TW201005355A - Optical film adhesion device and production method of a display panel - Google Patents

Abstract

This invention provides an optical film adhesion device. An optical film is held on a drum, when the optical film is adhered to two sides of a display panel substrate nearly at the same time, the optical film is uniformly pressed on the display panel and an adhesion processing of high quality is performed, then the category replacement can be realized easily at a low cost when an adsorption drum having several adsorption holes is used, a bad adhesion such as bubbles and foreign article entrainment occurred when the optical film is adhered to the display panel will not occur. When an optical film is adhered to a display panel, both stand up slantly in a slant state of a specific angle relative to a vertical direction. In such a slant standing state, a polaroid is kept on a slant drum, and the optical film is nearly at the same time adhered to the two sides (the first main surface (CF surface) and the second main surface (TFT surface)) of the display panel by rotating and controlling the drum. An adsorption drum is constructed by a cylindrical drum (a drum formed by rolling a thin-plate-shaped panel into a cylindrical shape). At the wall-thickness portion of the cylinder, a linear hollow portion roughly parallel to a rotation axis is installed at the positions respectively corresponding to the front end and the rear end of the optical film, and some adsorption holes are installed on the outer circumferential surface of the drum along the hollow portion. By using adhesive gum member installed on the outer circumferential surface of the drum means, the optical film is kept adhered and the optical film is adhered to the display panel. Furthermore, by using a first and a second drum means including an adhesive gum member, the first and the second optical films are kept adhered, and adhesion can be performed nearly at the same time from the left and the right sides of the display panel.

Description

[Technical Field] The present invention relates to attaching an optical film to an optical film comprising a polarizing plate or a retardation plate to a display panel such as a liquid crystal panel. The present invention relates to a method of manufacturing a display panel using the same, and more particularly to a method of attaching an optical film to a viscous roller or a absorbing roller while rotating the viscous roller or the absorbing roller while attaching the optical film to the display. An optical film attaching device on a panel and a method of manufacturing the display panel. [Prior Art] In the manufacturing process of the liquid crystal display device, a liquid crystal panel is formed by encapsulating a liquid crystal between a thin film transistor (TFT) substrate and a color filter substrate, and then in a liquid crystal panel. The surface of the polarizing plate is _. In addition, sometimes it also attaches visual

A phase difference plate for compensation. The attachment of such an optical film composed of a polarizing plate or a phase difference (10) is performed by an attaching device. Usually, an adhesive is applied to the optical film in advance, and a protective film is coated on the adhesive. The attaching device is provided with a first working position for peeling off the protective film from the optical film, and a second working position for riding the optical film on the display panel to hold the optical film in a simple mechanism such as a thief attachment table. At the same time, 2' peels the protective film from the optical film at the first working position and then moves the film from the first working position to the second (four) position, and at the second working position, the optical film _ in the display panel on. In addition, as an attachment device for attaching an optical film to a liquid crystal panel, for example, an attachment device described in Korean Patent No. 10-0556339 is known.

