JP4885304B2 - Optical display manufacturing system - Google Patents

Description

  The present invention relates to an optical display device manufacturing system and a method of manufacturing the optical display device.

  Conventionally, an optical display panel in which a polarizing film is bonded to a liquid crystal panel has been widely manufactured. When bonding a liquid crystal panel and a polarizing film, the manufacturing system which unwinds a long roll polarizing film and bonds with a sheet-like liquid crystal panel is proposed.

  For example, Patent Literature 1 and Patent Literature 2 disclose an apparatus for laminating an optical film. According to these apparatuses, the optical film can be bonded with high work efficiency.

  Patent Document 3 discloses a laminating machine that joins a plurality of original fabric rolls with a turret.

JP 2004-361744 A (published on December 24, 2004) JP 2009-61498 A (published March 26, 2009) JP-A-8-208083 (released on August 13, 1996)

  However, the conventional manufacturing system has a problem that the production efficiency of the optical display panel is insufficient.

  If it demonstrates concretely, in the manufacturing system disclosed by patent document 1 and patent document 2, the unwinding part which fixes the original fabric roll of a polarizing film is provided in one place. Therefore, when replacing the used raw roll, the operator first stops the production system line. Next, the unwinding part is moved horizontally in the core direction of the original roll. Then, an operator will perform exchange work by bonding a used original fabric roll and a new original fabric roll in a film edge part in the unwinding part moved horizontally.

  That is, since it is necessary to perform the replacement | exchange operation | work of an original fabric roll after moving an unwinding part horizontally to the core direction of an original fabric roll, it requires much time for an exchange operation. As a result, the manufacturing time per optical display panel is required for a long time, resulting in a decrease in production efficiency.

  Moreover, in the laminating machine described in Patent Document 3, the original fabric roll is spliced with a turret. When such a method is adopted in an optical display panel manufacturing system, a large installation place is required to install the turret. For this reason, at the time of paper joining, it is necessary to secure a space for the turret to rotate, and the manufacturing system is increased in size.

  The present invention has been made in view of the above-described conventional problems, and an object of the present invention is to provide a manufacturing system for a miniaturized optical display device that can shorten the manufacturing time of the optical display device. is there.

  In order to solve the above-mentioned problems, the optical display device manufacturing system of the present invention is a manufacturing system for manufacturing an optical display device by laminating a polarizing film on a liquid crystal panel, and the surface of which is protected by a protective film. An unwinding part for unwinding the film, a peeling part for peeling the protective film from the polarizing film, a transport mechanism for transporting the liquid crystal panel to the bonding part, the polarizing panel from which the liquid crystal panel and the protective film are peeled off It has a laminating part for pasting and a winding part for winding up the protective film peeled off from the polarizing film, and the unwinding part can move horizontally with respect to the core direction of the polarizing film. The first unwinding portion and the second unwinding portion, which are the unwinding portions, are arranged in parallel.

In the manufacturing system, the two unwinding portions, the first unwinding portion and the second unwinding portion, are provided, and the first unwinding portion and the second unwinding portion are replaced without replacing the roll of the polarizing film with a new roll. Using the polarizing film at the unwinding portion, the polarizing films can be immediately connected to each other, and the replaced polarizing film can be unwound quickly. Therefore, since the time required for the replacement work of the raw roll of the unwinding part can be reduced, the manufacturing time of the optical display device can be shortened .

Moreover , the said unwinding part can move horizontally with respect to the core direction of a polarizing film. For this reason, when exchanging a polarizing film, the roll of a new polarizing film can be installed in the unwinding part moved to the said horizontal direction. Therefore, unlike a laminating machine having a turret, the unwinding portion does not move upward. For this reason, the range which an unwinding part moves can be made small, and the manufacturing system reduced in size can be provided.

  Moreover, the manufacturing method of the optical display device of the present invention is a manufacturing method of an optical display device in which a polarizing film is bonded to a liquid crystal panel using the above-described optical display device manufacturing system, and the surface is protected by a protective film. The polarizing film unwound by the unwinding part, the peeling process for peeling the protective film from the polarizing film by the peeling part, the liquid crystal panel transported by the transport mechanism, and the polarized light from which the protective film was peeled off Including a laminating step of laminating a film and a winding step of winding the protective film peeled off from the polarizing film by a winding unit, the polarizing film of the first unwinding unit and the polarization of the second unwinding unit A polarizing film on the line side of the first unwinding part or the line side of the second unwinding part and the unwinding part side of the second unwinding part among the cut polarizing films. The other is a method comprising the coupling step of coupling the polarizing film unwinding side of the first winding out part.

