KR100322456B1 - Rubbing device for manufacturing of liquid crystal display - Google Patents

Abstract

As a rubbing device that can minimize the wear and damage of the rubbing cloth to prevent degradation of the alignment layer due to rubbing cloth damage,

The rubbing device includes a table for seating and moving a glass substrate coated with an alignment film, and a rubbing cloth positioned on an outer circumference of the glass substrate. A cushioning member that provides a rubbing roller that contacts and performs an alignment treatment, and an inclined surface that connects the table surface and the glass substrate surface on at least one surface of the glass substrate facing the rubbing roller to gently induce contact between the rubbing cloth and the glass substrate. It includes. As a result, the rubbing roller is in direct contact with the alignment layer through the inclined surface of the buffer member instead of directly contacting the side or edge portion of the glass substrate, thereby making contact with the glass substrate more gentle, thereby minimizing wear and damage of the rubbing cloth.

Description

Rubbing device for manufacturing liquid crystal display

The present invention relates to a rubbing device used to fabricate a liquid crystal display device, and more particularly, to minimize wear and damage caused when the rubbing cloth touches the edge of the glass substrate to prevent deterioration of the alignment layer due to rubbing cloth damage. It relates to a rubbing device that can be.

A liquid crystal display is a display device that composes a screen by changing light transmittance for each pixel by using a liquid crystal whose twist angle changes according to an applied voltage. A liquid crystal display device is a portable electronic device such as a digital camera due to its thin, light, and low voltage driving ability. It is widely used from the display device of a device to large display devices, such as a monitor.

6 is a cross-sectional view of a general liquid crystal display device, in which a transparent conductive film 5 is formed on an inner surface of a transparent upper substrate 1 and a lower substrate 3 to function as a common electrode and a pixel electrode, respectively. An insulating film 7 and an alignment film 9 are formed on the entire surface of the substrate on which the substrate 5 is formed, and the liquid crystal 11 is oriented into the pair of alignment films 9, and the respective surfaces are formed on the outer surfaces of the upper and lower substrates 1, 3. The polarizing plate 13 is located.

The liquid crystal 11 maintains a pretilt angle by the alignment layer 9. Currently, the polyimide is most used as the alignment layer 9, and although the side chain of the alignment layer 9 has a pretilt, Since they are arranged irregularly without directivity, the surface of the alignment film 9 is mainly rubbed.

The rubbing process refers to an operation of orienting the pretilt of an irregularly distributed alignment film in a predetermined direction by gently rubbing the surface of the alignment film with a nylon, rayon or cotton-based rubbing cloth.

FIG. 7 is a schematic view of a rubbing device according to the prior art, in which a glass roller 17 having an alignment film 9 coated thereon is seated on a table 15 and a rubbing roller 21 having a rubbing cloth 19 wound around its outer circumferential surface. When the table 15 is moved in the direction of the arrow while being rotated by the driving of the motor 23, the rubbing roller 21 comes into contact with the surface of the alignment film 9 formed on the glass substrate 17, and the surface of the alignment film 9 has a constant directionality. A pretilt angle with is formed.

In general, as the rubbing pressure on the glass substrate 17 increases, the pretilt angle of the alignment layer 9 decreases, and as the film requiring a higher pretilt angle, the uniformity is easily damaged even with slight changes in rubbing conditions. Attention is needed.

However, in a normal rubbing operation, the rubbing roller 21 first contacts the side or edge portion of the glass substrate 17 when the table 15 moves, and then a rubbing operation is performed, wherein the rubbing operation is performed. Even if the thickness is thin, the soft rubbing cloth 19 is likely to be worn while coming into contact with the side or sharp edge portion of the glass substrate 17, and is very likely to be damaged.

Accordingly, the residue phenomenon in which debris of the rubbing cloth 19 remains on the surface of the alignment film 9 due to abrasion and damage of the rubbing cloth 19 appears, and scratches are generated in the advancing direction of the rubbing roller 21. It lowers the film quality of 9) and causes a problem of impairing the uniformity of the liquid crystal display element.

Therefore, the present invention is designed to solve the above problems, the object of the present invention is to suppress the wear and damage of the rubbing cloth generated by contacting the side or edge portion of the substrate to reduce the occurrence of residue and scratches caused by rubbing cloth damage It is to provide a rubbing device that can improve the quality of the alignment film by preventing it in advance.

Another object of the present invention to provide a rubbing device that can extend the life of the rubbing cloth while effectively preventing the rubbing cloth wear and damage in a relatively simple configuration.

1 is a perspective view of a rubbing device according to the present invention.

2 is a side view of the rubbing device according to the present invention.

3 is an enlarged perspective view of the shock absorbing member.