In the polarizing plate attaching device described in the Japanese Patent Publication No. 10-0556339, in order to suppress the expansion of the space (fGQtprint) of the polarizing plate attaching device due to the increase in size of the color liquid crystal display, the liquid crystal cell (liquid cell) CryStalcell) The polarizing plate is adsorbed on the rhyme cylinder while the substrate is raised, and the polarizing plate is simultaneously attached to the main surface (CF (color filter) surface) and the second main surface of the Wei cell substrate ( On the TFT surface, the enlargement of the occupied space in the direction (width direction) orthogonal to the transport direction of the liquid crystal cell substrate is suppressed. In the polarizing plate attaching device described in the Japanese Patent Publication No. 10-0556339, when a polarizing plate (optical film) is attached to a liquid crystal cell substrate (display panel), the two are erected in a substantially vertical state. The polarizing plate is adsorbed and held on the adsorption roller in the standing state, and the adsorption roller is subjected to the rotation and rotation control, thereby attaching the polarizing plate to both sides of the liquid crystal cell substrate at almost the same time (the first main surface (CF surface) And the second main surface (TFT surface)). However, when the polarizing plate is simultaneously attached to both surfaces of the liquid crystal cell substrate, there is a problem that the posture of the liquid crystal cell substrate becomes unstable in the vertical state, thereby affecting the attaching quality. In addition, when attaching, the polarizing plate is uniformly pressed on the liquid crystal cell substrate by the adsorption roller, but if both are in a vertical state, then the posture of the liquid crystal cell substrate becomes unstable and 6 201005355 „ difficult The problem of applying a uniform pressing force to the polarizing plate. On the other hand, in the manufacturing step of the liquid crystal, while the liquid crystal display is enlarged, the manufacturing apparatus is increasingly required to be high-speed, inexpensive, simplified, and occupying space. In addition, with the rapid growth of the large-sized liquid crystal panel, the type of the optical film attaching device is frequently changed, and the loss due to the replacement of the type is minimized. The size of the degree of freedom is also required to be high. The adsorption roller described in the Japanese Patent Publication No. Hei No. Hei No. 556-339339 has a plurality of vacuum suction holes provided on the side of the drum, but the current situation is how to replace the vacuum adsorption corresponding to each size. The hole is not clear and does not explicitly correspond to the type of replacement. In addition, the vacuum film is used to carry out the optical film. In the case of vacant adsorption and holding, 'because this vacuum is tightly held to cause the adsorption force to act on the - part of the optical film', there will be a slight problem with the S-film due to the material or warpage. SUMMARY OF THE INVENTION A first object of the present invention is to provide an optical film attaching apparatus that holds an optical raft on a drum and attaches the optical film to the display panel substrate almost simultaneously. On both sides, the optical film can be uniformly pressed on the display panel to perform high-quality attaching treatment. A second object of the present invention is to provide an optical film attaching device which can be easily and inexpensively used. When the adsorption roller of a plurality of adsorption holes is used, 7 201005355 lx is replaced. The third object of the present invention is to provide an optical film attachment device which is used for attaching an optical film to a display after peeling the protective film from the optical film. In the period until the panel, foreign matter can be prevented from adhering to the optical film. A fourth object of the present invention is to provide an optical film attaching method and an optical film attaching In the method of manufacturing a display panel, the optical film attaching method can easily and inexpensively realize the replacement of the type when the roller is used, and the bubble generated when the optical film is attached to the display panel does not occur. [Technical means for solving the problem] The optical film attachment device of the present invention is characterized in that the film is conveyed in a state of being inclined at a predetermined angle with respect to the vertical direction. The optical film is attached to the display panel while the tilting state is maintained, and the optical film attaching device is attached to the display panel. When the two are not erected vertically, but they are tilted up in a state inclined at a predetermined angle with respect to the vertical direction, and the polarizing plate is held on the inclined roller in the state of being inclined and raised, and This roller is rotationally controlled', whereby the optical film is attached to both sides (the first main surface (CF surface) and the second main surface (TFT surface)) of the display panel almost simultaneously. Therefore, the pressing of the drum can be made uniform when attached, so that the attached product can be improved 8 201005355.  quality. In addition, When transporting the display panel and optical film, Compared with the vertical standing state, the state in which the inclined state is raised as in the case of the present invention has an effect of stabilizing the conveying characteristics. and, As a method of tilting the display panel and the optical film,  You can use any of the following methods: The upper bottom portion of the base portion on which each of the stages is placed is inclined only by a predetermined angle ' with respect to the horizontal direction or the ground portion on which the bases are placed is inclined at a predetermined angle.  A second feature of the optical film attachment device of the present invention is that it comprises: Display ^ with the panel supply mechanism, Carrying the display panel in a state inclined at a predetermined angle with respect to the vertical direction; a first optical film supply mechanism and a second optical film supply mechanism, The optical film is conveyed in the inclined state along the left and right positions of the display panel to be conveyed; And an optical film attachment mechanism, The first roller mechanism and the second roller mechanism are configured. The optical film of the first and second optical film supply mechanisms is transported from the first optical film supply mechanism and the second optical film supply mechanism. And - facing the optical film, pressing toward the display panel side, The optical film is attached to both sides of the display panel almost simultaneously while the first roller mechanism and the second roller mechanism are rotationally moved 'where the first roller mechanism and the second roller mechanism rotate The shaft is disposed substantially parallel to the display panel surface of the inclined state conveyed from the display panel supply mechanism.  The present invention relates to a display panel supply mechanism, Optical film supply 9 201005355 Optical film attachment device composed of mechanism and optical film attachment mechanism, The panel supply mechanism is configured such that the display panel is tilted up in a state of being inclined at a predetermined angle with respect to the vertical direction. And transporting and supplying the display panel; The optical film supply mechanism also transports the supply optical film in an inclined state; The optical film attaching mechanism attaches the optical film to the display panel in an inclined state.  A third feature of the optical film attachment device of the present invention is that: As described in the section ©. The optical tape recorded in the feature towel is placed, The first roller mechanism and the second roller mechanism closely hold the one-side side of the optical film by the first viscous rubber member and the second viscous rubber member provided on the outer peripheral surface thereof.  In the optical film attachment device, For the roller mechanism that holds the optical film, the adhesive film is held by the adhesive member provided on the outer peripheral surface thereof, The optical film is attached to the display panel.  A fourth feature of the optical film attachment device of the present invention is that: The optical film attaching device according to the above feature, The first roller mechanism and the second roller mechanism absorb and hold the one-sided side of the optical film by a plurality of adsorption holes provided on the outer peripheral surfaces thereof.  In the optical film attaching apparatus, 'the roller mechanism for holding the optical film' has an adsorption hole on the outer peripheral surface thereof, The adsorption hole is used to adsorb and hold the optical film.  A fifth feature of the optical medium attaching device of the present invention is that it comprises: Display 201005355 with panel supply mechanism, The display panel is transported in a substantially horizontal state; a first optical film supply mechanism and a second optical film supply mechanism, The optical film is conveyed in the substantially horizontal state along the upper and lower sides of the display panel to be conveyed; And an optical film attachment mechanism, It is composed of a first roller mechanism and a second roller mechanism, The one surface side of the optical film supplied to the first roller mechanism and the second roller mechanism is transported from the first optical film supply mechanism and the second optical film supply mechanism, And one facing the optical film toward the display panel side, Rotating the first roller mechanism and the second roller mechanism while rotating, And the optical film is attached to both sides of the display panel almost simultaneously. The first roller mechanism and the second roller mechanism are such that the rotation axis is substantially parallel to the display panel surface of the substantially horizontal state conveyed from the display panel supply mechanism. It is disposed at a position along the upper and lower sides of the display panel.  The present invention relates to an optical film attachment device, The display panel supply mechanism and the optical film supply mechanism transport the supply display panel and the optical film in a substantially horizontal state. The one side of the optical film is held by the roller mechanism disposed on the upper and lower sides of the display panel for the conveyance and supply, And pressing the held optical film from the up and down direction onto the display panel, While rotating the roller mechanism 'from the secret optical film evenly _ on the display panel.  A sixth feature of the optical film attachment device of the present invention is that: An optical film attaching device as recited in claim 11, wherein: The first roller mechanism and the second roller mechanism closely hold the one-side side of the optical film by the first viscous rubber member and the first viscous rubber structure # provided on the outer peripheral surface thereof.  In the optical film attachment device, As a roller mechanism that holds an optical film that is conveyed in a substantially horizontal state, The adhesive film is held tightly by the adhesive rubber member provided on the outer peripheral surface thereof, Attach the optical film to the display panel.  The seventh feature of the optical film attaching device of the present invention is that: As described in the fifth feature, the optical film attachment device carried by S, The first roller mechanism and the second roller mechanism adsorb and hold the one-sided side of the optical film by a plurality of adsorption holes provided on their outer peripheral faces.  In the optical ray attachment device, as a mechanism for tilting an optical film that is transported in a substantially horizontal state, It has an adsorption hole on its outer peripheral surface. And the adsorption hole is used to adsorb and hold the optical film.  制造 The method of manufacturing the display panel of the present invention is characterized by: The optical film attaching device according to any one of the above-described first to seventh features is attached to the display panel. The present invention relates to a method of manufacturing a display panel in which an optical film is attached to a display panel using any of the photonic film attaching devices.  [Effect of the Invention] According to the present invention, the optical film is held on the drum, When the optical film 12 201005355 is attached to both sides of the display panel substrate at the same time, It has the effect of uniformly pressing the optical film on the display panel to perform high-quality attaching treatment.  The optical film attaching device of the present invention attaches an optical film to a display panel for transporting and moving. The first feature is as follows: Including optical film attachment mechanism,  a cylindrical drum mechanism that is disposed such that a rotating shaft is substantially parallel to at least one surface of the display panel to be conveyed, In the outer peripheral surface of the roller mechanism along the linear © cavity portion, That is, a position corresponding to the size of the optical film, Providing a plurality of adsorption holes for adsorbing and holding the front end portion and the rear end portion of the optical film, As soon as the optical film is pressed toward the display panel side, Rotating the drum mechanism on one side, Thereby attaching the optical film to the display panel, The linear cavity portion is formed in the cylindrical wall thickness portion and is substantially parallel to the rotation axis.  〇 In the optical film attachment mechanism, The adsorption roller is configured by a cylindrical roller (a roller formed by winding a thin plate-like panel into a cylindrical shape). In the wall thickness portion of the drum, at a position corresponding to the optical front and the rear end, respectively. a linear cavity portion substantially parallel to the rotation axis is provided, And an adsorption hole is arranged on an outer circumferential surface of the drum along the cavity portion, Therefore, the front end portion and the rear end portion of the optical film are adsorbed and held. The optical film is attached. such, The cavity portion and the adsorption hole are provided in advance so as to correspond to the front end portion and the rear end portion 13 201005355 of the optical film of a different type. The type can be easily replaced. Thereby low cost can be achieved. In addition, The optical film attaching mechanism is not limited to the case of attaching in a substantially vertical state, It can also be used for attaching in a substantially horizontal state.  A second feature of the optical film attachment device of the present invention is that it comprises: Display panel supply mechanism, Carrying the display panel in a state of being substantially vertically erected; a first optical film supply mechanism and a second optical film supply mechanism, The optical film is conveyed in a state of being substantially vertically raised on the left and right sides of the display panel to be transported by ©; Optical film attachment mechanism, The first cylindrical shape roller mechanism and the second cylindrical shape roller mechanism are configured. The outer circumferential surface of the first cylindrical roller mechanism and the second cylindrical roller mechanism along the linear cavity portion, That is, a position 'corresponding to the size of the optical film' is provided with a plurality of pairs of the first optical film supply mechanism and the second optical film supply mechanism, and is transported and supplied to the first cylindrical drum mechanism and the second circle An adsorption hole for adsorbing and holding the one end side of the front end portion and the rear end portion of the optical film of the cartridge-shaped roller mechanism, The optical film is pressed toward the display panel side by the first cylindrical roller mechanism and the second cylindrical roller mechanism. Rotating the first cylindrical drum mechanism and the second cylindrical drum mechanism while rotating, And attaching the optical film to both sides of the display panel at the same time, The first circularly-shaped roller mechanism and the second cylindrical roller mechanism are disposed such that the rotational axis is substantially parallel to the display panel surface that is transported from the display panel supply mechanism with respect to 201005355. a linear cavity portion is formed in a wall thickness portion of the first cylindrical roller mechanism and the second cylindrical roller mechanism and is substantially parallel to the rotation axis; And a panel discharge mechanism for display,  The optical film corresponding to the optical 臈 attaching mechanism is attached to the display panel, and the optical slab is attached to the display panel.  In addition to using the optical film attachment mechanism described in the first feature, Also using a display panel supply mechanism, The optical film supply mechanism and the display panel discharge mechanism constitute an optical film attachment device.  A third feature of the optical film attachment device of the present invention is that: An optical film attaching device as recited in the first or second feature, A peeling mechanism is provided 'the protective film is peeled off from the optical film adsorbed on the adsorption roller' and the optical film attaching mechanism is configured as follows, which is, Having at least two cavity portions as adsorption holes for adsorbing and holding 0 at the front end portion of the optical film and in the two cavity portions, The opening portion of the adsorption hole provided on the outer peripheral side surface of the cavity portion for adsorbing and holding the optical film is first larger than the opening portion area of the other adsorption hole.  The optical film attaching device is newly provided with a peeling mechanism on the optical film attaching device as described in the second feature. And in the adsorption holes of the adsorption roller constituting the optical film attachment mechanism, The adsorption hole that first adsorbs and holds the front end portion of the optical film is larger than the other adsorption holes. Thereby, the adsorption force of this portion 15 201005355 is sufficiently large in advance to withstand the large tensile stress applied when peeling by the peeling mechanism. In addition, In the optical film attachment device, The protective film is peeled off from the optical film adsorbed on the adsorption roller mechanism by providing a peeling mechanism, and the film is peeled off until it is attached to the display panel. It is possible to prevent foreign matter or the like from adhering to the optical film.  A fourth feature of the optical film attachment device of the present invention is that it comprises: Display panel supply mechanism, The display panel conveyed in a substantially horizontal state is erected to be conveyed in a substantially vertical state; a first optical film supply mechanism and a second optical film supply mechanism, On the left and right sides of the display panel to be transported, Carrying the optical film placed in a substantially horizontal state upright in a substantially vertical state; Optical film attachment mechanism, The first cylindrical shape roller mechanism and the first cylindrical shape roller mechanism are configured. The outer circumferential surface of the first cylindrical shape roller mechanism and the second cylindrical roller mechanism along the linear cavity portion, That is, a position corresponding to the size of the optical film, The front end of the optical film that is transported and supplied to the first cylindrical drum mechanism and the second cylindrical drum mechanism from the first optical film supply mechanism and the second optical film supply mechanism The adsorption hole held by the single-side side of the portion and the rear end portion, Using the first cylindrical roller mechanism and the first cylindrical roller mechanism to pressurize the optical film toward the display panel side, the first cylindrical roller mechanism and the first The cylindrical roller mechanism rotates, And the optical film is attached to both sides of the display panel at the same time, almost 16 201005355. The first cylindrical roller mechanism and the second cylindrical roller mechanism are disposed such that the rotational axis is substantially parallel to the display panel surface conveyed from the display panel supply mechanism. The linear cavity portion is formed in a wall thickness portion of the first cylindrical roller mechanism and the second cylindrical roller mechanism and is substantially parallel to the rotating shaft; The first peeling mechanism and the second peeling mechanism 'separate the protective film from the optical film adsorbed and held by the first cylindrical roll mechanism and the second cylindrical roll mechanism; And the display panel discharge mechanism </ RTI> discharges the display panel which is attached to the optical film of the optical film attachment mechanism and which is attached to the optical film in a substantially vertical state.  In addition to the optical film attaching mechanism described in the first feature of the optical film attaching device, Also using a display panel supply mechanism, Optical film supply mechanism, The peeling mechanism and the panel discharge mechanism for display constitute an optical 0 film attachment device.  A fifth feature of the optical film attaching device of the present invention is that it comprises: Display panel supply mechanism, The display panel that is transported in a substantially horizontal state is transported in the transport direction. The display panel is erected to a substantially vertical state; a first optical film supply mechanism and a second optical film supply mechanism, The optical film placed in a substantially horizontal state is erected in a substantially vertical state and transported; Optical film attachment mechanism, It is composed of a first cylindrical shape 17 201005355 ❹ a roller mechanism and a second cylindrical roller mechanism, The outer circumferential surface of the first cylindrical roller mechanism and the second cylindrical roller mechanism along the linear cavity portion, That is, a position corresponding to the size of the optical film,  a plurality of distal end portions of the optical film that are transported and supplied to the first cylindrical roller mechanism and the second cylindrical roller mechanism from the first optical film supply mechanism and the second optical film supply mechanism An adsorption hole that is adsorbed and held on one side of the rear end portion, The optical axis is pressed against the display panel side by the first cylindrical roller mechanism and the second cylindrical roller mechanism. Rotating the first cylindrical shape roller mechanism and the second cleaning roller mechanism while rotating, * attaching the optical film to both sides of the display panel at about the same time, The first cylindrical drum mechanism and the second cylindrical roller mechanism are disposed such that the rotating shaft is substantially parallel to the display panel surface conveyed from the display panel supply mechanism. The linear cavity portion is formed at a wall thickness adjacent to the first cylindrical shape roller mechanism and the second closed shape roller mechanism and is substantially parallel to the rotation axis; The first peeling mechanism and the second peeling.  Constructing a protective film from the optical film adsorbed on the second cylindrical drum mechanism of the first cylindrical shape machine; The protection ° and the structure are taken up by the first hearing mechanism and the second protective film, And the protective film is built and the panel discharge mechanism for display is in a state of being wound up. The display panel is attached to the optical film attachment mechanism from the optical film attachment mechanism by 18 201005355 in a substantially vertical state in which the optical film is attached to both surfaces of the optical film attachment mechanism. The display panel is transported in the transport direction. It is discharged from the substantially vertical state to the substantially horizontal state.  In addition to the optical film attaching mechanism described in the first feature of the optical film attaching device, Also, a display panel supply mechanism having a posture changing function, Optical film feeder with the same posture change function © structure, Stripping mechanism, The protective film discharge mechanism and the display panel discharge mechanism having the posture changing function constitute an optical film attaching device.  A sixth feature of the optical film attaching device of the present invention is that it comprises: Display panel supply mechanism, The display panel that is transported in a substantially horizontal state is transported in the transport direction. Raise it to a vertical position on one side, Display panel alignment mechanism, Using the side transfer mechanism and the lower transfer mechanism, The display panel is conveyed in a substantially vertical state. Positioning an optical film attached to both sides of the display panel almost simultaneously with the display panel, The side conveying mechanism is provided in contact with both surfaces of the display panel that are supplied from the display panel supply mechanism in a substantially vertical state. The lower conveying mechanism is disposed in contact with a lower end portion of the display panel; The first optical film supply means and the second optical film supply means 'transport the optical film placed in a substantially horizontal state up to a substantially vertical state of 19,053,053,55; Optical film attachment mechanism, The first cylindrical shape roller mechanism and the first cylindrical shape roller mechanism are configured. The outer circumferential surface of the first cylindrical roller mechanism and the second cylindrical roller mechanism along the linear cavity portion, That is, a position corresponding to the size of the optical film, a plurality of distal end portions of the optical film that are transported and supplied to the first cylindrical roller mechanism and the second cylindrical roller mechanism from the first optical film supply mechanism and the second optical film supply mechanism The single-sided side near the rear end portion is sucked and held by the adsorption hole, The optical film is pressed toward the display panel side by the first cylindrical roller mechanism and the second cylindrical roller mechanism. Rotating the first cylindrical drum mechanism and the second cylindrical drum mechanism while rotating, And the optical film is attached to both sides of the display panel almost simultaneously. The first cylindrical roller mechanism and the second cylindrical roller mechanism are disposed such that the rotation axis is substantially parallel to the display panel surface conveyed from the display panel supply mechanism. The linear cavity portion is formed in a wall thickness portion of the first cylindrical roller mechanism and the second cylindrical roller mechanism and is substantially parallel to the rotating shaft; a first peeling mechanism and a second peeling mechanism,  Stripping the protective film from the optical film adsorbed on the first cylindrical roller mechanism and the second cylindrical roller mechanism; Protective film discharge mechanism, Winding up the protective film peeled off by the first peeling mechanism and the second peeling mechanism, And discharging the protective film in a wound state; Optical film 201005355, the display panel transport mechanism' receives the optical film attaching mechanism corresponding to the optical film attaching mechanism from the optical film attaching mechanism, and the substantially vertical state in which the optical film is adhered to both sides Display panel, And transporting the display panel in the transport direction; And a display panel discharge mechanism, The optical film display panel that is supplied from the optical film display panel transport mechanism in a substantially vertical state is transported in the transport direction. It is discharged from a substantially vertical state to a substantially water level state.  In addition to the optical film attaching mechanism described in the first feature of the optical film attaching device, Also, a display panel supply mechanism having a posture changing function, Display panel alignment mechanism, An optical film supply mechanism having a posture changing function, Stripping mechanism, The optical film attaching device is configured by a panel transporting mechanism for an optical film display and a display panel discharging mechanism having a posture changing function.  The seventh feature of the optical film attaching device of the present invention is that: As described in the fourth feature, The fifth thief or the sixth special financial account - the optical film attached device, The optical film attaching mechanism is configured as follows, which is, Having at least two cavity portions as adsorption holes for adsorbing and holding the front end portion of the optical film, And in the two cavity portions, The opening portion of the adsorption hole provided on the outer peripheral side surface of the cavity portion which is first adsorbed and held by the optical film is larger than the opening portion area of the other adsorption hole.  201005355 The fourth feature of the optical film attachment device, The optical feature described in any of the fifth feature or the sixth feature, Like the optical film attaching mechanism described in the third feature of the optical film attaching device, The adsorption holes that contribute to the peeling of the protective film are made larger than the other adsorption holes.  An eighth feature of the optical film attaching device of the present invention is that it comprises: Display panel supply mechanism, Carrying the display panel in a state of being substantially vertically erected; a first optical film supply mechanism and a second optical film supply mechanism, The optical film is conveyed substantially vertically in the left and right sides of the display panel that is transported by ®; Optical film attachment mechanism, The optical film is pressed toward the display panel side by the first cylindrical drum mechanism and the second cylindrical roller mechanism. Rotating the first cylindrical roller mechanism and the second cylindrical roller mechanism, And the optical film is attached to both sides of the display panel almost simultaneously. The first cylindrical drum mechanism and the second cylindrical drum mechanism are disposed such that the rotary yoke is substantially parallel to the display panel surface conveyed from the display panel supply mechanism. And the degree of size is such that the optical film can be wound without overlapping the front end portion and the rear end portion of the optical film;  And a panel discharge mechanism for display, The display panel corresponding to the optical film attaching mechanism of the optical film attaching mechanism is attached to the display panel in a substantially vertical state in which the optical film is attached to both sides.  In the optical film attachment device, Set on the left and right sides of the display panel 22 201005355,  The extent of the size of the first cylindrical drum mechanism and the second cylindrical drum mechanism on the side is: Winding can be performed without overlapping the front end portion and the rear end portion of the largest optical film attached by the optical film attaching device. In this way, The first cylindrical drum mechanism and the second cylindrical roller mechanism having a large diameter are pressurized from the left and right sides of the display panel. Attach it on one side, Thereby, even in the case where the size of the optical film or the attachment start position and the like of the first main surface (CF surface) and the second main surface (TFT surface) which are simultaneously attached to the display panel are different from each other, It is also possible to attach the optical film to both sides of the display panel almost simultaneously.  The method of manufacturing the display panel of the present invention is characterized by: The optical film is attached to the display panel by using the optical film attaching skirt described in any one of the first to eighth features of the optical film attaching device. The present invention relates to any one of using the optical film attaching method or the optical film attaching device, A method of manufacturing a display panel ❺ for attaching an optical film to a display panel.  [Effects of the Invention] According to the present invention, the following effects are obtained. The replacement of the adsorption roller __ having a plurality of suctions can be realized easily and at low cost.  and, According to the present invention, Has the following effects: After the protective film is peeled off from the optical film until the optical film is attached to the display panel,  It prevents foreign matter from adhering to the optical film.  23 201005355 [Technical means for solving the problem] The optical film attaching method of the present invention is to attach an optical film to a display panel that is transported and moved. Keeping the optical film in close contact with the viscous rubber member, As soon as the optical film is pressed toward the display panel side, Rotating the drum mechanism on one side, Thereby attaching the optical film to the display panel, The viscous rubber member is disposed on a circumferential surface of the roller mechanism disposed such that the rotating shaft is substantially parallel to at least one side of the © of the display panel that is moved and moved.  