TW202246861A - Continuous inspection method of optical display panel, continuous inspection device, continuous manufacturing method of optical display panel and continuous manufacturing system - Google Patents

Abstract

The present invention provides a continuous inspection method and a continuous inspection apparatus for optical display panels, with which defects can be detected with the same or higher accuracy even if the number of imaging units is reduced in comparison with the prior art. The continuous inspection method for optical display panels includes: a first irradiation step for irradiating a line inspection region of the optical display panel with a first linear light parallel to the width direction of the optical display panel from the direction perpendicular to one surface of the optical display panel and inclined for a first angle toward the upstream side in the conveyance direction, wherein the width direction is perpendicular to the conveyance direction of the optical display panel; a second irradiation step for irradiating the line inspection region with a second linear light parallel to the width direction of the optical display panel from the direction perpendicular to one surface of the optical display panel and inclined for a second angle toward the downstream side in the conveyance direction; and an imaging step for using one imaging unit to continuously photograph the line inspection region irradiated by the first linear light and the second linear light linearly parallel to the width direction of the optical display panel.

Description

Continuous inspection method and continuous inspection device for optical display panel, and continuous manufacturing method and continuous manufacturing system for optical display panel

field of invention The invention relates to a continuous inspection method and a continuous inspection device of an optical display panel, as well as a continuous manufacturing method and a continuous manufacturing system of the optical display panel.

Background of the invention The inspection method of Patent Document 1 discloses that linear light parallel to the width direction of the conveying device is irradiated vertically from one side of the liquid crystal display panel, and images are captured by two imaging units on the other side of the liquid crystal display panel. In the region irradiated with linear light, the two imaging units are arranged symmetrically on the other side of the liquid crystal display panel at positions inclined by a predetermined angle relative to the direction of irradiation of the panel in the direction of conveyance of the panel and in the direction opposite thereto.

Patent Document 1: Japanese Patent Laid-Open No. 2012-194509

Summary of the invention The problem to be solved by the invention In the inspection method of Patent Document 1, two imaging units that photograph the inspection area from two different angles are provided, and one of the two imaging units detects the light that does not scatter strongly toward the downstream side of the transport direction with respect to the irradiation direction. Foreign objects that strongly scatter upstream are detected by the other of the two imaging units that do not scatter strongly upstream but strongly scatter downstream. That is, since there are defects (foreign objects) that can only be detected by the first imaging unit on the upstream side in the conveying direction and defects (foreign objects) that can only be detected by the second imaging unit on the downstream side in the conveying direction, two imaging units need to be arranged.

However, equipment costs increase due to the arrangement of a plurality of imaging units. In addition, the time for adjusting the optical axis of the imaging unit also becomes longer in proportion to the number of imaging units. The capacity of the storage medium required to store the captured image data for a long time also increases in proportion to the number of units. In addition, in the inspection method of Patent Document 1, it is necessary to perform image processing on the two image data obtained by the two imaging units, and then match the defect positions and coordinates obtained based on each image data to create a Single defect information.

Therefore, an object of the present invention is to provide a continuous inspection method of an optical display panel and a continuous inspection device thereof that can detect flaws with the same or higher accuracy even if the number of imaging units is reduced compared to conventional ones. Another object of the present invention is to provide a continuous production system for optical display panels capable of continuously producing high-quality optical display panels at high speed and a continuous production system for optical display panels by performing optical inspections with high precision while conveying the optical display panels at high speed. Production method. means for solving problems

As a result of repeated studies in order to solve the above-mentioned problems, the following invention has been completed.

The present invention is a method for continuously inspecting an optical display panel. The optical display panel is continuously inspected optically while the optical display panel is being transported. Both sides or one side of the aforementioned optical display panel are provided with a film having at least an optical function. The optical film of the aforementioned optical display panel comprises the following steps: In the first irradiation step, a first irradiation unit that irradiates first linear light parallel to the width direction of the optical display panel is used, and is inclined to the upstream side of the conveying direction (d1) by a second angle from one surface perpendicular to the optical display panel. In the direction of an angle (θ1), the first linear light is irradiated to the line inspection area of the optical display panel being transported, and the width direction of the optical display panel is perpendicular to the transport direction (d1) of the optical display panel direction(d2); In the second irradiation step, using a second irradiation unit that irradiates a second linear light parallel to the width direction of the optical display panel, the second irradiation part is inclined to the downstream side of the conveying direction (d1) from one surface perpendicular to the optical display panel by a second direction. In the direction of two angles (θ2), the second linear light is irradiated to the aforementioned line inspection area of the optical display panel being transported, and the width direction of the optical display panel is perpendicular to the transport direction (d1) of the optical display panel. the direction of (d2); and In the imaging step, an imaging unit is used to scan the line parallel to the width direction of the optical display panel from the other side of the optical display panel to the line inspection area irradiated by the first linear light and the second linear light. shooting continuously.

In the above invention, in the imaging step, the line inspection area may be imaged from the other surface of the optical display panel through a slit portion defining an imaging area corresponding to the line inspection area.

In the above invention, the imaging unit may be arranged in a direction perpendicular to the other surface of the optical display panel.

In the above invention, in the first irradiation step and the second irradiation step, the first angle (θ1) and the second angle (θ2) may have the same value, and the first linear light may be The irradiation direction is symmetrical to the irradiation direction of the aforementioned second linear light.

In the above invention, when the optical display panel is continuously optically inspected while the optical display panel with the optical film provided on one side is being transported, an inspection filter is arranged and photographed, and the inspection filter It has an optical axis corresponding to the optical axis of the optical functional film included in the optical film, and the inspection filter is arranged between the first irradiation unit, the second irradiation unit, and the one imaging unit, and is arranged from the optical The other side of the display panel which is different from the side provided with the aforementioned optical film is separated by a predetermined distance. The "predetermined distance" needs to be, for example, a distance that does not touch the surface of the optical display panel, and can be set in consideration of the arrangement relationship of the panel conveyance unit, illuminating unit (for example, a first illuminating unit, a second illuminating unit), and an imaging unit. When the optically functional film has a polarizing film, the inspection filter has a polarizing film, and the inspection filters are arranged such that their absorption axes are in a mutually orthogonal arrangement relationship. In addition, the inspection filter may be fixedly arranged, or may be configured to be movable according to the transport state of the optical display panel.

