JP2007249218A - Optical film laminate and manufacturing method of optical film laminated chip - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical film laminate with which an optical film laminated chip can be manufactured and which is easy to handle. <P>SOLUTION: The optical film laminate (5) is constituted by laminating a first optical film (15) and a second optical film (25) and has a first side (EF), a second side (HG), a third side (FC) and a fourth side (AH). The third side (FC) and the fourth side (AH) form an angle (ϕ3), which is equal to (-θ1) or (180°-θ1) toward an optical axis (10) of the first optical film [where θ1 denotes the angle made by the optical axis (10) of the first optical film with respect to a reference side (91) in the optical film laminated chip (9)], and the first side (EF) and the second side (HG) are parallel to or vertical with respect to the optical axis (20) of the second optical film. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an optical film laminate and a method for producing an optical film laminate chip.

  An optical film typified by a polarizing film, a retardation film, etc. is important as one of the optical components constituting a liquid crystal display device. For example, in an STN (Super Twisted Nematic) type liquid crystal display device, a polarizing film is used. A rectangular optical film laminated chip (9) in which a film (19) and a retardation film (29) are laminated is used.

The angle of the optical axis (absorption axis, slow axis) of each optical film in the optical film laminated chip is important, and if it is slightly different from the design value, the obtained liquid crystal display device exhibits the intended performance. I can't do that. Therefore, the angle (θ1) of the absorption axis (10) and the angle (θ2) of the slow axis (20) with respect to the reference line in the optical film laminated chip must be strictly controlled. Here, the reference line is usually selected so that the long side or the short side of the optical film laminated chip (9) is parallel to the reference side (91). In addition, the angle (θ1) is an angle displayed as a positive counterclockwise when viewed from the polarizing film side, and the angle (θ2) is an angle displayed as a positive counterclockwise when viewed from the polarizing film side (FIG. 12). ).
The angles (θ1) and (θ2) are between the relative angle (θ) of the optical axis (20) of the second optical film with respect to the optical axis (10) of the first optical film in the optical film laminated chip (9). Formula (I)
θ = θ2 − θ1 (I)
(FIG. 12). Here, the relative angle (θ) is an angle displayed as positive in the counterclockwise direction when viewed from the first optical film side of the optical film laminated chip.

  Such an optical film laminated chip (9) is usually produced from a polarizing film strip (11) and a retardation film strip (21), and these strips (11, 21) usually have their optical axes (absorption axes). , The slow axis) (10, 20) is parallel or perpendicular to the length direction, and when the absolute value of the angle (θ1) is not 0 ° or 90 °, the rectangular optical film laminated chip (9 The polarizing film (19) constituting the) is cut out obliquely from the polarizing film strip (11), and when the absolute value of the angle (θ2) is not 0 ° or 90 °, a rectangular optical The retardation film constituting the film laminated chip (9) is cut obliquely from the retardation film strip (21).

As a method for producing such an optical film laminated chip (9), for example, a polarizing film and a retardation film are laminated, and are parallelograms, and two opposite sides (AB, DC) are absorption of the polarizing film. Cutting the optical film laminate (5) (FIG. 13) parallel to the axis (10) and the other two opposite sides (BC, AD) parallel to the slow axis (20) of the retardation film The manufacturing method is known (Japanese Patent Laid-Open No. 11-231129). In this manufacturing method, the optical film laminate (5) is manufactured from the polarizing film strip (11) and the retardation film strip (21) (FIG. 13).
According to this manufacturing method, the vertical and horizontal dimensions, the size, the angle of the absorption axis (θ1) and the angle of the slow axis (θ2) with respect to the reference side are different, but the relative angle (θ) of the slow axis with respect to the absorption axis is different. A plurality of types of common optical film laminated chips (9) can be cut out from one type of optical film laminated body (5).

  However, in such a production method, a polarizing film strip having an absorption axis parallel to the length direction is used, and a retardation film strip having a slow axis parallel to the length direction is used. When the relative angle (θ) of the slow axis with respect to the absorption axis is 40 ° or less or 140 ° or more, the shape of the optical film laminate (5) tends to be elongated (FIG. 13). There was a problem that it would be difficult.

  In order to solve such a problem, it is also described in the same publication that a retardation film strip having a slow axis perpendicular to the length direction is used. (FIG. 14). According to this manufacturing method, even if the relative angle (θ) is 40 ° or less or 140 ° or more, the shape of the optical film laminate (5) is not elongated and is relatively easy to handle. .