  According to said manufacturing method, it is possible to connect a polarizing film at a connection process using the manufacturing system provided with two unwinding parts, the 1st unwinding part and the 2nd unwinding part. . Thereby, without replacing the roll of the polarizing film with a new roll, the polarizing films can be immediately connected to each other using the polarizing films of the first unwinding portion and the second unwinding portion, and the polarizing film was quickly replaced. A polarizing film can be unwound. Therefore, since the time required for the replacement work of the roll of the unwinding part can be reduced, it is possible to provide a manufacturing method for shortening the manufacturing time of the optical display device.

  The optical display device manufacturing system of the present invention is a manufacturing system for manufacturing an optical display device by bonding a polarizing film to a liquid crystal panel as described above, and unwinds a polarizing film whose surface is protected by a protective film. An unwinding unit, a peeling unit for peeling the protective film from the polarizing film, a transport mechanism for transporting the liquid crystal panel to the bonding unit, a bonding unit for bonding the polarizing film from which the liquid crystal panel and the protective film have been peeled off A winding portion for winding the protective film peeled off from the polarizing film, and the unwinding portion is movable horizontally with respect to the core direction of the polarizing film, The 1st unwinding part and 2nd unwinding part which are parts are arranged in parallel.

  Therefore, without changing the roll of the polarizing film to a new roll, the polarizing films can be immediately connected to each other using the polarizing films of the first unwinding portion and the second unwinding portion, and the polarizing film is quickly replaced. A polarizing film can be unwound. Therefore, since the time required for the replacement work of the raw roll of the unwinding part can be reduced, the manufacturing time of the optical display device can be shortened. Moreover, the said unwinding part can move horizontally with respect to the core direction of a polarizing film. For this reason, when exchanging a polarizing film, the roll of a new polarizing film can be installed in the unwinding part moved to the said horizontal direction. Therefore, unlike a laminating machine having a turret, the unwinding portion does not move upward. For this reason, it is possible to reduce the range in which the unwinding part moves and to provide an effect that a miniaturized manufacturing system can be provided.

It is sectional drawing which shows the manufacturing system of the optical display apparatus which concerns on this invention. It is sectional drawing which shows the structure of the nip roll vicinity in the said manufacturing system. It is a perspective view which shows a film connection part and a cutting machine. It is a perspective view which shows a cutting bonding part. It is process drawing which shows the connection process by the manufacturing system which concerns on this Embodiment.

  An embodiment of the present invention will be described with reference to FIGS. 1 to 5 as follows.

[Configuration of optical display device manufacturing system]
FIG. 1 is a cross-sectional view showing an optical display device manufacturing system 30 according to the present invention. The manufacturing system 30 bonds the polarizing film 10 or 20 and the liquid crystal panel 2 together. As the liquid crystal panel 2, a known liquid crystal panel may be used, and a known liquid crystal panel in which an alignment film is disposed between a substrate such as a glass substrate and a liquid crystal layer may be used.

  As shown in FIG. 1, each component of the manufacturing system 30 includes an unwinding part (first unwinding part) 1, an unwinding part (second unwinding part) 11, and a film connecting part (first film connecting part) 3. , A film connecting part (second film connecting part) 13 and a transport mechanism 12 are provided. Further, as shown in FIG. 2, a knife edge (peeling portion) 23 and nip rolls 22 and 22a (in the present specification, “·” means “and”) are provided.

  The unwinding part 1 and the unwinding part 11 are apparatuses which hold | maintain the roll of polarizing film 10 * 20, respectively, and have the structure which can adjust the tension | tensile_strength applied to polarizing film 10 * 20. The polarizing film 10 unwound from the unwinding part 1 is sent to the line side through each guide roll. The same applies to the polarizing film 20 unwound from the unwinding section 11.

  The unwinding part 1 and the unwinding part 11 are arranged in parallel. Moreover, the unwinding part 1 and the unwinding part 11 have a structure which can move to a horizontal direction, respectively in the direction of the core 1a * 11a of the polarizing films 10 * 20. In other words, the unwinding part 1 can move in the width direction of the polarizing film 10, and the unwinding part 11 has a structure that can move in the width direction of the polarizing film 20. More specifically, as shown on the left side of FIG. 1, it is structured to be movable in at least one of both directions along the cores 1a and 11a (the rear side direction in the drawing (marked with x in the circle)) and It can be moved to the front side of the drawing (movable to at least one of the marks in the circle). For this reason, when the remaining amount of the polarizing film 10 or 20 decreases, the unwinding unit 1 or the unwinding unit 11 is moved horizontally in the winding core direction by the operator, and the roll of the polarizing film is replaced with a new roll.