Another invention is a continuous inspection device for an optical display panel, wherein the optical display panel is continuously inspected optically while the optical display panel is being transported, and both sides or one side of the aforementioned optical display panel are provided with at least The optical film of the film, the aforementioned continuous inspection device for the optical display panel has: The first irradiating unit is configured to irradiate and irradiate the line inspection area of the optical display panel being transported in a direction inclined by a first angle (θ1) to the upstream side of the transport direction (d1) from the side perpendicular to the optical display panel. The first linear light parallel to the width direction of the optical display panel, the width direction of the optical display panel is a direction (d2) orthogonal to the conveying direction (d1) of the optical display panel; The second irradiating unit irradiates the line inspection area of the optical display panel being transported in a direction inclined at a second angle (θ2) to the downstream side of the transport direction (d1) from perpendicular to one surface of the optical display panel. second linear light parallel to the width direction of the optical display panel, the width direction of the optical display panel being a direction (d2) orthogonal to the conveying direction (d1) of the optical display panel; and An imaging unit, which is continuous in a line parallel to the width direction of the optical display panel, from the other side of the optical display panel to the line inspection region irradiated with the first linear light and the second linear light. to shoot.

In the above invention, it may further include a slit portion disposed on the other side of the optical display panel and defining an imaging area corresponding to the line inspection area. The imaging unit may perform imaging via the slit.

In the present invention, "one imaging unit" may be a single-eye imaging unit or a compound-eye imaging unit. Corresponding to a predetermined linear imaging area (a fixed area parallel to the film width direction), a plurality of line sensor cameras (line sensor cameras) arranged in a line and arranged in a straight line (one row) may also be used. Monocular camera composition.

In the above invention, the imaging unit may be arranged in a direction perpendicular to the other surface of the optical display panel.

In the above invention, the first irradiating unit and the second irradiating unit may be arranged so that the first angle (θ1) and the second angle (θ2) have the same value, and the first linear light The irradiation direction is symmetrical to the irradiation direction of the aforementioned second linear light.

In the above invention, there is further provided an inspection filter provided so that when the optical display panel is continuously optically inspected while the optical display panel having the optical film provided on one side is being conveyed, the A predetermined distance is set between the first and second irradiating parts and the aforementioned one imaging part, and between the other side of the optical display panel that is different from the side on which the aforementioned optical film is provided, and is compatible with the optical function included in the aforementioned optical film. The optical axes of the films form a predetermined arrangement relationship. The "predetermined distance" needs to be, for example, a distance that does not touch the surface of the optical display panel, and can be set in consideration of the arrangement relationship of the panel conveyance unit, illuminating unit (for example, a first illuminating unit, a second illuminating unit), and an imaging unit. When the optically functional film has a polarizing film, the inspection filter has a polarizing film, and the inspection filters are arranged such that their absorption axes are in a mutually orthogonal arrangement relationship. In addition, the inspection filter may be fixedly arranged, or may be configured to be movable according to the transport state of the optical display panel. When the bright part, the optical display panel with the optical film provided on the illuminating part side, and the imaging part are arranged in this order, the inspection filter is arranged between the optical display panel and the imaging part. When a slit is disposed between the optical display panel and the imaging unit, the inspection filter may be disposed between the imaging unit and the slit, or between the optical display panel and the slit. When the bright part, the optical display panel with the optical film provided on the imaging part side, and the imaging part are arranged in this order, the inspection filter is arranged between the illuminating part and the optical display panel, so that the illumination light passes through the inspection. The light obtained after applying the filter is incident on the inspection area.

According to the present invention, inspection capability can be ensured and the number of imaging units can be reduced by a simple configuration in which only two illumination processes and one imaging process are performed. In addition, by processing the image data obtained from a single imaging unit, it is possible to determine defects that can only be detected by the imaging unit on the upstream side of the conveying direction, and defects that can only be detected by the imaging unit on the downstream side of the conveying direction. Detected defects. There is no need to perform image processing on two pieces of image data acquired by two imaging units to create a single piece of defect information as in the past, and the work and complexity for this can be reduced.

In addition, in the present invention, the aforementioned slit portion disposed on the other side of the optical display panel is preferably such that the distance (D1) from the other surface of the optical display panel to the slit portion is smaller than the distance (D2) from the imaging portion to the slit portion. The slits are arranged such that (D1<D2). Rather than disposing the slit near the imaging unit, it is better to arrange the slit near the optical display panel (for example, D1 is more than 0 mm to within 150 mm, preferably within 100 mm, more preferably within 30 mm). By arranging the slit near the optical display panel, it is possible to prevent the influence of stray light (or reflected light) from the edge of the optical display panel when the optical display panel enters or leaves the imaging field of view of the imaging unit. cannot be checked. Also, disposing the slit in the vicinity of the imaging unit is not preferable because the amount of light received by the imaging unit itself is reduced or limited.

The continuous manufacturing method of an optical display panel of another invention includes the following steps: a manufacturing step of attaching a first optical film having at least an optical functional film to the first surface of an optical unit, and attaching a second optical film having at least an optical functional film bonded to the second surface of the optical unit to manufacture an optical display panel; and The steps involved in the aforementioned continuous inspection method for optical display panels, Wherein, the steps included in the aforementioned manufacturing steps and the aforementioned continuous inspection method are performed by a series of transport devices for transporting the aforementioned optical units and the aforementioned optical display panels.

A continuous manufacturing system for an optical display panel according to another invention includes: a manufacturing device for bonding a first optical film having at least an optical functional film to a first surface of an optical unit, and bonding a second optical film having at least an optical functional film. combined with the second side of the optical unit to produce an optical display panel; and A continuous inspection device for the aforementioned optical display panel, Wherein, the aforementioned manufacturing device and the aforementioned continuous inspection device are configured in a series of transporting devices for transporting the aforementioned optical unit and the aforementioned optical display panel.

In the aforementioned manufacturing step and manufacturing apparatus of the above-mentioned invention, it may also be: The single-sheet-shaped first optical film obtained by cutting the first elongated optical film while feeding out the first elongated release film and the first elongated optical film from the first optical film roll is attached to the conveyed the aforementioned first surface of the aforementioned optical unit, or attaching a single-piece first optical film to the first surface of the aforementioned optical unit; and/or The second optical film obtained by cutting the second elongated optical film from the roll of the second optical film while feeding out the second elongated release film and the second elongated optical film is separated from the first optical film. The optical axis of the optical axis of the aforementioned second optical film and the optical axis of the aforementioned second optical film are attached to the aforementioned second surface of the transported aforementioned optical unit, or the single-sheet second optical film is attached to the aforementioned second surface of the single-sheet-shaped second optical film. The optical axis of an optical film and the optical axis of the single-piece second optical film are arranged at a predetermined angle and attached to the second surface of the optical unit.

