KR20110043408A - Liquid supplying system, liquid supplying method and coating apparatus - Google Patents

Abstract

PURPOSE: A liquid supplying system, a liquid supplying method, and a coating device are provided to suppress micro bubbles by reducing the amount of gas inputted to liquid supplied to a coating unit. CONSTITUTION: A buffer tank(3) stores a chemical. A second flow path is connected to the buffer tank to supply the chemical. A third flow path(5-4) is connected to the buffer tank to supply pressured gas. A fourth flow path(5-5) is connected to the buffer tank and a coating unit to supply liquid from the buffer tank to the coating unit. A first flow path and the second flow path are detachably connected to a resin container(17). The gas is supplied to the resin container through the first flow path.

Description

LIQUID SUPPLYING SYSTEM, LIQUID SUPPLYING METHOD AND COATING APPARATUS}

The present invention relates to a liquid supply system, a liquid supply method and an application device. More specifically, the present invention relates to a liquid supply system for supplying liquid to an application portion of an application device, a liquid supply method using the same, and an application device having the same.

In order to supply chemical liquids, such as a resist and pigment dispersion liquid in the manufacturing process of a semiconductor and a liquid crystal display device, the system which loads the sealing liner for accommodating a chemical liquid in a metal container, and fills the chemical liquid in the liner is widely used. . This is to introduce a pressurized liquid supply gas into the air gap between the liner and the outer metal container, and shrink the liner at the pressure to pressurize the chemical liquid through the tube. There is an advantage that the chemical liquid surface is not in direct contact with each other, and the gas can be prevented from penetrating and absorbing into the liquid in the pressurized atmosphere. Patent Literature 1 discloses an example of such a liner and a metal container.

The above advantages are particularly advantageous in positive resists (such as those containing novolak resins and diazonaphthoquinone, etc.) which do not utilize radical polymerization. On the other hand, in a negative photoresist including a photopolymerization initiator or the like, monomers and oligomers in a chemical solution generate radicals due to thermal energy and polymerize during storage (dark reaction), so that a gas containing oxygen is dissolved. In addition, by securing a predetermined volume of the air layer in contact with the resist liquid on the upper portion of the chemical liquid container, the free radicals generated by oxygen contained in the air are inactivated to inhibit the dark reaction, thereby improving storage stability.

For this reason, such an effect cannot be fully obtained in the airtight filling with the liner which has little contact with air, and it cannot be said that it is an optimal storage state of the photoresist using a radical polymerization reaction.

On the operation side, the outer container can be reused by cleaning or cleaning the outer container and replacing the used liner or tube.However, the initial introduction cost for procuring the outer container and the replacement of the liner or tube consuming member There is a problem of economical cost because the purchase cost is incurred, and since the time required for cleaning and transporting the outer container is generated, the normal operation also requires the preparation of more spare inventory than the actual number of containers used.

In addition, the used liner or tube is difficult to reuse due to the maintenance of the quality of the chemical solution, which is often a waste. Teflon (registered trademark) materials used for resists and liners or the like attached to a liner are difficult to recycle, and the recycling efficiency is lowered.

Therefore, it is considered to apply the chemical liquid to a metal container such as a drum or a pail can and to apply it to the chemical liquid supply. This is to introduce gas into the container into which the chemical liquid is put, pressurize the chemical liquid, and deliver the chemical liquid through the siphon tube by the siphon effect. Since the container is metal, recycling is easy. However, there is a risk of deformation, damage, leakage of the contents, etc., such as depression due to impact resistance or external force during transportation, etc., so that handling is difficult. In addition, the amount of waste is increased due to packing for protecting the container.

On the other hand, a chemical liquid may be put into a resin container, and it may apply to chemical liquid supply by the same method. In the chemical liquid supply system to which the resin container is applied, the variation ratio can be suppressed inexpensively as compared with the type using the liner, and a resin container of a clean specification can be easily obtained as a commercial item. Moreover, since it has elasticity compared with a metal container etc., it is excellent in the prevention of the damage from the exterior by the impact of falling. If the resin container is made of polyethylene or the like, the environmental load can be reduced by material recycling or thermal recycling of the used container.