  Due to the above configuration, when the polarizing film is exchanged, a new polarizing film roll can be installed on the unwinding portion moved in the horizontal direction. Therefore, unlike the laminating machine having a turret, the unwinding portions 1 and 11 do not move upward. For this reason, the range which an unwinding part moves can be made small, and the manufacturing system reduced in size can be provided.

  In particular, since the unwinding units 1 and 11 move in the horizontal direction, a space for moving the unwinding units 1 and 11 between the unwinding units 1 and 11 and the transport mechanism 12 is not required. As a result, the space between the unwinding units 1 and 11 and the transport mechanism 12 can be reduced, and the manufacturing system 30 can be reduced in size. The present invention is greatly different from a conventional manufacturing system having a turret in that such downsizing can be achieved.

  A known polarizing film may be used as the polarizing films 10 and 20. As the polarizing film in the present invention, a long polarizing film is usually used. Specifically, a TAC (triacetylcellulose) film or the like is bonded as a protective film on both sides of the polarizer film, and a protective film is laminated on one or both TAC films via an adhesive. It has become. Among the polarizing films 10, examples of the polarizer film located in the center include a film in which a polyvinyl alcohol film is dyed with iodine or the like, and a protective film such as TAC is bonded to the stretched film or the like. it can. Also, instead of the polyvinyl alcohol film, a partially formalized polyvinyl alcohol film, an ethylene / vinyl acetate copolymer partially saponified film, a hydrophilic polymer film such as a cellulose film, etc. Polyene-oriented films such as vinyl chloride dehydrochlorinated products can also be used.

  The total thickness including the polarizing film 10 and the protective film is not particularly limited, but can be 100 μm or more and 500 μm or less. In addition, the thickness of the polarizer film in the polarizing film 10 is generally 10 μm or more and 50 μm or less. Furthermore, in addition to the above three layers, other layers may be included within the practical range of the polarizing film 10.

  Although not shown in FIG. 1, the surface of the polarizing film is protected by a protective film. An adhesive layer is present between the polarizing film 10 and the protective film, and the polarizing film 10 and the liquid crystal panel 2 are bonded through the adhesive layer after the protective film is peeled off. Although the said protective film is set as the structure provided in the single side | surface of the polarizing film 10, you may be provided in both surfaces.

  As the protective film, a polyester film, a polyethylene terephthalate film, or the like can be used. In addition, the thickness and width of the protective film are not particularly limited, but from the viewpoint of being used as a protective film for a polarizing film, for example, a thickness of 5 μm or more and 50 μm or less, 200 mm or more and 1500 mm or less. A protective film having a width can be preferably used.

  The transport mechanism 12 transports the liquid crystal panel 2 to nip rolls (bonding portions) 22 and 22a that are bonded to the polarizing film 10 (or 20). The transport mechanism 12 is disposed in the flow direction of the polarizing film 10 and is disposed above the polarizing film 10. As described above, the transport mechanism 12 and the nip rolls 22 and 22a are arranged on the upper stages of the lower unwinding sections 1 and 11, the film connecting sections 3 and 13, and the knife edge 23. Thus, since each member is arrange | positioned along the up-and-down stage, the manufacturing system 30 has a space-saving structure.

  The transport mechanism 12 in the manufacturing system 30 has a roller-shaped structure, but the transport mechanism 12 is not limited to the roller shape as long as the liquid crystal panel can be transported. The liquid crystal panel 2 is transported from the left side to the right side (nip rolls 22 and 22a side) in the figure by the transport mechanism 12. The film connecting portions 3 and 13 and a cutting machine not shown in FIG. 1 will be described later.

  Next, bonding of the polarizing film 10 and the liquid crystal panel 2 will be described with reference to FIG. FIG. 2 is a sectional view showing the structure of the manufacturing system 30 near the nip rolls 22 and 22a. As shown in FIG. 2, the polarizing film 10 is cut and attached to the protective film via the pressure-sensitive adhesive layer. That is, the polarizing film 10 is cut to a size preferable for bonding to the liquid crystal panel 2 by a half cutter (not shown) in the stage before reaching the nip rolls 22 and 22a. On the other hand, the protective film 10a is not cut.