According to the aforementioned configuration, the optical display panel is irradiated with two types of linear light (L1, L2) inclined at a predetermined angle while the optical display panel is being conveyed, and the transmitted light (P ) is linearly and continuously photographed, whereby the optical display panel can be transported at high speed, and the foreign matter mixed between the optical unit and the optical film can be photographed on the entire surface of the optical display panel with a clear contrast. That is, since the optical display panel can be inspected with high precision while transporting the optical display panel at high speed, high-quality optical display panels can be continuously produced at high speed.

In addition, in the aforementioned inspection, not only foreign objects mixed between the optical unit and the optical film (such as bonding air bubbles, broken glass, thread ends, dirt, dust, etc.) can be detected with high precision, but also dirt can be detected with high precision Wait.

The irradiating directions of the first and second irradiating units irradiating the first and second linear lights are respectively inclined at predetermined angles from the vertical to the optical display panel, so the linear light for one can be simultaneously detected by a single imaging unit. The direction of light irradiation does not strongly scatter toward the downstream side of the conveying direction but strongly scatters toward the upstream side, and the foreign matter does not strongly scatter toward the upstream side but strongly scatteres toward the downstream side, so the optical Check the display panel.

In addition, from the viewpoint of inspecting the optical display panel with high precision, the aforementioned first angle (θ1) is 1° to 60° from the vertical, preferably 5° to 45°, more preferably 10° to 30° . In addition, the aforementioned second angle (θ2) is 1°-60° relative to the vertical, preferably 5°-45°, and more preferably 10°-30°.

In the present invention, the "optical film roll" is a roll formed by laminating a long release film and a long optical film (adhesive layer, optical functional film, and surface protection film) in the order described above. "Roll-to-panel method" is to cut the adhesive layer, optical functional film and surface protection film along the width direction for the release film and long optical film released from the optical film roll (half-cut : Half-cut), a method in which the long release film is peeled off from the single-sheet optical film obtained by cutting, and the single-sheet optical film is bonded to the optical unit through the exposed adhesive layer.

On the other hand, there is a "sheet-to-panel method" as an optical film bonding method different from the roll-to-panel method. "Sheet-to-panel method" is to attach a single-piece optical film formed in a single-piece state to an optical unit through an adhesive layer that is exposed by peeling off a single-piece release film or a long release film. The way. "Optical film roll with slits" refers to a roll in which a single optical film (adhesive layer, optical functional film, and surface protection film) is laminated on a long release film.

form for carrying out the invention Hereinafter, although the continuous manufacturing system and continuous manufacturing method of an optical display panel are demonstrated more concretely with reference to FIG. 1, this invention is not limited to the aspect of this embodiment. (Embodiment 1)

The optical display panel is a liquid crystal display panel, the optical cell is a liquid crystal cell, and the optical film is a polarizing film.

The continuous manufacturing system of liquid crystal display panels has a continuous manufacturing apparatus 100 . The continuous production apparatus 100 cuts the first long polarizing film 11 from the first optical film roll R1 while feeding out the first long release film 12 and the first long polarizing film 11. A polarizing film 111 is attached to the first surface 4 a of the liquid crystal cell 4 . Alternatively, the continuous manufacturing apparatus 100 cuts the second elongated polarizing film 21 from the second optical film roll R2 while feeding out the second elongated release film 22 and the second elongated polarizing film 21. Two monolithic polarizing films 211 are attached to the second surface 4b of the liquid crystal cell 4 in such a way that the absorption axis of the first monolithic polarizing film 111 and the absorption axis of the second monolithic polarizing film 211 are perpendicular to each other, thereby manufacturing LCD panel Y.

The continuous manufacturing system of the liquid crystal display panel has the continuous inspection apparatus 300 which optically inspects the liquid crystal display panel Y while conveying the liquid crystal display panel Y. The continuous manufacturing system of the liquid crystal display panel arranges the continuous manufacturing apparatus 100 and the continuous inspection apparatus 300 in a series of conveying apparatus 400 for conveying the liquid crystal cell 4 and the liquid crystal display panel Y. (optical film roll)

As an optical film roll formed by winding a long polarizing film, for example, (1) a continuous strip (web) of a long polarizing film having a release film and an adhesive layer formed on the release film The elongated optical film laminate in the form is rolled into a roll-shaped optical film roll. In this case, the continuous manufacturing system of the liquid crystal display panel has a cutting device (for forming a cut-in line) in order to form a single polarizing film (sheet) from a long polarizing film, and the cutting device leaves the release film On the other hand, the long polarizing film (including the adhesive layer) is cut (halved) at predetermined intervals in a direction perpendicular to the feeding direction of the release film. In addition, examples of optical film rolls include (2) optical film rolls in which a long optical film laminate having a release film and a single-sheet polarizing film (including an adhesive layer) is rolled into a roll (so-called The polarizing film roll containing slits), the above-mentioned single-sheet polarizing film is adjacent to each other in the direction perpendicular to the feeding direction of the release film across the incision line on the release film.

The first optical film roll R1 shown in FIG. 1 is formed by rolling the first elongated optical film laminate 10 into a roll shape. The first elongated optical film laminate 10 has a first elongated release film 12, And the first elongated polarizing film (including the aforementioned adhesive layer) 11 having an absorption axis parallel to the feed direction (longitudinal direction) formed on the first elongated release film 12 via an adhesive layer. The second optical film roll R2 is formed by rolling the second elongated optical film laminate 20 into a roll shape. The second elongated optical film laminate 20 has a second elongated release film 22 and an adhesive A second elongated polarizing film (including the aforementioned adhesive layer) 21 having an absorption axis parallel to the feed direction (longitudinal direction) is formed on the second elongated release film 22 .

The first and second elongated polarizing films 11 and 21 are, for example, separated by a polarizer (about 5-80 μm in thickness) and a polarizer protective film (generally about 1-500 μm in thickness) formed on one or both sides of the polarizer. Formed with an adhesive, or formed without an adhesive (such as a self-adhesive polarizer protective film). Examples of other films constituting the first and second elongated polarizing films 11 and 21 include retardation films (generally 10 to 200 μm in thickness), viewing angle compensation films, brightness enhancement films, and surface protection films. The thicknesses of the first and second elongated polarizing films 11 and 21 are, for example, in the range of 10 μm to 500 μm.

