JP3711456B2 - Substrate coating method, substrate coating apparatus, liquid crystal display manufacturing method, and surface illumination device manufacturing method - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to a method for forming a thin film by applying a solution to a substrate, and more particularly to a method for coating a solution on a substrate. In particular, the surface of the liquid crystal display substrate used in the liquid crystal display and the liquid crystal display member are coated with a liquid crystal display thin film material solution, or the crystal resonator electrode is formed on the surface or side of the crystal substrate. The present invention relates to a method for coating a resist solution and an apparatus therefor. Furthermore, the present invention relates to a surface illumination device for a liquid crystal display device to which these coating methods are applied.
[0002]
[Prior art]
Conventionally, as a method for forming a thin film by applying a solution to a substrate, a dip-up method, a spinner method, and a spray method are known.
[0003]
Moreover, the coating of the material solution for the liquid crystal display thin film used for the functional film of the liquid crystal display has been performed by a method such as spin coating, roll coating, and printing.
[0004]
As for spin coating, for example, as described in Patent Document 1, around the rotating head that rotates the member to be coated, the rotating head integrally rotates with the surface of the member to be coated on the periphery of the member to be coated. By providing an auxiliary member that is substantially flush with the surface, there is one that uniformly applies the coating liquid to a member to be coated having a corner other than a circle.
[0005]
As for roll coating, as described in JP-B-61-267004, a photosensitive paint containing a colorant is applied to the entire surface of a transparent substrate such as glass as a medium for forming a color filter by a spinner or a roll coater. There was something to apply to.
[0006]
Further, as described in Japanese Patent Publication No. 61-146540, printing is performed by shifting the relative position between the screen printing pattern mask and the thick film pattern surface in the squeegee moving operation direction during the squeegee moving operation. There was something to form.
[0007]
The coating is described on pages 259 to 398 in the coating method in “Advances in Latest Coating Technology” issued on April 30, 1988, and the special coating is described on pages 515 to 545.
[0008]
In addition, as to coating relating to static electricity, fog, and liquid crystal, as described in Japanese Examined Patent Publication No. 2-122873, the gas generated in the method in which the aerosol generated by the aerosol generation device is guided to the surface of the object to be coated is applied. In the presence of solvent vapor, the coating placed in the vapor is cooled to below the saturation point of the solvent vapor, so that the solvent vapor contained in the aerosol is deposited on the surface of the coating. The above-mentioned aerosol dispersoid (hereinafter referred to as “particles”) is deposited on the surface of the dew droplets or on the surface of the same film formed by aggregating them, and then the liquid film is formed. A method such as evaporating the solvent and applying only the remaining aerosol particles has been proposed.
[0009]
[Patent Document 1]
Japanese Patent Publication No. 61-61069
[0010]
[Problems to be solved by the invention]
However, the conventional techniques as described above have the following problems.
[0011]
Usually, a substrate for a liquid crystal display body or a liquid crystal display body member is an insulator using a square plate material. As a processing method, lapping processing or molding processing is performed, but the thickness accuracy is about ± 0.1 mm. Further, the accuracy of flatness and flatness is usually from 0.1 μm to 0.5 μm, and it takes a high cost to obtain higher accuracy. However, since the gap accuracy of the liquid crystal layer of the cell of the liquid crystal display body is laminated in the range of ± 0.01 μm and ± 0.5 μm, the accuracy cannot be obtained by such a processing method, so the display quality as a liquid crystal display body Can't keep up. Therefore, in the conventional processing method, it has been difficult to stably perform uniform thin film coating or thin film printing on the surface of the liquid crystal display substrate (or liquid crystal display member). Furthermore, there is a problem that impurities are mixed into the thin film material solution for liquid crystal display bodies and the paint to deteriorate the quality of the film, and the display quality of the liquid crystal display and the yield at the time of manufacture cannot be improved.
[0012]
Therefore, the present invention solves such problems, and its object is to form a fine mist of a liquid crystal display thin film material solution or paint on the surface of a liquid crystal display substrate or a liquid crystal display member. To provide a method for obtaining a high-quality coating thin film by charging the static electricity generated by the static electricity generator into a fine mist and applying it to the surface of a liquid crystal display substrate or liquid crystal display member. is there.
[0013]
[Means for Solving the Problems]
The present invention is for achieving the above-described object, and the contents thereof will be described below.
[0014]
The substrate coating method of the present invention is a substrate coating method in which a thin film material solution is applied to a substrate, the step of placing the substrate on a grounded table, and the thin film material solution is granulated to form the thin film material solution. And a step of applying the charged thin film material solution to the substrate, wherein the applying step includes disposing a charged mask above the substrate, A thin film material solution is applied to the substrate through the mask.
[0015]
According to such a substrate coating method, the charged thin film material solution is in a fine granular form, and further, is appropriately dispersed with respect to the surface of the substrate (without being partially concentrated). And a uniform thin film can be formed on the liquid crystal display member. For example, when a uniform coating thin film is formed on the entire surface of the substrate, it is very effective because a high quality thin film can be easily formed.
[0016]
The substrate coating method can be used, for example, in a manufacturing process for forming an electrode film of a crystal resonator. This is intended for applications other than the formation of a thin film on a substrate. That is, a high-quality thin film can be formed by applying a granular crystal electrode forming resist solution to the surface and side surfaces of the crystal substrate.
[0017]
According to such a substrate coating method, a thin film pattern having an arbitrary shape can be formed by using a mask, so that the photoetching process, which is a selective pattern forming method essential as a post-process for the entire surface coating, can be eliminated. Become. For example, it is effective when regularly forming a pattern.
[0018]
Further, in the above-described substrate coating method, the granular thin film material solution may be conveyed using a gas, and the gas may be intermittently flowed.
[0019]
According to this substrate coating method, fine grooves can be formed on the surface of the substrate. Moreover, this substrate coating method can be used, for example, in a method for producing a liquid crystal display. In this case, the orientation of the liquid crystal is performed by intermittently changing the pressure of the gas carrying the granular thin film material solution and regularly applying the charged granular thin film material solution to the surface of the substrate. be able to. This can eliminate the rubbing cleaning in the conventional liquid crystal display manufacturing process. Thus, by eliminating the step of rubbing cleaning, it is possible to improve the alignment quality and the display quality of the liquid crystal display.