  Moreover, the knife edge 23 is arrange | positioned along the protective film 10a. The knife edge 23 has a triangular shape as its side surface, and the bottom surface of the knife edge 23 is arranged along the unwinding direction of the protective film 10a. The knife edge 23 is composed of a member having a small frictional force between the knife edge 23 and the protective film 10a and capable of easily peeling the protective film 10a from the pressure-sensitive adhesive layer, for example, a member whose surface is processed with diamond-like carbon or the like. ing. Thereby, the protective film 10a is peeled off and removed from the polarizing film 10 by moving following the knife edge 23, and then wound around a winding portion (not shown). Examples of the material for the knife edge 23 include SUS304 and SUS420.

  The winding unit is a device for winding the protective film 10a, and the basic structure is the same as that of the unwinding unit 1 or 11. In addition, it is set as the structure which is provided with two winding parts, and connects the protective film 10a with two film connection parts so that a polarizing film may be connected with two film connection parts so that it may mention later. You can also.

  The nip rolls 22 and 22a are for bonding the liquid crystal panel 2 transported by the transport mechanism 12 and the polarizing film 10 by pressure bonding. What is necessary is just to adjust the pressure at the time of bonding in the nip rolls 22 and 22a suitably.

  FIG. 3 is a perspective view showing the film connecting portion 3 and the cutting machine 7. As shown in FIG. 3, the film connecting portion 3 includes adsorption portions 4 and 4 a and a cutting and bonding portion 5.

  The adsorbing parts 4 and 4a are members for adsorbing and fixing the polarizing film. The adsorbing parts 4 and 4a have a flat plate shape and are provided with a plurality of adsorbing mechanisms 9 on the surface thereof. The adsorption mechanism 9 is not particularly limited as long as the polarizing film can be adsorbed, and a configuration in which the polarizing film is adsorbed by sucking air with a pump can be adopted.

  The cutting bonding part 5 is rotatable and has a plurality of surfaces. Specifically, the cutting bonding part 5 has a polygonal shape. Moreover, it arrange | positions so that rotation is possible. Furthermore, as a preferable form, it is movable in the vertical direction with respect to the polarizing film 10. By being movable in the vertical direction with respect to the polarizing film 10, when the cutting and bonding unit 5 rotates, the cutting and bonding unit 5 is in a direction perpendicular to the polarizing film 10 and away from the polarizing film 10. Can then be moved and then rotated. Thereafter, the cutting and bonding part 5 is in a direction perpendicular to the polarizing film 10 and can be moved in a direction close to the polarizing film 10 to return to the original position. Thereby, it is possible to avoid reliably that the corner | angular part of the cutting bonding part 5 contacts the polarizing film 10, and it is very preferable.

  In addition, although the cutting | disconnection bonding part 5 is polygonal shape and also has the cutting | disconnection support surface 5a and the bonding surfaces 5b * 5c as shown also in FIG. 4, it has a cutting | disconnection support surface and / or bonding. A mating surface may be further provided. For example, a configuration in which the cutting support surface is provided on one surface, a bonding surface is provided on three or four surfaces, and a cutting support surface is provided on two surfaces, and a configuration in which a bonding surface is provided on three or four surfaces are given. Can do. In addition, if the corner | angular part is chamfered like the cutting | lamination bonding part 5 of FIG. 3, it is preferable from a viewpoint which can avoid a contact with a polarizing film. What is necessary is just to determine suitably the magnitude | size of the cutting bonding part 5 with the width | variety of the polarizing film 10, Although it does not specifically limit, For example, the length of 200 mm or more and 2000 mm or less, and the width of 10 mm or more and 300 mm or less can do.

  FIG. 4 is a perspective view showing the cutting and bonding part 5. FIG. 4 shows a state where the cutting and bonding part 5 of FIG. As shown in FIG. 4, the cutting and bonding unit 5 includes the polarizing film 10 so as to cover the cutting support surface 5 a that supports the polarizing film 10 along the width direction of the polarizing film 10 and the cutting line of the cut polarizing film 10. -It has 2 or more cutting support surfaces 5a and the bonding surface 5b provided with the adsorption | suction mechanism 9 which adsorb | sucks the connection material which connects 20. FIG.