The adhesives constituting the adhesive layers of the first and second elongated polarizing films 11 and 21 are not particularly limited, and examples thereof include acrylic adhesives, silicone adhesives, and polyurethane adhesives. The thickness of the adhesive layer is preferably in the range of, for example, 10 to 50 μm. As the first and second release films 12 and 22 , conventionally known films such as plastic films (for example, polyethylene terephthalate films, polyolefin films, etc.) can be used. In addition, a film coated with a suitable release agent such as polysiloxane-based, long-chain alkyl-based, fluorine-based, or molybdenum sulfide can also be used as appropriate according to conventional standards, as needed. (LCD panel)

The liquid crystal display panel Y is obtained by forming at least a polarizing film on one or both sides of the liquid crystal cell 4, and a driving circuit may be incorporated as required. For the liquid crystal cell 4 , any type of liquid crystal cell such as a vertical alignment (VA) type or an in-plane switching (IPS) type can be used. The liquid crystal cell 4 has a structure in which a liquid crystal layer is sealed between a pair of opposing substrates (first substrate 4 a, second substrate 4 b ). (Continuous Manufacturing Equipment)

The continuous manufacturing apparatus 100 has a first release film conveying device 101 , a first attaching unit 102 , a second release film conveying device 103 , and a second attaching unit 104 .

The first release film conveying device 101 feeds out the first elongated release film 12 and the first elongated polarizing film 11 (the first elongated optical film laminate 10) from the first optical film roll R1 to the first sticking film. Section 102 delivers. In this embodiment, the first release film conveying device 101 has a first cutting unit 31 , a first dancer roll 32 , a first peeling unit 41 , and a first winding unit 61 .

The first cutting part 31 fixes the first elongated optical film laminate 10 in advance from the first release film 12 side by the first adsorption part 31a, and leaves the first elongated release film to separate the first elongated film. The polarizing film (including the adhesive layer) 11 is cut in its width direction, and the first single-sheet polarizing film 111 is formed on the first elongated release film 12 . As the 1st cutting part 31, a cutter, a laser device, etc. are mentioned, for example. As the first adsorption part 31a, for example, an adsorption plate having many holes connected to a vacuum pump and capable of sucking air from the holes by negative pressure may be used.

The first adjusting tension roller 32 has a function of maintaining the tension of the first long release film 12 .

The first peeling part 41 folds the first elongated release film 12 inside at its front end, and peels the first single-sheet polarizing film 111 from the first elongated release film 12 . The peeled first single-sheet polarizing film 111 is supplied to the first attaching unit 102 . In this embodiment, as the first peeling part 41, a sharp edge part is used at the front end part, but it is not limited to this.

The first take-up unit 61 is used to take up the first elongated release film 12 from which the first single-sheet polarizing film 111 has been peeled off. The first take-up unit 61 may also be constituted by a self-rotating roller.

The first attaching unit 102 applies the first single-sheet polarizing film after the first elongated release film 12 has been peeled off by the first peeling unit 41 from the upper side (first surface 4a) of the liquid crystal cell 4 conveyed by the conveying device 400. 111 is attached through the adhesive layer. In this embodiment, the first sticking unit 102 is composed of a first sticking roller 51a and a first driving roller 51b.

Various means for sticking the second single-sheet polarizing film 211 on the other surface (second surface 4 b ) of the liquid crystal cell 4 can use the various components, devices, and the like described above. The second release film conveying device 103 releases the second elongated release film 22 and the second elongated polarizing film 21 (the second elongated optical film laminate 20) from the second optical film roll R2 to the second sticking film. Section 104 delivers. In this embodiment, the 2nd release film conveyance apparatus 103 has the 2nd cutting part 33, the 2nd tension adjustment roller 34, the 2nd peeling part 42, and the 2nd winding part 62. The second release film conveying device 103 can be constituted by the same device as the first release film conveying device 101 , and the second sticking unit 104 can be constituted by the same device as the first sticking unit 102 . For example, the second cutting part 33 and the second adsorption part 33a can be constituted by the same device as the first cutting part 31 and the first adsorption part 31a. The second tension adjustment roller 34 can be constituted by the same device as the first tension adjustment roller 32 . The second winding unit 62 can be constituted by the same device as that of the first winding unit 61 . The second bonding roller 52a and the second driving roller 52b can be configured by the same mechanism as the first bonding roller 51a and the first driving roller 51b. (irradiation department)

The continuous inspection apparatus 300 has a first irradiation unit 311 that is inclined at a first angle θ1 to the upstream side of the transport direction from being perpendicular to one surface of the liquid crystal display panel Y (the first surface 4a in FIG. 3 ). The direction of the line inspection area E (refer to FIG. 3 ) of the liquid crystal display panel Y being transported is irradiated with the first linear light L1 parallel to the width direction d2 (vertical direction of the paper surface of FIG. 3 ) of the liquid crystal display panel Y. The width direction d2 of the display panel Y is a direction perpendicular to the conveyance direction d1 of the liquid crystal display panel Y.

In addition, the continuous inspection apparatus 300 has a second irradiation unit 312 that is inclined by a second angle to the downstream side of the conveying direction from being perpendicular to one surface of the liquid crystal display panel Y (the first surface 4a in FIG. 3 ). In the direction of angle θ2, the second linear light L2 parallel to the width direction of the liquid crystal display panel Y is irradiated to the line inspection region E of the liquid crystal display panel Y being transported. The conveying direction d1 is orthogonal to the direction d2.

In the present embodiment, the first angle θ1 and the second angle θ2 have the same value and are set to 17°. In addition, in this embodiment, the first irradiating unit 311 and the second irradiating unit 312 are arranged such that the irradiating direction of the first linear light L1 is symmetrical to the irradiating direction of the second linear light L2 . The first angle θ1 and the second angle θ2 are not limited to 17°, and may be 5°-30°, preferably 10°-30°.