[0020]
The method of manufacturing a liquid crystal display according to the present invention includes a step of placing the substrate on a grounded table in a method of manufacturing a liquid crystal display in which a thin film material solution is applied to a substrate, and the thin film material solution is made granular. A step of charging the thin film material solution; and a step of applying the charged thin film material solution to the substrate, wherein the applying step includes disposing a charged mask above the substrate. The granular thin film material solution is applied to the substrate through the mask.
[0021]
According to such a method for manufacturing a liquid crystal display body, the charged mist is finely granular, and further, the mist is appropriately dispersed (without being partially concentrated) on the surface of the substrate. And a uniform thin film can be formed on the liquid crystal display member.
[0022]
For example, when a uniform coating thin film is formed on the entire surface of the substrate, it is very effective because a high quality thin film can be easily formed.
[0023]
According to such a method for manufacturing a liquid crystal display, a thin film pattern having an arbitrary shape can be formed by using a mask, so that the photoetching process, which is an essential selective pattern forming method, can be abolished as a subsequent process of the entire surface coating. It becomes like this. For this reason, a substrate with a thin film or a member with a paint film can be produced by a simple process design, and the yield improvement and cost reduction of a liquid crystal display can be achieved. For example, it is effective when regularly forming a pattern. Moreover, in this liquid crystal display manufacturing method, for example, a gap forming material can be used as a granular thin film material solution. In this case, the gap material forming material is applied at a predetermined interval or other than the pixels of the substrate by applying the gap forming material at a predetermined position on the surface of the substrate using a mask. This stabilizes the gap material and improves the display quality of the liquid crystal display. Further, the coating method configured such that there is no gap forming material in the display pixel can provide a display with good contrast.
[0024]
The method of manufacturing a liquid crystal display according to the present invention includes a step of placing the substrate on a grounded table in the method of manufacturing a liquid crystal display in which a thin film material solution and a gap forming material are applied to a substrate, and the thin film material solution. And charging each of the thin film material solution and the gap forming material by making the gap forming material granular, and applying the charged thin film material solution and the charged gap forming material to the substrate; And in the applying step, a charged mask is disposed above the substrate, and at least one of the granular thin film material solution and the granular gap forming material is applied to the substrate through the mask. It is characterized by that.
[0025]
According to such a liquid crystal display manufacturing method, a thin film is formed on the substrate surface, and the work of uniformly dispersing and fixing the gap forming material is simultaneously performed. For example, if an alignment film material solution is used as a thin film material solution, all processes of alignment film coating, baking, rubbing, cleaning, and gap material spraying in the conventional liquid crystal display manufacturing process can be realized in just one step. This greatly improves the manufacturability of the liquid crystal display. Further, since the gap material does not move due to external vibration to the finished liquid crystal display, the display quality of the liquid crystal display is improved.
[0026]
The method for producing a liquid crystal display according to the present invention comprises a step of placing the substrate on a grounded table in the method for producing a liquid crystal display by applying a liquid crystal and a gap forming material to a substrate, and the liquid crystal and the gap formation. A step of charging the liquid crystal and the gap forming material by making each material granular, and a step of applying the charged liquid crystal and the charged gap forming material to the substrate. Is characterized in that a charged mask is disposed above the substrate and the granular gap forming material is applied to the substrate through the mask.
[0027]
According to such a method for manufacturing a liquid crystal display, the work of injecting a liquid crystal group into an empty cell in which liquid crystal display glass is bonded in a vacuum apparatus is abolished. That is, after a coating film having an appropriate thickness is formed, the liquid crystal display substrates are bonded together in a vacuum apparatus, whereby a liquid crystal display having a uniform gap can be easily manufactured.
[0028]
The method for producing a liquid crystal display of the present invention comprises a step of placing the substrate on a grounded table in a method for producing a liquid crystal display by applying a thin film material solution and a conductive material to a substrate, and the thin film material solution and Comprising the steps of charging the thin film material solution and the conductive material by making each of the conductive materials granular, and applying the charged thin film material solution and the charged conductive material to the substrate, The step of applying is characterized in that a charged mask is disposed above the substrate and the granular thin film material solution is applied to the substrate through the mask.
[0029]
According to such a method for manufacturing a liquid crystal display, a substrate with a conductive thin film having a low resistance value can be realized by the conductive film thus formed.
[0030]
The method for producing a liquid crystal display according to the present invention comprises a step of placing the substrate on a grounded table in the method for producing a liquid crystal display in which a thin film material solution is applied to a substrate on which a pattern is formed, and the thin film material A step of charging the thin film material solution into a granular form, and a step of applying the charged thin film material solution to the substrate and the pattern, wherein the applying step comprises a charged mask. Is disposed above the substrate, and the granular thin film material solution is applied to the substrate through the mask.
[0031]
According to such a method of manufacturing a liquid crystal display, a flattening film is formed by forming a thin film material solution into a granular form and applying the charged granular thin film material solution to a step pattern formed on the surface of the substrate. It is. As a result, a thin film with high quality can be uniformly formed even if the surface of the substrate and the member have some uneven surfaces.
[0032]
The substrate coating apparatus of the present invention is a substrate coating apparatus for forming a thin film by applying a thin film material solution to a substrate. An atomization generator for granulating the thin film material solution, and an electrostatic for charging the thin film material solution And a static electricity generating nozzle for applying a charged thin film material solution to the substrate, a charge amount sensor for detecting the charge amount of the thin film, and the thin film material based on data of the charge amount sensor An electrostatic charge control device for setting a charge amount to the solution, and a charged mask is disposed above the substrate, and the granular thin film material solution is applied to the substrate through the mask. And
[0033]
According to such a substrate coating apparatus, the charged thin film material solution is in a fine granular form, and further, is appropriately dispersed (without partially concentrated) on the surface of the substrate, so that the surface of the substrate is And a uniform thin film can be formed on the liquid crystal display member. In addition, the control means controls the film thickness, film quality and density of the coating by forming a thin film for a liquid crystal display on the surface of the substrate while controlling the amount of electrostatic charge. This makes it possible to perform manufacturing management for forming various functional films.
