical film of the present invention is a laminated optical film in which a lower prism sheet and a diffusion sheet in which prism rows are periodically arranged in parallel are laminated via an adhesive layer. The protrusions are periodically arranged in parallel, and the row direction of the line protrusions is not parallel on the same plane as the prism row direction of the lower prism sheet, but is an angle θ ₁ ± 2 ° from the prism row direction of the lower prism sheet (However, 67 ° <θ ₁ <83 °) is provided, and the upper prism sheet that is superimposed on the lower prism sheet is arranged so that the prism rows of the upper prism sheet and the prism rows of the lower prism sheet are orthogonal to each other. The row direction of the line projections is not parallel to the prism row direction of the upper prism sheet, but is an angle θ ₂ ± 2 ° from the prism row direction of the upper prism sheet (however, 7 ° <θ ₂ < 3 °), characterized in that is provided.
Moire occurs between the upper prism sheet and the diffusion sheet, but the upper prism sheet and the lower prism sheet are laminated so that the prism rows are orthogonal to each other. By adhering with a predetermined angle, it is possible to prevent the occurrence of moire when the upper prism sheet is superimposed on the lower prism sheet.

In the laminated optical film of the present invention, the angle θ ₂ provided in the row direction of the line projections of the diffusion sheet with respect to the prism row direction of the upper prism sheet to be superimposed is P ₁ It is preferable that the following formula 2 is satisfied, where P ₂ is the pitch of the linear projections of the diffusion sheet. In the following formula 2, n is a natural number that satisfies 0.9205 <cos θ ₂ <0.9925, and P ₂ is a range that satisfies 5 to 10 times P ₁ . As described above, a preferable range of n is determined for the following formula 2 as well as the above formula 1.

(Equation 2)
cos θ ₂ = P ₂ / n · P ₁ (Formula 2)

In the laminated optical film of the present invention, the angle θ ₂ provided in the row direction of the linear protrusions of the diffusion sheet with respect to the prism row direction of the upper prism sheet is the pitch (P ₁ ) of the prism rows of the upper prism sheet. Is preferably 20 to 50 μm, and the pitch (P ₂ ) of the line projections of the diffusion sheet is preferably 8 to 12 °.

The laminated optical film of the present invention has an effect of preventing the occurrence of moire in a film in which a prism sheet is laminated on a diffusion sheet having linear convex portions.

Overall configuration diagram of laminated optical film of Example 1 Explanatory drawing of the laminated optical film of Example 1 Cross-sectional schematic diagram of the laminated optical film of Example 1 Explanatory drawing of the lower prism sheet of Example 1 Lamination image of laminated optical film of Example 1 Fig. 1 Explanatory drawing of the lower diffusion sheet of Example 1 Lamination image of laminated optical film of Example 1 Fig. 2 Cross-sectional schematic diagram of the laminated optical film of Example 2 Schematic structure diagram of a typical liquid crystal panel Lamination image diagram of laminated optical film of Example 3 Lamination image diagram of laminated optical film when linear convex part is trapezoidal Lamination image diagram of laminated optical film when linear convex part is elliptical

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The scope of the present invention is not limited to the following examples and illustrated examples, and many changes and modifications can be made.

FIG. 1 shows an overall configuration diagram of the laminated optical film of Example 1. Moreover, FIG. 2 is explanatory drawing of the laminated | multilayer optical film of Example 1, and has shown the angle by which the linear protrusion part of a diffusion sheet is provided. As shown in FIG. 1, the laminated optical film 1 includes an upper prism sheet 2, a lower prism sheet 3, and a lower diffusion sheet 4. The upper prism sheet 2 is provided with a prism row 2a in the Y-axis direction. The lower prism sheet 3 is provided with prism rows (3a, 3b) in the X-axis direction. As shown in FIGS. 1 and 2, the lower diffusion sheet 4 is provided with linear protrusions 4a with an angle θ from the Y-axis direction.

FIG. 3 shows a schematic cross-sectional view of the laminated optical film of Example 1. As shown in FIG. 3, an adhesive layer 5 a is provided on the back surface of the upper prism sheet 2, and is adhered to a prism row 3 a provided on the surface of the lower prism sheet 3.
On the surface of the lower diffusion sheet 4, linear protrusions 4 a and dot-like protrusions 4 b having diffusion performance are provided. An adhesive layer 5b is provided on the back surface of the lower prism sheet 3, and is adhered to the linear protrusion 4a.
Prism rows 2a pitch P ₁ of the cross provided on the surface of the upper prism sheet 2 has a 38 [mu] m. Also, the linear convexes 4a mutual pitch P ₂ which is provided on the surface of the lower diffusion sheet 4 has a 300 [mu] m.