  However, the relative angle (θ) in the target optical film laminated chip (9) varies, and each time the relative angle (θ) in the target optical film laminated chip is switched, the retardation film strip (21) As a result, it is necessary to switch between the case where the slow axis is parallel to the length direction and the case where the slow axis is vertical (FIGS. 13 and 14).

Therefore, the present inventor does not change the phase difference film strips even if the relative angle (θ) in the optical film laminated chip (9) changes, and passes the optical film via the optical film laminated body that is relatively easy to handle. As a result of diligent research to develop a method capable of producing a film-laminated chip, after the polarizing film sheet whose first side and second side are parallel or perpendicular to the absorption axis is cut along a specific cutting line The optical film laminate obtained by laminating the retardation film strip and cutting the retardation film strip is obtained by comparing the direction of the slow axis of the retardation film and the relative angle (θ ) Regardless of whether the shape is relatively easy to handle, and by cutting the optical film laminate (5), the desired optical film laminate The present inventors have found that a chip (9) can be obtained and have reached the present invention.

  That is, in the present invention, a rectangular optical film laminated chip (9) formed by laminating a first optical film (19) and a second optical film (29) is used as a first side (AB) and a second side (DC). ), The third side (BC) and the fourth side (AD), the first side (AB) and the second side (DC) are parallel to each other and parallel or perpendicular to the optical axis (10). It is a method of manufacturing from a certain first optical film sheet (3) and a second optical film strip (21) whose optical axis (20) is parallel or perpendicular to its length direction,

Relative of the optical axis (20) of the second optical film to the optical axis (10) of the first optical film in the optical film laminated chip (9) with respect to the first side (AB) of the first optical film sheet (3) An angle (φ1) equal to the angle (θ) or (θ + 90 °) is formed, cut along the first cutting line (C1) intersecting the third side (BC), and the first cutting line (C1) A distance (L1) equal to the width (W2) of the two optical film strips is parallel and spaced along the second cutting line (C2) intersecting the fourth side (AD), and the first cutting line (C1 ) Along the first side (EF) formed along the second cutting line (C2), the second side (HG) formed along the second cutting line (C2), and the first side of the first optical film sheet (3). The third side (FC) corresponding to a part of the three sides (BC) and the fourth side of the first optical film sheet (3) It has a fourth side (AH) corresponding to a part of the side (AD), and the first side (EF) and the second side (HG) have an angle of θ or θ + 90 ° with respect to the optical axis (10). Obtained first optical film cut sheet (4) (FIGS. 1, 3, 5, and 7),

The obtained first optical film cut sheet (4) is used as the second optical film strip (21), and the first side (EF) and second side (HG) of the first optical film cut sheet (4) are second. While laminating along both edges (IJ, KL) of the optical film strip (21), the second optical film strip (21) is cut along the shape of the first optical film cut sheet (4). The first side (EF) corresponding to the first side (EF) of the first optical film cut sheet (4) and the second side corresponding to the second side (HG) of the first optical film cut sheet (4) (HG), the third side (FC) corresponding to the third side (FC) of the first optical film cut sheet (4), and the fourth side (AH) corresponding to the fourth side (AH) of the first optical film cut sheet (4). It has four sides (AH), the first side (EF) and the second side (HG To obtain an optical film laminate (5) is parallel or perpendicular to the optical axis (20) of the second optical film (2, 4, 6, 8),

The optical film laminate (5) obtained is cut (FIG. 9), and a method for producing an optical film laminate chip (9) is provided.

  According to the manufacturing method of the present invention, since the first optical film sheet (3) is cut along the first cutting line (C1) and the second cutting line (C2), the shape of the optical film laminate (5) is Since it does not become elongated, handling such as transportation is easy. Further, the third side (FC) and the fourth side (AH) of the optical film laminate (5) are equal to (−θ1) or (180 ° −θ1) with respect to the optical axis (10) of the first optical film. If the angle is formed, the third side (FC) and the fourth side (AH) can be used as a reference line for starting the cutting of the optical film laminated chip (9), so that the cutting can be easily performed. it can.

  As a 1st optical film and a 2nd optical film applied to the manufacturing method of this invention, a polarizing film, retardation film, a polarization separation film etc. are mentioned, for example.

