KR20200047259A - Method and device for inspecting defect of optical film - Google Patents

Abstract

The present invention relates to a method and a device for inspecting a defect of an optical film. The method for inspecting a defect of an optical film comprises: (a) a step of positioning an optical film on a stage; (b) a step of discharging a transparent film from a discharge roll to position the transparent film on the optical film; (c) a step of lowering first and second guide rolls arranged on the transparent film until a lower portion of the transparent film touches an upper portion of the optical film; (d) a step of emitting a light to one surface of the optical film to acquire a surface image of an upper portion of the optical film; (e) a step of detecting a defect from the surface image; and (f) a step of lifting the first and second guide rolls. A protective film is affixed to one surface of the transparent film which is not affixed to the optical film by using an adhesive to suppress detection of scratches existing on the transparent film to selectively and easily detect only scratches of the optical film.

Description

METHOD AND DEVICE FOR INSPECTING DEFECT OF OPTICAL FILM

The present invention relates to a method and apparatus for inspecting defects in optical films.

Recently, with the development of mobile devices such as smartphones and tablet PCs, there have been attempts to develop not only thinning and slimming of substrates for displays, but also foldable displays.

In general, display panels such as liquid crystal displays (LCDs), light emitting diodes (LEDs), and organic light emitting diodes (OLEDs) are defective in the pattern of the display panel itself or inside or on the surface of the optical film constituting the display panel Since a defective pixel may be generated due to a particle (foreign material) or a scratch that may be present in the optical film, a process of detecting a defect using an optical camera is performed.

Referring to Figure 1a, the sheet-shaped test body 100 may be positioned on the stage 10. When the test body 100 can be provided in a roll form as shown in FIG. 1B, the test body 100 is unwound from the unwinding roll 20 to perform defect inspection, and the inspection body 100 after the inspection is completed is wound up The process of being wound by the roll 30 is performed. At this time, the inspection is performed by the light irradiated to the light source 40, the image acquisition unit 50 positioned on the upper portion of the inspection body 100 acquires the surface image of one surface of the inspection body 100 have.

For example, Korean Patent Publication No. 10-2017-0129077 includes a light source that irradiates light on an object; A light blocking part disposed between the inspected object and the light source to partially block the light; And a photographing unit accommodating light passing through the inspected object to acquire an image.

These conventional inspection methods generally process transparent on at least one side of the inspection body to prevent damage to the inspection body (scratching, etc.) in the process of unwinding and winding the inspection body to inspect defects of the inspection body. The film is bonded and inspection proceeds.

However, when the inspection is performed by attaching a transparent film that is bonded to protect the inspection body as described above, not only the scratches present on the inspection body itself, but also the scratches present on the transparent film are recognized as defects, thereby increasing unnecessary defect rate. There is a problem. In addition, when inspecting an optical film using a conventional optical inspection device, in particular, a flexible optical film in the form of a sheet such as a film-type touch sensor, the optical film is generated due to curl of the film itself. There is a problem in that inspection is not easy because an out-of-focus phenomenon occurs in the image acquisition unit for mastering.

Republic of Korea Patent Publication No. 10-25017-0129077 (2017.11.24)

The present invention is to solve the above problems, it is possible to selectively prevent only the scratch of the optical film itself to prevent unnecessary increase in defect rate, it is possible to secure the flatness during the defect inspection process of the optical film, the film type An object of the present invention is to provide a method and apparatus for inspecting defects in an optical film capable of inspecting a flexible optical film such as a touch sensor.

Defect inspection method of the optical film of the present invention for achieving the above object comprises the steps of: (a) placing the optical film on the stage; (b) unwinding the transparent film from the unwinding roll and placing it on the optical film; (c) lowering the first and second guide rolls provided on the transparent film until the lower portion of the transparent film contacts the upper portion of the optical film; (d) irradiating light to one surface of the optical film to obtain a surface image on the top of the optical film; (e) detecting a defect from the surface image; And (f) raising the first and second guide rolls, wherein the transparent film is characterized in that a protective film is bonded using a pressure-sensitive adhesive on one surface not bonded to the optical film.

 The optical film inspection method of the present invention can discriminate only the scratches of the optical film itself, thereby reducing unnecessary defect rates, and ensuring flatness during the defect inspection process of the optical film, making it flexible, such as a film type touch sensor. It is possible to inspect the optical film.