The first and second illuminating units 311 and 312 are not particularly limited as long as they radiate straight-forward first and second linear lights L1 and L2, and examples thereof include halogen lamps, metal halide lamps, and LED linear lighting. . In addition, the first and second linear lights L1 and L2 are lights that extend linearly along the width direction d2 of the conveying device 400 , and the short-side direction of the first and second linear lights L1 and L2 (compared to the direction of the conveying device 400 The width in the direction parallel to the conveyance direction d1) is shorter than the length in the conveyance direction of the liquid crystal display panel Y. In addition, the first and second irradiation units 311 and 312 may include a lens unit for narrowing the width of the first and second linear lights L1 and L2 in the short-side direction. As the lens portion, for example, a round rod-shaped lens formed along the longitudinal direction of the first and second linear lights L1 and L2 is exemplified. It is desirable to condense the first and second linear lights L1 and L2 by narrowing their width in the short-side direction in that they can irradiate high-intensity light onto the liquid crystal display panel surface and can use a small-area Image data is used to suppress the data processing capacity to shorten the calculation processing time (higher speed can be achieved), and high inspection accuracy can be obtained. In addition, the distance between the first and second irradiation units 311, 312 and the transport device 400 can be appropriately adjusted according to the type, size, transport speed, etc. of the liquid crystal display panel Y. (camera department)

The continuous inspection device 300 has an imaging unit 316 that is irradiated with the first linear light L1 and the second linear light L2 from the other surface (the second surface 4b in FIG. 1 ) of the liquid crystal display panel Y. The line inspection area E is continuously imaged in a line parallel to the width direction of the liquid crystal display panel Y (direction d2 perpendicular to the conveyance direction d1). One imaging unit 316 may include, for example, one or more optical cameras such as CCD cameras, CMOS sensor cameras, and line sensor cameras arranged in a line. One imaging unit 316 is configured to photograph a linear region corresponding to a linear inspection region E irradiated by two linear lights, and in this embodiment, four CCD cameras are configured to a straight line. In the present embodiment, one imaging unit 316 is arranged in a direction perpendicular to the other surface (second surface 4 b ) of the liquid crystal display panel Y. As shown in FIG. In addition, as another embodiment, one imaging unit 316 may be disposed so as to be inclined at a third angle relative to the other surface (second surface 4 b ) of the liquid crystal display panel Y from the vertical axis. The third angle is, for example, an angle exceeding 0° and not more than 30° from the vertical axis.

The continuous inspection device 300 has a slit 314 disposed on the other surface (second surface 2 b ) of the liquid crystal display panel Y and defines an imaging area 314 a corresponding to the line inspection area E. The arrangement of the first and second irradiation units 311 and 312, the imaging unit 316, and the slit unit 314 is fixed relative to the transport device 400, and the imaging unit 316 detects the transmitted light P (transmitted light image) passing through the imaging region 314a of the slit unit 314. to shoot. The slit 314 is arranged such that the distance D1 from the other surface (second surface 4 b ) of the liquid crystal display panel Y to the slit 314 is smaller than the distance D2 from the imaging unit 316 to the slit 314 ( D1 < D2 ). In the present embodiment, the slit portion 314 is arranged in the vicinity of the liquid crystal display panel Y (for example, D1 is within 10 mm to 50 mm).

In addition, as another embodiment, according to the state of the liquid crystal display panel Y at the time of inspection, the first and second light irradiation units 311 and 312 can be arranged on the upper side of the transport device 400, and one imaging unit 316 and the slit unit 314 can be arranged On the underside of the delivery device 400 .

In this embodiment, when there is a foreign object between the liquid crystal cell 4 and the first single-sheet polarizing film 111 or the second single-sheet polarizing film 211, as shown in FIG. Light scattered by a foreign object passing through the imaging region 314 a with the slit portion 314 interposed therebetween is photographed. Therefore, one imaging unit 316 can image a foreign object with clear contrast. (Conveyor)

The transport device 400 is a series of transport devices for transporting the liquid crystal cell 4 and the liquid crystal display panel Y with the first and second single-sheet polarizing films 111 and 211 attached to both surfaces of the liquid crystal cell 4 . The conveying device 400 described above is configured to include, for example, conveying rollers 70 , suction plates, and the like. In this embodiment, the conveying device 400 is equipped with a winding mechanism and an overturning mechanism. The above-mentioned winding mechanism is used to horizontally rotate the liquid crystal cell 4 attached with the first single sheet polarizing film 111 by 90°. The above-mentioned turning mechanism is used to make the The liquid crystal cell 4 attached with the first single-sheet polarizing film 111 is turned upside down. In addition, the conveyance device 400 conveys the liquid crystal display panel Y while the inspection device 300 is inspecting. (check process)

In this embodiment, based on the image data acquired by the imaging unit 316 , it is determined whether the liquid crystal display panel Y is a good product or a defective product. For this purpose, the inspection apparatus 300 includes an image processing unit 317 , a memory 302 , an image statistical processing/image combining unit 303 , and a good/bad judgment unit 301 as shown in FIG. 4 . Description will be made with reference to FIGS. 4 to 6 .

First, a control unit (not shown) controls the transport device 400 to temporarily stop the liquid crystal display panel Y at the inspection waiting position (see FIG. 6( a )). Next, the control unit controls the conveyance device 400 and the inspection device 300 to start conveyance of the liquid crystal display panel Y (step S1), and to start inspection by the inspection device 300 (step S2).

In this inspection, the control unit controls the transport device 400 to continuously transport the liquid crystal display panel Y along the transport direction d1 from the start of the test to the end of the test. In addition, during this period, the control unit controls the inspection apparatus 300 so that the first and second linear lights L1 and L2 are irradiated to the liquid crystal display panel Y by the first and second irradiation units 311 and 312, and the imaging unit 316 uses The transmitted light P that is irradiated to the liquid crystal display panel Y by the first and second linear lights L1 and L2 and passes through the imaging region 314 a of the slit portion 314 is captured linearly. The linear imaging data obtained by the imaging unit 316 is image-processed by the image processing unit 317, and the image-processed linear image data is stored in the memory 302 (steps S3, S4. ( b) Display the status in the middle of the inspection.) As shown in FIG. 5, the above-mentioned processing is sequentially performed until the control unit (not shown) controls the conveying device 400 to convey the liquid crystal display panel Y to the inspection end position (refer to FIG. 6 (c) ).

Next, the image statistical processing/image combination unit 303 reads the linear image data processed by the image processing unit 317 from the memory 302, performs image statistical processing, and creates an overall view of the liquid crystal display panel Y. image data (step 5). Next, the overall image data is stored in the memory 302 (step 6).

Next, the good/failure judging unit 301 reads the overall image data from the memory 302, and judges good/failure of the liquid crystal display panel Y based on the overall image data (step S7). Here, when the good/failure judging unit 301 judges the liquid crystal display panel Y to be a good product, the judgment result of the good product is stored in the memory 302 in a form associated with the identification information of the liquid crystal display panel Y ( Step S9). The liquid crystal display panel Y is transported to the good product port by the transport device 400 . On the other hand, in step S7, when the good/bad judgment unit 301 judges the liquid crystal display panel Y to be defective, the result of judgment as a defective product is stored in a format associated with the identification information of the liquid crystal display panel Y, etc. to the memory 302 (step S10). The liquid crystal display panel Y is transported to the defective product port by the transport device 400 .