[0034]
The atomization generator may have a plurality of nozzles for conveying the granular thin film material solution.
[0035]
According to such a substrate coating apparatus, a plurality of nozzles are provided so that a granular thin film material solution can be simultaneously applied to different surfaces of the substrate. Thereby, a thin film can be formed at high speed.
[0036]
The method for manufacturing a surface illumination device according to the present invention is a method for manufacturing a surface illumination device in which a reflective film solvent is applied to form a reflective film on a light guide plate, and the light guide plate is disposed on a grounded table; The step of charging the reflective film solvent by making the reflective film solvent granular, and the step of applying the charged reflective film solvent to the light guide plate, wherein the applying step is charged. A mask is disposed above the substrate, and the granular thin film material solution is applied to the substrate through the mask.
[0037]
According to such a method for manufacturing a surface illumination device, such a thin film forming technique is applied, and is applied to a surface illumination device having a light guide plate. Then, a darkened reflective film is formed on the surface of the light guide plate by controlling the charge amount with respect to the granular reflective film solvent. As a result, bright and uniform illumination can be realized in the surface illumination. In addition, the substrate coating method, substrate coating apparatus, liquid crystal display manufacturing method, and surface illumination apparatus manufacturing method of the present invention are non-contact coating methods and do not require mechanical precision, so that coating is inexpensive. An apparatus can be realized. Furthermore, the solvent used in the photoetching process is no longer necessary, which is an effective measure for preventing environmental destruction.
[0038]
【Example】
Hereinafter, the present invention will be described in detail with reference to the drawings.
[0039]
(Example 1)
FIG. 1 is a sectional view showing the overall configuration of an embodiment of a substrate coating apparatus according to the present invention. Here, a case where a thin film for a liquid crystal display is formed on a substrate will be described as an example. In the figure, a solvent tank 4 filled with a thin film material solution 3 for a liquid crystal display is set in the atomization generator main body 2. The atomization generator main body 2 includes an ultrasonic transducer 1. The ultrasonic vibrator 1 vibrates from when the thin film material solution 3 for the liquid crystal display body is filled on the upper surface of the ultrasonic vibrator 1, thereby generating a mist 5 of the thin film material solution 3 for the liquid crystal display body. Then, dry air or nitrogen gas or the like is passed from the outer peripheral side (in the direction of arrow A) of the atomization generator main body 2 to the blower nozzle 7 installed so as to penetrate the atomization generator main body 2 so as to communicate with the inside of the mist guide nozzle 6. The mist 5 of the liquid crystal display thin film material solution 3 is conveyed along the inside of the mist guide nozzle 6. A static electricity generating nozzle 20 is installed near the tip of the mist guiding nozzle 6. When a control signal is sent to the static electricity generation nozzle 20 from the static electricity amount control device 21, static electricity is generated, and the mist 5 of the liquid crystal display thin film material solution 3 is charged. At this time, since the liquid crystal display substrate table 14 to which the liquid crystal display substrate 12 is fixed is grounded, the mist 5 flies toward the liquid crystal display substrate 12 and the liquid crystal display substrate 12. It is applied and coated on the top surface. The coated film is heated by the heater 15 during coating. The above is the basic configuration of the substrate coating method and apparatus of the present invention.
[0040]
FIG. 2 is a perspective view showing an example of an actual method of coating the substrate described in FIG. In this example, a method of forming a thin film by scanning in the XY direction on the surface of the liquid crystal display substrate 12 will be described.
[0041]
First, the mist guide nozzle 6 and the static electricity generation nozzle 20 are configured to be movable at a constant speed in a direction parallel to the atomization generator main body 2 (arrow Y direction). On the other hand, the liquid crystal display substrate table 14 is configured to be movable at a constant speed in a direction (arrow X direction) perpendicular to the atomization generating device body 2. Then, the coating film 23 is formed by appropriately moving in the X and Y directions, making the liquid crystal display thin film material solution into mist-like particles, charging with the static electricity generating nozzle 20 and flying the mist. Here, by setting the gap between the tip of the static electricity generating nozzle 20 and the surface of the liquid crystal display substrate 12 to an appropriate distance, the surface of the liquid crystal display substrate 12 has a uniform film quality / coating thickness ± 1. % High quality film can be formed. The gap between the tip of the static electricity generation nozzle 20 and the surface of the liquid crystal display substrate 12 is preferably set at an interval of about 1 mm to 10 mm. The size of the mist generated by the atomization generator main body 2 is desirably in the range of 500 to 1000 liters.
[0042]
Next, a method of forming a pattern by charging static electricity to the hollow pattern mask and flying mist on the surface of the liquid crystal display substrate will be described.
[0043]
In FIG. 1 again, when the coating film 11 is formed, the mask 9 with the hollow pattern is set on the liquid crystal display substrate table 14 using the mask holding jig 10. Then, the mask 9 with the hollow pattern is charged by the voltage variable device 22. When the entire surface coating or a plurality of coating films 11 are formed on the liquid crystal display substrate 12, the atomization generator main body 2 is placed in a direction parallel to the static electricity generation nozzle 20 (arrow Y direction) The atomization generator Y-axis moving motor 8 is moved at a constant speed by the atomization generator slide shaft 19. Further, a grounded liquid crystal display substrate table 14 is mounted on a table body 16 by a liquid crystal display substrate table table X direction moving motor 18, and the table sliding shaft 17 and the liquid crystal display substrate substrate are used. The receiving part 13 is connected and moved in the direction of arrow X at a constant speed. With this configuration of the apparatus, the photoetching process in the process of manufacturing the liquid crystal display body can be eliminated.
[0044]
3 and 4 are perspective views of a method for forming a mosaic pattern and a stripe pattern shown as an example of forming a thin film on a substrate using a hollow pattern mask having various shapes.
[0045]
A mask 25 with a hollow mosaic pattern or a mask 27 with a hollow stripe pattern charged by the voltage variable device 22 is provided, and the gap with the surface of the liquid crystal display substrate 12 is kept at an appropriate distance. This distance may be in the range of 0.1 mm to 1 mm, and 0.1 mm is particularly preferable. When the static electricity generating nozzle 20 is moved at a constant speed while blowing the mist of the thin film material solution for the liquid crystal display body and the substrate table 14 for the liquid crystal display body is moved in the direction of the arrow X, the mosaic pattern film 24 and the stripe pattern film 26 are moved. Can be formed. As the pattern size, a mosaic pattern thin film or a stripe pattern thin film having a minimum dot of 80 μm and a film thickness of about 200 mm can be formed.