  Here, the polarizing film is an optical film having a property of absorbing linearly polarized light having a vibration plane parallel to the absorption axis (optical axis) and transmitting linearly polarized light having a vibration plane perpendicular to the polarizing film. For example, a film obtained by adsorbing and orienting a dichroic dye such as iodine or a dichroic dye on a uniaxially stretched polyvinyl alcohol film may be used. In the polarizing film, a protective film may be bonded to one side or both sides of such a polyvinyl alcohol film. As a protective film, the film etc. which consist of cellulose resins, such as a triacetyl cellulose and a diacetyl cellulose, are mentioned, for example.

  The retardation film has a function of giving a phase difference between linearly polarized light having a vibration plane parallel to the slow axis (optical axis) and linearly polarized light having a vibration plane perpendicular to the retardation film. Examples of the optical film include a stretched film obtained by stretching a polymer film made of polycarbonate resin, polysulfone, polyethersulfone, or the like. In the retardation film, a protective film may be bonded to one side or both sides of such a stretched film. As a protective film, the film etc. which consist of cellulose resins, such as a triacetyl cellulose and a diacetyl cellulose, are mentioned, for example.

  The polarization separation film is an optical film having a function of transmitting linearly polarized light having a vibration surface parallel to the transmission axis (optical axis) and reflecting linearly polarized light having a vibration surface perpendicular to the transmission axis. .

  These optical films can be supplied as an optical film strip wound on a roll or the like, and the width thereof is, for example, about 500 to 2000 mm. In the production method of the present invention, the first optical film may be a polarizing film and the second optical film may be a retardation film, or the first optical film may be a polarization separation film and the second optical film may be a retardation film. The first optical film may be a polarizing film and the second optical film may be a polarizing separation film, the first optical film may be a polarizing separation film and the second optical film may be a polarizing film. May be.

Hereinafter, the manufacturing method of the present invention will be described with reference to FIGS. The 1st optical film sheet (3) used for the manufacturing method of this invention is a sheet-like object which consists of this optical film. The first optical film sheet (3) shown in FIG. 1, FIG. 3, FIG. 5, and FIG. 7, respectively, has at least four sides, that is, the first side (AB), the second side (DC), the third side (BC) and It has a fourth side (AD). The first side (AB) and the second side (DC) are parallel (FIGS. 1 and 3) or perpendicular (FIGS. 5 and 7) to the optical axis (10) and are a pair of opposite sides parallel to each other. . The other sides of the first optical film, that is, the third side (BC) and the fourth side (AD) are a pair of opposite sides, and may be parallel to each other or not. When the third side (BC) and the fourth side (AD) are parallel to each other, (−θ1) or (90 ° −θ1) with respect to the first side (AB) and the second side (DC) An equal angle (φ3) may be formed. The first optical film sheet (3) can be produced, for example, from a first optical film strip (11) whose optical axis (10) is parallel or perpendicular to the length direction. Specifically, it can be produced by cutting the first optical film strip (11) along a cutting line (C3) forming an angle (φ3) with respect to the length direction (FIG. 10, FIG. 11). The angle (φ3) is equal to the angle (−θ1) when using the first optical film strip (11) whose optical axis (10) is parallel to the length direction (FIG. 10), When the first optical film strip (11) having the optical axis (10) perpendicular to the length direction is used, it may be equal to the angle (90 ° −θ1) (FIG. 11). In this case, the third side (BC) and the fourth side (AD) of the first optical film sheet (3) have an angle equal to the angle (φ3) with respect to the first side (AB) and the second side (DC). None, at an angle equal to (−θ1) with respect to the optical axis (10).
The optical axis (20) of the second optical film strip (21) is parallel or perpendicular to the length direction.

  The production method of the present invention is a method for producing an optical film laminated chip (9) from the first optical film sheet (3) and the second optical film strip (21). ) Is cut along the first cutting line (C1) and along the second cutting line (C2) (FIGS. 1, 3, 5, and 7).

  The first cutting line (C1) is a straight line having an angle (φ1) equal to the relative angle (θ) or (θ + 90 °) with respect to the first side (AB) of the first optical film sheet (3).