The optical film attaching method is to adhere and hold the optical film by using an adhesive rubber member provided on the outer peripheral surface of the drum mechanism. Thereby, the optical film is attached to the display panel. According to the present invention, Since the adsorption holes such as the background art are not used, Therefore, the type can be easily changed regardless of the size of the components to be invested. Thereby simplifying the structure, And to achieve low cost. and,  Because the adhesive material is used to maintain the entire surface of the display panel, So you can correct the warpage of the component, And can be attached while being kept in a correct state. Therefore, the end face of the optical film does not deviate or is affected by wrinkles, etc. And suppress the occurrence of bad things such as bubbles or foreign objects, This enables high-quality attaching work. and, This optical film attaching mechanism is not limited to the case of attaching in a substantially vertical state. It can also be used for attaching in a substantially horizontal state.  The optical film attaching method of the present invention is a left and right sides of a display panel that is transported and moved in a state of being substantially vertically raised 24 201005355. The first optical film and the second optical film supplied in a state of being substantially vertically erected are attached to both sides of the display panel at substantially the same time. Its second feature is: Holding the first optical film and the second optical film in close contact with the first viscous rubber member and the second viscous rubber member, Pressing the first optical film and the second optical yoke toward the display panel side, Rotating the first roller mechanism and the first roller mechanism, Thereby, the first optical film and the second optical film are attached to both sides of the display panel almost simultaneously. The first adhesive mechanism and the second adhesive rubber member are disposed on the first roller mechanism and the second roller that are disposed so that the rotation axis is substantially parallel to the left and right surfaces of the display panel that is moved and moved. The outer perimeter of the body.  The optical film attaching method uses a first roller mechanism and a second roller mechanism provided on the left and right sides of the display panel. Further, an optical film affixing method of attaching the first optical film and the second optical film to the left and right sides of the display panel is performed at the same time. such, The surface of the first cylindrical drum mechanism and the second cylindrical drum mechanism are attached while being pressed from the left and right sides of the display panel. Therefore, even if it is attached to the first main surface (CF surface) and the first surface of the display panel at the same time: The size of the optical film on the main surface (TFT surface) or the attachment start position and the like are different from each other, It is also possible to attach the optical film to both sides of the display panel almost simultaneously.  A third feature of the optical pickup attachment method of the present invention is that: A method of attaching an optical film as described in a feature or a second feature of the 25th 200505355, The protective film is peeled off from the optical film held tightly on the viscous rubber member.  In the optical film attaching method, By peeling off the protective film from the optical film held against the viscous rubber member of the roller mechanism, While the protective film is peeled off until it is attached to the display panel, It prevents foreign matter and the like from adhering to the optical film.  The optical film of the optical film attaching device of the present invention is attached to a ϋ display panel for transporting and moving. Its first feature is: Including optical film attachment mechanism,  a roller mechanism configured such that a rotating shaft is substantially parallel to at least one surface of the display panel that is moved and moved, An adhesive rubber member that closely holds the optical film is provided on an outer circumferential surface of the roller mechanism. Pressing the optical film toward the display panel side, Rotating the roller mechanism on one side, The optical film is thus attached to the display panel.  The present invention relates to an invention of a device for realizing the first feature of the optical film attaching method.  A second feature of the optical film attachment device of the present invention is that it comprises: The display panel supply mechanism ‘the display panel is conveyed in a substantially vertical state; a first optical film supply mechanism and a second optical film supply mechanism, The optical film is conveyed in a state of being substantially vertically raised on the left and right sides of the display panel to be conveyed; Optical film attachment mechanism, The first roller mechanism and the second roller are disposed such that the rotation axis is substantially parallel to the display panel surface conveyed from the display panel supply mechanism with respect to 26 201005355. A first viscous rubber member and a second viscous rubber member that respectively hold the first optical film and the second optical film in close contact with each other on the outer peripheral surface of the roller mechanism are provided. Facing the first optical film and the second optical film toward the display panel side, Rotating the first roller mechanism and the second roller mechanism, Thereby, the first optical film and the second optical film © are attached to both surfaces of the display panel almost simultaneously.  The present invention is directed to an apparatus for implementing the second feature of the optical film attachment method.  A third feature of the optical film attaching device of the present invention is the optical film attaching device as described in the first or second feature, Including the stripping mechanism, The protective film is peeled off from the optical film held tightly on the viscous rubber member.  The present invention relates to an invention of a device for realizing the third feature of the optical film attaching method.  The method of manufacturing the display panel of the present invention is characterized by: Using the first feature, The optical film attaching method described in the second or third feature, Or the first feature, The optical film attaching device described in the second or third feature, To attach the optical film to the display panel.  The present invention relates to any one of using the optical film attaching method or the optical film attaching device 27 201005355, (4) Film _ The manufacturing method of the display panel on the display panel.  [Effects of the Invention] According to the present invention, the following effects are obtained. The replacement of the type when the drum is used can be easily and cost-effectively realized. Moreover, it can be optically attached without causing sticking defects such as air bubbles or foreign matter generated when the optical film is attached to the display panel.  For the above and other purposes of the present invention, Features and benefits can be more obvious and easy to understand, The preferred embodiment is hereinafter described. And with the drawings, The details are as follows.  [Embodiment] Hereinafter, Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a view showing an overall configuration of a polarizing plate attaching apparatus according to an embodiment of the present invention. This polarizing plate attaching device is a state in which the liquid crystal panel is moved from the right direction in the right direction in FIG. And causing the liquid crystal panel to advance in an upright state, The polarizing plate is attached to the first main surface and the second main surface of the liquid crystal panel which are continuously advancing almost simultaneously.  As shown in Fig. 1, the polarizing plate attaching device of the present embodiment is composed of the following parts: The liquid crystal panel is supplied to the stage 100, The liquid crystal panel conveyed in a substantially horizontal state is converted into a state in which it is supplied to the polarizing plate attaching stage 200 in the subsequent stage; a polarizing plate supply station 700, 750, The polarizing plate attached to the polarizing plate attaching stage 28 201005355 200 is converted into a substantially vertical state by a polarizing plate placed in a substantially horizontal state, and then supplied to the polarizing plate attaching stage 200; Polarized plate attachment station 200,  From the polarizing plate supply station 700, 750 polarizer plate supplied in an upright state, Almost simultaneously attached to the first main surface and the second main surface of the liquid crystal panel (cell) supplied from the liquid crystal panel supply stage 1 in an upright state; Protective film discharge station 800, 850, Set on both sides of the polarizing plate attachment table 2〇〇, The protective film peeled off from the polarizing plate is taken up and discharged; And LCD panel discharge station ® 900, The liquid crystal panel to which the polarizing plate is attached by the polarizing plate attaching table 200 is changed from the standing state to the substantially horizontal state, and then discharged.  Fig. 2 is a view showing a detailed configuration of a liquid crystal panel supply station of Fig. 1;  Fig. 3 is a side view of the liquid crystal panel supply stand of Fig. 2 as seen from the right side. As shown in Figure 1, The liquid crystal panel supply stage 100 is disposed in front of the polarizing plate attaching stage 200 (on the right side of the drawing), and the liquid crystal panel 10 that is transported in a substantially horizontal state is a liquid crystal panel 1 that is vertically raised. The supply is supplied to the polarizing plate attaching station 200.  As shown in Fig. 2 and Fig. 3, the liquid crystal panel supply table ι is composed of a liquid crystal panel transport unit 110 and a substantially vertical conversion unit 15A. The liquid crystal panel transport unit 110 transfers the liquid crystal panel to the surface. When it is changed from a substantially horizontal state to a state (substantially vertical state), And as shown in Figures 2 and 3, It is composed of a side roller 111 and a lower portion 112. The side rollers are disposed on the side opposite to both sides of the liquid crystal panel 10, And play the following roles: Supported by the side surface of the liquid crystal 29 201005355" panel 10, So that the liquid crystal panel 10 does not fall up and down or left and right sides, Further, the liquid crystal panel 10 is moved in a predetermined direction. The lower roller 112 is in contact with the lower surface of the liquid crystal panel 10 in the upright state to support the liquid crystal panel 10, Further, the liquid crystal panel 10 is moved in a predetermined direction. The side roller lu is rotationally controlled by a driving force source (not shown) such as a motor. The lower roller 112 is not rotated by the driving force, Instead, it is in contact with the ® liquid crystal panel that moves in response to the rotation of the side roller U1. And passively rotate. and, It is also possible to provide a power source on the lower roller 112 to actively perform the rotation control.  There are a plurality of side members 111 and a whole liquid crystal panel supply stage. The side roller 111 is provided, for example, on one side. A plurality of contact rolleres 111a to 11ld are provided on the rotation axis of each of the side rollers m. The outer peripheral portion of each of the contact rolleres Ilia to llld is in contact with the surface of the liquid crystal panel 1A. The respective rotating shafts of the side rollers 111 are mechanically connected via a power transmission mechanism. It is controlled by rotation by one or more driving force sources.  The lower roller 112 is disposed such that a plurality of turns are arranged in a row at a predetermined interval in a substantially horizontal direction. The respective one faces constituting the lower roller 112 are in passive contact with the lower end portion of the liquid crystal panel 10 in the upright state, and are passively rotated. The movement of the liquid crystal panel U) is guided while being guided. and, As mentioned above, The liquid crystal panel conveying portion m is based on the side stick lu * lower light (1) as a basic constituent element. And connecting the elements together by a frame mechanism or the like, 30 201005355 This constitutes a liquid crystal panel transport unit 11A as shown in FIGS. 2 and 3.  The substantially vertical conversion unit 150 is composed of the following components: The moving part main body 15 guide rail 152, 153 ‘rack 154, 155,  Pinion 156, 157, Power transmission shaft 158, 159, Power transmission circular plate 160, 161 and a substantially vertical substantially horizontal movable portion 162,  163. The moving portion main body 151 is along the guide rail 152, 153 is configured to move in the up and down direction in Fig. 2 . For the movement of the moving part main body 151 ® and Lu, Although not shown, But the composition is as follows: On the guide rail 152, The lower side of the 153 is provided with a ball screw. And mechanically coupling the nut portion and the moving portion main body 151 combined with the ball screw. The moving portion main body 151 is along the guide rail 152 by the rotational driving of the ball screw 153 moves. and,  The moving unit main body 151 can also be moved by a driving method other than this.  Bracket 154, 155 with the guide 152, 153 is set in parallel and is in the guide 152, The outside of 153. Bracket 154, 155 and a pinion 156 disposed on the moving part 〇 H51, 157 interlocking. therefore, When the moving portion main body 151 is along the guide rail 152, When 153 moves, Pinion 156, 157-face is fastened to the bracket 154, 155, - The surface is rotated. As shown in Figure 3,  a power transmission shaft 158 having a gear on the outer circumference, 159 mechanically combined with the pinion 156, 157. Power transmission circular plate 160, 161 is disposed in the moving portion main body 151, And with a power transmission shaft 158, 159 gears are engaged with the gears. Power transmission disc 丨60, 161 is mechanically coupled to the liquid crystal panel 31 201005355 on the transport unit 110. therefore, When the moving portion main body 151 is along the guide rail 152,  When 153 moves, Pinion 156, 157 and power transmission axis i58, 159 to rotate, Accompanied by this rotational movement, Power transmission disc 16〇, (6) - start to rotate', The liquid crystal panel transfer unit 110 that is coupled to the power transmission disk 161 is also integrally rotated.  FIG. 4 and FIG. 5 are views showing an example of an operation of the liquid crystal panel supply stage in a state in which the liquid crystal panel 10 in a substantially horizontal state is converted and established. The moving body main body (5) is along the guide rail 152, 153 moves in the right direction of FIGS. 4 and 5,  Thereby the pinion 156, 157 in the bracket 154, Rotate on 155,  And the rotational driving force is via the power transmission shaft 158, 159 is transmitted to the power transmission circular plate 160, On 161, Thereby, the power transmission circular plate 16〇, (6) Perform a rotational movement. thus, The liquid crystal panel transport unit 11 rotates around the power transmission circular plate 160 161.  4 and 5 show that the liquid crystal panel transport unit 110 transmits the circular plate 160 by power. 161 is the main body (5) along the guide rail 152 H. Fig. 4 shows a state in which the movement 153 has moved about the right side of Fig. 4 to about the left and right. thus, Power transmission circular plate 160, 161 is rotated by about 45 degrees in the reverse 2 direction. therefore, The LCD surface button U0 is shown in Figure 3 and The state becomes a state of being inclined by 45 degrees as shown in FIG. And 'as shown in Figure 5, |狡必如士秘 In the Lan 5 body 151 along the guide rail 152, (5) B side moves ' and moves to guide rail 152, The general middle of ι53 32 201005355.  In the vicinity of the center, the liquid crystal panel transport unit 110 is in a state of being inclined at 45 degrees from the substantially horizontal state of Fig. 3 through a state of 45 degrees as shown in Fig. 5, and is raised at 90 degrees as shown in Fig. 5 . In addition, the liquid crystal panel transport unit 11 () is transported in a state in which the liquid crystal panel 10 is raised at 90 degrees, and the liquid crystal panel 10 is tilted by about 5 degrees such as 85 degrees or 95 degrees. It is more effective to carry out the transfer. FIG. 6 is a view showing an overall configuration of the polarizing plate attaching stage 200. As shown in FIG. 6, the polarizing plate attaching stage 200 is composed of the liquid crystal panel aligning portions 201 'protective film peeling portions 300 and 350, the polarizing plate attaching portions 400 and 450, and the polarizing plate standing up supply unit 500. 550, and a polarizing plate liquid crystal panel transport unit 600. The liquid crystal panel alignment portion 201 is for positionally collimating the liquid crystal panel 1A and the polarizing plate that are transported from the liquid crystal panel supply table 100. The protective film peeling portions 300 and 350 are for peeling off the protective film from the polarizing plate which has not been attached to the liquid crystal panel 10. The polarizing plate attaching portions 400 and 450 are 0 for attaching the polarizing plate to the liquid crystal panel 10 in the standing state. The polarizing plate erecting supply units 500 and 550 are supplied to the polarizing plate attaching portions 400 and 450 after the polarizing plates that have been transported from the polarizing plate supply stages 700 and 750 are set up. The polarizing plate liquid crystal panel transport unit 600 is for transporting the liquid crystal panel 1A to which the polarizing plate is attached by the polarizing plate attaching portions 400 and 450 to the liquid crystal panel discharge table 900. FIG. 7 is a view showing a detailed configuration of the alignment portion of the liquid crystal panel of FIG. 6, and 33 201005355, which is an enlarged view of the liquid crystal panel alignment portion 2〇1 of FIG. 6 and is viewed from the upper side of the polarizing plate attaching device. . In the liquid crystal panel alignment unit 201, the liquid crystal panel 10 in the upright state (substantially vertical state) conveyed from the liquid crystal panel transport unit 110 is accurately aligned with the rotating progens of the polarizing plate attaching portions 400 and 45〇. The side roller 202 and the lower roller 203 which are the same as the liquid crystal panel transport unit 110 of FIG. 3 are provided. The side roller 202 is disposed to face both surfaces of the liquid crystal panel 10, and functions to be supported in contact with both surfaces of the liquid crystal panel 10 so that the liquid crystal panel 10 does not fall to the left and right sides, and The liquid crystal panel 10 is moved in a predetermined direction (the left direction in FIG. 7). The lower roller 2〇3 is in contact with the lower side of the liquid crystal panel 10 in the standing state to support the liquid crystal panel 1A, and to move the liquid crystal panel 10 in a predetermined direction (leftward in the drawing). In the present embodiment, the side rollers 202 are rotationally controlled by motors (driving force sources) 204 and 205 provided on the left and right sides, respectively. As shown in Fig. 7, Φ the driving forces of the motors 204 and 205 are transmitted to the respective side rollers 202 via the transport mechanisms 2〇23, 2〇24. The lower light 2〇3 is disposed on the lower side of the moving liquid crystal panel 10#, and is set to be lower than the lower roller 112 of the liquid crystal panel supply table (10). The motor 2031 actively performs rotation control and is caused by the liquid crystal panel. The liquid crystal panel 1A supplied from the supply stage 1 is actively moved in the left direction in FIG. Fig. 8 is a side view of the liquid crystal panel alignment portion 2〇1 201005355 of Fig. 7 as seen from the lower side of Fig. 7 . Further, in Fig. 8, only one side of the side roller 2〇2 of Fig. 7 is shown, and the illustration of the opposite side is omitted. As shown in Fig. 8, a plurality of side portions are provided throughout the liquid crystal panel alignment portion 201. In Fig. 8, nine rotating shafts are provided on one side of the side roller 202. A plurality of (six in the drawing) contact rolleres 2〇2a to 2〇2fe are provided on the respective rotating shafts as viewed from the side as shown in Fig. 8, and the outer peripheral faces of the respective contact rolleres 2〇2a to 2〇2f are observed. It is in contact with both surfaces of the liquid crystal panel 10. The β side 2 indicates that each of the rotating shafts is mechanically connected via the power transmission mechanism, and the motors 204 and 205 perform rotation control. A plurality of lower rollers 2〇3 (14 in the drawing) are disposed in a row at a predetermined interval in a substantially horizontal direction. The plurality of rollers constituting the lower roller 2〇3 are in contact with the lower end portion of the liquid crystal panel 10 in the upright state to actively rotate, and the liquid crystal panel 10 is moved in the substantially horizontal direction. As described above, the basic configuration of the liquid crystal panel alignment portion 201 is the side roller 2〇2 and the lower roller 2〇3, and the side roller 2〇2 and the lower roller 203 are formed by the frame mechanism or the like. A liquid crystal panel alignment portion 2〇1 as shown in FIGS. 7 and 8 is formed. Each of the contact adjacent rollers 202a to 202f is not uniformly disposed on the entire side roller 2〇2, but is mainly disposed on the upper side of the side roller 2〇2 as shown in Fig. 8 . In this manner, in order to be able to cope with an optical film having a different size, that is, a size, each of the contact rolleres 202a to 202f can be brought into contact with the vicinity of the upper end portion of the optical film. Therefore, the contact roller is not provided on the lower side of the side roller 202. 35 201005355 However, it is also possible to provide a contact roller on the lower side of the side view 202. Fig. 9A is a view showing a state in which one side of the side edge 2 of the liquid crystal panel alignment portion 2A1 has been moved (extracted) to the side of the liquid crystal panel supply stage 1. That is, in order to observe whether or not the liquid crystal panel 10 held on the liquid crystal panel alignment portion 201 has been accurately positioned on the adsorption roller of the polarizing plate attaching portions 4, 450 of FIG. 6, the liquid crystal panel alignment portion 201 is made. The one side of the side roller 2〇2 is moved toward the liquid crystal panel supply stage 100 side, and the positioning state between the adsorption roller® and the liquid crystal panel ίο (for example, the state of the attachment start position, the gap, and the like) is visually confirmed. Further, even when the line is stopped during the conveyance of the liquid crystal panel 10 or the liquid crystal panel 10 is broken, the liquid crystal panel 10 in the middle of conveyance can be easily and safely taken out. 10, FIG. 11, and FIG. 12 are views showing a detailed configuration of the polarizing plate standing supply unit and the polarizing plate liquid crystal panel transport unit of FIG. Fig. 1A is an enlarged view of the polarizing plate standing supply units 500 and 550 and the polarizing plate liquid crystal panel of Fig. 6 as viewed from the upper side of the polarizing plate attaching device. Fig. 11 is a view of the polarizing plate standing supply unit 500 of Fig. 1A viewed from the lower side of Fig. 1A. Fig. 12 is a circle in which the polarizing plate upright supply units 500 and 550 and the polarizing plate liquid crystal panel transport unit 600 of Fig. 10 are viewed from the right side (adsorption drum side) of Fig. 1A. The polarizing plate upright supply units 500 and 550 convert the polarizing plate in a substantially horizontal state that has been transported from the polarizing plate supply stages 700 and 750 to the up state 36 201005355 (substantially vertical state), and accurately position the polarizing plate. The adsorption rollers of the attachment portions 400 and 450 are supplied after being supplied. The liquid crystal panel 10 to which the polarizing plate has been attached by the polarizing plate attaching portions 400 and 450 is transported to the liquid crystal panel discharge table 9A. The polarizing plate standing supply portions 500 and 550 are composed of the following portions: side rollers 5〇2 and 552, and lower rollers 503 and 553' to raise the rollers 505 and 555 and the conveying rollers 5〇6 and 556. As shown in FIG. 10, the side rollers 5〇2 and 552 are provided with a “polarizing plate that is nipped and lifted from the polarizing plate supply stages 700 and 750” in a manner of facing the both surfaces of the polarizing plate. The polarizing plate is set to the upright state (substantially vertical state). As shown in FIG. 11, the side roller 502 is provided with a plurality of a pair of rollers composed of a first side roller 5021 and a second side roller 5〇22 in a substantially vertical direction, wherein the first side roller 5021 The second side roller 5022 is composed of a roller having a smaller diameter, and the belt 5〇23 is wound around the first side roller 5021 and the second side roller 5〇22. The belt 5023 provided on both sides of the polarizing plate 10 lifts the polarizing plate 10 while holding it up. Further, the illustration of the belt 5023 is omitted in the figure η for convenience of explanation. The lower rollers 503, 553 are in contact with the lower end portion of the polarizing plate 10 in the upright state to thereby control the polarizing plate 10, and the polarizing plate 1 is oriented in a predetermined direction (the right direction in the figure of FIG. It is the side of the adsorption roller that moves. In the present embodiment, the side light members 5, 2, and 552 are rotationally controlled by motors (driving force sources) 504 and 554 respectively provided at 37 201005355. The driving forces of the motors 504, 554 are transmitted toward the respective side members 5, 2, 552. The lower rollers 503 and 553 are disposed on the lower end side of the standing polarizing plate, and are set to be lower than the lower roller 112 of the liquid crystal panel supply stage 1 or the lower roller 2G3- of the liquid crystal panel alignment unit 2〇1. The rotation control is actively performed by the motor view and the view, so that the standing polarizing plate 1 is actively moved from the polarizing plate upright supply portions 500 and 550 toward the suction roller side. ❺ As shown in FIG. 11, the air blocks 520 to 526 are disposed between the directly controlled first side roller and the smaller diameter second side roller, and the polarizing plate 10 in the upright state. The jets are kept upright. The gas-filled crucibles 520 to 526 are completely housed in the side rollers 502 and 552 of the polarizing plate standing supply portions 5〇〇 and 55〇, and are polarized by the lower end portions in contact with the conveying belts 5〇33 and 5〇34. The both sides of the plate 10 are jetted to maintain the standing state of the polarizing plate 1〇. The air cushions 520 to 526 may have any shape as long as the polarizing plate 1 〇 © in the standing state is not in contact with the side rollers 5 〇 2, 552. Further, the polarizing plate 1 can be efficiently transported by setting the air jet direction of the air cushions 520 to 526 as the direction ' along the transport direction of the polarizing plate 10. As shown in Fig. 11, the plurality of rollers of the lower roller 5〇3 of the polarizing plate rising up the supply portion 5 are not in direct contact with the lower end portion of the polarizing plate, but the plurality of rollers are divided into two parts' Transport belts 5〇33, 5034 are wound around a plurality of rollers. The conveyance belts 5033 and 5〇34 are configured to be in contact with the lower end portion 38201005355 of the polarizing plate. Since the side roller ill of the liquid crystal panel supply stage and the side roller 2〇2 of the liquid crystal panel alignment part 201 are in the same direction as the conveyance direction of the liquid crystal panel 10, there is no problem, but the polarizing plate is formed. Since the roller rotation directions of the side rollers 5〇2 and 552 of the supply units 500 and 55〇 are substantially perpendicular to each other and are orthogonal to the direction in which the polarizing plate is conveyed, that is, the direction in which the polarizing plate is conveyed is present. There are some problems. Therefore, the side rollers 502 and 552 move toward the direction away from the polarizing plate 10 at a time point when the polarizing plate 1 is lifted upward, thereby releasing the sandwiching of the polarizing plate 10. Thus, the polarizing plate 1 下落 falls due to its own weight, and its lower end portion comes into contact with the conveying belts 5033 and 5034. Since the contact area between the transport belts 5033 and 5034 and the polarizing plate 1 is sufficiently large, the polarizing plate 10 can be efficiently moved in the transport direction. As shown in Fig. 12, upright rollers 505, 555 are provided on the lower side of the polarizing plate standing supply portion 5' of Fig. 10, and the standing rollers 5?, 5, 555 are supplied from the polarizing plate. The stages 700 and 750 are guided to the side rollers 502 and 552 of the polarizing plate upright supply units 500 and 550 in a polarizing plate ′ that is supplied in a substantially horizontal state. Transport rollers 506 and 556 are provided between the polarizing plate supply stages 700 and 750 and the upright rolls 505 and 555, and the transfer rolls 506 and 556 are used to transport the polarizing plates from the polarizing plate supply stages 700 and 750 to the standup. Rollers 505, 555. As shown in Fig. 10, the conveying rollers 506, 556 are disposed in parallel with the standing rollers 505, 555, and their lengths are also associated with the standing roller 39 201005355.  505 and 555 are constructed in substantially the same manner. Further, power transmission rollers 507 and 557 are provided at the ends of the conveyance rollers 506 and 556. The power transmitting rollers 507 and 557 are connected to the driving motors 51 coupled to the rising rollers 505 and 555 via the power transmitting rollers 509, 510, 559, and 56, respectively. Therefore, the rollers 505 and 555 and the conveying rollers are erected. 506, 556 are rotated in synchronization with each other. In order to guide the polarizing plates that are supplied from the polarizing plate supply stages 700 and 750 in a substantially horizontal state to the side rollers 502 and 552 of the polarizing plate standing supply unit 500, as shown in FIG. On the lower right side, a guide belt 512 that rotates in accordance with the rotation of the standing roller 505 is provided over about one quarter of the circumferential surface of the standing roller 505. The guide belt 512 is configured to be supported by the guide rollers 513, 514, and 515 at three points and to rotate in accordance with the rotation of the upright drum 505. Similarly, as shown in Fig. 12, on the lower left side of the standing roller 555, a guide belt 562 that rotates in accordance with the rotation of the rising roller 555 is provided over about a quarter of the circumferential surface of the rising roller 555. The guide belt 562 is configured to be swung by the guide rollers 563, 564, and 565 at three points, and rotates in accordance with the rotation of the upright drum 555. Therefore, the polarizing plate supplied from the polarizing plate supply stages 700 and 750 in a substantially horizontal state passes between the rising rollers 505 and 555 and the conduction bands 512 and 562, and is bent thereby to change from the substantially horizontal state to the state where the polarizing plate is changed from the substantially horizontal state. The polarizing plate is erected by the side rollers 5〇2, 552 of the supply unit 500, and is directed upwards 201005355.  