FIG. 4 is an explanatory diagram of the lower prism sheet. As shown in FIG. 4, the prism row 3a of the lower prism sheet 3 is formed higher than the prism row 3b. Therefore, as shown in FIG. 3, when bonding to the adhesive layer 5a provided on the back surface of the upper prism sheet 2, only the prism row 3a is bonded, and the prism row 3b is not bonded. Since the prism row 3b is not adhered to the adhesive layer 5a, a brightness enhancement effect can be obtained, and the occurrence of bleeding called wet-out can also be prevented.
In the present embodiment, the prism rows 3a and the prism rows 3b are alternately arranged, but it is not always necessary to be alternated, and a plurality of them may be provided so as to be continuous.
Pitch _{P 3} of the prism rows 3a and the prism array 3b has a 38μm

FIG. 5 shows a lamination image diagram of the laminated optical film of Example 1. As shown in FIG. 5, the laminated optical film 1 has a structure in which a lower prism sheet 3 and an upper prism sheet 2 are sequentially laminated on a lower diffusion sheet 4. On the surface of the upper prism sheet 2, a prism row 2a is provided in parallel with the longitudinal direction of the sheet, and on the surface of the lower prism sheet 3, prism rows (3a, 3b) are provided in the longitudinal direction of the sheet. On the surface of the lower diffusion sheet 4, linear protrusions 4a are provided at an angle in an oblique direction with respect to the longitudinal direction of the sheet.

6 shows an explanatory diagram of the lower diffusion sheet of Example 1. FIG. As shown in FIG. 6, the linear protrusion 4 a is provided with a predetermined angle θ with respect to the Y-axis direction.
Verification was performed to confirm that the effect of eliminating moire can be obtained only when the angle θ is provided within a certain range. Table 1 below, the prism rows 2a mutual pitch _{P 1} is 38 [mu] m of the prism sheet, the prism column 3a and the prism array 3b of the pitch _{P 3} is 38 [mu] m, the diffusion sheet of the linear convex portion 4a mutual pitch _{P 2} is 300 [mu] m, the angle The result of verifying when θ is 0 ° is shown. As a verification method, the lower prism sheet 3 and the upper prism sheet 2 are sequentially laminated on the lower diffusion sheet 4, and the initial arrangement angle of the lower diffusion sheet 4 in a state where the lower prism sheet 3 and the upper prism sheet 2 are fixed. Verification was performed starting from 0 ° and changing to an angle of 90 ° (that is, equivalent to changing the angle θ). The presence or absence of moiré was confirmed visually.

As shown in Table 1 above, occurrence of moire has been confirmed when the angle θ is in the range of 0 ° to 7 °. On the other hand, no moire occurs when the angle θ is in the range of 8 ° to 82 °. In the range where the angle θ is 83 ° to 90 °, moire is confirmed again. This is because when the angle θ is near 90 °, moire occurs due to the influence of the prism rows of the lower prism sheet.
From this, it was found that providing the angle θ in the range of 8 ° to 82 ° is effective for preventing moire. However, when combined with a liquid crystal panel, moire occurs due to the influence of the pixels of the liquid crystal panel. Therefore, the angle θ is not necessarily within the range of 8 ° to 82 °. It will be in the range. This limited range is a range of angle θ ± 2 ° (where 7 ° <θ <23 °).

As shown in FIG. 6, when the pitch of the line projections of the diffusion sheet is P ₂ and the angle between the direction of the prisms of the upper prism sheet and the direction of the lines of protrusions is θ, The substantial pitch (P ₂ ′) that is the pitch direction is P2 / cos θ. When the pitch (P ₁ ) of the prism rows of the upper prism sheet and the actual pitch (P ₂ ′ = P2 / cos θ) of the linear projections of the diffusion sheet are in an integer multiple relationship, moire is less likely to occur.
That is, a relationship of P ₁ × n = P ₂ / cos θ (n is a natural number) is established.
From this, the equation of cos θ = P ₂ / n · P ₁ is obtained. If θ is in the range of 7 ° <θ <23 °, cos θ takes a value in the range of 0.9205 to 0.9925 from the trigonometric table of cosine (cos θ) (see Table 2 below). .

For example, when the pitch (P ₁ ) of the prism row of the upper prism sheet is 35 μm and the pitch (P ₂ ) of the line projections of the diffusion sheet is 300 μm, cos θ = P ₂ / n · P ₁ and cos θ is 0. Within the range of .9205 to 0.9925, the case where n is 9 satisfies the condition.
When n = 8: cos θ = 1.071
When n = 9: cos θ = 0.952
When n = 10: cos θ = 0.857
When n is 9, the value of cos θ is 0.952, and θ can be calculated as 18 ° from the trigonometric table. Accordingly, when the pitch (P ₁ ) of the prism rows of the upper prism sheet is 35 μm and the pitch (P ₂ ) of the line projections of the diffusion sheet is 300 μm, the row direction of the line projections of the diffusion sheet and the upper prism By setting the angle of the sheet to the prism row direction in the range of 16 to 20 ° (θ ± 2 °), the occurrence of moiré can be reduced.