[0046]
Next, a method of forming a mist of a thin film material solution for a liquid crystal display body on the surface of the liquid crystal display body substrate uniformly or entirely on the surface will be described. This method is a method of forming a thin film without moving the atomization generator main body 2 described above.
[0047]
FIG. 5 is a perspective view for explaining a method of uniformly forming a thin film of a thin film material solution for a liquid crystal display body over the entire surface.
[0048]
In the figure, a wide-angle static electricity generating nozzle 28 equipped with a dispersion nozzle 29 for uniformly dispersing the mist over the entire surface is provided at the tip of the mist guiding nozzle 6. The wide-angle static electricity generating nozzle 28 charges static electricity in a range of −30 kv to −70 kv in a fixed state. The dispersion nozzle 29 is blown with N2 gas at a rate of 0.01 liter / minute to 1.5 liter / minute. The liquid crystal display substrate substrate 14 on which the liquid crystal display substrate 12 is set is moved in the direction of arrow X and stopped at the lower part of the wide-angle static electricity generating nozzle 28 on the surface of the liquid crystal display substrate 12. The mist 5 of the thin film material solution is coated. When the liquid crystal display substrate table 14 is coated with an arbitrary stop time, a coating thin film can be formed on the entire surface of the liquid crystal display substrate 12. The film thickness distribution can be coated with an accuracy of ± 1%. In this example, when the thin film was formed with the stop time of the liquid crystal display substrate 12 being 2 minutes, a uniform thin film could be formed in the thickness range of 0.5 μm to 0.6 μm.
[0049]
Next, perspective views of a method for forming a thin film having a uniform pattern on the entire surface of the liquid crystal display substrate are shown in FIGS. 6 is a perspective view of a method of forming a mosaic pattern, and FIG. 7 is a method of forming a stripe pattern. In this method, the entire surface of the liquid crystal display substrate 12 is coated with a mosaic pattern film 24 ′ and a stripe pattern film 26 ′. A mask 25 ′ with a hollow mosaic pattern or a mask 27 ′ with a hollow stripe pattern is provided at a lower portion of the wide-angle static electricity generation nozzle 28 with an appropriate gap. For example, the gap between the liquid crystal display substrate 12 is set in a range of 0.1 mm to 1 mm with respect to the liquid crystal display substrate 12, the liquid crystal display substrate table 14 is moved in the direction of the arrow X, and the wide-angle static electricity generating nozzle 28. The surface of the substrate 12 for liquid crystal display body is coated with a mist of the thin film material solution for liquid crystal display body in a state stopped at the lower part of the substrate. When the liquid crystal display substrate table 14 is coated by arbitrarily setting the stop time, the mosaic pattern film 24 ′ or the stripe pattern film 26 ′ can be formed on the entire surface of the liquid crystal display substrate 12. The film thickness distribution can be coated with an accuracy of ± 1% as described above. Further, the mosaic pattern accuracy and the stripe pattern accuracy can be ensured to be ± 5 μm or less, and the mosaic pattern group and the stripe pattern group can be formed in a shape without blur. Thus, a thin film having excellent film quality characteristics could be formed.
[0050]
(Example 2)
In this embodiment, an alignment treatment method capable of forming fine grooves on the surface of a liquid crystal display substrate and a coating method for uniformly dispersing and fixing a liquid crystal display gap forming material will be described with reference to FIGS. . Note that the basic configuration of the substrate coating method and apparatus of this embodiment is the same as that shown in FIG. 1, and therefore, only different parts are shown, and illustration and description of other common parts are omitted. To do. Further, since the basic configurations of the third to sixth embodiments and other embodiments described below are the same as those shown in FIG. 1, illustration and description of common parts are omitted as in the second embodiment. .
[0051]
FIG. 8 is a perspective view showing an embodiment of a method for aligning the surface of a liquid crystal display substrate. In the figure, liquid crystal display alignment is produced by intermittently flowing a gas such as door raied air or nitrogen from the blow nozzle to the mist 30 of the alignment film material solution for liquid crystal display generated by an ultrasonic vibrator. The mist 30 of the membrane material solution is intermittently conveyed through the mist guide nozzle and charged by the static electricity generating nozzle 20 provided at the outlet of the mist guide nozzle. Then, the mist 30 of the charged alignment film material solution for the liquid crystal display body is applied to the surface of the substrate 12 for the liquid crystal display body by flying to form a fine groove 31. At this time, the shape and width of the fine groove 31 can be changed by changing the timer set value for intermittently flowing the gas. As a result, the alignment strength of the liquid crystal can be controlled.
[0052]
In this example, when the timer set value for intermittent gas flow was varied between about 0.01 m / sec and 0.05 m / sec, a groove 31 with a groove width of 100 to 500 mm was formed. Further, when the timer set value was varied between about 0.1 m / sec and 1 m / sec, a groove 31 with a groove width of 1000 to 5000 mm could be formed. And by comprising in this way, since the rubbing washing | cleaning in the conventional liquid crystal display body manufacturing process can be abolished, orientation quality and the display quality of the liquid crystal display improved.
[0053]
FIG. 9 is a cross-sectional view showing a method for uniformly dispersing and simultaneously applying an alignment treatment and a liquid crystal display gap forming material on the surface of a liquid crystal display substrate. In the drawing, a liquid crystal display gap forming material 32 is mixed in the liquid crystal display alignment film material solution. Then, by charging the mist of the alignment film material solution 30 for the liquid crystal display body and the mist of the gap forming material 32 for the liquid crystal display body with the static electricity generating nozzle 20, the gap forming material 32 for the liquid crystal display body is uniformly dispersed. At the same time as the mist of the alignment film material solution 30 for the liquid crystal display, it can be applied to the surface of the substrate 12 for the liquid crystal display. By forming a thin film by this method, it is possible to simultaneously form an alignment process, disperse a gap for a liquid crystal display, and fix a gap material for a liquid crystal display.