  The angle (φ1) is such that the first side (AB) and the second side (DC) of the first optical film sheet (3) are parallel to the optical axis (10), and the second optical film strip (21 ) Is equal to the relative angle (θ) when the optical axis (20) is parallel to the length direction (FIG. 1), and the first side (AB) of the first optical film sheet (3). And the second side (DC) is parallel to its optical axis (10), and the second optical film strip (21) has the optical axis (20) perpendicular to its length direction. , Equal to the relative angle (θ + 90 °) (FIG. 3), and the first side (AB) and the second side (DC) of the first optical film sheet (3) are perpendicular to the optical axis (10). When the optical axis (20) is parallel to the length direction of the second optical film strip (21), Equal to the relative angle (θ + 90 °) (FIG. 5), the first side (AB) and the second side (DC) of the first optical film sheet (3) are perpendicular to its optical axis (10), When the optical axis (20) is perpendicular to the length direction, the second optical film strip (21) is selected to be equal to the relative angle (θ) (FIG. 7).

  The first cutting line (C1) intersects the third side (BC) of the first optical film sheet (3). The first cutting line (C1) may intersect the first side (AB), may intersect the fourth side (AD), and the first side (AB) and the fourth side (AD) You may pass through the vertex (A) of the 1st optical film sheet (3) which is an intersection of these.

  The second cutting line (C2) is a straight line parallel to the first cutting line (C1). The second cutting line (C2) intersects the fourth side (AD) of the first optical film sheet (3). The second cutting line (C2) may intersect the second side (DC), may intersect the third side (BC), and the second side (DC) and the third side (BC) You may pass through the vertex (C) of the 1st optical film sheet (3) which is an intersection. The distance (L1) between the first cutting line (C1) and the second cutting line (C2) may be approximately equal to the width (W2) of the second optical film strip (21). The second cutting line (C2) intersects the second side (DC) at an angle (φ2), and this angle (φ2) is equal to the angle (φ1) (FIGS. 1, 3, 5, and 7). ).

  In order to cut the first optical film sheet (3) along the first cutting line (C1) and the second cutting line (C2), it may be cut by an ordinary method using, for example, a roll cutter. The order of cutting is not particularly limited. After cutting along the first cutting line (C1), the cutting may be performed along the second cutting line (C2), or the second cutting line (C2). After cutting along the first cutting line (C1), it may be cut along the first cutting line (C1) or simultaneously along the second cutting line (C2). Good.

  The first optical film cut sheet (4) is obtained by cutting the first optical film sheet (3) along the first cutting line (C1) and the second cutting line (C2). The first optical film cut sheet (4) has at least four sides, that is, a first side (EF), a second side (HG), a third side (FC), and a fourth side (AH). The first side (EF) is a side formed by cutting the first optical film sheet (3) along the first cutting line (C1). The second side (HG) is a side formed by cutting the first optical film sheet (3) along the second cutting line (C2). The first side (EF) and the second side (HG) are parallel to each other, and the distance therebetween is equal to the distance (L1) between the first cutting line (C1) and the second cutting line (C2). The first side (EF) and the second side (HG) are relative to the optical axis (10) of the first optical film (θ) (FIGS. 1 and 5) or (θ + 90 °) (FIGS. 3 and 7). ) And the same angle.

  The third side (FC) is a side corresponding to a part of the third side (BC) of the first optical film sheet (3). The fourth side (AH) is a side corresponding to a part of the fourth side (AD) of the first optical film sheet. When the third side (BC) and the fourth side (AD) of the first optical film sheet are parallel to each other and form an angle (φ3) with respect to the first side (AB) and the second side (DC) In the first optical film sheet (4), the third side (FC) and the fourth side (AH) are parallel to each other and are (−θ1) or (−) with respect to the optical axis (10) of the first optical film. An angle equal to 180 ° −θ1).

  The first optical film cut sheet (4) has at least six sides, that is, a first side (EF), a second side (HG), a third side (FC), a fourth side (AH), and a fifth side ( AE) and the sixth side (GC). The fifth side (AE) is a side corresponding to at least a part of the first side (AB) in the first optical film sheet (3). The sixth side (GC) is a side corresponding to at least a part of the second side (DC) in the first optical film sheet (3). The fifth side (AE) and the sixth side (GC) are parallel to each other. The fifth side (AE) and the sixth side (GC) are parallel (FIGS. 1 and 3) or perpendicular (FIGS. 5 and 7) to the optical axis (10) of the first optical film.