On the other hand, for example, if the pitch (P ₁ ) of the prism row of the upper prism sheet is 38 μm and the pitch (P ₂ ) of the line projections of the diffusion sheet is 300 μm, cos θ = P ₂ / n · P ₁ When cos θ is in the range of 0.9205 to 0.9925, the condition is satisfied when n is 8.
When n = 7: cos θ = 1.127
When n = 8: cos θ = 0.986
When n = 9: cos θ = 0.877
When n is 8, the value of cos θ is 0.986, and θ can be calculated as 10 ° from the trigonometric table. Therefore, when the pitch (P ₁ ) of the prism rows of the upper prism sheet is 38 μm and the pitch (P ₂ ) of the line projections of the diffusion sheet is 300 μm, the row direction of the line projections of the diffusion sheet and the upper prism By setting the angle of the sheet to the prism row direction in the range of 8 to 12 ° (θ ± 2 °), the occurrence of moire can be reduced.
In addition, the result of visually confirming the presence or absence of moire (Table 1) is 8 to 12 °, which is consistent with the above result.

On the other hand, for example, when the pitch (P ₁ ) of the prism row of the upper prism sheet is 22 μm and the pitch (P ₂ ) of the line projections of the diffusion sheet is 190 μm, cos θ = P ₂ / n · P ₁ When cos θ is in the range of 0.9205 to 0.9925, the condition is satisfied when n is 9.
When n = 8: cos θ = 1.079
When n = 9: cos θ = 0.959
When n = 10: cos θ = 0.863
When n is 9, the value of cos θ is 0.959, and θ can be calculated as 16 ° from the trigonometric table. Therefore, when the pitch (P ₁ ) of the prism row of the upper prism sheet is 22 μm and the pitch (P ₂ ) of the line projections of the diffusion sheet is 190 μm, the row direction of the line projections of the diffusion sheet and the upper prism By setting the angle of the sheet to the prism row direction in the range of 14 to 18 ° (θ ± 2 °), the occurrence of moire can be reduced.

FIG. 5 shows a lamination image diagram of the laminated optical film of Example 1. The laminated optical film 1 has a structure in which a lower prism sheet 3 and an upper prism sheet 2 are sequentially laminated on a lower diffusion sheet 4, and FIG. 7 shows a state in which the laminated optical film 1 is viewed in plan view. Yes. Since the linear protrusion 4a is provided at the angle shown in FIG. 6, it has a structure in which moire does not occur.

FIG. 8 shows a schematic cross-sectional view of the laminated optical film of Example 2. As shown in FIG. 8, in the case of the laminated optical film 10, the lower prism sheet 3 is laminated on the lower diffusion sheet 4 in the same manner as in the first embodiment. The upper prism sheet 2 is not integrally laminated on the upper prism sheet, but when mounting, the upper prism sheet 2 is superposed on the lower prism sheet 3 without an adhesive layer. When superimposing, the prism rows of the upper prism sheet and the prism rows of the lower prism sheet (3a, 3b) are set to be orthogonal in plan view.
By using the laminated optical film of Example 2, even when the upper prism sheet is laminated at the time of mounting, the occurrence of moire can be prevented and the effect of reducing moire is exhibited.

FIG. 10 shows a lamination image diagram of the laminated optical film of Example 3. As shown in FIG. 6, the linear protrusion 4 a is provided with a predetermined angle θ with respect to the Y-axis direction.
Verification was performed to confirm that the effect of eliminating moire can be obtained only when the angle θ is provided within a certain range. Table 3 below, the prism rows 2a mutual pitch _{P 1} is 38 [mu] m of the prism sheet, the prism column 3a and the prism array 3b of the pitch _{P 3} is 38 [mu] m, the diffusion sheet of the linear convex portion 4a mutual pitch _{P 2} is 300 [mu] m, the angle The result of verifying when θ is 0 ° is shown. As a verification method, the lower prism sheet 3 and the upper prism sheet 2 are sequentially laminated on the lower diffusion sheet 4, and the initial arrangement angle of the lower diffusion sheet 4 in a state where the lower prism sheet 3 and the upper prism sheet 2 are fixed. Verification was performed starting from 0 ° and changing to an angle of 90 ° (that is, equivalent to changing the angle θ). The presence or absence of moiré was confirmed visually. As shown in Table 3 below, when the angle θ is in the range of 8 to 82 °, moire is unlikely to occur, and the same result as in Example 1 was obtained even when the shape of the linear convex portion was a semicircular shape.