[0054]
By carrying out by this method, the process of alignment film coating, baking, rubbing, cleaning, and gap material spraying in the conventional liquid crystal display manufacturing process can be manufactured in one step. In addition, since the gap material does not move to the finished liquid crystal display due to external vibration, the display quality of the liquid crystal display is improved.
[0055]
(Example 3)
In this embodiment, a liquid crystal group (a collection of liquid crystals) is applied to the surface of the liquid crystal display substrate by forming it into a fine mist and electrostatically charged, and a liquid crystal display body gap material is mixed in the liquid crystal group. The method of applying the coating will be briefly described with reference to FIGS.
[0056]
FIG. 10 is a cross-sectional view showing a method for applying a liquid crystal group to the surface of a liquid crystal display substrate. In the figure, the surface of the substrate 12 for liquid crystal display body is subjected to alignment treatment by forming fine grooves 31 in advance by the method described in the second embodiment (FIG. 8 or FIG. 9). Then, the liquid crystal group 33 which is atomized and conveyed by the mist guiding nozzle and further charged by the static electricity generating nozzle 20 is applied to the surface of the liquid crystal display substrate 12 with an arbitrary film thickness. Thereafter, the substrates for the liquid crystal display body are bonded together in a vacuum apparatus to complete the liquid crystal display body.
[0057]
FIG. 11 is a cross-sectional view showing a method of mixing and applying a liquid crystal group and a gap material to the surface of a liquid crystal display substrate. In the figure, an arbitrary liquid crystal display gap forming material 32 is mixed in the liquid crystal group 33, and the liquid crystal group 33 and the liquid crystal display gap forming material 32 that are made into a mist by an ultrasonic vibrator are mixed with an air flow or gas. The mist is transported by a flow, and the mist is charged by an electrostatic generator (not shown) to repel the gap members, and is applied to the surface of the liquid crystal display substrate 12. When the desired film thickness is reached, the liquid crystal display substrate is bonded together in a vacuum apparatus.
[0058]
By carrying out this method, it is not necessary to inject the liquid crystal group into the empty cell in which the liquid crystal display glass is bonded in a vacuum apparatus as in the conventional case, so that the gap is easily uniform. Liquid crystal display can be manufactured.
[0059]
Next, a method for applying a liquid crystal display gap material forming material to a predetermined position on the surface of the liquid crystal display substrate will be described.
[0060]
FIG. 12 is a cross-sectional view illustrating a method for applying a gap material forming material to a predetermined position on the surface of the liquid crystal display substrate. In the figure, a fine groove 31 is formed in advance on the surface of the liquid crystal display substrate 12 and subjected to alignment treatment. Here, the mask 9 with the hollow pattern is charged using the voltage variable device 34. Then, the gap forming material 32 for the liquid crystal display is mixed in a volatile solvent or pure water and transported in the form of a mist. Then, the volatile solvent or pure water is volatilized, and only the liquid crystal display gap forming material 32 is repelled and dispersed by charging with the static electricity generating nozzle 20, while passing through the mask 9 with the hollow pattern and flying. Then, it drops and is applied to the surface of the liquid crystal display substrate 12.
[0061]
By carrying out this method, the gap material forming material can be applied to the surface of the liquid crystal display substrate at regular intervals. In addition, by arranging the hollow pattern mask in consideration of the position of the pixel on the liquid crystal display substrate, the gap material forming material can be applied to places other than the pixel on the liquid crystal display substrate. With the above method, the display quality of the liquid crystal display is improved, and the coating method configured such that there is no gap material forming material in the display pixel can provide a display with good contrast.
[0062]
(Example 4)
In this example, a method of forming a conductive film on the surface of a liquid crystal display substrate using a mixture of conductive particles in a liquid crystal display thin film material solution will be described.
[0063]
FIG. 13 is a cross-sectional view showing a method for forming a conductive thin film on the surface of a liquid crystal display substrate. In the figure, a volatilization preventing liquid is prepared by mixing conductive particles 38 in a special liquid crystal display thin film material special solution. The volatilization preventing liquid can control the film quality of the special solution for thin film material for liquid crystal display. The thin film material special solution 37 for a liquid crystal display, which has been atomized by the atomization generator main body, is charged by the static electricity generating nozzle 20 and is applied to the surface of the liquid crystal display substrate 12 together with the conductive particles 38. At least two or more electrode probes 35 are brought into contact with each electrode pattern 39 formed in advance on the surface of the liquid crystal display substrate 12, and a voltage is applied by the voltage control device 36 to reduce the amount of mist applied. Control. The conductive thin film 40 can be formed by baking with a heater (not shown) installed on the liquid crystal display substrate table 14 simultaneously with the application.
[0064]
By implementing this method, a liquid crystal display substrate with a conductive thin film having a low resistance value can be realized.
[0065]
(Example 5)
In this embodiment, a method for planarizing a surface in which a step pattern is formed in advance on the surface of a liquid crystal display substrate will be described.
[0066]
FIG. 14 is a cross-sectional view showing a method of flattening the surface of the liquid crystal display substrate. In the figure, it is assumed that a step pattern 43 is formed in advance on the surface of the liquid crystal display substrate 12 by a process such as photoetching. Here, a mixture of the flattening solution 41 for liquid crystal display and the volatilization preventing liquid is atomized by the atomization generator main body, and further charged by the static electricity generation nozzle 20. The charged mist is applied onto the step pattern 43 on the surface of the liquid crystal display substrate 12, whereby a flat planarizing film 42 can be formed on the surface of the step pattern 43.
[0067]
By carrying out this method, a flattening film in submicron units can be formed, so that the gap of the liquid crystal display becomes uniform and the gradation of the liquid crystal display device can be displayed with high definition. In this embodiment, when the step pattern 43 on the surface of the liquid crystal display substrate 12 has a step of 0.5 μm to 1.5 μm, the planarization solution 41 for liquid crystal display and the volatilization preventing liquid are obtained by this method. As a result, the film was made into a mist and electrostatically charged and applied onto the step pattern 43. As a result, a flattened film having a flatness in the range of about 80 to 100 mm could be formed.