The control unit (not shown) can be configured with a processor and a memory, the program displaying the control sequence is stored in the memory, and the processor executes the program, and the control unit can also be a dedicated circuit or firmware. The image processing unit, the image statistical processing/image combination unit, and the good/bad judgment unit may be configured with a processor and a memory, and a program showing the processing sequence is stored in the memory, and the aforementioned program is executed by the processor, as shown in FIG. The image processing unit, the image statistical processing/image combining unit, and the good/bad judging unit may also be implemented by dedicated circuits or firmware. (Continuous inspection method of liquid crystal display panel)

The continuous inspection method of the liquid crystal display panel is continuously optically inspected while the liquid crystal display panel is being transported. The two sides or one side of the liquid crystal display panel are provided with an optical film having at least an optical function film (such as a polarizing film). The continuous inspection method of the liquid crystal display panel can preferably use the above-mentioned continuous inspection device. The continuous inspection method of the liquid crystal display panel includes the following steps: In the first irradiation step, a first irradiation unit that irradiates first linear light parallel to the width direction of the liquid crystal display panel is used, and is inclined at a first angle (θ1 ), irradiate the first linear light to the line inspection area of the optical display panel being transported, and the width direction of the liquid crystal display panel is a direction perpendicular to the transport direction of the liquid crystal display panel; In the second irradiating step, a second irradiating unit that irradiates second linear light parallel to the width direction of the liquid crystal display panel is used, and is inclined at a second angle (θ2 ) direction, irradiating the second linear light to the aforementioned line inspection area of the liquid crystal display panel being transported, the width direction of the aforementioned liquid crystal display panel is a direction perpendicular to the transport direction of the liquid crystal display panel; and In the imaging step, one imaging unit is used to face the line inspection area irradiated by the first linear light and the second linear light from the other side of the liquid crystal display panel, and continuously in a line parallel to the width direction of the liquid crystal display panel. to shoot.

In the imaging step, the line inspection area may be imaged from the other surface of the liquid crystal display panel through a slit portion defining an imaging area corresponding to the line inspection area. The imaging unit may be arranged in a direction perpendicular to the other surface of the liquid crystal display panel. In the first irradiation step and the second irradiation step, the first angle (θ1) and the second angle (θ2) may have the same value, and the irradiation direction of the first linear light may be different from the irradiation direction of the second linear light. The direction is symmetrical. (Continuous manufacturing method of liquid crystal display panel)

The continuous manufacturing method of the liquid crystal display panel comprises the following steps: a manufacturing step, attaching a first optical film having at least an optical function film (such as a polarizing film) to the first surface of the optical unit, and attaching a first optical film having at least an optical function film (such as a polarizing film) The second optical film of the film) is attached to the second surface of the optical unit to manufacture the liquid crystal display panel; and the steps included in the continuous inspection method of the liquid crystal display panel, wherein, the liquid crystal display panel is transported with a A series of conveying devices to carry out the manufacturing steps and the steps involved in the above-mentioned continuous inspection method. (Other implementation forms)

In this embodiment, the first single-sheet polarizing film 111 is pasted from the upper side of the liquid crystal cell 4, and then the liquid crystal cell 4 to which the first single-sheet polarizing film 111 is attached is reversed (the front and the back are reversed, and if necessary, Rotate 90°), attach the second single-sheet polarizing film 211 from the upper side of the liquid crystal cell 4. However, it is also possible to attach the first single-sheet polarizing film from the lower side of the liquid crystal cell 4, after the liquid crystal cell 4 is turned over, and then attach the second single-sheet polarizing film from the lower side of the liquid crystal cell 4, or to attach the second single-sheet polarizing film from the lower side of the liquid crystal cell 4. Paste the first single-sheet polarizing film on the upper side of the liquid crystal cell without flipping the liquid crystal cell, and attach the second single-sheet polarizing film from the lower side of the liquid crystal cell, and attach the first single-sheet polarizing film from the lower side of the liquid crystal cell As for the polarizing film, the second single-sheet polarizing film is attached from the upper side of the liquid crystal cell without inverting the liquid crystal cell. In addition, the first single-sheet polarizing film and the second single-sheet polarizing film may be attached simultaneously from the upper side and the lower side of the liquid crystal cell.

In addition, in this embodiment, the structure in which the optical film is attached to both surfaces of the optical unit is exemplified, but the continuous inspection of the present invention may be performed after the optical film is attached to one side of the optical unit. 7A and 7B exemplify a configuration in which a polarizing film is attached to one side of a liquid crystal cell and then inspected. 7A arranges bright portions 311 and 312 , inspection filter 321 , liquid crystal display panel Y with polarizing film 111 on the imaging portion side, slit portion 314 , and imaging portion 316 in order. The inspection filter 321 may be fixed, or may be configured to be movable only during inspection. 7B , bright sections 311 and 312 , liquid crystal display panel Y provided with polarizing film 111 on the illuminating section side, slit section 314 , inspection filter 322 , and imaging section 316 are arranged in order. The inspection filter 322 may be fixed, or may be configured to be movable only during inspection. The inspection filter may be arranged between the liquid crystal display panel Y and the slit portion 314 . The inspection device in FIG. 7A may also be arranged downstream of the first attaching part 102 and perform inspection. The inspection device of FIG. 7B may also be arranged downstream of the 90° turn upside down element and perform the inspection. In FIGS. 7A and 7B , the illuminating unit may be disposed on the upper side of the transport device 400 and the imaging unit may be disposed on the lower side of the transport device 400 .

In addition, in this embodiment, the structure in which the optical film is attached to both sides of the optical unit by the so-called "roll-to-panel method" is exemplified. It is also possible to attach the optical film to one side of the optical unit in the "roll-to-panel method" and to the other side in the "sheet-to-panel method".

In addition, in this embodiment, an optical film roll is used, but the structure of the roll-shaped optical film is not limited to this, and a so-called "optical film roll including slits" may also be used.

In addition, in this embodiment, the elongated polarizing film unwound from the optical film roll is cut at predetermined intervals, but the present invention is not particularly limited to the aforementioned configuration. For example, a long polarizing film unwound from an optical film roll may be inspected for flaws, and cut so as to avoid flaws based on the results of the inspection (so-called skip cut). In addition, it is also possible to read the defect information previously attached to the long polarizing film or the mark attached to the position of the defect, and to cut so as to avoid the defect based on the defect information or the mark.

In addition, in the present embodiment, the elongated polarizing film has an absorption axis parallel to the longitudinal direction, but the direction of the absorption axis of the elongated polarizing film is not limited thereto. For example, the first elongated polarizing film may have an absorption axis parallel to its short-side direction (width direction), and the second elongated polarizing film may have an absorption axis parallel to its long-side direction. In this case, the winding mechanism for horizontally rotating the liquid crystal cell on which the first polarizing film is attached by 90° can be appropriately omitted.