guide. Further, in Fig. 12, the conveyance belts 5033 and 5034 are configured such that the conveyance belts 5033 and 5034 are directed before the polarizing plates are completely guided to the side rollers 502 and 552 of the polarizing plate standing supply portions 5 and 550. When the central portion is moved to avoid, when the polarizing plate 10 is completely accommodated in the side rollers 5〇2 and 552 of the polarizing plate standing supply unit 500, as shown in FIG. 12, the conveying belts 5033 and 5034 are moved to and from the center. The position where the lower end portion of the polarizing plate contacts. In the conveyance belts 5533, 5534, 5533, and 5534 on the right side in Fig. 12, the conveyance belts are moved toward the center portion to avoid the state, and the conveyance belts 5033 and 5534 on the left side are moved to a position where they can be brought into contact with the polarizing plate. Further, the conveyance belts 5033, 5034, 5533, and 5534 actually perform the same operation, but for convenience of explanation, different operation states are shown in Fig. 12. Further, although only one polarizing plate 11' is supplied from the polarizing plate supply stages 7 and 75, a plurality of partial polarizing plates may be actually supplied in a state of being overlapped. At this time, discharge guide plates 530 and 580 are provided between the power transmitting rollers 509 and 559 and the guide rollers 513 and 563, and the discharge guide plates 530 and 580 are configured to discharge the superposed polarizing plates to the outside. If a plurality of polarizing plates are supplied in a state of weight 4, a thickness gauge (not shown) is used to identify the polarizing plates for a plurality of sheets. When the thickness gauge is used to recognize that the polarizing plate is a plurality of sheets, as shown in the lower left side of the discharge guide sheet 53A as shown in FIG. 12, the guide sheet 530 is ejected between the power transmitting roller 509 and the guide roller 513 to perform rotational movement at 201005355. Thereby, the superposed polarizing plates are discharged to the outside. Further, when only one polarizing plate 11 is supplied from the polarizing plate supply stages 700, 750, as shown in the lower right side of FIG. 12, the discharge guide plate 580 is avoided from between the power transmitting roller 559 and the guide roller 563, thereby The polarizing plate 11 is normally guided to the side of the standing roller 555. As shown in FIG. 10 and FIG. 12, the polarizing plate liquid crystal panel transport unit 600 is attached to the polarizing plate of the polarizing plate attaching portions 400 and 450 of FIG. The state-attached polarizing plate liquid crystal panel 10a is conveyed to the liquid crystal panel discharge stage 900. The polarizing plate liquid crystal panel transport unit 600 includes a side roller 602 and a lower roller 615 which are the same as the liquid crystal panel transport unit 110 of Fig. 3 or the liquid crystal panel alignment unit 201 of Fig. 6 . The side roller 602 is disposed to face the both surfaces of the polarizing plate liquid crystal panel i〇a and functions to be in contact with both surfaces of the polarizing plate liquid crystal panel 10a to support the polarizing plate liquid crystal. The panel φ 10a does not fall to the left and right sides. The lower roller 615 is in contact with the lower side of the polarizing plate liquid crystal panel 10a in the upright state to support the polarizing plate liquid crystal panel 10a, and the polarizing plate liquid crystal panel 10a is oriented in a predetermined direction (in the drawing of FIG. 10). The left direction) moves. In the present embodiment, the side rollers 602 are rotationally controlled by motors (driving force sources) 603 and 604 provided on the left and right sides, respectively. The driving forces of the motors 603, 604 are transmitted to the respective side portions 42 201005355 by the power transmission mechanisms 6〇5, 6〇6. The lower roller 615 is disposed on the lower side 'the lower side of the moving polarizing plate liquid crystal panel 10a and is set to be higher than the lower roller 112 of the liquid crystal panel supply stage 1A, and is actively rotated and controlled by the motor 6〇8. The polarizing plate liquid helium panel 10a supplied from the adsorption roller of the polarizing plate attaching portions 4A, 45A is positively moved toward the liquid crystal panel discharge table 900 (the left direction in the drawing of FIG. 10). As shown in Fig. 10, a plurality of side rollers 602 are disposed throughout the entire polarizing plate liquid crystal panel transfer cassette 600. In the figure, the side roller 602 is provided with a plurality of rotating shafts on one side. A plurality of (6 in FIG. 12) contact portions 6〇2a to 6〇2f are provided on each of the rotating shafts. As shown in Fig. 12, the outer peripheral surface of each of the contact frequencies 6G2a to 6G2f is in contact with the surface (polarizing plate surface) of the liquid crystal panel with a polarizing plate. Each of the contact rolleres 6〇2&amp;~6〇2 is not equally disposed on the entire side 602, but is mainly disposed on the upper side of the side 602 as shown in FIG. In this way, it is configured to be able to cope with the type, that is, the ko-lin film, and the mosquitoes can contact each of the contact ends 602a to f2f to contact the vicinity of the upper end portion of the optical film. Therefore, the contact portion is not provided on the lower side of the side roller 6〇2. However, it is of course also possible to provide a contact roller on the lower side of the side roller 602. Each rotation of the side rollers 6〇2 is connected to the motor 6〇3 6〇4 via the power transmission mechanisms 6〇5 and 6〇6, and reaches 6〇3 and 6〇4 for rotation control. Although not shown, the lower roller 615 is disposed in the same manner as the side roller 6〇2, and is arranged in a row at a predetermined interval of 43 201005355 in a substantially horizontal direction. The plurality of rollers constituting the lower roller 615 are moved in contact with the lower end portion of the polarizing plate liquid crystal panel 10a in the standing state to actively rotate, and the polarizing plate liquid crystal panel 10a is moved in the substantially horizontal direction. As described above, the basic structure of the polarizing plate liquid crystal panel transport unit 6 is the side roller 602 and the lower roller 615, and the side light 602 and the lower light 615 are formed by a frame mechanism or the like, thereby forming The polarizing plate liquid crystal panel transport unit 6〇0 shown in FIGS. 10 and 12 is used. Fig. 13 is a view showing a state in which one side of the polarizing plate standing supply units 500 and 550 and the polarizing plate liquid crystal panel transport unit 600 has moved to the liquid crystal panel discharge stage side. In other words, the liquid crystal panel 1A to which the polarizing plate is attached by the adsorption roller of the polarizing plate attaching portions 400 and 450 of FIG. 6 is held in a state of being attached to the polarizing plate liquid crystal panel transport unit 600. In the attached state and the like, the one side of the polarizing plate standing supply unit 550 and the polarizing plate liquid crystal panel transport unit 600 can be moved toward the liquid crystal panel row #900 side. Further, as shown in FIG. 12, since the polarizing plate upright supply units 500 and 550 and the polarizing plate liquid crystal panel transport unit 6 are coupled by the frame mechanisms 609 to 612, they are attached as shown in FIG. The one side roller of the polarizing plate liquid crystal panel transport unit 600 and the polarizing plate standing supply unit 550 move together. As shown in FIG. 13 , the side roller 6〇2 on one side of the polarizing plate liquid crystal panel transport unit 600 is moved together with the polarizing plate upright supply unit 550, whereby it can be easily confirmed by visual inspection. 201005355 The attached state of the polarizing plate liquid crystal panel l〇a. Further, even when the line is stopped during transportation or the polarizing plate liquid crystal panel 10a is broken, the polarizing plate liquid crystal panel 10a in the middle of transportation can be easily and safely taken out. FIG. 14 is a view showing a detailed configuration of the protective film peeling portion and the polarizing plate attaching portion of FIG. 6, and the protective film peeling portion and the polarizing plate attaching portion are enlarged and viewed from the upper side of the polarizing plate attaching device. To the map. Fig. 15 is a view for explaining a peeling operation of the peeling portion of the protective film of Fig. 14; Fig. 16 is a view showing a detailed configuration of a peeling unit portion of the protective film peeling portion of Fig. 14; Fig. 17 is a development view of a cylindrical suction drum showing a detailed configuration of a polarizing plate attaching portion. Fig. 18 is a side view of the vicinity of the adsorption roller of the polarizing plate attaching portion of Fig. 14 as seen from the lower side of Fig. 14; In addition, since the protective film peeling portion 3 and the polarizing plate attaching portion 400 have the same configuration as the protective film peeling portion 35 and the polarizing plate attaching portion 450, only the protective film peeling portion 3 (8) and the polarizing plate are attached. The configuration of the portion 400 omits the illustration and description of the protective film peeling portion 350 and the polarizing plate attaching portion 450. As shown in Fig. 14, the protective film peeling portion 3 is composed of a peeling unit portion 3, a peeling unit driving portion 320, and a polarizing plate guiding portion 33. The peeling unit portion 301 is composed of the following portions: an adhesive tape 31〇, which is in contact with one end of a polarizing plate u (dotted line in the drawing) vacuum-adsorbed by the adsorption roller 410; the rollers 311 to 314 are wound The adhesive tape 31 〇; the chuck 321 holds an end portion of the protective film 11a (dash line in the figure) attached to the adhesive tape by the rotation of the rollers; and a protective film connection In the portion, the peeled protective film 11a is connected to the protective 臈Ub which was peeled off last time. As shown in Fig. 16, the peeling unit portion 301 is provided in plural along the length direction of the suction drum. In the present embodiment, five are provided: Training. Therefore, the peeling unit portion 3 () 1 (four) is capable of peeling off the protective film at five locations. Moreover, the adhesive tape 31A is omitted in FIG. The peeling unit drive unit 320 controls the movement of the entire peeling unit unit 301 other than the protective film connecting portion 315, and controls the processing of the embGss. The imprint processing causes the adhesive tape 31 to be aligned. The position of the protective 臈Ua contact is moved, and the lost disk 321 holding the peeled protective film lu is guided to the protective film connecting portion 315, and the protective film lla is connected to the last time by the protective film connecting portion 315. Peeled protective film lib. Further, the protective film may be bonded by a process other than the imprint process, such as a thermocompression bonding process or an ultrasonic bonding process. As shown in FIG. 14 , the protective film peeling portion 300 is used to close the front end of the adhesive tape 310 and the protective film 11a by the peeling unit driving portion 320 at a position close to the attaching position of the liquid crystal panel 10 and the polarizing plate u. Contact. Then, the peeling unit portion 301 is slightly moved in the peeling direction (the lower side direction in Fig. 14), and the end portion of the protective dome 11a attached to the adhesive tape 310 is separated from the polarizing plate 11. The end portion of the protective ll aa separated from the polarizing plate u is introduced into the chuck by the rotation of the rollers 311 to 314, and the end portion of the protective film 11a is sandwiched into the chuck 321 by 46 201005355. Then, in a state in which the end portion of the protective film 11a is sandwiched by the chuck 321, the peeling unit 301 moves only a predetermined distance in the peeling direction (the lower direction in FIG. 14), thereby peeling off the protective film 11a from the polarizing plate u. . Then, as shown in FIG. 15, the peeling unit 301 is further moved in the peeling direction (the lower side direction of the drawing) so that the peeled portion of the protective film 11a is overlapped with the last peeled protective film lib of the protective film connecting portion 315. on. ® Since the hole 317' into which the pin 316 can be inserted is provided in the protective film connecting portion 315, as shown in Fig. 15, the peeling unit driving portion 32 插入 inserts the pin 316 into the hole 317. Thereby, the last protective film lib and the current protective film 11a are connected to each other by imprint processing. The joined protective film 11a is guided onto the guide roller 318 and sequentially peeled off from the polarizing plate 11. Since the protective film 11a of the polarizing plate 11 is sequentially peeled off at a position close to the attachment position of the liquid crystal panel 1 and the polarizing plate 11, it is possible to prevent foreign matter from adhering to the polarizing plate 11. The polarizing plate guide unit 330 guides the polarizing plate in the upright state (substantially perpendicular state) conveyed from the polarizing plate supply stages 700 and 750 to the adsorption drum 410 of the polarizing plate attaching unit 400 and is composed of the following parts. : a feed roller 331 for feeding the polarizing plate 11 to the adsorption roller 410 , a cleaning portion 332 for cleaning the surface of the polarizing plate 11 , and a support frame for supporting the supply roller 331 and the cleaning portion 332 333. The supply roller 331 47 201005355 has a function of a clamp for accurately positioning the polarizing plate u on the adsorption roller 410. The cleaning unit 332 can be constituted by a cleaning roller unit or the like. The polarizing plate attaching portion 400 temporarily adsorbs the polarizing plate in the upright state (substantially perpendicular state) that has been transported from the polarizing plate supply stages 7 and 750, and attaches it to the liquid crystal panel supply station 1 to be transported. The liquid crystal panel 10 is in an upright state (substantially vertical state). That is, the polarizing plate attaching portion 4〇〇 e simultaneously attaches the polarizing plate 11 to the left and right sides of the liquid crystal panel supplied in the standing state. In the adsorption drum 410, as shown in Fig. 6, the two cylindrical adsorption drums 410 are arranged in parallel in a state of being substantially vertically raised. The two cylindrical adsorption rolls 410 are configured such that the outer peripheral surfaces of the two adsorption rolls 410 are in line with the surface of the liquid crystal panel transferred from the liquid crystal panel supply stage. Further, since the two adsorption rollers 410 are set to be in a state of being subjected to a predetermined pressure in the opposite direction to each other, the surface of the liquid crystal panel passing between the two adsorption rollers 410 is subjected to a predetermined pressure', thereby performing the polarizing plate. U is attached to both sides of the LCD panel at the same time. At this time, a pressure applying member (not shown) that applies a predetermined pressure is provided between the two adsorption rollers 41 so that the interval between the two adsorption rollers 410 corresponds to the liquid crystal panel passing between the two adsorption rollers 410. The thickness changes freely. The pressure applying members are respectively provided in combination with the two adsorption rollers 410, and the adsorption rollers 41 are urged toward each other in a direction facing each other 48 201005355, and a predetermined pressure is applied to the contact faces of the adsorption rollers 410 and the liquid crystal panels. The polarizing plate attaching portion 400 is constituted by two cylindrical adsorption rollers 410 as described above. The adsorption roller 410 is formed by winding a thin plate-shaped panel having a predetermined thickness into a cylindrical shape. Further, although an adsorption roller in which a thin plate-shaped panel is wound into a cylindrical shape is exemplified here, a cylindrical member may be used as the adsorption roller. Fig. 17 is a developed view showing the cylindrical suction roller 410. As shown in Fig. 17, the adsorption drum 410 is provided with a plurality of adsorption regions 411 (regions surrounded by the dotted frame) at about half of its position. Each of the adsorption regions 411 is composed of: a suction hole provided in the cavity portion 412 corresponding to the length of the polarizing plate 11c having the smallest area in the short-axis direction; and a length in the short-axis direction of the polarizing plate ud having the largest area. An adsorption hole at a side portion of the corresponding cavity portion 413; and a cavity portion provided so that the number of the adsorption holes gradually increases from the cavity portion 412 to the cavity portion 413. The cavity portion is linearly arranged so as to be substantially parallel to the rotation axis of the cylindrical suction drum 410. That is, the diameter of the adsorption roller 410 is such that the front end portion and the rear end portion of the polarizing plate lid which can be wound without causing the largest area overlap each other. Thus, a side of the adsorption roller 410 having a large diameter is used. When the liquid crystal panel is pressed and applied to the left and right sides of the liquid crystal panel, the size of the polarizing plate of the CF panel and the TFT surface of the liquid crystal panel and the orientation of the attachment are different from each other. It is also possible to attach the polarizing plate to both sides of the liquid crystal panel almost simultaneously. Each of the adsorption holes is an opening hole provided from the side surface of the cylindrical drum toward the cavity portion with respect to the cavity portion provided in the plate of the thin plate-like panel. The cavity portion of each of the adsorption holes has an opening at both end portions of the adsorption drum 410, and the opening end of the left side of the adsorption drum 410 is kept sealed by a stopper (not shown), and is adsorbed on the adsorption drum 410. At the opening portion ® end on the right side, only the cavity portion inserted into the thin plate-shaped panel to which the vacuum suction port 414 is inserted is vacuum-inhaled. On the other hand, the cavity portion 420 having the adsorption hole for adsorbing the tip end portion of the polarizing plate u in the upright state (substantially vertical state) which is transported from the polarizing plate supply stages 7A and 750 is the first. The upper side is provided with an adsorption hole whose opening area is larger than the opening area of the adsorption hole. The reason for this is that the protective film is peeled off by the adhesive tape 31 of the protective film peeling portion 300. Therefore, a large stress is applied during peeling, and the polarizing plate 11 is adsorbed against the stress. Further, since the opening portion of the adsorption hole provided in the cavity portion 420 has a large area, when the polarizing plate is attached to the liquid crystal panel, the pressing force may not be sufficiently transmitted. Therefore, in the present embodiment, after the protective film 11a is peeled off, the protective films 11a and Ub are connected by imprinting, and the position of the tip end portion of the polarizing plate is shifted from the position of the adsorption hole provided in the cavity portion 421, and The adsorption hole is provided on the cavity portion 421 to 50 201005355.  The polarizing plate 11 is adsorbed and held. Vacuum suction ports 415, 416' are inserted into the right end portions of the cavity portions 420, 421, and the cavity portions 420, 421 are sucked into a vacuum. On the other hand, rod-shaped stopper members 422 and 423 are inserted into the left end portions of the cavity portions 420 and 421 so as to be effective for the adsorption holes of the cavity portions 42A and 421 in accordance with the size of the polarizing plate. / Invalid to set. In other words, in Fig. 17, the end portions of the stopper members 422 and 423 are inserted into the © position of the left end portion of the polarizing plate, and the adsorption holes in the portions where the stopper members 422 and 423 are inserted do not function as vacuum suction. Therefore, when the polarizing plate lid having the largest area is suction-held, the front end portions of the stopper members 422 and 423 are moved to the left side more than in the case of FIG. 17, so that the front end portions of the stopper members 422 and 423 are located on the polarizing plate lid The position of the left end. Thus, by positioning the front end portions of the stopper members 422, 423 at the left end portion of the polarizing plate, it is possible to efficiently adsorb the polarizing plates of various sizes. In this manner, the polarizing plate is rotationally moved in a state of being wound around the outer peripheral surface of the adsorption drum 410. Since the polarizing plate itself is preferably soft, the polarizing plate is stretched by the adsorption roller 410, whereby the polarizing plate is bent along with the curvature of the adsorption roller 410, thereby becoming wound on the adsorption roller 410. . In the present embodiment, the operation of rotating the polarizing plate in a state of being wound around the adsorption drum 410 and attaching the polarizing plate to the liquid crystal panel are simultaneously performed. Further, in the state of the present embodiment 51 201005355, although the cavity portion and the adsorption hole are not provided between the cavity portion 412 and the cavity portion 421, the cavity portion 412 and the cavity portion 421 may be provided. A plurality of cavity portions having the same adsorption holes as the cavity portion 412. Fig. 18 is a side view showing the detailed configuration of the vicinity of the adsorption roller of the polarizing plate attaching portion. As shown in Fig. 18, the adsorption roller 41 is formed by winding a thin plate-like panel into a cylindrical shape, and the inside of the adsorption roller 41 is hollow. Further, on the bottom surfaces of the cylindrical suction drums 41, circular closing members 430 and 43 are provided, and the center of the closing members 43A and 431 is inserted through the rotating shaft 432. The upper and lower sides of the rotating shaft 432 are supported to be freely rotatable. As shown in Fig. 18, a ventilation member 433 having a vent hole is provided at a lower end portion of the rotating shaft 432. The suction pipes 417, 418, and 419 are supported from the ventilation members 433 to the support members 435 on the vacuum suction ports 414, 415, and 416, respectively, to support the rotation shaft 432, and the support members 436 are provided to the ventilation members. 433 for support. The support member 435, the phantom 6 &amp; struts 437 are supported. The ventilating member 433 is configured to connect a vent hole that rotates together with the rotating suction drum 410 and a vacuum pump that is provided outside. 19 and FIG. 20 are views showing a detailed configuration of the polarizing plate supply table of FIG. 1, and FIG. 19 is an enlarged view of the polarizing plate supply table of FIG. 1 and is viewed from the upper side of the polarizing plate attaching device. Fig. 20 is a side view of the polarizing plate supply stage of Fig. 19 as seen from the lower side of Fig. 19. The polarizing plate supply stage 7A, 52, 201005355 750 takes out the polarizing plate from the polarizer storage (Stocker) 701, and supplies it to the polarizing plate standing supply parts 500 and 550. Further, since the configurations of the polarizing plate supply stages 700 and 750 are the same, only the configuration of the polarizing plate supply stage 700 is shown in Figs. 19 and 20 . The polarizing plate supply stage 700 is composed of a polarizing plate storage 701, suction pads 7021 to 702c, vertical movement mechanisms 703 and 704, and front and rear moving mechanisms 705 and 706. The polarizing plate storage 701 mounts a polarizing plate in which a plurality of 〇 stickers are housed. The adsorption pads 7021 to 702c adsorb the single-sided side of the polarizing plate 11 placed in the polarizing plate storage 701. The polarizing plates 11 sucked by the adsorption pads 7021 to 702c are lifted from the polarizing plate storage 701 by the vertical moving mechanisms 703 and 704. The lifted polarizing plate 11 is supplied to the transport roller 506 of the polarizing plate standing supply unit 500 by the front and rear moving mechanisms 705 and 706. In Fig. 19, twelve adsorption pads 7021 to 702c are provided. The adsorption pads 7021, 7024, 7027, and 702a are respectively disposed on the pad support frame 707, and the adsorption pads 7022, 7025, 7028, and 702b are respectively disposed on the pad support frame 708. The adsorption pads 7023, 7026, 7029, and 702c are respectively disposed on the pad. Support frame 709. The support frame 708 and the pad frame 709 are configured to be movable in the vertical direction of FIG. 19 along the guide rails 710 and 711. Further, the adsorption pads 7027 and 702a are configured to be movable in the longitudinal direction of the pad supporting frame 7〇7 (the horizontal direction in Fig. 19). Similarly, the adsorption pad, 7〇2b 53 201005355, is configured to be movable in the longitudinal direction of the pad support frame 708 (the left-right direction of FIG. 19) to form the adsorption pads 7029, 702c so as to be in the longitudinal direction of the pad support frame 709 ( The left-right direction of FIG. 19 is configured to move upward. This is because the size of the polarizing plate supplied from the polarizing plate supply table 700 is different depending on the size of the liquid crystal panel 10. Therefore, the arrangement of the adsorption ports 7021 to 702c is made to correspond to polarizing plates of different sizes. Further, even if the size of the polarizing plate is different, the positions of the adsorption pads 7021 and 7024 do not have to be changed, so that the adsorption pads 7021 and 7024 are not configured to be movable. Fig. 21 is a view showing a state in which each of the adsorption ports 7022, 7023, 7025, 7026, 7027, 7028, 7029, 702a, 702b, and 702c has moved in accordance with a polarizing plate having a small size. The adsorption pads 7〇22, 7025, 7028, 702b are moved in the up and down direction of Fig. 21 by the pad support frame 708 moving along the guide rails 710, 711. Similarly, the adsorption pads 7〇23, 7026, 7029, 702c are also moved along the guide rails 710, 711 by the support frame 709, and Q can be moved in the up and down direction of Fig. 21. Further, since the adsorption pads 7027, 702a, 7028, 702b, 7029, 702c are movable along the longitudinal direction of the frame 707, 708, 709 (the left-right direction of the figure), they are as shown in FIGS. 19 and 21, It is configured to conform to the size of the polarizing plate and to be movable in the plane of the upper surface of the polarizing plate storage 701. 22 and FIG. 23 are views showing a detailed configuration of the protective film discharge table of FIG. 1, and FIG. 22 is an enlarged view of the protective film discharge table of FIG. 1 and is observed from the polarizing light 54 201005355 above the plate attaching device. Figure. Fig. 23 is a side view of the protective film discharge table of Fig. 22 as viewed from the lower side of Fig. 22; The protective film discharge stages 8 (10) and 850 are taken up by the protective film peeled off by the protective film peeling parts 3A and 35, and discharged. In addition, since the structures of the protective film discharge stages 8A and 85B are the same, only the protective film discharge stage 8A is shown in FIG. 22 and FIG. The protective film discharge table 800 is composed of a winding buffer portion 81, a winding portion 820, and a protective film discharge vehicle 827. The winding buffer portion 81 暂时 temporarily sucks the protective film lib continuously supplied from the protective 连结 连结 connecting portion 315 into the inside, and applies a predetermined tension to the protective film lib. The winding buffer portion 81 is constituted by a casing having a size that can be sucked into the protective film 11b, and a gas discharge portion 811 is provided on the left side of Fig. 22, and an exhaust port 812 is provided on the opposite right side. Air of a predetermined pressure is ejected from the gas ejecting portion 811 toward the exhaust port 812 on the right side. As shown in Fig. 22, the protective film 11b is placed inside the winding/recovering portion 81〇 by the air ejected from the gas ejecting portion 811 via the guide rollers 813 and 814, and is formed to be pushed toward the exhaust port. The state of 812. Thereby, the protective film 11b is subjected to a fixed tension, so that a fixed tension can be applied to the peeling action of the protective film. Further, the winding buffer portion 81 can supply the protective film 11b to the winding portion 820 with a constant tension. Further, although the winding buffer portion 810 is a fixed tension applied by air having a predetermined pressure, the tension applying mechanism may be used to impart tension. As shown in Fig. 23, the winding unit 820 is wound by the winding drive unit 82, the winding shaft 55 201005355 822, the gas supply unit 823, the rotating shaft holding unit 824, the protective film holding unit 825, the protective film relief portion 826, and the protective film.纟 827 constitutes. The winding drive unit 821 is constituted by a driving force source such as a motor, and transmits a rotational driving force to the winding shaft 822 via a rotating gear like 829. Therefore, the take-up shaft seems to be rotationally controlled by the take-up drive unit Mi. The gas supply unit milk supplies compressed gas from a compressor (not shown) provided outside to the flow path 83 provided in the take-up shaft 822. As shown in Fig. 23, the flow path 83 provided in the take-up shaft 822 extends in the longitudinal direction of the take-up shaft a], and the end portion thereof is hermetically sealed. The flow path 830 provided in the take-up shaft 822 is provided with exhaust ports 831 to 836 for discharging the compressed milk from the side surface of the take-up shaft 822. The exhaust ports 831 to 836 are constituted by 3 to 5 linear flow paths extending from the central axis of the winding shaft 822 in the normal direction, and these linear flow paths and the flow path 830 provided in the winding shaft 822, respectively. connection. Therefore, the compressed gas supplied from the gas supply unit 823 passes through the flow path 83, and is uniformly discharged from the exhaust ports 831 to 836. A cylindrical elastic member made of rubber or the like is hermetically attached to cover the winding shaft 822 including the exhaust ports 831 to 836. When the compressed gas is discharged from the exhaust ports 831 to 836 via the flow path 830 of the take-up shaft 822, the cylindrical elastic member expands. A cylindrical member 56 having a slit along the longitudinal direction of the take-up shaft 822 is provided on the cylindrical elastic member so as to further cover the periphery thereof. The elastic member expands, thereby causing the ___ result of the cylindrical member to be such that when the supply of the compressed gas to the flow path 83G is stopped, when the elastic member is contracted, the slit along the long axis direction The call becomes smaller, and as a result, the diameter of the cylindrical member is reduced. The upper end portion of the circular member is mounted on the milk using the Anzhen member 843. Further, as the cylindrical elastic member is expanded and contracted, it is possible to use a motor drive instead of the gas to rotate the plate material to expand and contract the cylindrical elastic member. That is, as long as the cylindrical elastic member is swollen and contracted, the cylindrical elastic member may be in an expanded state when the polarizing plate is attached by a method other than gas, and the protective film 11b is sequentially wound. . Fig. 23 shows a state in which the protective film 11C is wound around the take-up shaft 822. As shown in Fig. 23, when the protective film nc is wound as indicated by a dashed line, the supply of the gas to the gas supply portion is stopped. Since the supply of the gas is stopped, the cylindrical elastic member contracts, and the diameter of the cylindrical member is reduced, so that the diameter of the cylindrical member becomes smaller than the inner diameter of the protective film lie, so that the winding is kept at the take-up pumping The upper protective medium lie will fall off the take-up shaft 822 due to its own weight and fall downward. Since the protective film llc wound on the take-up shaft 822 is wound into a plurality of layers, its weight is about tens of kilograms. The protective film holding portion 825 causes the protective film llc which is detached by its own weight to be held on the holding table 8251 in a state of 201005355: moved to the lower protective film relief portion 826, and the protective film holding portion milk is provided by the back surface of the protective film 825. The root pillar thanked, 8262 support. The movement of the moving portion 82 that is slidably moved along the struts 8261 and 8262 is maintained. The holding table 8251 and the moving portion 8252 are combined with a wire coffee that is rotatably wound around the upper and lower pulleys (_ey) 8264 and 8265. Therefore, if the pulleys 8264 and 8265 are driven by the rotational driving force source _