  Subsequently, while laminating the obtained 1st optical film cut sheet (4) on a 2nd optical film strip (21), a 2nd optical film strip (21) is a 1st optical film cut sheet (4). Cut along the shape (FIGS. 2, 4, 6, and 8).

  In order to laminate the first optical film cut sheet (4) on the second optical film strip (21), for example, an adhesive is used. As the adhesive, usually an acrylic pressure-sensitive adhesive, a urethane-based pressure-sensitive adhesive. A transparent and optically isotropic pressure sensitive adhesive (adhesive) such as an adhesive is used. Such an adhesive is usually applied in advance to one surface of the first optical film sheet (3) or the first optical film strip (11) or the second optical film strip (21) which is a raw material thereof, and bonded. It is provided as an agent layer, and its thickness is usually about 10 to 40 μm.

  Upon lamination, the first optical film cut sheet (4) has a first side (EF) along one edge (IJ) of the second optical film strip (21) and a second side (HG) of the second side (HG). It is laminated so as to be along the other edge (KL) of the optical film strip (21). Both edges (IJ, KL) are parallel to the length direction of the second optical film strip state (21).

  In order to cut | disconnect a 2nd optical film strip | belt body (21), what is necessary is just to cut | disconnect by the normal method using a roll cutter etc., for example.

  The step of laminating the first optical film strip (4) on the second optical film strip (21) may be performed after cutting the second optical film strip (21). When the rigidity is larger than that of the two optical film, the first optical film cut sheet (4) is secondly laminated in that the first optical film can be easily laminated without causing wrinkles on the second optical film. It is preferable that the second optical film (21) is cut after being laminated on the optical film strip (21).

  Thus, an optical film laminate (5) is obtained. The optical film laminate (5) shown in FIG. 2, FIG. 4, FIG. 6, and FIG. 8, respectively, has a first optical film (15) and a second optical film (25) laminated, and has at least four sides, It has a first side (EF), a second side (HG), a third side (FC), and a fourth side (AH). The first side (EF) and the second side (HG) correspond to the first side (EF) and the second side (HG) in the first optical film cut sheet (4), and the optical axis of the second optical film ( 20) parallel (FIGS. 2, 6) or perpendicular (FIGS. 4, 8) and parallel to each other. The third side (FC) and the fourth side (AH) correspond to the third side (FC) and the fourth side (AH) in the first optical film cut sheet (4). As the first optical film sheet (3), a sheet in which the third side (BC) and the fourth side (AD) form an angle (φ3) with respect to the first side (AB) and the second side (DC) was used. In this case, the third side (FC) and the fourth side (AH) are at an angle equal to (−θ1) or (180 ° −θ1) with respect to the optical axis (10) of the first optical film, They are parallel to each other.

  The optical film laminate (5) includes at least six sides, that is, a first side (EF), a second side (HG), a third side (FC), and a fourth side (AH), and a fifth side. (AE) and the sixth side (GC) may be included. The fifth side (AE) and the sixth side (GC) correspond to the fifth side (AE) in the first optical film cut sheet, and the sixth side (GC) is the sixth side (in the first optical film cut sheet). GC), parallel (FIGS. 2 and 4) or perpendicular (FIGS. 6 and 8) to the optical axis (10) of the first optical film, and parallel to each other.

  In the optical film laminate (5), the first side (AB) and the second side (DC) of the used first optical film sheet (3) are parallel to the optical axis (10), and the second side The optical axis (20) of the optical film strip (21) is parallel to the length direction, and the relative angle (θ) is 50 ° or less or 130 ° or more, preferably 45 ° or less and 135 ° or more, more preferably. When it is 40 ° or less and 140 ° or more (FIG. 2), the first side (AB) and the second side (DC) of the first optical film sheet (3) are parallel to the optical axis (10), The optical axis (20) of the second optical film strip (21) is perpendicular to the length direction, and the relative angle (θ) is 40 ° to 140 °, preferably 45 ° to 135 °, more preferably. Is 50 ° to 130 ° (FIG. 4), the first light The first side (AB) and the second side (DC) of the scientific film sheet (3) are perpendicular to the optical axis (10), and the optical axis (20) of the second optical film strip (21) is When parallel to the length direction and the relative angle (θ) is 40 ° to 140 °, preferably 45 ° to 135 °, more preferably 50 ° to 130 ° (FIG. 6), or The first side (AB) and the second side (DC) of the first optical film sheet (3) are perpendicular to the optical axis (10), and the optical axis (20 of the second optical film strip (21)). ) Is perpendicular to the length direction, and the relative angle (θ) is 50 ° or less or 130 ° or more, preferably 45 ° or less 135 ° or more, more preferably 40 ° or less 140 ° or more (FIG. 8). ) Is an acute angle from the optical film sheet (3) Since the vicinity of the vertex B and the vicinity of the vertex D is previously cut and separated by the first cutting line (C1) and the second cutting line (C2), the shape is not elongated and handling such as carrying is possible. Easy.