In addition, in this embodiment, although the liquid crystal cell was illustrated as an optical cell, it is not limited to this, The optical cell may be an organic EL cell. The organic EL cell has a structure in which an electroluminescent layer is sandwiched between a pair of electrodes. As the organic EL unit, any type of organic EL unit such as a top emission method, a bottom emission method, or a double emission method can be used. The organic EL display panel is obtained by laminating a polarizing film on one or both sides of the organic EL unit, and a driving circuit can be incorporated as required. (Example)

In the examples, the device according to the first embodiment (FIGS. 3 to 6) was used. In the comparative example, an inspection device was used in which a light irradiation unit was arranged in a direction perpendicular to one surface of a liquid crystal display panel, and an imaging unit was arranged in a direction perpendicular to the other surface. As a reference example, the apparatus (FIGS. 4-6) related to Japanese Patent Application No. 2011-60335 (Japanese Patent Laid-Open No. 2012-194509) was used. In the embodiment, the light irradiation unit is arranged so that the first angle θ1 and the second angle θ2 have the same value of 17°, and the imaging unit is arranged in a direction perpendicular to the liquid crystal display panel. The slit part was arrange|positioned at the position of 20 mm (distance D1) from the other surface (2nd surface 2b) of the liquid crystal display panel Y. In the reference example, the light irradiation unit was arranged in a direction perpendicular to the liquid crystal display panel, and the imaging unit was arranged so as to be inclined by 30° with respect to the irradiation direction of the linear light. The inspection is carried out while transporting 200 sheets (n=200) of liquid crystal display panels whose defects were found in advance. The number of sheets of liquid crystal display panels with defects was 0 sheets in both the examples and the reference examples, but it was 15 sheets in the comparative example. Based on this fact, it can be confirmed that even if the number of imaging units is reduced compared to conventional ones, it is possible to detect flaws with the same degree of accuracy or higher.

4: LCD unit 4a: the first side; the first substrate 4b: second side; second substrate 10: The first long optical film laminate 11: The first long polarizing film 12: The first release film 20: The second long optical film laminate 21: The second strip polarizing film 22: The second release film 31: The first cutting part 31a: the first adsorption part 32: The first adjustment tension roller 33: Second cutting part 33a: the second adsorption part 34: the second adjustment tension roller 41: The first stripping department 42: The second peeling part 51a: the first attachment roller 51b: The first driving roller 52a: the second attachment roller 52b: Second drive roller 61: The first coiling department 62: The second coiling part 70: Conveyor roller 100: Continuous manufacturing device 101: The first release film conveying device 102: The first attachment part 103: The second release film conveying device 104: The second attaching part 111: The first monolithic polarizing film 211: the second monolithic polarizing film 300: Continuous inspection device 301: Good/Bad Judgment Department 302: memory 303: Image Statistical Processing/Image Combination Department 311: The first irradiation department 312:Second irradiation department 314: Slit 314a: camera area 316: Camera Department 317: Image Processing Department 321,322: Filters for inspection 400: Conveyor d1: conveying direction d2: width direction E: Line inspection area L1: the first linear light L2: Second linear light P: transmitted light R1: The first optical film roll R2: Second optical film roll Y: LCD display panel θ1: first angle θ2: second angle D1, D2: distance S1~S11: Steps

FIG. 1 is a schematic diagram showing an example of a continuous manufacturing system of an optical display panel. FIG. 2 is a schematic diagram showing an example of a procedure for laminating an optical film on an optical unit. FIG. 3 is a schematic diagram showing an aspect of inspection of foreign matter. FIG. 4 is a schematic diagram showing an example of an inspection device. FIG. 5 is a flowchart showing an example of a processing flow of the inspection device. FIG. 6 is a schematic diagram showing an example of the state of conveyance of the optical display panel from waiting for inspection to completion of inspection. Fig. 7A is a schematic diagram showing an example of an inspection device according to another embodiment. Fig. 7B is a schematic diagram showing an example of an inspection device according to another embodiment.

4: LCD unit

10: The first long optical film laminate

11: The first long polarizing film

12: The first release film

20: The second long optical film laminate

21: The second strip polarizing film

22: The second release film

31: The first cutting part

31a: the first adsorption part

32: The first adjustment tension roller

33: Second cutting part

33a: the second adsorption part

34: the second adjustment tension roller

41: The first stripping department

42: The second peeling part

51a: the first attachment roller

51b: The first driving roller

52a: the second attachment roller

52b: Second drive roller

61: The first coiling department

62: The second coiling part

70: Conveyor roller

100: Continuous manufacturing device

101: The first release film conveying device

102: The first attachment part

103: The second release film conveying device

104: The second attaching part

111: The first monolithic polarizing film

211: the second monolithic polarizing film

300: Continuous inspection device

311: The first irradiation department

312:Second irradiation department

314: Slit

316: Camera department

400: Conveyor

d1: conveying direction

d2: width direction

R1: The first optical film roll

R2: Second optical film roll

Claims (14)