The rotary drive 'the protective film holding portion 825 moves downward in the up and down direction. The protective film lle which has been detached from the take-up shaft 822 is discharged to the vehicle 827 by the protective film holding portion 825' as the protective film Ud and remaining in the protective film relief portion. As shown in FIG. 23, the protective film discharge vehicle milk is moved on the guide rail 8271 by placing the protective film lid, and the protective film lid is discharged from the protective film relief portion 826 to the outside, so that the protective film becomes "o" As shown in Fig. 22, the center of the protective film discharge vehicle 827 © A has a C-shape of π cut. The protective film holding portion 825 has a shape that can pass through the central portion in the C-shape, and The protective film is placed on the center portion of the vehicle 827 by the protective film, and the protective film is placed on the protective sputum discharge vehicle 827. Δ As shown in Fig. 1, the liquid crystal panel discharge table 900 is disposed in the polarized light. The polarizing plate liquid crystal panel to which the polarizing plate has been attached by the polarizing plate attaching stage 2 is discharged downstream of the board attaching stage 200. The liquid crystal panel discharge stage 9〇〇 and the liquid 58 201005355 crystal panel supply station HK) The same structure is used, and the liquid crystal panel to which the polarizing plate is attached on both sides is received in a state of being substantially vertically raised by the operation "opposite to the liquid crystal panel supply stage 100", and is converted into a substantially horizontal state. Discharge it. In the above-described embodiment, the liquid crystal panel supply table 100 is provided with a function of transferring the liquid crystal panel from a substantially horizontal position, and the liquid crystal panel is discharged. The stage 9GG has a function of transferring the eccentric liquid crystal panel from a substantially vertical state to a substantially horizontal state, but the liquid crystal panel aligning unit 201 can also transfer the liquid crystal panel 1 from the surface. In the state in which the horizontal state is changed to the state (substantially vertical state), the polarizing plate liquid crystal panel transporting unit has a function of transferring the polarizing plate liquid crystal panel from a substantially vertical state to a substantially horizontal state. 'The LCD panel supply table 〇〇 and / 0 or the liquid crystal panel discharge table 900 can be omitted, and the space occupied in the transport direction of the liquid crystal panel can be greatly reduced. In the above embodiment, as shown in Fig. 6, the polarized light is shown in Fig. 6. The board attaching table 200 is disposed in a casing 210 for attaching the polarizing plate to the stage 200 and the liquid crystal panel supply station 100. The polarizing plate supply stations 700 and 750, the protective film discharge stations 800 and 850, and the liquid crystal panel discharge table 900 are separated to ensure the cleanliness area. That is, as shown in Fig. 6 59 201005355, the liquid B panel pair The second part 2〇1, the protective film peeling parts 3(8), 35〇, the polarizing plate accommodating 400, 450 'the polarizing plate erecting supply parts 5 〇〇, 55 〇 and the polarizing plate liquid 曰曰 panel conveying part _ are all arranged in the cleaning The highest weight 21 〇 inner liquid B 曰 panel supply table 100 and the liquid crystal panel aligning portion 2 〇 1 on the housing 210 'has a side of the side of the liquid crystal panel alignment portion 201 The liquid crystal panel is supplied to the slit which moves on the side of the stage 1, and the slit can pass through the liquid crystal panel in the standing state. The casing 21 between the protective film peeling portion 3 (8) and the protective film discharge tables 800 and 850 has a slit through which the peeled protective film passes in an upright state. The housing 21a between the polarizing plate standing supply units 500 and 550 and the polarizing plate supply stages 70A and 75B has a narrow space through which the polarizing plate placed in the polarizing plate storage can pass in a substantially horizontal state. Seam. In the casing 210 between the polarizing plate liquid crystal panel conveying unit 6 and the liquid crystal panel discharge table 900, the polarizing plate standing supply units 500 and 550 and the polarizing plate liquid crystal panel conveying unit 6〇〇 are provided. A slit that moves sideways on the side of the liquid crystal panel discharge stage 900, and the slit is allowed to pass through the polarizing plate liquid crystal panel in an upright state. As described above, the casing 210 is provided with only the minimum required slits&apos; and is configured to suppress the intrusion of foreign matter as much as possible, so that a high degree of cleanliness can be maintained. In addition, as described above, the liquid crystal panel aligning portion 201 has a function of transferring the liquid crystal panel 1 from the substantially horizontal state to the state (substantially vertical state), and the polarizing plate liquid crystal panel transporting portion 201005355 is provided. f 600 has a function of transferring a polarizing plate liquid crystal panel from a substantially vertical state to a substantially horizontal state. In this case, a slit is provided in the casing, and the slit is in the liquid crystal panel pair. The alignment unit 2〇1 and the polarizing plate liquid crystal panel transport unit 600 allow the liquid crystal panel to pass through while the liquid crystal panel is raised. Further, it is also possible to provide only the protective film peeling portions 300, 35A and the polarizing plate attaching portions 400, 450 in the casing in which the high cleanliness is maintained, and only the required minimum is provided on the side surface of the casing. The slit of the limit. For example, the housing may be provided so as to surround only the protective film peeling portions 300 and 350 and the polarizing plate attaching portions 400 and 450, and the calender attachment portions 400 and 450 may be formed on the side surface of the desired body. A slit for allowing the liquid crystal panel to pass through is provided between the liquid crystal panel aligning portion 2〇1, and is disposed between the polarizing plate attaching portions 4〇〇 and 45〇 and the polarizing plate liquid crystal panel transport unit 6〇〇. A slit for passing only the polarizing plate liquid crystal panel is provided between the polarizing plate attaching portions 4A and 45B and the polarizing plate standing supply portions 500 and 550, and a slit for passing only the polarizing plate is provided. A slit through which only the peeled protective film passes is provided between the protective film peeling portions 300 and 350 and the protective film discharge tables 800 and 85A. Further, in the above-described embodiment, the configuration in which the liquid crystal panel aligning unit 2〇1 and the one side roller attached to the polarizing plate liquid crystal panel transport unit 6〇〇 are movable has been described. Similarly to the panel supply stage 100 and the liquid crystal panel discharge stage 900, the one side roller is provided to move. Fig. 24 is a view showing another embodiment of the polarizing plate attaching apparatus of the present invention. 61. The sheet of the polarizing plate attaching apparatus of the polarizing plate attaching apparatus of the liquid crystal panel supply stage view. 〇, 550, a diagram of the polarizing plate liquid crystal panel transport unit 600 and the protective film discharge stages 8A and 85B. Further, in the figure %, the polarizing plate attaching portions 400 and 450 and the liquid crystal panel aligning portion 2 are omitted (corresponding to Fig. 12. It is clear from Fig. 24 that the polarizing plate attaching device of Fig. 24 and the above-described implementation The difference in morphology is that the polarizing plate attaching device is inclined by about 3 in the clockwise direction with respect to the vertical direction. Thus, as shown in the present invention, when the liquid crystal cell is vertically erected and the polarizing plate is simultaneously attached In the case of the liquid crystal cell, since the posture of the liquid crystal cell in the vertical state becomes unstable, the pressing of the attaching roller which affects the quality of the polarizing plate adhesion is difficult, and therefore, in order to solve this problem, The problem is that the entire polarizing plate attaching device is inclined in the clockwise direction or the counterclockwise direction by about 3 to 5 in the vertical direction as shown in Fig. 24. Thereby, the pressing of the attaching roller can be made uniform. In addition, in the embodiment of Fig. 24, the effect of stabilizing the transport characteristics when the vertical transfer substrate is transported is obtained by tilting the entire polarizing plate and the attached device with respect to the vertical direction. The upper bottom portion of the base portion on which the respective stages are placed is inclined by about 3 to 5 with respect to the horizontal direction. However, the floor portion tilting 25 in which the bases are provided may be the polarizing plate attaching device of the present invention. A diagram showing a modification of the polarizing plate attaching portion and the protective film peeling portion, and a schematic configuration of the polarizing plate attaching portion 62 201005355 f and the protective film peeling portion, wherein the polarizing plate attaching portion is to be erected The state-provided polarizing plate is attached to the first main surface and the second main surface of the liquid crystal panel (cell) supplied in an upright state at the same time, and the edge-preserving film peeling portion is provided at two of the polarizing plate attaching portions On the other side, the protective film is peeled off from the polarizing plate. Further, the main portions of the polarizing plate attaching portion and the protective film peeling portion are enlarged and shown in Fig. 25, and the portions are shown obliquely from the upper side. This is an example of a vacuum suction roller in which a plurality of vacuum holes are provided on the side of the drum. However, when the vacuum plate is used to vacuum-adsorb and hold the polarizing plate as an optical film, this is true. The vacancy adsorption is such that the adsorption force acts on a part of the optical film. Therefore, the optical film is slightly deformed by bending or warping, which may cause bubbles or foreign matter to be caught in the attached portion. Therefore, in the present embodiment, A viscous roller is used, and the viscous roller does not cause a problem such as air bubbles or foreign matter entrapped when the optical film is attached to the display panel. (12) An adhesive silicone member provided on the outer peripheral surface of the cylindrical roller mechanism is used to adhere and hold the optical film, and the optical film is attached to the display panel. According to the embodiment, the adsorption hole is not used. 'Therefore, the variety can be easily changed regardless of the size of the member to be put in, so that the structure can be simplified and the cost can be reduced. In addition, since the entire surface of the display panel is held by the adhesive material, it can be 63 201005355 The warpage is corrected, and the attachment can be performed while maintaining the corrected state. Therefore, the end surface of the optical film is not deviated or affected by wrinkles, etc., and is suppressed. In the event of a problem such as air bubbles or foreign matter being caught, high-quality attachment work can be performed. Further, the optical film attaching mechanism is not limited to the case of attaching in a substantially vertical state, and may be used in the case of attaching in a substantially horizontal state. In the polarizing plate attaching device of FIG. 25, after the liquid crystal panel is moved from the left direction in the left direction of the image by the liquid crystal panel supply unit, the liquid crystal panel is rotated and the two are freely rotatable by the shaft support. The viscous rollers 11, 12 are attached to the first main surface and the second main surface of the liquid crystal panel 71 which are advanced in the standing state at almost the same time. Further, the protective film peeling mechanism 30 and the protective film take-up mechanism 40 are also on the side of the adhesive roller 12, but are not shown in the figure. The polarizing plate attaching device temporarily adheres (adheres) the polarizing plate 50 in a standing state (substantially perpendicular state) conveyed from the polarizing plate supply unit, and attaches it to the liquid crystal panel supply unit. On the liquid crystal panel 71 in the upright state (substantially vertical state). That is, the polarizing plate attaching means simultaneously attaches the polarizing plates 50, 60 to the left and right surfaces of the liquid crystal panel 71 supplied in the standing state. As shown in Fig. 25, the viscous rollers 11, η are rotatably supported by both sides of the polarizing plate attaching portion for performing the polarizing plate attaching operation, and the two cylindrical rollers are erected substantially vertically. 64 201005355 Parallel configuration. The viscous rollers 11, 12 are formed of a columnar amino acid urethane layer, and are wound around the outer surface of the cylindrical urethane layer on the rotating surface of the viscous rollers 11, 12. Viscous rubber bands 13, 14. The entire surface of the viscous rubber knee belts 13, 14 in the outer circumferential direction is adhesive, and the entire surface of the polarizing plate is closely held on the viscous rubber bands 13, 14. The viscous rollers 11 and 12 are configured such that the polarizing plates 50 and 60 that are carried in a standing state from a polarizing plate supply unit (not shown) are closely attached to the viscous rubber bands 13 and 14 and can be attached thereto. The polarizing plates 50 and 60 are held by the adhesive force of the viscous rubber bands 13, 14. As shown in Fig. 25, the viscous rubber tape 13 of the viscous roller 11 is attached to the front end of the polarizing plate 51 which is conveyed from the right side of Fig. 25. The adhesive portion is held, and then the viscous roller 13 is rotated clockwise, thereby being held (adhered) on the outer peripheral surface of the viscous rubber tape 13 as the polarizing plate 5 。. The polarizing plate 6 is rotated clockwise in a state of being held tightly on the outer peripheral surface of the viscous rubber tape 13, and is conveyed to a position corresponding to the liquid crystal panel 71. On the other hand, in the viscous rubber band 14 of the viscous roller 12, the front end portion of the polarizing plate 61 sent from the right side of FIG. 25 is adhered and held, and then the viscous roller 12 is rotated counterclockwise. As in the polarizing plate 60, it is adhered (adhered) to the outer peripheral surface of the viscous rubber tape 14. The polarizing plate 60 is rotated counterclockwise in a state of being held against the outer peripheral surface of the viscous rubber tape 14 in a state of 65 201005355, and is conveyed to a position corresponding to the liquid crystal panel 71. The two cylindrical adhesive rollers 11 and 12 are configured such that the viscous rubber bands 13 and 14 disposed on the outer peripheral surface thereof are in line with the surface of the liquid crystal panel 71 transferred from the liquid crystal panel supply unit. Upper contact. Further, since the two viscous rollers 11 and 12 are disposed in a state of being subjected to a predetermined pressure in the direction toward the central axis of each other, the surface of the liquid crystal panel 71 passing between the two viscous rollers 11 and 12 is regulated. The pressing force is applied to attach the polarizing plates 50 and 60 to both surfaces of the liquid crystal panel 71 at the same time. At this time, a pressure applying member (not shown) that always applies a predetermined pressure is provided between the two adhesive rollers 11 and 12 so that the interval between the two adhesive rollers 11 and 12 passes through the two adhesive rollers 11, The thickness of the twelve liquid crystal panels 71 is free to vary correspondingly. The pressure applying member is disposed in combination with the two viscous 0 rollers 11, 12, respectively, and urges the two viscous rollers 11, 12 toward each other, and always faces the two viscous rollers 11, 12 and A predetermined pressure is applied to the contact surface of the liquid crystal panel 71. Further, since the viscous rubber sheets 13, 14 are elastically deformed by themselves, the thickness of the liquid crystal panel 71 can be absorbed by the elastic deformation function. The viscous rollers 11 and 12 move the polarizing plates 50 and 60 to the protective bismuth by the rotation of the viscous rubber bands 13 and 14 while the polarizing plates 50 and 60 are being adhered and held. Near the institution 3〇. Further, the protective film peeling mechanism on the side of the second adhesive roller 20 is omitted. The protective film peeling mechanism 30 is composed of a rubber dead band that is in contact with one end of the polarizing plates 51 and 61 held by the adhesive rollers 11 and 12, and is attached to the adhesive tape by the rotation. The chuck at the end of the protective film and the protective film connecting portion that connects the peeled protective film to the protective film that was peeled off last time. The details of these constituent mechanisms are omitted in Fig. 25, and for convenience of explanation, the protective film 41 that has been joined after peeling is shown. The connected protective film 41 is guided to the protective film take-up mechanism 40 by a guide or the like (not shown), and sequentially taken up by the protective film take-up mechanism 40 while being sequentially peeled off from the polarizing plate 51. Since the protective film 41 of the polarizing plate 51 is sequentially peeled off at a position close to the attachment position of the liquid crystal panel 71 and the polarizing plate 51, foreign matter can be prevented from adhering to the polarizing plate 51. The diameter of the viscous rollers 11, 12 is as large as possible: φ winding can be performed without overlapping the front end portion and the rear end portion of the polarizing plate having the largest area. In this way, the viscous roller having a large diameter is pressed while being pressed from the left and right sides of the liquid crystal panel, and the size or sticker of the polarizing plate attached to the CF surface and the TFT surface of the liquid crystal panel at the same time is attached. The initial positions and the like are different from each other'. It is also possible to attach the polarizing plates to both sides of the liquid crystal panel almost simultaneously. Further, although not shown, the pressing force of the cleaning roller of 67 201005355 can be pressed to the vicinity of the viscous rubber tape 14 of the viscous rollers 11 and 12, that is, the polarizing plate 51 is not held tightly. At the portion of 61, impurities such as dust adhering to the viscous rubber bands 13, 14 are removed. Further, the present invention is not limited to attaching a polarizing plate to a liquid crystal panel, and can be widely used for attaching an optical film having a protective film to a display panel. In the above-described embodiment t, the case where the optical film (polarizing plate) is attached in a substantially vertical state has been described. However, the present invention is not limited thereto, and the bonding may be performed in a substantially horizontal state. Fig. 20 is a view showing a schematic configuration of a case where the viscous roller of Fig. 25 is substantially horizontal to constitute a polarizing plate attaching device. The polarizing plate attaching device of FIG. 26 advances the liquid crystal panel moved in a substantially horizontal state while maintaining a substantially horizontal state, and attaches the polarizing plate to the first main surface and the second main surface of the advancing liquid crystal panel almost simultaneously. On both sides. As shown in Fig. 26, the viscous rollers ΐ5 and Μ are rotatably supported by the shaft support © on both sides of the polarizing plate attaching portion for performing the polarizing plate attaching operation, and the two cylindrical rollers are vertically parallel in a substantially horizontal state. Ground configuration. The viscous rollers 15 and 16 are formed of a cylindrical urethane layer in the same manner as the viscous roller of FIG. 25, and the cylindrical surface of the viscous rollers 15 and 16 is a cylindrical potassium amide. A viscous rubber tape (not shown) is wound around the outer peripheral surface of the acid ester layer. The entire surface of the viscous rubber tape in the outer circumferential direction has adhesiveness, and the entire surface of the polarizing plate is closely adhered to the viscous rubber tape. 68 201005355 The viscous roller 5 is configured as follows: a polarizing plate 5G that is conveyed in a substantially horizontal state from a polarizing plate supply unit (not shown), and a bonding force of a viscous rubber tape on a viscous rubber tape. Force to keep the polarizing plates 5〇, 6〇. Further, the polarizing plate attaching device shown in Fig. 26 is obtained by changing the polarizing plate attaching portion of Fig. 26 to a substantially horizontal state, and the configuration thereof is the same as that of the polarizing plate attaching device of Fig. 25. FIG. 27 is a view showing an example of a polarizing plate attaching device in which an optical film (polarizing plate) of FIG. 26 is attached in a substantially horizontal state. Although the figure % shows the condition in which the optical film (polarizing plate) is attached in a substantially horizontal state, FIG. 27 shows a specific example in the case where the polarizing light in FIG. In the polarizing plate attaching portion of the plate attaching device, a viscous roller (adhesive rubber tape) in which an optical film (polarizing plate) is attached in a substantially horizontal state is used. In the polarizing plate attaching apparatus, the polarizing plate attaching portion of the polarizing plate attaching table 200a is configured such that the optical film © (polarizing plate) is attached to the liquid crystal panel in a substantially horizontal state as shown in FIG. 26 (display) Use the panel). In this case, the liquid crystal panel supply table that is supplied to the polarizing plate attaching stage of the subsequent stage after the liquid crystal panel which has been conveyed in a substantially horizontal state is changed and the following parts are omitted. 100', the polarizing plate placed in a substantially horizontal state is converted into a substantially vertical state, and then supplied to the polarizing plate attaching table of the polarizing plate attaching stage to raise the supply portions 50A and 550', and the polarizing plate is attached to the polarizing plate and attached to the polarizing plate. 69 201005355. The liquid crystal panel discharge table 900 is discharged from the standing state to the substantially horizontal state, and the space occupied by the entire polarizing plate attaching device can be greatly reduced. Fig. 27 is a view of the polarizing plate attaching stage 2A seen from the lateral side. In the polarizing plate attaching table 200a, two cylindrical adhesive rollers 15 and 16 arranged in a substantially horizontal state are arranged in parallel in the vertical direction. Therefore, in the polarizing plate attaching device of Fig. 27, the polarizing plate supply stages 7a, 750a and the protective film discharge stages 800a, 850a are also arranged vertically in the vertical direction. The viscous rollers 15, 16 are formed by the viscous roller of Fig. 25 or Fig. 26. The polarizing plate supply stages 700a and 750a take out the polarizing plate from the polarizing plate storage 701a, and accurately supply the polarizing plates 15 and 16 with the polarizing plate attaching portions, and supply them as follows: The mechanism for taking out the polarizing plate storage 701a is constituted by the same mechanism as that of the machine shown in Figs. 19 to 21, and the mechanism for accurately aligning the polarizing plate and the viscous rollers 15 and 16 is provided. In other words, the same transport mechanism as the liquid crystal panel alignment unit 201 shown in FIGS. 7 to 9 or the polarizing plate liquid crystal panel transport unit 600 shown in FIG. 13 is used for horizontal conveyance of the polarizing plate. In addition, in Fig. 27, the polarizing plate storage 701a and the take-out mechanism portion are shown only with respect to the polarizing plate supply table 7A. Although the same mechanism exists on the side of the polarizing plate supply table 750a, it is located on the back side of the polarizing plate attaching device, and is not shown from 201005355. The basic configuration of the protective film discharge stages _a and 850a is the same as that of the protective film discharge stage shown in Fig. 22 . In addition, since the polarizing plate is conveyed in a substantially horizontal state, the winding body (the protective film wound around the winding shaft) that has been peeled off by the protective film peeling portion is oriented as follows. The polarizing plate attaching device moves in the back direction (the depth direction in FIG. 27), and further moves the protective film downward in the vertical direction by using a protective film holding portion (not shown) that moves up and down in the vertical direction. The vehicle (not shown) is discharged from the protective film provided on the floor and transported and discharged. Although the present invention has been described in its preferred embodiments, it is not intended to limit the invention, and the invention may be modified and modified without departing from the spirit and scope of the invention. The scope of protection is subject to the definition of the scope of the patent application attached. [Brief Description of the Drawings] ❹ ® 1 疋 shows a general configuration of a polarizing plate attaching apparatus according to an embodiment of the present invention. Fig. 2 is a view showing a detailed configuration of a liquid crystal panel supply station of Fig. 1; Fig. 3 is a side view of the liquid crystal panel supply stand of Fig. 2 as seen from the right side. FIG. 4 is a view showing a first half of an example of an operation in which the liquid crystal panel supply table converts the liquid crystal panel in a substantially horizontal state. FIG. 5 is a view showing a second half of an example of an operation in which the liquid crystal panel supply table converts the liquid crystal panel in a substantially horizontal state. 71 201005355 Fig. 6 is a view showing the overall configuration of a polarizing plate attaching stage. Fig. 7 is a view showing a detailed configuration of a liquid crystal panel alignment portion of Fig. 6, and the liquid crystal panel alignment portion of Fig. 6 is shown enlarged and viewed from the upper side of the polarizing plate attaching device. Fig. 8 is a side elevational view of the liquid crystal panel alignment portion of Fig. 7 as seen from the lower side of Fig. 7; FIG. 9 is a view showing a state in which one side of the side roller of the alignment portion of the liquid crystal panel has been moved (extracted) to the liquid crystal panel supply stage side. (7) is a view showing a detailed configuration of the polarizing plate standing supply unit and the polarizing plate liquid crystal panel transport unit of FIG. 6 , and the polarizing plate standing supply unit and the polarizing plate liquid crystal panel transport unit of FIG. 6 are enlarged and shown. A view as seen from the upper side of the polarizing plate attachment device. . FIG. 5 is a view showing a detailed configuration of the polarizing plate upright supply unit and the polarizing plate liquid crystal panel transport unit of FIG. 6 and a view of the polarizing plate standing supply unit of FIG. 10 © as viewed from the lower side of the drawing. FIG. 2 is a view showing a detailed configuration of the polarizing plate standing supply unit and the polarizing plate liquid crystal panel transport unit of FIG. 6 , and the polarizing plate standing supply unit of FIG. 1A is viewed from the right side (adsorption drum side) of the drawing. A diagram of a polarizing plate liquid crystal panel transport unit. FIG. 13 is a view showing a state in which one side of the polarizing plate standing supply unit and the polarizing plate liquid crystal panel transport unit has moved to the liquid crystal panel discharge stage side. 72 201005355 FIG. 14 is a view showing a detailed configuration of the protective film peeling portion and the polarizing plate attaching portion of FIG. 6 , and the protective film peeling portion and the polarizing plate attaching portion are respectively enlarged and displayed from the upper side of the polarizing plate attaching device. The observed image. Fig. 15 is a view showing a detailed configuration of the protective film peeling portion and the polarizing plate attaching portion of Fig. 6, and is a view for explaining the peeling operation of the protective film peeling portion of Fig. 14. Fig. 16 is a view showing a detailed configuration of the peeling portion of the protective film and the polarizing plate attaching portion of Fig. 6, and is a view showing a detailed configuration of the peeling unit portion of the peeling portion of the protective film of Fig. 14 . Fig. 17 is a view showing a detailed configuration of the protective film peeling portion and the polarizing plate attaching portion of Fig. 6, and is a developed view of a cylindrical suction drum showing a detailed configuration of the polarizing plate attaching portion. FIG. 18 is a view showing a detailed configuration of the protective film peeling portion and the polarizing plate attaching portion of FIG. 6, and is a side view of the vicinity of the adsorption roller in which the polarizing plate of FIG. 14 is attached to the 0 portion from the lower side of FIG. Fig. 19 is a view showing a detailed configuration of a polarizing plate supply table of Fig. 1, and is an enlarged view of the polarizing plate supply table of Fig. 1 and is viewed from the upper side of the polarizing plate attaching device. Fig. 20 is a view showing Fig. 1 The detailed configuration of the polarizing plate supply stage is a side view of the polarizing plate supply stage of FIG. 9 as seen from the lower side of FIG. Fig. 21 is a view showing a state in which each of the adsorption pads is moved by 73 201005355 corresponding to a polarizing plate having a small size. Fig. 22 is a view showing a detailed configuration of the protective film discharge stage of Fig. i. The protective film discharge stage of Fig. 1 is shown enlarged, and is viewed from the upper side of the polarizing plate attaching device. Fig. 23 is a view showing a detailed configuration of the protective film discharge table of Fig. i and a side view of the protective film discharge table of Fig. 22 from the lower end of Fig. 22;