11 and 12 show laminated image diagrams of the laminated optical film. FIG. 11 shows a case where the cross section of the linear convex portion is trapezoidal, and FIG. 12 shows a case where the cross section of the linear convex portion is elliptical. Is shown.
Both FIG. 11 and FIG. 12 were verified under the conditions shown below. When the pitch (P ₁ ) of the upper prism row is 24 μm, the pitch (P ₂ ) of the line projections of the diffusion sheet is 100 to 400 μm and the line projections of the diffusion sheet satisfying n is 6 to 10 Design.
If the design is focused on the cost aspect, the cost decreases as the number of patterns of the linear protrusions decreases. Therefore, a case where n is 10 is considered here.
P ₂ satisfying 8 ≦ cos θ ≦ 12 and cos θ = P ₂ / n · P ₁ is shown in Table 4 below. From Table 4, the pitch (P ₂ ) of the line projections of the diffusion sheet is 238 μm at the maximum value and 235 μm at the minimum value.
When P ₂ is 238Myuemu, the angle θ is 8 °, was verified as in Example 3. However, the difference is that the initial arrangement angle of the lower diffusion sheet 4 is changed from -8 ° to 82 ° (that is, the angle θ is changed in the range of 0 ° to 90 °).
Table 5 shows the results of the presence or absence of moiré.

The present invention is useful for optical films used for liquid crystal panels and the like.

DESCRIPTION OF

SYMBOLS

1,10 Laminated optical film 2

Upper prism sheet

2a, 3a, 3b Prism row | line | column 3 Lower prism sheet 4 Lower diffusing sheet 4a Line | wire convex part 4b Point-like

convex part

5a, 5b Adhesive layer 11 Panel part 12 Backlight part 13 Light guide plate 14 Antireflection Film 15 Polarizing Plate 16 Liquid Crystal Cell 17 Reflector 18 Light Source P Pitch X, Y, Z Axis θ Angle

Claims

An upper and lower prism sheet and a diffusion sheet in which prism rows are periodically arranged in parallel are laminated optical films laminated via an adhesive layer,
The upper and lower prism sheets are arranged so that the prism rows of the upper prism sheet and the prism rows of the lower prism sheet are orthogonal to each other,
On the surface of the diffusion sheet, linear protrusions are periodically arranged in parallel,
The laminated optical film is characterized in that the row direction of the line projections is not parallel on the same plane as the prism row direction of the upper prism sheet, but is provided with an angle.
2. The laminate according to claim 1, wherein the line direction of the line protrusions is in the range of an angle θ ± 2 ° (7 ° <θ <23 °) from the prism row direction of the upper prism sheet. Optical film.
3. The laminated structure according to claim 2, wherein the angle θ satisfies the following formula 1 where P 1 is a pitch of the prism row of the upper prism sheet and P 2 is a pitch of the line convex portion row of the diffusion sheet. Optical film:
(Equation 1)
cos θ = P 2 / n · P 1 (Formula 1)
(In Formula 1, n is a natural number that satisfies 0.9205 <cos θ <0.9925, and P 2 is a range that satisfies 5 to 10 times P 1 ).
The angle is 8 to 12 ° when the pitch (P 1 ) of the prism row of the upper prism sheet is 20 to 50 μm and the pitch (P 2 ) of the line projections of the diffusion sheet is 100 to 400 μm. The laminated optical film according to any one of claims 1 to 3, wherein:
The lower prism sheet and the diffusion sheet in which the prism rows are periodically arranged in parallel are laminated optical films laminated through an adhesive layer,
On the surface of the diffusion sheet, linear protrusions are periodically arranged in parallel,
The row direction of the line projections is not parallel to the prism row direction of the lower prism sheet, and is at an angle θ 1 ± 2 ° (67 ° <θ 1 <83 from the prism row direction of the lower prism sheet). °)
The upper prism sheet superimposed on the lower prism sheet is arranged so that the prism rows of the upper prism sheet and the prism rows of the lower prism sheet are orthogonal to each other,
The row direction of the linear protrusions is not parallel to the prism row direction of the upper prism sheet, and is an angle θ 2 ± 2 ° from the prism row direction of the upper prism sheet (however, 7 ° <θ 2 <23 A laminated optical film characterized in that a) is provided.
The angle θ 2 satisfies the following expression (2), where P 1 is the pitch of the prism rows of the upper prism sheet and P 2 is the pitch of the line projections of the diffusion sheet. Laminated optical film:
(Equation 2)
cos θ 2 = P 2 / n · P 1 (Formula 2)
(In Formula 2, n is a natural number that satisfies 0.9205 <cos θ <0.9925, and P 2 is a range that satisfies 5 to 10 times P 1 ).
The angle θ 2 is 8 to 12 ° when the pitch (P 1 ) of the prism row of the upper prism sheet is 20 to 50 μm and the pitch (P 2 ) of the line convex portion row of the diffusion sheet is 100 to 400 μm. The laminated optical film according to claim 5, wherein the laminated optical film is provided.