1A and 1B are diagrams illustrating a defect inspection apparatus of a conventional optical film.
2 is a view illustrating a defect inspection apparatus for an optical film according to the present invention.
3 is a view illustrating the structure of a test body according to the present invention.

In the present invention, when a member is positioned "on" another member, this includes not only the case where one member is directly in contact with the other member but also another member interposed between the two members.

In the present invention, when a part “includes” a certain component, this means that other components may be further included, rather than excluding other components, unless otherwise specified.

Hereinafter, a defect inspection method of the optical film of the present invention will be described in more detail with reference to the drawings.

An aspect of the invention, (a) placing the optical film 100 on the stage 10; (b) unwinding the transparent film 200 from the unwinding roll 20 and placing it on the optical film 100; (c) lowering the first and second guide rolls 60 and 70 provided on the transparent film 200 until the lower portion of the transparent film 200 contacts the upper portion of the optical film 100. step; (d) irradiating light to one surface of the optical film 100 to obtain a surface image of the optical film 100; (e) detecting a defect from the surface image; And (f) raising the first and second guide rolls 60 and 70, but after the step (c), the transparent film 200 not bonded to the optical film 100 is included. It further relates to a defect inspection method of the optical film 100 further comprising; a step of further laminating the protective film 400 using an adhesive 300 on one side.

2 shows a defect inspection apparatus of the optical film 100 according to an embodiment of the present invention. Referring to FIG. 2, the surface image of the optical film 100 to be inspected can be obtained through the light source 40 and the image acquisition unit 50.

As described above, a method of detecting a defect on the optical film 100 through the light source 40 is generally detected using a refractive index ratio (difference in refractive index) of a medium before and after incident of light emitted from the light source 40. The refractive index ratio can be calculated based on Snell's law. When a scratch occurs on the optical film 100 and the transparent film 200 is bonded on the optical film 100, an air layer 500 is formed where the scratch occurs, and the air layer 500 is thus formed. In the formed portion, the presence or absence of scratch is discriminated using the point that the difference in refractive index of light is large. However, in this way, not only the scratches present on the optical film 100, but also the scratches present on the transparent film 200 bonded on the optical film 100, since a difference in refractive index occurs, substantially Even if there is no scratch on the optical film 100, if a scratch is present on the transparent film 200, it is also determined that a scratch exists and is detected as a defect, which increases the unnecessary defect rate.

Therefore, in the detection method of the optical film 100 of the present invention, the protective film 400 was further bonded using the adhesive 300 on one surface of the transparent film 200 to which the optical film 100 was not bonded. As described above, the present invention further comprises an adhesive 300 on the transparent film 200, thereby filling the scratch portion present on the transparent film 200 with the adhesive 300 to prevent the formation of an air layer, thereby making the transparent film The detection of scratches present on the 200 is suppressed, and an unnecessary defect rate is reduced by selectively detecting only the scratches present on the optical film 100.

In the present invention, "optical film 100" may refer to a film having optical properties, for example, a film-type touch sensor, a patterned film, a polarizer, a transparent protective film, and a protective film attached to at least one surface of the polarizer Polarized plates, retardation films, and the like, but are not limited thereto. Specifically, the "optical film 100" may be a sheet-type flexible (flexible) optical film 100.

The defect inspection method of the optical film 100 according to the present invention includes the steps of: (a) placing the optical film 100 on the stage 10.

The stage 10 supports the optical film 100 and may be a transparent or opaque material. Specifically, the stage 10 may use a suitable material according to a defect inspection method of the optical film 100, for example, a transmission optical system or a reflection optical system.

Specifically, when the defect inspection method of the optical film 100 uses a transmission optical system and the stage is made of an opaque material, light is transmitted by the light source 40 provided at the lower portion of the optical film 100. Penetrations should be provided to ensure that. In addition, the stage 10 may be provided with an adsorption hole capable of adsorbing the optical film 100, but is not limited thereto.

The defect inspection method and apparatus of the optical film 100 according to the present invention may be one using a “transmission optical system”.

The stage 10 may be made of glass in that it is preferably excellent in light transmittance and easy to secure flatness, but is not limited thereto.

The defect inspection method of the optical film 100 according to the present invention includes (b) unwinding the transparent film 200 from the unwinding roll 20 and placing it on the optical film 100.