Fig. 24 is a view showing another embodiment of the polarizing plate attaching device of the present invention. Fig. 25 is a view showing a modification of the polarizing plate attaching portion and the protective film peeling portion of the polarizing plate attaching device of the present invention. Fig. 26 is a view showing a schematic configuration of a case where the viscous roller of Fig. 25 is formed in a substantially horizontal state. Fig. 27 is a view showing an example of a polarizing plate attaching device in which an optical film (polarizing plate) of Fig. 26 is attached in a substantially horizontal state. [Main component symbol description] Liquid crystal panel with polarizing plate Liquid crystal panel Adhesive roller protective film Adhesive rubber with adhesive roller 10, 71 10a 11, 12, 15, 16 11a, lib, 11c, lid, lie 13, 14 15 16 74 30 201005355 111, 202, 502, 552, 602 40 41 50, 51, 60, 61 100 110 Protective film peeling mechanism Protective film take-up mechanism Protective film Polarizing plate Liquid crystal panel Supply table Liquid crystal panel conveying part side roller

111&amp;~111 (1, 202 &amp; 〜202 £, 602 &amp; 602 602 "contact roller 112, 203, 503, 553, 615 lower roller 150 substantially vertical conversion portion 151 moving portion main body 152, 153, 710, 711, 8271 Guide rails 154, 155 156, 157 158, 159 160, 161 162, 163 200, 200a 201 204, 205, 603, 604 210 bracket pinion power transmission shaft power transmission circular plate substantially vertical substantially horizontal movable portion polarizing plate attachment table liquid crystal Panel alignment motor (drive power source) housing 75 201005355