  Groove-shaped opening 6 is formed in cutting support surface 5a, and it has the structure which can pass the portion of the blade of cutting machine 7 with which cutting pasting part 5 shown in Drawing 3 is provided. By forming the opening 6, the cutting machine 7 can be reliably passed along the width direction of the polarizing film 10, and the polarizing films 10 and 20 can be more accurately connected.

  As the cutting machine 7, a known cutter can be adopted, and the polarizing film 10 can be easily cut. Further, the cutting machine 7 is supported by a base 8 that can be driven in the width direction of the polarizing film 10.

  The bonding surfaces 5b and 5c have the same configuration as each other, and include a plurality of suction mechanisms 9 as in the suction portions 4 and 4a. Moreover, the single-sided adhesive tape (connecting material) 5d is arrange | positioned at the bonding surfaces 5b and 5c, the non-adhesive surface of the single-sided adhesive tape 5d is hold | maintained by the adsorption | suction mechanism 9, and an adhesive surface is bonding surfaces 5b and 5c. It is arranged to be on the opposite side.

  The said single-sided adhesive tape 5d should just bond polarizing films, and a well-known single-sided adhesive tape can be used. For example, film materials for tape include polyethylene terephthalate film (PET film), cellulose, Japanese paper, aluminum, non-woven fabric, polytetrafluoroethylene, polyvinyl chloride, polyvinylidene chloride, polycarbonate, polyurethane, ABS resin, polyester, polystyrene, Polyethylene, polypropylene, polyacetal resin, polylactic acid, polyimide, polyamide and the like can be mentioned. As the adhesive used in the adhesive layer, acrylic, epoxy, polyurethane, synthetic rubber, EVA, silicone, Examples of the adhesive include vinyl chloride, chloroprene rubber, cyanoacrylate, isocyanate, polyvinyl alcohol, and melamine resin.

  The film connecting part 3 is disposed so as to face the polarizing film 10. For this reason, in FIG. 1, since the polarizing film 10 is arrange | positioned perpendicularly | vertically, the film connection part 3 is also arrange | positioned perpendicularly | vertically with respect to the polarizing film 10. FIG. On the other hand, when the polarizing film 10 is arrange | positioned, for example in the diagonal direction (or horizontal direction), what is necessary is just to set it as the structure where the film connection part 3 is also arrange | positioned in the diagonal direction (or horizontal direction).

  The film connecting portion 13 has the same structure as the film connecting portion 3. As shown in FIG. 1, the film connecting portions 3 and 13 are arranged so that the suction mechanisms 9 of the suction portions 4 (the suction portions 4 a) provided in the film connecting portions 3 and 13 face each other. Moreover, the film connection parts 3 and 13 are arranged with the passage positions of the polarizing film 10 and the polarizing film 20 interposed therebetween. In addition, the manufacturing system 30 provided with the film connection part 3 * 13 is a preferable form in this Embodiment, and can also be set as the form which does not include the film connection part 3 * 13.

[Operation of optical display device manufacturing system]
Below, operation | movement of the manufacturing system 30 which concerns on this Embodiment is demonstrated. Note that the description related to the operation also serves as a description of a method of manufacturing the optical display device.

  First, as shown in FIG. 1, the polarizing film 10 is unwound from the unwinding part 1 (unwinding process). Then, as shown in FIG. 2, only the polarizing film 10 is half-cut by a half cutter (not shown), and the protective film 10a is peeled off by the knife edge 23 (peeling step). Furthermore, the liquid crystal panel 2 and the polarizing film 10 from which the protective film 10a has been peeled off are bonded by pressing with the nip rolls 22 and 22a (bonding step). The peeled protective film 10a is wound and collected by a winding unit (not shown). Through the series of steps, the liquid crystal panel 2 and the polarizing film 10 are bonded to obtain an optical display device.

  As the polarizing film 10 is unwound in the series of steps described above, the remaining amount of the roll of the polarizing film 10 held by the unwinding unit 1 decreases. Below, the connection process which connects polarizing films is demonstrated.

  A connection process cut | disconnects the polarizing film of the said 1st unwinding part, and the polarizing film of the 2nd unwinding part, The unwinding part 1 among the polarizing film 10 of the unwinding part 1, and the polarizing film 20 of the unwinding part 11 Alternatively, it is a step of connecting the polarizing film 10 or 20 on the line side of the unwinding part 11 and the polarizing film 20 or 10 on the unwinding part side of the unwinding part 11 or unwinding part 1. In other words, the “line side” indicates a direction in which the polarizing film is unwound. Examples of the connecting step include (1) a technique by an operator and (2) a technique using the film connecting portions 3 and 13.