[0068]
(Example 6)
In this embodiment, it will be described that the reflection film of the light guide plate of the surface illumination for the liquid crystal display device can be darkened by controlling the amount of electrostatic charge.
[0069]
FIG. 15 is a perspective view showing a method for realizing the concentration of the reflection film of the light guide plate of the surface illumination device for a liquid crystal display device according to the present invention. In the figure, the solvent 44 for reflective film particles is diluted with a diluent to form a solution having a viscosity of several tens of cps, atomized by the atomization generator main body, and further charged by the static electricity generation nozzle 20. The charged mist is applied onto the light guide plate 45. At this time, the reflection film 46 can be darkened by applying it to the light guide plate 45 while changing the amount of electrostatic charge from −60 kv to −10 kv by the static electricity amount control device.
[0070]
FIG. 16 is a cross-sectional view of a surface illumination device for a liquid crystal display device incorporating a light-concentrating light guide plate 45 realized by using the method shown in FIG. In the figure, the light beam generated by the light source 49 is guided into the light guide plate 45 directly or via the mirror 48. The light beam that has traveled into the light guide plate 45 is refracted in the light guide plate 45, is reflected by the reflection film 46 that is formed to be light and dark, and is guided to the light collection film 47. At this time, since the reflection film 46 is formed thicker as the distance from the light source 49 increases, the amount of reflected light changes according to the distance from the light source, and the reflection film far from the light source reflects many light rays. become. As a result, the surface illumination can be made uniform.
[0071]
FIG. 17 shows the luminance measurement data of the surface illumination device for a liquid crystal display body formed by this darkening. The luminance data 50 has an average luminance of 500 nits or more and the in-plane luminance distribution is ± 2% or less. By implementing this method on the light guide plate, a bright and uniform surface illumination can be performed as a surface illumination device for a liquid crystal display device. Further, members for flattening the brightness such as a diffusion film and a light collecting film which have been conventionally used are not necessary.
[0072]
(Other examples)
In this embodiment, after the liquid crystal display thin film material solution (or paint) is atomized, the surface of the liquid crystal display substrate (or liquid crystal display member) is controlled while controlling the amount of static electricity to be charged. An apparatus for forming a thin film will be described.
[0073]
FIG. 18 is a diagram showing an embodiment of a control system (control means) for a substrate coating apparatus according to the present invention. In the figure, the mist generated by the atomization generating unit 51 is configured to be conveyed to the static electricity generating nozzle 20, and is further configured to be charged by the static electricity generating nozzle 20 and applied to the substrate 12. Yes. This is a configuration common to many of the embodiments described above.
[0074]
Now, the substrate coating apparatus is controlled by the personal computer 54. The electrostatic quantity control device 21 that determines the amount of charge with respect to the fog is connected to the personal computer 54 via a voltage variable device 52 configured by a D / A converter or the like, and can generate an arbitrary voltage within a predetermined range. . First, voltage change is commanded from the personal computer 54 to the voltage variable device 52, predetermined static electricity is generated, fog is charged, and a thin film is formed on the substrate. The state of the thin film formed on the substrate is detected by a plurality of charge amount sensors 56 installed on the back surface of the substrate 12 and input to the personal computer 54 via the I / O unit 55. The personal computer 54 controls the electrostatic quantity control device 21 based on the input data, and operates to form a desired thin film.
[0075]
Such a program for controlling the amount of static electricity is filed in the data storage unit 53, and can store various procedures and methods for forming a coating film. With this system configuration, it is possible to control the film thickness, film quality, and concentration of the coating, and to perform manufacturing management for forming various functional films.
[0076]
Next, an apparatus for uniformly coating a plurality of surfaces (both surfaces or step surfaces, edges, etc.) of a liquid crystal display substrate will be described.
[0077]
FIG. 19 is a cross-sectional view of a double-side coating apparatus. In the figure, the mist 5 of the different liquid crystal display material solution is coated on both sides of the front and back surfaces of the liquid crystal display substrate 12. This can be done by moving the two static electricity generating nozzles 20 in parallel and perpendicular to the liquid crystal display substrate 12 (in the direction of the arrow shown in FIG. 19) by the static electricity amount control device 21. By implementing this method, it is possible to form a composite pattern on both sides simultaneously.
[0078]
The substrate coating method according to the present invention is a coating method in which an inorganic / organic thin film is uniformly formed on a substrate (such as a substrate having a hollow shape) processed into an arbitrary shape other than a substrate for a liquid crystal display body It can also be applied. Here, an example applied to an electrode film forming process of a crystal resonator will be described.
[0079]
FIG. 20 is a perspective view of a forming method in which a solvent is atomized and uniformly applied to the surface and side surfaces of a substrate having a hollow shape. The organic material solution (photosensitive resist) is atomized and charged to the fine mist 30 with the static electricity generation nozzle 20, so that it can be applied to the surface and side surfaces of the quartz substrate 57. By carrying out by this method, it becomes possible to easily form a thin film on a substrate formed in an arbitrary shape in addition to a conventional flat substrate.
[0080]
In addition to this, the thin film can be easily formed on the quartz substrate 57 by using an inorganic material solution (for example, a solution containing ceramic particles) or the like as the mist-like charged solution.
[0081]
Further, even in a film forming process other than the manufacturing process for forming an electrode film of a crystal resonator described here, a thin film can be formed by the substrate coating method and apparatus of the present invention.
[0082]
【The invention's effect】
As described above, the present invention has the following effects.
[0083]
According to the first and the second aspects of the invention, the charged mist is finely granular, and is further appropriately dispersed (without partial concentration) on the surface of the substrate. A uniform thin film can be formed on the surface of the body substrate or the liquid crystal display member. Furthermore, according to the invention of claim 3, a high-quality uniform thin film can be easily formed.
[0084]
According to invention of Claim 2, 13, since the thin film pattern for liquid crystal display bodies of arbitrary shapes can be formed by using the mask with a hollow pattern of arbitrary shapes, selection pattern formation essential as a post process of whole surface coating The photoetching process which is a method can be abolished. For this reason, a substrate with a thin film for a liquid crystal display body and a member with a paint film for a liquid crystal display body can be produced with a simple process design, and the yield and cost reduction of the liquid crystal display can be achieved. Furthermore, according to the invention described in claim 4, a regular pattern can be easily formed.