The unwinding roll 20 is rotated by a driving motor to serve to unwrap the transparent film 200. Although not shown, the driving motor for rotationally driving the unwinding roll 20 and the driving motor for rotationally driving the winding roll 30 to be described later are moved to each other while maintaining the tension of the transparent film 200 by a controller. It can be controlled as much as possible.

A tension adjusting mechanism may be installed on the lower side of the winding roll 20 and the winding roll 30 to be described later, but is not limited thereto.

When the defect of the optical film 100 is inspected, the transparent film 200 is raised and lowered by the first and second guide rolls 60 and 70 so as to contact one surface of the optical film 100. It is not limited as long as it does not affect the defect inspection of the optical film 100, but is preferably a PET film or a TAC film, for example, in view of good light transmittance and less occurrence of defects in the film itself.

The transparent film 200 unwound by the unwinding roll 20 is lowered by the first and second guide rolls 60 and 70. Specifically, the defect inspection method of the optical film 100 according to the present invention is (c) the first and second guide rolls 60 and 70 provided on the transparent film 200, the transparent film 200 And lowering the lower portion until the lower portion of the optical film 100 contacts the upper portion.

In addition, although not shown in the present invention, as a means for preventing detection of scratches present on the transparent film 200, an adhesive on one side of the transparent film 200 that is not bonded to the optical film 100 The protective film 400 is further bonded using 300. At this time, the pressure-sensitive adhesive 300 may be used without limitation, a general pressure-sensitive adhesive used in the industry, the specific content of the protective film 500 may be the same content of the above-mentioned transparent film 200.

The pressure-sensitive adhesive 300 and the protective film 400 apply the pressure-sensitive adhesive 300 on one side of the transparent film 200 before entering the unwinding roll 20 and the protective film 400 on the pressure-sensitive adhesive 300 This may be pre-stacked.

The first and second guide rolls 60 and 70 are movable in a vertical direction and are installed to be positioned on the unfolded transparent film 200.

As the first and second guide rolls 60 and 70 move in the vertical direction, the transparent film 200 can also move in the vertical direction according to the first and second guide rolls 60 and 70. Is done.

The first and second guide rolls 60 and 70 may serve to maintain the tension of the transparent film 200.

2, the first and second guide rolls 60 and 70 are positioned such that defect inspection is performed between the first guide roll 60 and the second guide roll 70, as shown in FIG. It is preferred in terms of.

In the defect inspection method and apparatus of the optical film 100 according to the present invention, the first and second guide rolls allow the transparent film 200 to contact the optical film 100 with appropriate tension. The flatness of the optical film 100 can be secured, and there is an advantage of suppressing curls that may occur during a defect inspection process.

In the present invention, the tension imparted by the first and second guide rolls 60 and 70 is not limited. For example, the tension applied to the transparent film 200 when the transparent film 200 comes into contact with the optical film 100 by the first and second guide rolls 60 and 70 may be 50 to 1000 N. .

In the present invention, "contacting" means that the transparent film 200 is completely in contact with the surface of the optical film 100 by tension, or the optical film 100 can be inspected at a level capable of inspecting the optical film 100. ) May mean a state in which the curl is suppressed by the transparent film 200.

In one embodiment of the present invention, the step of lowering the stage pin 90 provided on the stage 10 so that the lower portion of the transparent film 200 is in contact with the upper portion of the optical film 100; It can contain.

The stage pin 90 may serve to support and fix the optical film 100 so that the optical film 100 does not move, so that the stage 10 shows the stage pin 90 in FIG. 2. As described above, it is preferable to include two or more parts in the periphery of the optical film 100.

The stage pin 90 according to the present invention can move in the vertical direction like the first and second guide rolls 60 and 70.

Referring to FIG. 2, the stage pin 90 is provided in a state having a predetermined height so that the optical film 100 does not move when the first and second guide rolls 60 and 70 are raised. Thereafter, when the first and second guide rolls 60 and 70 descend, the stage pin 90 may also descend so as not to be caught by the transparent film 200.

In another embodiment of the present invention, the step of ionizing the transparent film 200 unwound from the unwinding roll 20 with an ionizer 80 may be further included.

The ionizer 80 serves to remove the static electricity of the transparent film 200 by ionizing the transparent film 200. Referring to FIG. 2, the unwinding roll 20 and the agent 1, the transparent film 200 disposed on the guide roll 60 and unwound can be ionized.

The defect inspection method of the optical film 100 according to the present invention includes (d) irradiating light to one surface of the optical film 100 to obtain a surface image on the top of the optical film.