4 is a plan view of a rubbing device according to another embodiment of the present invention.

Fig. 5 is a schematic diagram showing the rubbing angle of the styrene type liquid crystal display device.

6 is a cross-sectional view of a general liquid crystal display device.

7 is a schematic view of a rubbing device according to the prior art.

In order to achieve the above object, the present invention,

A table for seating and moving the glass substrate coated with the alignment film;

A rubbing roller positioned at an outer side of the glass substrate and having a rubbing cloth mounted on an outer circumferential surface thereof so that the rubbing cloth contacts with the surface of the alignment film in a relative motion with the glass substrate while rotating itself when the motor is driven;

And at least one surface of the glass substrate facing the rubbing roller, providing a slope connecting the surface of the table and the surface of the glass substrate to provide a rubbing device including a means for gently inducing contact of the rubbing cloth and the glass substrate.

The means comprises a buffer member comprising a bottom surface in contact with a table, a vertical surface in contact with a side surface of the glass substrate, and an inclined surface connecting the bottom surface and the vertical surface.

With this configuration, the rubbing roller makes contact with the glass substrate more smoothly by contacting the alignment film through the inclined surface of the buffer member instead of directly contacting the side or edge portion of the glass substrate, thereby causing wear and damage of the rubbing cloth. Can be prevented to improve the film quality of the alignment film.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are a perspective view and a side view of the rubbing device according to the present embodiment, respectively. The rubbing device according to the present embodiment includes a table 6 and an outer peripheral surface on which the glass substrate 4 to which the alignment film 2 is applied is seated. And a means for gently inducing contact between the rubbing roller 10 in which the rubbing cloth 8 is wound and the rubbing roller 10 and the glass substrate 4.

The rubbing roller 10 is a motor 12 is connected to one side of the rotating shaft is rotated when driving the motor 12 while rubbing treatment is performed while rubbing the surface of the alignment film 2 in a relative motion with the glass substrate 4 In addition, the rubbing roller 10 may move linearly at the same time as the rotation, and as shown, the table 6 may move linearly toward the rubbing roller 10 while the rubbing roller 10 rotates itself at a fixed position.

The movement of the table 6 may be a conventional belt conveyor, a rack-pinion type table or a table driven by a cylinder.

In all cases, one side of the glass substrate 4 facing the rubbing roller 10 is in contact with the rubbing roller 10 first. At this time, as the glass substrate 4 has a predetermined thickness, the rubbing cloth 8 is likely to be worn or damaged while the rubbing cloth 8 comes into contact with the edge line where the side and the surface of the glass substrate 4 contact. high. As a result, one side of the glass substrate 4 facing the rubbing roller 10 is provided with a means for gently inducing contact between the rubbing roller 10 and the glass substrate 4.

As shown in FIG. 3, the means includes a bottom surface 14a in contact with the surface of the table 6, a vertical surface 14b in contact with the side surface of the glass substrate 4, and a bottom surface 14a and a vertical surface 14b. It consists of a buffer member 14 consisting of an inclined surface (14c) for connecting the, is formed over the entire surface of the glass substrate (4) facing the rubbing roller (10).

The vertical surface 14b of the buffer member 14 is formed at the same height as the thickness of the glass substrate 4 in response to the glass substrate 4 seated on the table 6, and the bottom surface 14a is the vertical surface 14b. It is preferable to form a width sufficiently larger than the height of) to smooth the inclination of the inclined surface 14c.

In addition, the inclined surface 14c of the buffer member 14 is formed with a predetermined curvature convex toward the outside of the inclined surface 14c, for example, so that the rubbing cloth 8 smoothly moves on the inclined surface 14c and the glass substrate 4. Induces more gentle contact with the rubbing cloth (8).

The buffer member 14 having such a configuration is installed on the table 6 in consideration of the position where the glass substrate 4 is seated. The buffer member 14 may be fixedly fixed to the table 6. 6) can be provided detachably removable. And the material of the shock absorbing member 14 is a metal material with strong abrasion resistance, for example, consists of stainless steel.

As the buffer member 14 is installed on one surface of the glass substrate 4 facing the rubbing roller 10 in this manner, when the table 6 moves simultaneously with the rotation of the rubbing roller 10, the rubbing roller 10 is moved to the rubbing roller 10. The wound rubbing cloth 8 comes into contact with the alignment film 2 applied to the surface of the glass substrate 4 via the inclined surface 14c of the buffer member 14.

As a result, the rubbing cloth 8 is not in contact with the edge of the glass substrate 4, but rather gently contacts the glass substrate 4 via the inclined surface 14c of the buffer member 14, thereby causing wear and damage due to contact with the edge. This has the advantage of being prevented.