  First, the method (1) by the operator will be specifically described. When the polarizing films are connected by an operator, the conveyance speed of the polarizing film 10 is set to 0 m / min. After the above (after stopping the polarizing film 10), the operator cuts the polarizing film 10. Next, after unwinding the polarizing film 20 from the unwinding part 11 and cutting the end part, for example, a method of connecting using the single-sided adhesive tape 5d described above can be used.

  Thus, in the manufacturing system 30 according to the present invention, the two unwinding portions of the unwinding portions 1 and 11 are provided, and the polarizing films 10 and 20 can be obtained without replacing the polarizing film roll with a new roll. Can be used to immediately connect the films, and the polarizing film 20 can be unwound quickly. Therefore, unlike the conventional manufacturing system in which the unwinding unit is installed only at one place, the original roll roll can be replaced at the unwinding unit that is vacant during operation. Can be reduced. As a result, it is possible to shorten the manufacturing time of the optical display device. In the manufacturing system 30, after the polarizing films 10 and 20 are connected, the roll of the polarizing film 10 in the unwinding unit 1 is replaced with a new roll while the polarizing film 20 is unwound. When the remaining amount of the polarizing film 20 decreases, it is of course possible to connect the polarizing film 20 and the polarizing film 10 in the same manner.

  Next, the case where the film connecting portions 3 and 13 are used will be specifically described with reference to FIG. FIG. 5 is a process diagram showing a connecting process by the manufacturing system 30. When the remaining amount of the polarizing film 10 decreases, as shown in FIG. 5A of the polarizing film 10, the conveying speed of the polarizing film 10 is set to 0 m / min. Then, the adsorbing parts 4 and 4a and the cutting and bonding part 5 (film connecting part 3) are moved in the vertical direction with respect to the polarizing film 10. Next, the polarizing film 10 is sucked and fixed by the suction mechanism 9 of the suction parts 4 and 4a (suction process).

  At this time, in the cutting and bonding unit 5, the cutting support surface 5 a is in contact with the polarizing film 10. Then, as shown in FIG.5 (b), the cutting machine which is not shown in figure is moved along the opening 6, and the polarizing film 10 is cut | disconnected (cutting process). After cutting, the cutting and bonding part 5 is moved in the direction perpendicular to the polarizing film 10 and away from the polarizing film 10 (left side in the figure), and rotated clockwise by 1/3 turn to the polarizing film 10. On the other hand, it is moved in a direction perpendicular to the polarizing film 10 (right side in the figure). Thereby, as shown in FIG.5 (c), the single-sided adhesive tape 5d of the bonding surface 5b is bonded together so that the cutting line of the polarizing film 10 facing the single-sided adhesive tape 5d (not shown) may be covered (pasting). Joint process). The said cutting line shows the edge | side which opposes the bonding surface 5b among the cut surfaces produced in the polarizing film 10 by the cutting process. In the bonding step, the single-sided adhesive tape 5d is disposed so as to cover the cutting line, that is, the polarizing film 10 is also disposed on a portion where the polarizing film 10 does not exist beyond the cutting line.

  Furthermore, the single-sided adhesive tape 15d is adhered to the cut support surface 15a of the polarizing film 20 in the same manner as in FIGS. The same members as those described above are given the same names, and the description thereof is omitted.

  First, after the polarizing film 20 is unwound from the unwinding portion 11 and the end portion of the polarizing film 20 is cut in the same manner as in FIG. 5A, a cutting machine (not shown) is formed in the opening formed on the cutting support surface 15a. And the polarizing film 20 is cut. After cutting, the cutting and bonding unit 15 is moved in the direction perpendicular to the polarizing film 20 and away from the polarizing film 20 (right side in the figure), and rotated counterclockwise by 1/3 turn, the polarizing film 20 In the direction perpendicular to the polarizing film 20 (left side in the figure). Thereby, as shown in FIG.5 (e), the single-sided adhesive tape 15d can be affixed so that the cutting line of the polarizing film 20 facing the single-sided adhesive tape 15d of the bonding surface 15b may be covered.