[0085]
According to the fifth aspect of the present invention, the liquid crystal alignment process can be easily performed. This makes it possible to eliminate the rubbing cleaning in the conventional liquid crystal display manufacturing process, thereby improving the alignment quality and the display quality of the liquid crystal display.
[0086]
According to the sixth aspect of the invention, the liquid crystal alignment treatment can be performed, and the work for uniformly dispersing and fixing the liquid crystal display gap forming material can be performed simultaneously. As a result, all steps of alignment film coating, baking, rubbing, cleaning, and gap material distribution in the conventional liquid crystal display manufacturing process can be realized in just one step. As a result, the manufacturability of the liquid crystal display can be greatly improved. Further, since the gap material does not move due to external vibration to the finished liquid crystal display, the display quality of the liquid crystal display is improved.
[0087]
According to the seventh aspect of the present invention, since the operation of injecting the liquid crystal group into the empty cell in which the liquid crystal display glass is bonded in the vacuum apparatus is eliminated, the gap is easily uniform. A liquid crystal display can be manufactured.
[0088]
According to the eighth aspect of the present invention, the gap material forming material can be applied at a fixed interval or at a place other than the pixels of the liquid crystal display substrate. Accordingly, the display quality of the liquid crystal display is improved, and a display with good contrast can be provided by the coating method configured such that there is no gap material forming material in the display pixel.
[0089]
According to invention of Claim 9, the board | substrate for liquid crystal display bodies with a conductive thin film with low resistance value is realizable.
[0090]
According to the invention described in claim 10, the planarizing film can be formed on the surface of the substrate. Thereby, even if the surface of the substrate for liquid crystal display body and the member for liquid crystal display body have some uneven surfaces, a high quality thin film can be formed uniformly.
[0091]
According to the fifteenth aspect of the present invention, by providing a plurality of nozzles, fog can be applied to different surfaces of the substrate at the same time. As a result, a thin film can be formed at high speed.
[0092]
According to the sixteenth aspect of the present invention, the film thickness / film quality / darkening of the coating is controlled by forming the liquid crystal display thin film on the surface of the substrate while controlling the electrostatic charge amount by the control means. be able to. This makes it possible to perform manufacturing management for forming various functional films.
[0093]
According to the seventeenth aspect of the present invention, a high-quality quartz substrate can be formed by applying the atomized resist solution for crystal resonator electrode formation to the surface and side surfaces of the quartz substrate. .
[0094]
Furthermore, according to the invention described in claim 18, by applying such a thin film forming technique, a surface illumination device for a liquid crystal display device capable of realizing bright and uniform illumination in surface illumination is obtained. Can do.
[0095]
In addition, since the substrate coating method and the apparatus thereof according to the present invention do not require mechanical precision because of a non-contact coating method, an inexpensive coating apparatus can be realized. Furthermore, the solvent used in the photoetching process is no longer necessary, which is an effective measure for preventing environmental destruction.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of an overall configuration showing an embodiment of a substrate coating apparatus of the present invention.
FIG. 2 is a perspective view showing a typical example in which coating is performed by moving a substrate or a nozzle.
FIG. 3 is a perspective view showing an embodiment of a method for forming a mosaic pattern using a mask.
FIG. 4 is a perspective view showing an embodiment of a method for forming a stripe pattern using a mask.
FIG. 5 is a perspective view showing an embodiment of a method for forming a uniform thin film on the entire surface.
FIG. 6 is a perspective view showing an embodiment of a method for forming a mosaic pattern on the entire surface using a mask.
FIG. 7 is a perspective view showing an embodiment of a method for forming a stripe pattern on the entire surface using a mask.
FIG. 8 is a perspective view showing an example of a coating method for performing alignment treatment of liquid crystal.
FIG. 9 is a cross-sectional view showing a method of uniformly dispersing and simultaneously applying a liquid crystal alignment treatment and a liquid crystal display gap forming material.
FIG. 10 is a cross-sectional view showing an example of a method for applying a liquid crystal group.
FIG. 11 is a cross-sectional view showing an example of a method of mixing and applying a liquid crystal group and a gap material.
FIG. 12 is a cross-sectional view showing an example of a method for applying a gap material forming material to a predetermined position on a substrate.
FIG. 13 is a cross-sectional view showing an example of a method for forming a conductive thin film.
FIG. 14 is a cross-sectional view showing an example of a method for flattening the surface of a liquid crystal display substrate on which a step pattern is formed.
FIG. 15 is a perspective view showing an embodiment of a method for darkening a reflection plate of a light guide plate in a surface illumination device for a liquid crystal display device according to the present invention.
FIG. 16 is a cross-sectional view showing an example of a surface illumination device for a liquid crystal display device of the present invention.
17 is a luminance measurement graph of the surface illumination device for the liquid crystal display device of FIG. 16;
FIG. 18 is a diagram showing an embodiment of a control system for a substrate coating apparatus according to the present invention.
FIG. 19 is a cross-sectional view showing an example of a double-side coating apparatus.
FIG. 20 is a perspective view showing an embodiment of a method for coating a quartz substrate (a substrate having a hollow shape).