300, 350 protective film peeling portion 301 peeling unit portion 310 adhesive tape 311, 312, 313, 314 roller 315 protective film connecting portion 316 pin 317 hole 318 guiding roller 320 peeling unit driving portion 321 chuck 330 polarizing plate guiding portion 331 Roller 332 Roller unit 333 Support frame 400, 450 Polarizing plate attachment portion 410 Adsorption roller 411 Adsorption region 412, 413, 420, 421 Cavity portion 414, 415, 416 Vacuum suction port 417, 418, 419 Suction tube 422 423 stopper member 76 201005355 430, 431 432 433 435 , 436 437 ' 8261 ' 8262 500, 550 closing member rotating shaft ventilation member supporting member pillar polarizing plate upright supply portion 504, 554, 2031, 5031, 5032, 608 motor

505, 555 standing drum 506, 556 conveying roller 507, 509, 510, 557, 559, 560 power transmission light 511, 561 driving motor 512, 562 conduction belt 513, 514, 515, 563, 564, 565 light 524 525, 526 Inflatable pad discharge guide plate with polarizing plate liquid crystal panel conveying portion motor (driving force source) Power transmission mechanism frame mechanism polarizing plate supply table polarizing plate storage 520, 521, 522, 523, 530, 580 600 603, 604 605 , 606 609 ' 610 '611 ' 612 700, 700a, 750, 750a 701, 701a 77 201005355 f

703, 704 up and down moving mechanisms 705, 706 front and rear moving mechanisms 707, 708, 709 pad support frames 800, 800a, 850, 850a protective film discharge table 810 winding buffer portion 811 gas ejection portion 812 exhaust ports 813, 814 820 take-up unit 821 take-up drive unit 822 take-up shaft

823 gas supply unit 824 rotation shaft holding portion 825 protective film holding portion 826 protective film relief portion 827 protective film discharge vehicle 828, 829 rotary gear 830 flow path 831, 832, 833, 834, 835, 836 exhaust port 843 mounting member 900 Liquid crystal panel discharge table 78 201005355 ^ 2023, 2024 conveying mechanism 5021 first side roller 5022 second side roller 5023 belt 5033, 5034, 5533, 5534 conveying belt 702 4822, 7023, 7024, 7025, 7026, 7027, 7028 , 7029, 702a, 702b, 702c ❹ 8251 8252 8263 8264, 8265 8266 Adsorption pad holding table moving part line pulley rotating driving force source

79

Claims (1)