A method for continuously inspecting an optical display panel, wherein the optical display panel is continuously inspected optically while the optical display panel is being transported, and an optical film having at least an optically functional film is provided on both sides or one side of the aforementioned optical display panel , the continuous inspection method of the aforementioned optical display panel includes the following steps: In the first irradiation step, a first irradiation unit that irradiates a first linear light parallel to the width direction of the aforementioned optical display panel is used, and is inclined at a first angle ( In the direction of θ1), the first linear light is irradiated to the line inspection area of the optical display panel being transported, and the width direction of the optical display panel is a direction perpendicular to the transport direction of the optical display panel; In the second irradiation step, a second irradiation unit that irradiates a second linear light parallel to the width direction of the aforementioned optical display panel is used, and is inclined at a second angle ( The direction of θ2), irradiating the second linear light to the aforementioned line inspection area of the optical display panel being transported, the width direction of the optical display panel is a direction perpendicular to the transport direction of the optical display panel; and In the imaging step, an imaging unit is used to scan the line parallel to the width direction of the optical display panel from the other side of the optical display panel to the line inspection area irradiated by the first linear light and the second linear light. to shoot continuously, The intersection point where the center of the optical axis of the first illuminating unit intersects the center of the optical axis of the second illuminating unit is located in the line inspection area. A continuous inspection method for optical display panels as claimed in item 1, wherein In the imaging step, the line inspection area is imaged from the other surface of the optical display panel through a slit portion defining an imaging area corresponding to the line inspection area. The method for continuously inspecting an optical display panel according to claim 1 or 2, wherein the imaging unit is arranged in a direction perpendicular to the other surface of the optical display panel. The method for continuously inspecting optical display panels according to claim 1, wherein in the first irradiation step and the second irradiation step, the first angle (θ1) and the second angle (θ2) have the same value, and the first angle The irradiation direction of the linear light is symmetrical to the irradiation direction of the second linear light. The method for continuously inspecting an optical display panel according to Claim 1, wherein when the optical display panel is continuously optically inspected while the optical display panel is being transported with the optical film provided on one side, in the first, Between the second illuminating unit and the aforementioned one imaging unit, a predetermined distance is separated from the other side of the optical display panel on which the optical film is provided, and an inspection filter is arranged and photographed. The aforementioned inspection filter has An optical axis corresponding to the optical axis of the optical functional film contained in the aforementioned optical film. A continuous inspection device for an optical display panel, which continuously and optically inspects the optical display panel while the optical display panel is being transported, and the optical display panel is provided with an optical film having at least an optical function film on both sides or one side of the optical display panel , the continuous inspection device of the aforementioned optical display panel has: The first irradiating unit is configured to irradiate the line inspection area of the optical display panel being conveyed in a direction inclined by a first angle (θ1) to the upstream side of the conveying direction from the surface perpendicular to the optical display panel. The first linear light parallel to the width direction of the panel, the width direction of the optical display panel is a direction perpendicular to the conveying direction of the optical display panel; The second irradiating unit is configured to irradiate the line inspection area of the optical display panel being transported in a direction inclined at a second angle (θ2) to the downstream side of the conveying direction from one surface perpendicular to the optical display panel. The second linear light parallel to the width direction of the display panel, the width direction of the optical display panel is a direction perpendicular to the conveying direction of the optical display panel; and An imaging unit, which is continuous in a line parallel to the width direction of the optical display panel, from the other side of the optical display panel to the line inspection region irradiated with the first linear light and the second linear light. to shoot, The intersection point where the center of the optical axis of the first illuminating unit intersects the center of the optical axis of the second illuminating unit is located in the line inspection area. The continuous inspection device for optical display panels as claimed in claim 6, which also has: The slit portion is disposed on the other side of the optical display panel and defines an imaging area corresponding to the line inspection area, The imaging unit performs imaging via the slit. The continuous inspection device for optical display panels according to claim 6 or 7, wherein the imaging unit is arranged in a direction perpendicular to the other surface of the optical display panel. The continuous inspection device for optical display panels according to claim 6, wherein the first irradiating section and the second irradiating section are configured such that the first angle (θ1) and the second angle (θ2) have the same value, and the aforementioned The irradiation direction of the first linear light is symmetrical to the irradiation direction of the second linear light. A continuous inspection device for an optical display panel as claimed in claim 6, which further has an inspection filter, and the aforementioned inspection filter is arranged to continuously optically inspect the optical display panel with the aforementioned optical film on one side being conveyed. When inspecting the aforementioned optical display panel, between the aforementioned first and second irradiation units and the aforementioned one imaging unit, and between the other side of the optical display panel on which the aforementioned optical film is provided, a predetermined distance, and form a predetermined arrangement relationship with the optical axis of the optical functional film included in the aforementioned optical film. A continuous manufacturing method for an optical display panel, comprising the following steps: A manufacturing step of attaching a first optical film having at least an optical functional film to the first surface of the optical unit, and attaching a second optical film having at least an optical functional film to the second surface of the optical unit to manufacture an optical display panels; and The steps included in the continuous inspection method of optical display panels as claimed in item 1 or 2, Wherein, the steps included in the aforementioned manufacturing steps and the aforementioned continuous inspection method are performed by a series of transport devices for transporting the aforementioned optical units and the aforementioned optical display panels. The continuous manufacturing method of an optical display panel as claimed in claim 11, wherein, in the aforementioned manufacturing steps, The aforementioned action of attaching the first optical film having at least an optically functional film to the first surface of the optical unit is as follows: The first optical film obtained by cutting the first elongated optical film from the first elongated optical film while leaving the elongated first release film while unwinding the first elongated optical film from the first optical film roll is pasted. Attaching a single sheet of first optical film to the first surface of the transported optical unit; and/or The aforementioned action of attaching the second optical film having at least an optically functional film to the second surface of the optical unit is as follows: The second optical film obtained by cutting the second elongated optical film from the second optical film roll while leaving the elongated second release film while unwinding the second elongated optical film, and The optical axis of the first optical film and the optical axis of the second optical film are attached to the second surface of the transported optical unit in a manner that the optical axis of the second optical film forms a predetermined angle, or the second optical film in the form of a single sheet is attached to the aforementioned second surface. The optical axis of the first optical film and the optical axis of the second optical film are attached to the second surface of the optical unit in such a way that the optical axis of the second optical film forms a predetermined angle. A continuous manufacturing system for optical display panels, comprising: A manufacturing device for bonding a first optical film having at least an optical functional film to a first surface of an optical unit, and bonding a second optical film having at least an optical functional film to a second surface of an optical unit to manufacture an optical a display panel; and A continuous inspection device for optical display panels as claimed in any one of items 6 to 10, Wherein, the aforementioned manufacturing device and the aforementioned continuous inspection device are configured in a series of conveying devices for transporting the aforementioned optical unit and the optical display panel. The continuous manufacturing system for optical display panels as claimed in claim 13, wherein, in the aforementioned manufacturing device, The aforementioned action of attaching the first optical film having at least an optically functional film to the first surface of the optical unit is as follows: The first optical film obtained by cutting the first elongated optical film from the first elongated optical film while leaving the elongated first release film while unwinding the first elongated optical film from the first optical film roll is pasted. attaching the first surface of the transported optical unit, or attaching a single sheet of the first optical film to the first surface of the optical unit, and/or The aforementioned action of attaching the second optical film having at least an optically functional film to the second surface of the optical unit is as follows: The second optical film obtained by cutting the second elongated optical film from the second optical film roll while leaving the elongated second release film while unwinding the second elongated optical film, and The optical axis of the first optical film and the optical axis of the second optical film are attached to the second surface of the transported optical unit in a manner that the optical axis of the second optical film forms a predetermined angle, or the second optical film in the form of a single sheet is attached to the aforementioned second surface. The optical axis of the first optical film and the optical axis of the second optical film are attached to the second surface of the optical unit in such a way that the optical axis of the second optical film forms a predetermined angle.

Images