  Next, as shown in FIG.5 (f), adsorption | suction part 4 * 4a and the cutting | disconnection bonding part 5 (film connection apparatus 3) adjoin to adsorption | suction part 14 * 14a and the cutting | disconnection bonding part 15 (film connection part 13). The cut surfaces of the polarizing film 10 and the polarizing film 20 are matched with each other (proximity step). Thereby, among the single-sided adhesive tapes 5d and 15d covering the cutting lines of the polarizing films 10 and 20, the part beyond the cutting line (the part not bonded to the polarizing films 10 and 20) is the other polarizing film 20 The polarizing films 10 and 20 are connected to each other. In FIG. 5 (f), the film connecting part 3 is brought close to the film connecting part 13, but the film connecting part 13 may be made close to the film connecting part 3, and the film connecting parts 3 and 13 are made close to each other. May be.

  After connecting the polarizing films 10 and 20, as a preparation step, as shown in FIG. 5 (g), the cutting and bonding parts 5 and 15 are perpendicular to the polarizing films 10 and 20, respectively, and are moved away. It moves to a direction, the cutting bonding part 5 is rotated 1/3 times counterclockwise, and the cutting bonding part 15 is rotated 1/3 times clockwise. And the cutting bonding parts 5 and 15 are perpendicular | vertical with respect to the polarizing films 10 and 20, respectively, and are moved to the direction which adjoins.

  Finally, the adsorbing parts 4 and 4a and the cutting and bonding part 5 (film connecting part 3) are returned to the position shown in FIG. 5A, and the series of steps is completed. In addition, since the single-sided adhesive tapes 5d and 15d are preliminarily adsorbed on the bonding surfaces 5c and 15c, after the roll of the new polarizing film 10 is installed on the unwinding unit 1, the polarized light is applied. 5 (a) to (c) are performed on the film 20, and the steps of FIGS. 5 (d) to (e) are performed on the polarizing film 10, and as described above, the processes illustrated in FIGS. 5 (f) to (h) are performed. Through the process, the polarizing films 20 and 10 can be connected. In addition, it is of course possible to continuously connect the polarizing films by replenishing the used single-sided adhesive tapes 5d and 15d.

  As described above, in the case of the connecting step using the film connecting portions 3 and 13, the polarizing film is adsorbed, cut, and bonded in a shorter time and more accurately than the connecting step by the operator. Is preferable.

  Specifically, in the manufacturing system 30, about 10 minutes were required in the case of the connecting step by the operator, but when the film connecting portions 3 and 13 were used, the time could be reduced to 1 minute or less.

  In the manufacturing system 30, when only the unwinding unit 1 is used, the unwinding unit 11 is not used, and the film connecting units 3 and 13 are not used, the operator replaces a new polarizing film with the unwinding unit 1. After that, the polarizing film 10 needs to be replaced, so that the connecting step requires about 30 minutes. For this reason, it is clear that the manufacturing system 30 according to the present embodiment is useful.

  The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims, and the technical means disclosed in different embodiments can be appropriately combined. Such embodiments are also included in the technical scope of the present invention. For example, the number of guide rolls in the manufacturing system and the arrangement of the unwinding unit, the winding unit, the film connecting unit, and the transport mechanism are not limited to the illustrated arrangement.

The present invention can also be expressed as follows.

That is, in the optical display device manufacturing system of the present invention, the first film connecting portion and the second film connecting the polarizing film unwound from the first unwinding portion and the polarizing film unrolled from the second unwinding portion. The film connecting part is interposed between the passage positions of both the polarizing films, and the first film connecting part is disposed to face the polarizing film unwound from the first unwinding part, and the second film connecting part is It arrange | positions facing the polarizing film unwound from the 2nd unwinding part, The said 1st film connection part and 2nd film connection part are two adsorption | suction parts provided with the adsorption | suction mechanism which can adsorb | suck a polarizing film, and And a cutting and bonding part that is disposed between the two adsorbing parts and is rotatably arranged along the width direction of the polarizing film. The cutting and bonding part cuts the polarizing film. Equipped with cutting machine Both of the plurality of surfaces of the cutting and bonding unit are provided with a cutting support surface that supports the polarizing film along the width direction of the polarizing film, and an adsorption mechanism that adsorbs and holds the connecting material that connects the polarizing films. It has at least 2 or more bonding surfaces, and it is preferable that the said 1st film connection part and a 2nd film connection part can mutually adjoin.

Thereby, a polarizing film can be adsorb | sucked by the said adsorption | suction part and it can cut | disconnect with a cutting machine in the state which supported the adsorbing polarizing film on the cutting support surface. Then, the cutting bonding part can be rotated and the connection material of a bonding surface can be bonded with respect to the cut | disconnected polarizing film. Furthermore, the 1st film connection part and the 2nd film connection part can mutually be brought close, and the two polarizing films with which the connection material was bonded can be contacted and can be connected easily.