  Next, the optical film laminate (5) is cut to obtain a target rectangular optical film laminate chip (9) (FIG. 9 (a)).

  The third side (FC) and the fourth side (AH) of the optical film laminate (5) form an angle (−θ1) or (180 ° −θ1) with respect to the optical axis (10) of the first optical film. The optical film laminate (5) along a cutting line (C4) parallel to the third side (FC) and the fourth side (AH) and a cutting line (C5) perpendicular thereto. (FIG. 9 (a)), the angle formed by the optical axis (10) of the first optical film with respect to the reference side (91) is (θ1), and the optical axis (20) of the second optical film. A square optical film laminated chip (9) having an angle of (θ2) can be obtained. Accordingly, the third side (FC) and the fourth side (AH) can be used as reference lines for starting the cutting out of the rectangular optical film laminated chip (9) (FIG. 9 (a)).

  Cutting is first performed along a cutting line (C4) parallel to the third side (FC) and the fourth side (AH) to obtain a strip-shaped optical film laminate (6) (FIG. 9 ( c)), which may then be cut. Further, a strip-shaped optical film laminate (6) is obtained by cutting along a cutting line (C5) perpendicular to the third side (FC) and the fourth side (AH) (FIG. 9B). ), Which may then be cut. When the strip-shaped optical film laminate (6) has a shape in which one of the corners is cut out, the front and back are not mistaken (FIGS. 9B and 9C). Furthermore, by a cutting method using a Thomson blade or the like, along the cutting line (C4) parallel to the third side (FC) and the fourth side (AH) and the cutting line (C5) perpendicular to the third side (FC) The rectangular optical film laminated chip (9) may be obtained by cutting.

In the manufacturing method of this invention, it is a schematic diagram which shows an example of the process of obtaining a 1st optical film cut sheet from a 1st optical film sheet. In the manufacturing method of this invention, it is a schematic diagram which shows an example of the process of obtaining an optical film laminated body from a 1st optical film cut sheet and a 2nd optical film strip. In the manufacturing method of this invention, it is a schematic diagram which shows an example of the process of obtaining a 1st optical film cut sheet from a 1st optical film sheet. In the manufacturing method of this invention, it is a schematic diagram which shows an example of the process of obtaining an optical film laminated body from a 1st optical film cut sheet and a 2nd optical film strip. In the manufacturing method of this invention, it is a schematic diagram which shows an example of the process of obtaining a 1st optical film cut sheet from a 1st optical film sheet. In the manufacturing method of this invention, it is a schematic diagram which shows an example of the process of obtaining an optical film laminated body from a 1st optical film cut sheet and a 2nd optical film strip. In the manufacturing method of this invention, it is a schematic diagram which shows an example of the process of obtaining a 1st optical film cut sheet from a 1st optical film sheet. In the manufacturing method of this invention, it is a schematic diagram which shows an example of the process of obtaining an optical film laminated body from a 1st optical film cut sheet and a 2nd optical film strip. In the manufacturing method of this invention, it is a schematic diagram which shows an example of the process of obtaining an optical film laminated chip from an optical film laminated body. It is a schematic diagram which shows an example of the process of obtaining a 1st optical film sheet from a 1st optical film strip. It is a schematic diagram which shows an example of the process of obtaining a 1st optical film sheet from a 1st optical film strip. It is a figure which shows the relationship between the reference | standard side in an optical film laminated chip, the optical axis of a 1st optical film, and the optical axis of a 2nd optical film. It is a schematic diagram which shows an example of the conventional optical film laminated body and its manufacturing method. It is a schematic diagram which shows an example of the conventional optical film laminated body and its manufacturing method.