4 is a plan view of a rubbing device according to another embodiment of the present invention, the rubbing roller 10 is positioned at a predetermined angle with one side of the glass substrate 4 to face the edge of the glass substrate 4, The table 6 is configured to move linearly toward the rubbing roller 10 as in the previous embodiment.

In general, since the electro-optical characteristics of the liquid crystal display are determined according to the rubbing angle, it is important to set a rubbing angle suitable for the use and characteristics of the product. Thus, the rubbing roller 10 is disposed on one side of the glass substrate 4. The rubbing angle can be controlled by adjusting the rubbing direction by arranging to have an arbitrary angle with.

As shown in FIG. 5, in the case of a normal ethiene type liquid crystal display device, the rubbing directions of the upper and lower substrates are indicated by dashed lines and dashed lines, respectively. In this case, the rubbing angle? It means the angle in which the rubbing direction is symmetrical. In the normal estylene type liquid crystal display device, the rubbing angle θ varies from 180 ° to 270 °, but 180 °, 200 °, 220 °, and 240 ° are commonly used, and the center of the rubbing angle θ is Optimum contrast is shown in the angular direction.

As such, when the rubbing roller 10 has an arbitrary angle with the glass substrate 4 and is disposed to face the edge of the glass substrate 4 to change the rubbing angle, the buffer member 14 may be connected to the rubbing roller 10. It is provided over the whole or part of the 1st surface 4a and the 2nd surface 4b centering on the edge of the glass substrate 4 which opposes. Specific shape and material of the shock absorbing member 14 are the same as in the previous embodiment, and thus detailed description thereof will be omitted.

As the above-mentioned buffer member 14 is formed on the first surface 4a and the second surface 4b of the glass substrate 4, the table on which the glass substrate 4 is seated simultaneously with the rotation of the rubbing roller 10 is provided. When 6 moves linearly in the direction of the arrow, the rubbing cloth 8 wound around the rubbing roller 10 contacts the alignment film 2 formed on the glass substrate 4 via the inclined surface 14c of the buffer member 14. Done.

Therefore, instead of contacting the edges of the glass substrate 4, the rubbing cloth 8 may be disposed on the inclined surface 14c of the buffer member 14 provided on both sides of the glass substrate 4 around the edge of the glass substrate 4. Since it makes gentle contact with the glass substrate 4, wear and damage by contact with an edge are reduced effectively.

As such, the present embodiment provides an inclined surface connecting the surface of the table and the surface of the glass substrate to minimize the wear and damage of the rubbing cloth, thereby improving the quality of the alignment layer, and improving the visibility and uniformity of the liquid crystal display device. .

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the range of.

As such, the present invention provides a buffer member having an inclined surface on at least one surface of the glass substrate facing the rubbing roller so that the rubbing cloth contacts the surface of the glass substrate via the inclined surface of the buffer member. As a result, the wear and damage of the rubbing cloth can be minimized to suppress the occurrence of residues and scratches on the surface of the alignment layer, thereby improving the film quality of the alignment layer, and improving the visibility and uniformity of the liquid crystal display device.

Claims (10)

A table for seating and moving the glass substrate coated with the alignment film; A rubbing roller positioned at an outer side of the glass substrate and having a rubbing cloth mounted on an outer circumferential surface thereof so that the rubbing cloth contacts the surface of the alignment film by a relative motion with the glass substrate while rotating the motor itself; And a means for smoothly inducing contact of the rubbing cloth and the glass substrate by providing an inclined surface connecting at least one surface of the glass substrate facing the rubbing roller to the surface of the table and the glass substrate. The method of claim 1, And a cushioning member comprising a bottom face in which said means is in contact with a table, a vertical face in contact with a side of a glass substrate, and an inclined face connecting said bottom face and a vertical face. The method of claim 2, A rubbing device in which the bottom surface of the buffer member is formed to have a width larger than the height of the vertical surface. The method of claim 2, A rubbing device in which the vertical surface of the buffer member is flush with the thickness of the glass substrate. The method of claim 2, A rubbing device comprising a curved surface in which the inclined surface of the buffer member is convex toward the outside of the inclined surface. The method of claim 1, A rubbing device in which the buffer member is made of a metal material containing stainless steel. The method of claim 1, The rubbing device is fixedly provided that the buffer member is fixed to the table. The method of claim 1, A rubbing device in which the buffer member is detachably provided on a table. The method of claim 1, The rubbing roller is positioned to face one surface of the glass substrate, the rubbing member is provided on one surface of the substrate facing the rubbing roller. The method of claim 1, The rubbing roller is positioned at a predetermined angle with one side of the glass substrate so as to face the edge of the glass substrate, the rubbing device is provided on both sides around the edge of the glass substrate facing the rubbing roller.