[Explanation of symbols]
1 Ultrasonic transducer
2 Atomization generator body
3 Thin film material solution for liquid crystal display
4 Solvent tank
5 Mist of thin film material solution for liquid crystal display film
6 Fog guiding nozzle
7 Blower nozzle
8 Atomization generator Y direction moving motor
9 Mask with hollow pattern
10 Mask holding jig
11, 23 Coating film
12 Liquid crystal display substrate
13 Table receiving part for substrate for liquid crystal display
14 Liquid crystal display substrate table
15 Heater
16 Table body
17 Table sliding shaft
18 Liquid crystal display substrate table X-direction movement motor
19 Atomization generator sliding shaft
20 Static electricity generating nozzle
21 Static electricity control device
22, 34 Voltage variable device
24, 24 'Mosaic pattern membrane
25, 25 'Mask with hollow mosaic pattern
26, 26 'stripe pattern film
27, 27 'Mask with hollow stripe pattern
28 Wide-angle static electricity generating nozzle
29 Dispersing nozzle
30 Mist of alignment film material solution for liquid crystal display
31 Fine groove
32 Gap forming material for liquid crystal display
33 Liquid crystal group
35 Electrode probe
36 Voltage controller
37 Special solution for thin film materials for LCD
38 Conductive particles
39 Electrode pattern
40 Conductive thin film
41 Flattening solution for liquid crystal display
42 Planarizing film
43 Step pattern
44 Solvent with reflective film particles
45 Light guide plate
46 Reflective film
47 Light collecting film
48 mirror
49 Light source
50 Luminance data
51 Atomization generation unit
52 Voltage variable device
53 Data storage
54 PC
55 IO unit
56 Charge amount sensor
57 Quartz substrate

Claims (10)

In the substrate coating method of applying a thin film material solution to a substrate,
Placing the substrate on a grounded table;
Charging the thin film material solution using a static electricity generating nozzle after making the thin film material solution granular;
Applying the charged thin film material solution to the substrate,
The applying step includes placing a charged mask above the substrate, moving the static electricity generating nozzle in one direction and moving the table in a direction perpendicular to the moving direction of the static electricity generating nozzle, A method for coating a substrate, comprising applying the granular thin film material solution to the substrate through the mask. In a method for producing a liquid crystal display, in which an alignment film material solution for a liquid crystal display is applied to a substrate,
Placing the substrate on a grounded table;
Charging the alignment film material solution for liquid crystal display into a granular form, and charging the alignment film material solution for liquid crystal display;
Applying the charged alignment film material solution for a liquid crystal display to the substrate, and
In the coating step, a charged mask is disposed above the substrate, and the granular alignment film material solution for a liquid crystal display is applied to the substrate through the mask while transporting the gas intermittently. And forming an alignment film having a plurality of grooves. In a method for producing a liquid crystal display, in which an alignment film material solution for a liquid crystal display and a gap forming material are applied to a substrate,
Placing the substrate on a grounded table;
Charging the liquid crystal display alignment film material solution and the gap forming material by making the liquid crystal display alignment film material solution and the gap forming material granular, respectively;
Applying the charged alignment film material solution for a liquid crystal display and the charged gap forming material to the substrate, and
In the step of applying, the charged mask is disposed above the substrate, the granular alignment film material solution for liquid crystal display body and the granular gap forming material are applied to the substrate through the mask, and the alignment is performed. A method of manufacturing a liquid crystal display, comprising: forming a film, spraying a gap material for a liquid crystal display, and fixing the gap material for a liquid crystal display simultaneously. In a method for manufacturing a liquid crystal display body in which liquid crystal is applied to a substrate,
Placing a substrate on which a groove has been formed and subjected to an orientation treatment on a grounded table;
Charging the liquid crystal by granulating the liquid crystal;
Applying the charged liquid crystal to the substrate,
In the applying step, a charged mask is arranged above the substrate, the granular liquid crystal is applied to the substrate through the mask, and then the substrates for the liquid crystal display body are bonded together in a vacuum apparatus. A method for producing a liquid crystal display body. In a method for manufacturing a liquid crystal display body in which a gap forming material is applied to a substrate,
Placing a substrate on which a groove has been formed and subjected to an orientation treatment on a grounded table;
Charging the gap forming material by making the gap forming material granular; and
Applying the charged gap forming material to the substrate,
In the applying step, a charged mask is disposed above the substrate, the granular gap forming material is applied to the substrate through the mask, and the gap forming material is applied to the substrate other than the pixels of the liquid crystal display substrate. A method for producing a liquid crystal display body, characterized in that the liquid crystal display body is applied to the part. In a method for manufacturing a liquid crystal display, in which a thin film material solution and a conductive material are applied to a substrate,
Placing a substrate on which an electrode pattern has been previously formed on a grounded table;
Charging the thin film material solution and the conductive material by making the thin film material solution and the conductive material granular, respectively;
Applying the charged thin film material solution and the charged conductive material to the substrate,
The applying step includes placing a charged mask above the substrate, applying the granular thin film material solution and the granular conductive material to the substrate, and applying a voltage to the electrode pattern. A method of manufacturing a liquid crystal display body, characterized by controlling an amount of wearing. In a method for manufacturing a liquid crystal display, in which a planarization solution for a liquid crystal display is applied to a substrate on which a step pattern is formed,
Placing a substrate on which a step pattern is formed in advance on a grounded table;
Charging the liquid crystal display body flattening solution by granulating the liquid crystal display body flattening solution;
Applying the charged planarizing solution for a liquid crystal display to the substrate and the pattern, and
In the applying step, a charged mask is placed above the substrate, and the granular liquid crystal flattening solution is applied to the substrate through the mask to flatten the surface of the liquid crystal display substrate. A method for producing a liquid crystal display, comprising forming a fluorinated film. In a substrate coating apparatus for forming a thin film by applying a thin film material solution to a substrate,
A table on which the substrate is placed;
An atomization generator for granulating the thin film material solution;
A mist guiding nozzle for conveying the thin film material solution by a gas flow;
A static electricity generating nozzle that is provided at the tip of the fog induction nozzle, generates static electricity that charges the thin film material solution, and applies the charged thin film material solution to the substrate;
A charge amount sensor for detecting the charge amount of the thin film;
An electrostatic charge control device for setting the charge amount to the thin film material solution based on the data of the charge amount sensor;
A charged mask is arranged above the substrate, and the granular thin film material solution is moved while moving the static electricity generating nozzle in one direction and moving the table in a direction perpendicular to the moving direction of the static electricity generating nozzle. An apparatus for coating a substrate, wherein the substrate is applied to the substrate through the mask.   9. The substrate coating apparatus according to claim 8, comprising two static electricity generating nozzles for coating different kinds of liquid crystal display material solutions. In the method of manufacturing a surface illumination device for forming a reflective film on a light guide plate by applying a reflective film solvent,
Placing the light guide plate on a grounded table;
Charging the reflective film solvent into a granular form of the reflective film solvent; and
Applying the charged reflective film solvent to the light guide plate, and
In the coating step, a charged mask is disposed above the substrate, and the granular reflection film solvent is applied to the substrate through the mask while varying the amount of electrostatic charge, thereby increasing the density of the reflection film. Forming a surface illumination device.

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