The light source 40 for irradiating the light is not particularly limited in the present invention. Specifically, the light source 40 is to irradiate light to the optical film 100, LED, metal halide, fluorescent lamps and halogens. For example, the light source 40 may be rod-shaped or rod-shaped, and the light emitting method may be surface lighting or light collection, but is not limited thereto. Preferably, the light source 40 may be in the form of surface lighting.

When the light source 40 is a surface light, it is easy to detect defects in the optical film 100 due to scattering of light compared to condensing light, and the surface image of the transparent film 200 in contact with the optical film 100 is defective It is preferable because the phenomenon recognized as can be suppressed.

The method for obtaining the surface image is not particularly limited in the present invention. For example, the surface image may be obtained using a line scan or area scan method.

After acquiring the surface image, defects such as foreign matter, thread, irregularities, pressing, scratches, bubbles, cracks, burrs, and lifting can be detected from the surface image.

In particular, in the present invention, by applying the adhesive 300 on the transparent film 200, there is an effect of suppressing the detection of the scratch by filling the scratches present in the transparent film 200, thereby causing the optical film 100 to Since only the scratches present on the screen can be selectively detected, there is an effect of suppressing unnecessary defect rates caused by the detection of scratches on the transparent film 200.

The defect inspection method of the optical film 100 according to the present invention includes (f) raising the first and second guide rolls 60 and 70.

After obtaining the surface image, the first and second guide rolls 60 and 70 are raised to raise the transparent film 200 in contact with the optical film 100.

In another embodiment of the present invention, after the step (f), the transparent film 200 is wound with a winding roll 30 to be recovered; and may be further included.

The transparent film 200 wound with the winding roll 30 may be replaced with a new transparent film 200 as necessary, and may be used again when inspecting a new optical film other than the optical film 100 that has been inspected. It might be. If necessary, an electronic device or the like for correcting meandering to recover the transparent film 200 may be additionally provided, but is not limited thereto.

The defect inspection method of the optical film 100 according to the present invention may further include the step of moving the optical film 100 after the inspection is completed, but is not limited thereto. At this time, the movement of the optical film 100 may be performed through a method commonly used in the art, for example, it may be performed using a conveyor belt, an adsorption method, but is not limited thereto.

In another embodiment of the present invention, the optical film 100 may be a flexible optical film 100.

The defect inspection method of the optical film 100 according to the present invention can secure the flatness of the optical film 100 by making the optical film 100 and the transparent film 200 come into contact during inspection. It is possible to suppress the curl phenomenon that occurs, even if the optical film 100 exhibits a flexible form, there is an advantage of easy inspection, and by applying the adhesive 300 on one side of the transparent film 200, the The advantage of being easy to selectively detect only the scratches present on the optical film 100 is reduced by filling the scratches present on the transparent film 200 and suppressing the detection of the scratches. have.

In another embodiment of the present invention, the optical film 100 may include a pattern layer. Specifically, the optical film 100 may be a touch sensor, and the defect inspection method of the optical film 100 according to the present invention is subject even in an inspection process that requires a short depth of focus in a high resolution state for inspecting a fine pattern. In other words, since deformation such as curl of the optical film 100 can be physically suppressed, there is an advantage of easy inspection even when a fine pattern layer is included.

Another aspect of the present invention, the image acquisition unit 50 for obtaining a surface image by photographing one surface of the optical film 100; A light source 40 irradiating light to one surface of the optical film 100; A winding roll 20 for unwinding the transparent film 200 and a winding roll 30 for winding the transparent film; First and second guide rolls 60 and 70 provided between the unwinding roll 20 and the unwinding roll 30 to raise and lower the unwound transparent film 200; And a stage (10) on which the optical film (100) is located.

The image acquisition unit 50 is preferably capable of acquiring a surface image of a color or black and white image, and may be a CCD camera or other two-dimensional camera, but is not limited thereto. The image acquisition unit 50 serves to obtain a surface image of the optical film 100 according to the present invention or an image inside a laminated structure.

When performing the vision alignment of the optical film 100, a vision image acquisition unit, an ultrasonic edge point controller (EPC), and a laser EPC for the alignment may be additionally provided.

The light source 40 is positioned to face the image acquisition unit 50. Specifically, referring to FIG. 2, the light source 40 is located below the stage, and the image acquisition unit 50 is protected. It is located on the top of the film 400.