Explanation of symbols

10: Optical axis of the first optical film (polarizing film) 11: First optical film (polarizing film) strip 15: First optical film (polarizing film)
19: First optical film (polarizing film)
20: Optical axis of the second optical film (retardation film) 21: Second optical film (retardation film) Band 25: Second optical film (retardation film)
29: Second optical film (retardation film)
3: First optical film sheet 4: First optical film cut sheet 5: Optical film laminate 6: Strip-like optical film laminate 9: Optical film laminated chip C1: First cutting line C2: Second cutting line C3: Cutting line C4: Cutting line C5: Cutting line L1: Distance between first cutting line and second cutting line W2: Width of second optical film strip θ: Optical axis of first optical film in optical film laminated chip The relative angle θ1 of the optical axis of the second optical film relative to the angle θ2 formed by the optical axis of the first optical film with respect to the reference side of the optical film laminated chip θ2: The optical axis of the second optical film relative to the reference side of the optical film laminated chip Angle φ1: Angle formed by the first cutting line with respect to the first side of the first optical film sheet φ2: Second cutting with respect to the second side of the first optical film sheet There angle .phi.3: angle formed third side and fourth sides with respect to the first side and the second side of the first optical film sheet

Claims (6)

  The first optical film (15) and the second optical film (25) are laminated, and the first side (EF), the second side (HG), the third side (FC), the fourth side (AH), Having a fifth side (AE) and a sixth side (GC), the fifth side (AE) and the sixth side (GC) being parallel or perpendicular to the optical axis (10) of the first optical film; The optical film laminate (5), wherein the first side (EF) and the second side (HG) are parallel or perpendicular to the optical axis (20) of the second optical film.   An optical film laminate (5) for cutting out a rectangular optical film laminate chip (9) in which a first optical film (19) and a second optical film (29) are laminated, and the first optical film (15 ) And the second optical film (25) are laminated and have a first side (EF), a second side (HG), a third side (FC) and a fourth side (AH), and a third side (FC) and the fourth side (AH) are (−θ1) or 180 ° −θ1 with respect to the optical axis (10) of the first optical film [where θ1 is the reference side in the optical film laminated chip (9) ( 91) shows the angle formed by the optical axis (10) of the first optical film. The first film (EF) and the second edge (HG) are parallel or perpendicular to the optical axis (20) of the second optical film. Body (5).   The optical film laminate (5) according to claim 2, wherein a cutting line (C4) parallel to a third side (FC) and a fourth side (AH) and a cutting line (C5) perpendicular thereto A method of manufacturing a rectangular optical film laminated chip, characterized by cutting along a line. The first optical film (15) and the second optical film (25) are laminated, and the second optical film (25) is composed of the second optical film strip (21), the first side (EF), It has two sides (HG), a third side (FC), a fourth side (AH), a fifth side (AE) and a sixth side (GC), and the fifth side (AE) and the sixth side (GC). Is parallel or perpendicular to the optical axis (10) of the first optical film, and the first side (EF) and the second side (HG) are parallel or perpendicular to the optical axis (20) of the second optical film. An optical film laminate (5), wherein   The first side (AB), the second side (DC), the third side (BC), and the fourth side (AD) are laminated with the first optical film (19) and the second optical film (29). A first optical film sheet (3) having a first side (AB) and a second side (DC) parallel to each other and parallel or perpendicular to the optical axis (10); and an optical axis (20) Is an optical film laminate (5) for cutting out a rectangular optical film laminate chip (9) produced from a second optical film strip (21) that is parallel or perpendicular to the length direction thereof, The first optical film (15) and the second optical film (25) are laminated, and the first side (EF), the second side (HG), the third side (FC), and the fourth side (AH) The third side (FC) and the fourth side (AH) are the optical axes of the first optical film (1 ) With respect to (-.theta.1) or 180 ° -.theta.1 [here, .theta.1 denotes the angle between the optical axis (10) of the first optical film with respect to the reference edge (91) in the optical film laminate chip (9). The first film (EF) and the second edge (HG) are parallel or perpendicular to the optical axis (20) of the second optical film. Body (5).   The optical film laminate (5) according to claim 5, wherein a cutting line (C4) parallel to a third side (FC) and a fourth side (AH) and a cutting line (C5) perpendicular thereto A method of manufacturing a rectangular optical film laminated chip, characterized by cutting along a line.

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