In the optical display device manufacturing system of the present invention, it is preferable that an opening through which the cutting machine can pass is formed in the cutting support surface along the width direction of the polarizing film.

Thereby, the cutting machine can be reliably passed along the width direction of the polarizing film, and the polarizing films can be more accurately connected later.

In the system for manufacturing an optical display device of the present invention, it is preferable that the cutting machine has a round blade shape.

Thereby, it becomes possible to cut | disconnect a polarizing film more easily.

Moreover, in the manufacturing system of the optical display apparatus of this invention, it is preferable that the said cutting | lamination bonding part is movable to a perpendicular direction with respect to the polarizing film adsorb | sucked by the adsorption | suction part.
U By this, when a cutting bonding part rotates, a cutting bonding part is a perpendicular | vertical direction with respect to a polarizing film, and can move to the direction away from a polarizing film, and can rotate after that. Thereby, when a cutting bonding part rotates, it can avoid reliably contacting a polarizing film.

The optical display device manufacturing method of the present invention is a manufacturing method for manufacturing an optical display device by bonding a polarizing film to a liquid crystal panel using the optical display device manufacturing system, wherein the connecting step includes An adsorbing step for adsorbing the polarizing film, a cutting step for supporting the adsorbing polarizing film on the cutting support surface and cutting with a cutting machine, and rotating the cutting laminating portion to connect the connecting material and the polarizing film. Of the polarizing film that has been cut by bringing the first film connecting portion and the second film connecting portion close together, and a bonding step of bonding so as to cover the cutting line of the polarizing film. A proximity step of connecting the polarizing film on the line side of the second unwinding portion or the polarizing film on the unwinding portion side of the second unwinding portion or the unwinding portion side of the first unwinding portion. Preferably .

Thereby, in the said adsorption | suction process, a polarizing film can be adsorb | sucked and it can cut | disconnect with a cutting machine in the state which supported the adsorbed polarizing film in the cutting | disconnection support surface in the cutting process. Furthermore, in the bonding step, the cut bonding portion can be rotated, and the connecting material on the bonding surface can be bonded to the cut polarizing film. Finally, in the proximity step, the first film connecting portion and the second film connecting portion are brought close to each other, and the two polarizing films bonded with the connecting material are brought into contact with each other, so that the polarizing films can be made in a shorter time and more accurately. Can be linked to.

  According to the manufacturing system of the present invention, when the optical display device is manufactured, the polarizing films can be quickly connected, and the manufacturing time of the optical display device can be shortened. Therefore, the present invention can be used in the field of manufacturing an optical display device.

1 Unwinding part (first unwinding part)
DESCRIPTION OF SYMBOLS 1a * 11a Core 2 Liquid crystal panel 3.13 Film connection part 4,4a * 14 * 14a Adsorption part 5.15 Cutting bonding part 5a * 15a Cutting support surface 5b * 5c * 15b * 15c Bonding surface 5d Single-sided adhesive tape (Connecting material)
6 Opening 7.17 Cutting machine 9 Adsorption mechanism 10.20 Polarizing film 10a Protective film 11 Unwinding part (second unwinding part)
12 Transport mechanism 22 / 22a Nip roll (bonding part)
23 Knife edge (peeling part)
30 Manufacturing system

Claims (1)

A manufacturing system for manufacturing an optical display device by laminating a polarizing film on a liquid crystal panel,
An unwinding section for unwinding the polarizing film whose surface is protected by the protective film;
A peeling portion for peeling the protective film from the polarizing film;
A transport mechanism for transporting the liquid crystal panel to the bonding section;
The liquid crystal panel, and a bonding portion for bonding the polarizing film from which the protective film is peeled off,
The unwinding unit is provided with a roll of two polarizing films, one polarizing film and the other polarizing film, each protecting the polarizing films, and two polarizing films being connected and unwinding. Having a first unwinding part and a second unwinding part,
The first unwinding unit and the second unwinding unit are arranged side by side along the transport direction so that the direction of the core of the roll installed on each of the first unwinding unit and the second unwinding unit is orthogonal to the transport direction of the liquid crystal panel by the transport mechanism. A system for manufacturing an optical display device, which is movable along the winding core direction of the polarizing film in order to replace the installed polarizing film roll with a new polarizing film roll.

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