The light source 40 may apply the above-described contents. Specifically, in the present invention, the light source 40 may be a surface light.

The unwinding roll 20 and the take-up roll 30 serve to unwind and wind the transparent film 200 on which the protective film 400 is stacked, respectively, and the above-described contents may be applied.

The unwinding roll 20 and the unwinding roll 30 may be positioned at a predetermined interval from the stage 10. Specifically, the unwinding roll 20 and the take-up roll 30 are in a state in which the first and second guide rolls 60 and 70 are raised, that is, the transparent film 200 and the optical film 100 When not in a lowered state to contact, it is preferable that the optical film 100 and the transparent film 200 are provided to have an appropriate height in the vertical direction so as not to contact.

The optical film 100, the transparent film 200, the pressure-sensitive adhesive 300, and the protective film 400 may apply the above-described content. In short, the optical film 100 may be a flexible optical film 100.

In addition, the optical film 100 may include a pattern layer.

The first and second guide rolls 60 and 70 are provided between the unwinding roll 20 and the take-up roll 30, and serve to raise and lower the unwound transparent film 200.

Referring to FIG. 2, it is preferable in terms of maintaining the tension of the transparent film 200 that the stage 10 is disposed between the first and second guide rolls 60 and 70.

The first and second guide rolls 60 and 70 are provided on the unloaded protective film 400 so that the transparent film 200 comes into contact with the optical film 100 through vertical movement. It may serve to descend and to raise the transparent film 200, which was in contact with the optical film 100, to a state before contact. The contents of the first and second guide rolls 60 and 70 may be understood as the contents described above.

The stage 10 is where the optical film 100 to be inspected is located. The stage 10 may be, for example, a transparent material, and may be specifically made of glass, but is not limited thereto.

In another embodiment of the present invention, the stage 10 may further include a stage pin 90 that aligns the optical film 100 and rises and falls.

The stage pin 90 is attached to the transparent film 200 when it is lowered by the first and second guide rolls 60 and 70 so that the transparent film 200 comes into contact with the optical film 100. It can be lowered so as not to get caught.

The stage pin 90 may be controlled simultaneously with the first and second guide rolls 60 and 70, but is not limited thereto.

The above-described content may be applied to the stage 10 and the stage pin 90.

In still another embodiment of the present invention, the ionizer 80 for ionizing the transparent film 200 unwound from the unwinding roll 20 may be further provided.

The ionizer 80 may remove static electricity generated on the surface of the transparent film 200 by spraying an ionized gas over the entire width direction of the transparent film 200.

Specifically, it may serve to remove static electricity generated on one surface of the transparent film 200 in contact with the optical film 100, thereby suppressing damage to the surface of the optical film 100, There is an advantage that can prevent additional defects due to foreign matter adhesion.

Defect inspection method and apparatus of the optical film 100 according to the present invention, because the defect inspection is performed in the state in which the optical film 100 and the transparent film 200 are in contact, to suppress the curl generated during the inspection process If the curl is formed on the optical film 100 itself, in short, the inspection of the flexible optical film 100 also has the advantage of being easy, and the transparent film 200 that is not bonded to the optical film 100 The adhesive film 300 is coated on the other side of the surface to further bond the protective film 400, so that the air layer of the scratch existing on the transparent film 200 is filled due to the application of the adhesive 300. Detection is suppressed, and thus, detection of scratches on the transparent film 200 is suppressed, so that it is easy to selectively detect only scratches on the optical film 100, which is a target inspection object, thereby making it easy to detect the scratches. There is an advantage that unnecessary defect rate was caused by a scratch detection decreases.

10: stage 20: winding roll
30: winding roll 40: light source
50: image acquisition unit 60: first guide roll
70: second guide roll 80: ionizer
90: stage pin 100: optical film
200: transparent film 300: adhesive
400: protective film 500: air layer

Claims (1)

(a) placing the optical film on the stage;
(b) unwinding the transparent film from the unwinding roll and placing it on the optical film;
(c) lowering the first and second guide rolls provided on the transparent film until the lower portion of the transparent film contacts the upper portion of the optical film;
(d) irradiating light to one surface of the optical film to obtain a surface image on the top of the optical film;
(e) detecting a defect from the surface image; And
(f) raising the first and second guide rolls;
The transparent film is a defect inspection method of the optical film, characterized in that the protective film is bonded using an adhesive on one surface not bonded to the optical film.

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