201005355 VII. Application for Patent Fan Yuan·· 1.---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- The inclined film I is described, and the optical film is attached to the display panel. 2. An optical hard to follow, characterized by: The display panel supply mechanism transports the display panel in a state of being inclined at a predetermined angle with respect to the vertical direction. The optical film supply mechanism and the second optical film supply mechanism are disposed along the display panel along the female side. The optical contact film is conveyed in the inclined state at the two-touch position; and the optical film=attachment mechanism is constituted by the first roller mechanism and the second roller mechanism, and the first optical film supply mechanism and the second optical film supply mechanism are held. The optical film supply mechanism transports the one side of the optical film supplied to the first roller mechanism and the second roller mechanism, and presses the optical film toward the display panel side while pressing The first roller mechanism and the second roller mechanism are rotationally moved, and the optical film is attached to both sides of the display panel at almost the same time, wherein the first roller mechanism and the second roller mechanism are opposite to each other with respect to the rotation axis The display panel faces in the inclined state conveyed from the display panel supply mechanism are disposed substantially in parallel. 3. The optical film attaching device according to claim 2, wherein: the first roller mechanism and the second roller mechanism utilize first viscous rubber members and second members disposed on outer peripheral surfaces thereof A viscous rubber member is attached to hold the one-sided side of the optical film. 4. The optical film attaching device according to claim 2, wherein: the first roller mechanism and the second roller mechanism adsorb and hold the optical by a plurality of adsorption holes provided on outer peripheral surfaces thereof One side of the membrane. An optical film attaching apparatus comprising: a display panel supply mechanism that transports the display panel in a substantially horizontal state; the first optical film supply mechanism and the second optical film supply mechanism are along The optical film is conveyed in the substantially horizontal state at the positions on the upper and lower sides of the display panel to be conveyed, and the optical film attaching mechanism is constituted by the first roller mechanism and the second roller mechanism, and is held by the The first optical film supply mechanism and the second optical film are supplied to the G-feeding mechanism to transport the one-side side of the optical film supplied to the first roller mechanism and the second roller mechanism, and face the optical film The display panel side is pressurized, and the first roller mechanism and the second roller mechanism are rotationally moved, and the optical film is attached to both sides of the display panel at substantially the same time, wherein the first The roller mechanism and the second roller mechanism are substantially the same as the display panel surface of the substantially horizontal state conveyed from the display panel supply mechanism by the rotation axis Line mode, the display positions arranged along the upper and lower sides of the panel. The optical film attachment device according to claim 5, wherein: the first roller mechanism and the second roller mechanism utilize a first viscous rubber member and a first surface disposed on an outer circumferential surface thereof A two-adhesive rubber member is attached to hold the one-sided side of the optical mold. 7. The optical film attaching device according to claim 5, wherein: the first roller mechanism and the second roller mechanism adsorb and hold the plurality of adsorption holes provided on an outer circumferential surface thereof One side of the optical film. 8. An optical film attaching device for attaching an optical film to a display panel for transporting and moving, characterized in that the optical film attaching mechanism includes a rotating shaft with respect to the display panel to be transported The cylindrical roller mechanism disposed at least in a substantially parallel manner on one side has a plurality of positions on the outer circumferential surface of the roller mechanism along the linear cavity portion, that is, the position corresponding to the size of the optical film The adsorption boring which adsorbs and holds the vicinity of the front end portion and the rear end portion of the optical film, and presses the roller mechanism while pressing the optical film toward the display panel side. The optical film is attached to the display panel, wherein the linear cavity portion is formed in the cylindrical wall thickness portion and is substantially parallel to the rotation axis. 9. An optical film attaching apparatus comprising: a display panel supply mechanism 'transporting a display panel in a substantially vertical state; a first optical film supply mechanism and a second optical film supply mechanism; Moving 82 201005355 r The left and right sides of the display panel are conveyed to convey the optical film in a substantially vertical state; the optical film attaching mechanism is rolled by the first cylindrical roller mechanism and the second circular shape According to the mechanism, the outer circumferential surface of the first circularly-shaped roller mechanism and the second cylindrical roller mechanism along the linear cavity portion, that is, the position corresponding to the size of the optical film a plurality of front ends of the optical film to be transported and supplied to the first cylindrical roll mechanism and the second cylindrical roll mechanism from the first optical film supply mechanism and the second optical film supply mechanism The adsorption film is adsorbed and held on one side of the rear end portion, and the optical film is applied to the optical film by the first cylindrical roller mechanism and the second cylindrical roller mechanism. The first cylindrical drum mechanism and the second cylindrical drum mechanism are rotationally moved while being pressed toward the display panel side, and the optical film is attached to the display panel almost simultaneously. On both surfaces, the first cylindrical drum mechanism and the second cylindrical drum mechanism are substantially parallel to each other with respect to the display panel surface conveyed from the display panel supply mechanism. Arranging that the linear cavity portion is formed in a wall thickness portion of the first cylindrical roller mechanism and the second cylindrical roller mechanism and substantially parallel to the rotation axis; and the display panel discharge mechanism 'will The display panel is discharged in a substantially vertical state in which the optical film is attached to both surfaces in accordance with the optical film attaching operation of the optical film attaching mechanism. 10. The optical film attaching device according to claim 8 or claim 9, wherein: 83 201005355 mechanism joint = retaining r adsorption is maintained at __ The optical film attaching mechanism is configured as follows, that is, having at least Two cavity portions are used as the adsorption holes for gripping the optical front end portion, and in the two cavity portions, the optical film is first adsorbed and held in the cavity portion The opening area of the adsorption hole on the outer peripheral side is larger than the opening area of the other adsorption hole. An optical film attaching apparatus comprising: a display panel supply mechanism that transports a display panel conveyed in a substantially horizontal state in a substantially vertical state; the first optical film supply mechanism and the first optical film supply mechanism The optical film supply mechanism conveys the optical film placed in a substantially horizontal state in a substantially vertical state on the left and right sides of the display panel to be conveyed; a cylindrical shape roller mechanism and a second cylindrical roller mechanism, and the outer circumferential surfaces of the first cylindrical roller mechanism and the second cylindrical roller mechanism along the linear cavity portion, that is, The position corresponding to the unrecognized size includes a plurality of pairs of the first optical tube supply mechanism and the second optical film supply mechanism, and is supplied to the first-is-tube-shaped roller mechanism and the second cylindrical shape. The first cylindrical roller mechanism and the second cylindrical shape are used for the adsorption hole that is adsorbed and held by the one end side of the optical film in the vicinity of the front end portion and the rear end portion of the optical film. a drum mechanism that rotates the optical film toward the display panel side to rotate the first cylindrical roller mechanism and the second cylindrical roller mechanism, and the optical film is almost At the same time, it is attached to both sides of the 84 201005355 'display panel, wherein the first cylindrical shape roller mechanism and the second cylindrical shape roller mechanism are rotated with respect to the supply from the display panel feeder. The display panel surface is arranged substantially parallel to each other. The linear cavity portion is formed in a wall thickness portion of the first cylindrical roller mechanism and the second cylindrical roller mechanism. The rotation axis is substantially parallel; the first peeling mechanism and the second peeling mechanism peel the protective film from the optical film of the first cylindrical shape roller mechanism and the second cylindrical roller mechanism on the second cylindrical roller mechanism; The mechanism discharges the display panel in a substantially vertical state in which the optical film is attached to the optical film in accordance with the attaching operation of the optical film. An optical film attaching apparatus comprising: a display panel supply mechanism that lifts the display panel while transporting the display panel that is transported in a substantially horizontal state in the transport direction The first optical film supply mechanism and the second optical film supply mechanism erect the optical film placed in a substantially horizontal state in a substantially vertical state; ^The optical film attaching mechanism is formed by the first circle The tubular shape roller mechanism and the second circularly-opening type drum mechanism are configured to surround the outer circumferential surfaces of the first cylindrical roller mechanism and the second cylindrical roller mechanism along the linear cavity portion, that is, a position corresponding to the size of the optical film, and a plurality of pairs are transported and supplied from the first optical film supply mechanism and the second optical film supply mechanism to the first cylindrical roller mechanism and the second cylinder In the case of the shape roller mechanism, the first cylindrical shape is used for the adsorption hole that is adsorbed and held on one side of the front end portion and the rear end portion of the optical film. The tubular mechanism and the second cylindrical roller mechanism rotate the optical film toward the display panel side while rotating the first cylindrical roller mechanism and the second cylindrical roller mechanism. The optical film is attached to both sides of the display panel at substantially the same time, wherein the first cylindrical shape roller mechanism and the second cylindrical shape rolling mechanism are supplied with respect to the display panel from the rotation axis The display panel surface that is transported by the mechanism is disposed substantially parallel to each other. The linear cavity portion is formed in a wall thickness portion of the first cylindrical roller mechanism and the second cylindrical roller mechanism. And being substantially parallel to the rotating shaft; the first peeling mechanism and the second peeling mechanism peeling off the protective film from the optical film adsorbed and held by the first cylindrical roller mechanism and the second cylindrical roller mechanism; a film discharge mechanism that winds the protective film peeled off by the first peeling mechanism and the second peeling mechanism, and discharges the protective film in a state of being wound up; And the display panel discharge mechanism, the display panel for receiving the optical film attachment mechanism corresponding to the optical film attachment mechanism and the substantially vertical state in which the optical film is attached to the optical film from the optical film attachment mechanism While the display panel is being transported in the transport direction, it is converted from a substantially vertical state to a substantially horizontal state and then discharged. 13. An optical film attaching apparatus comprising: a display panel supply mechanism, wherein a display panel conveyed in a horizontal state in a transport direction of the large 86 201005355 f is transported while being transported The display panel alignment mechanism is configured to convey the display panel in a substantially vertical state by using the side panel transport mechanism and the lower transport mechanism, and attach it to the front side at the same time. Positioning between the optical film on both sides of the display panel and the display panel, wherein the side transfer mechanism is provided for the display in a substantially vertical state from the display panel supply mechanism The two sides of the panel are provided in contact with each other, and the lower conveying mechanism is provided in contact with the lower end portion of the display panel; the first optical film supply mechanism and the second optical film supply mechanism are substantially The optical film placed in the horizontal state is erected to be conveyed in a substantially vertical state; the optical film attaching mechanism is formed by the first cylindrical shape a roller mechanism and a second circular shape roller mechanism, wherein the outer circumferential surface of the first cylindrical roller mechanism and the second cylindrical roller mechanism along the linear cavity portion, 0, and the optical a position corresponding to the size of the film, and a plurality of pairs of the first optical film supply mechanism and the second optical yoke supply mechanism are transported and supplied to the first cylindrical roller mechanism and the second cylindrical roller mechanism. The first film-shaped roller mechanism and the second cylindrical-shaped roller mechanism are used to face the optical film by the adsorption hole that is adsorbed and held on one side of the front end portion and the rear end portion of the optical film. In the display, the first cylindrical drum mechanism and the second cylindrical drum mechanism are rotationally moved while being pressed by the panel side, and the optical film is attached to the 87 at the same time. On both sides, the first cylindrical roller mechanism and the second cylindrical roller mechanism are rotated by the rotation axis with respect to the display from the display panel supply mechanism Substantially parallel to the panel surface is arranged, the cavity portion is formed in the straight portion of the first cylindrical wall thickness of the roller mechanism and the second cylindrical roller mechanism and substantially parallel to the rotation axis; ❹ the first peeling mechanism and the second peeling mechanism peeling the protective film from the optical film adsorbed and held by the first cylindrical roll mechanism and the second cylindrical roll mechanism; the protective film discharge mechanism The protective film peeled off by the first peeling mechanism and the second peeling mechanism is wound up, and the protective film is discharged in a wound state; 'The optical film display panel transfer mechanism is attached from the optical film The mechanism receives the display panel corresponding to the optical film attaching operation of the optical film attaching mechanism and adheres to the optical film in a substantially vertical state on both sides, and faces the display panel in the transport direction. In the transport direction, the optical panel supplied from the optical film display panel transport mechanism in a substantially vertical state is transported in the transport direction, and the surface is transported. The vertical state is changed to a substantially horizontal state and then discharged. 14. The optical film attaching device according to any one of the preceding claims, wherein the optical film attaching mechanism is configured as follows, having at least two 88 201005355 if cavity portions as An adsorption hole for adsorbing and holding the front end portion of the optical film, and the first of the two cavity portions for adsorbing and holding the optical film is placed on the outer peripheral side surface of the cavity portion The opening area of the adsorption hole is larger than the opening area of the other adsorption hole. 15. An optical film attaching apparatus comprising: a display panel supply mechanism that transports a display panel in a substantially vertical state; a first optical film supply mechanism and a second optical film supply mechanism; The optical film is conveyed substantially vertically in the left and right sides of the display panel to be transported, and the optical film attaching mechanism uses the first cylindrical roller mechanism and the second cylindrical roller mechanism The first cylindrical roll mechanism and the second cylindrical roll mechanism are rotationally moved while the optical film is pressed toward the display panel side, and the optical film is attached at almost the same time. On both surfaces of the display panel, the first cylindrical roller mechanism and the second cylindrical roller mechanism are rotated by the rotation axis with respect to the display from the display panel supply mechanism. The panel faces are arranged in a substantially parallel manner and are sized such that the optical film can be wound without overlapping the front end portion and the rear end portion of the optical film; Panel shows discharging means, corresponding to the operation of the optical film is attached to the attaching means of the optical film and the double-sided attached substantially perpendicular to the optical state of discharge display panel film. B-- an optical film attaching device for attaching an optical film to a display panel for transporting and moving, characterized in that: 89 201005355 if the optical film attaching mechanism includes a rotating shaft with respect to the display Face (4) at least one side of the substantially parallel side of the arrangement = the cylinder mechanism 'on the outer peripheral surface of the roller mechanism is provided with a miscellaneous member that is held tightly against the light" - facing the county purchase direction = display panel The side is pressurized, and the roller mechanism is rotated to attach the optical film to the display panel. 17. An optical film attachment device characterized by comprising The display panel supply mechanism transports the display panel in a substantially vertical state; the first optical film supply mechanism and the second optical film supply mechanism carry the optical film on the left and right sides of the displayed display panel The optical film attaching mechanism ' is disposed first in a state in which the rotational axis is substantially parallel to the display panel surface that is transported from the display panel supply mechanism. The roller mechanism and the second roller mechanism include a first viscous rubber member and a second viscous rubber member that respectively hold the first optical film and the second optical film in contact with each other on an outer circumferential surface of the roller mechanism. The first optical film and the second optical film are pressed toward the display panel side, and the first roller mechanism and the second roller mechanism are rotated to thereby form the first optical film and The second optical film is attached to both sides of the display panel almost simultaneously. 18. The optical film attachment device of claim 16, wherein: the peeling mechanism comprises a peeling mechanism for peeling off the protective film from the optical film held against the member of the viscous rubber 201005355. 19. An optical film attaching method, wherein an optical film is attached to a conveyed display panel, wherein the optical film is adhered to a viscous rubber member, and an optical film is faced The display panel side is pressurized, and the roller mechanism is rotated, thereby attaching the optical film to the display panel, wherein the viscous rubber member is disposed on a rotating axis relative to the The outer peripheral surface of the roller mechanism which is disposed so that at least one surface of the display panel that is moved is substantially parallel. 20. The optical film attachment method of the first optical film and the second optical film which are supplied in a substantially vertical state in the left and right sides of the display panel which is transported and moved in a state of being substantially vertically erected Attached to both sides of the display panel at the same time, the first optical film and the second optical film are closely held on the first viscous rubber member and the second viscous rubber member, Facing the first optical film and the second optical film, the first optical film and the second optical film are pressed toward the display panel side, and the first roller mechanism and the second roller mechanism are rotated, whereby the first optical film and the first optical film are The second precursor film is attached to both sides of the display panel at substantially the same time, wherein the first viscous rubber member and the second viscous rubber member are disposed on the display for moving with respect to the conveyance axis by the rotation axis The outer peripheral surfaces of the first roller mechanism and the second roller mechanism are disposed such that the left and right sides Φ of the panel are substantially parallel. The optical film attaching method according to claim 19, wherein: 201005355 f peels the protective film from the optical film held tightly on the viscous rubber member. A manufacturing method of a panel for display, characterized in that: film attachment === optical 7-arrangement according to any one of items 1 to 18, or optical as described in claim 19 to 2 Membrane attachment method to attach the optical chess stick to the display 92