By the way, when manufacturing a semiconductor or a liquid crystal display device, in order to prevent the fall of the yield by a foreign material etc., a filtration filter is generally provided in the piping path which conveys a chemical liquid to the discharge part side, such as a discharge pump. The filtration filter removes aggregated particles, gel-like foreign matters, and the like, for example, a pleated or disk-shaped filter such as a depth, a membrane, or a fiber is used alone or in combination (pore size O.1. About -10 micrometers). In addition, in order to remove micro bubbles, such as microbubbles generated by the dissolved gas in the chemical liquid, a degassing module (for example, Nitcept (trademark) manufactured by Nitto Denko Co., Ltd.) may be installed.

However, when a filtration filter or the like is provided in the pipe line, pressure loss may occur, and the power to supply the liquid during low pressure delivery may be insufficient. In such a situation, in order to feed the chemical liquid to the discharge portion side by the siphon effect, it is necessary to extrude the chemical liquid or to suck the liquid liquid to the discharge portion or the like with a force higher than the pressure loss. However, in the former, high pressing force is required, and in the latter, since the inside of the pipe path becomes negative, the dissolved gas in the chemical liquid foams, causing microbubbles or deterioration and damage due to suction load. It may or may not.

Therefore, in consideration of the pressure loss in the liquid supply piping path, an appropriate necessary pressing force is applied to the chemical liquid in the chemical liquid container and pumped through the siphon tube or the like to reduce the load of the dissolved gas due to the negative pressure at the time of suction or the pump. The method may be taken.

However, in order to obtain the required chemical liquid supply amount within a desired time, it is necessary to apply the pressing force according to the supply rate to the chemical liquid in the chemical liquid container.In a system with a large amount of chemical liquid supply per hour, it is necessary to apply a higher pressing force to improve the supply rate. have.

In the manufacture of liquid crystal display devices and the like, the amount of chemical liquid used for processing per substrate is also increasing with the recent increase in the size of the mother glass, and therefore, the liquid is often delivered at a relatively high pressure.

Japanese Patent Publication No. 2008-007153

Since the resin container (or a metallic container such as a drum or a pail can) as described above is not a pressure-resistant container, it is difficult to directly press only the inside of the container to a high pressing force. For example, in the case of a resin container, when the inside of the container is directly pressurized and the high pressurized state is normally maintained due to the characteristics of the resin, plastic deformation is likely to occur due to expansion deformation of the container, which may cause damage to the container. .

Therefore, it is common to use a cylindrical pressure-resistant outer container on the outer side of the container, and to take measures such as pressurizing the inside of the container and supplying pressure from the outside.

This example is shown in FIG. In the manufacture of a liquid crystal display device using a large mother glass, the die coating method is widely used in the coating process. As one of such coating devices, a reciprocating stage or gantry, a coating nozzle (die), and a coating nozzle are applied. There is a one provided with a chemical liquid supply system for supplying a chemical liquid. 10 illustrates an example of the chemical liquid supply system. The same applies to FIG. 11 described later.

In Fig. 10, 31 is a resin container, 33 is a siphon tube, 35 is a pressure-resistant outer container, 37 (37-1, 37-2) is a pipe, 39 is a valve, 41 is a regulator, 43 is a filtration filter, 45 is Discharge part (discharge pump etc.) and 47 are application | coating nozzles.

In the example of FIG. 10, the resin container 31 is sealed in the pressure-resistant exterior container 35 which has a cylindrical shape, and the resin container which chemical gas was put into gas, such as compressed air, through the conduit 37-1 ( It introduce | transduces into the space | gap of 31 inside and the resin container 31 and the pressure-resistant exterior container 35. In addition, suction by the discharge part 45 is performed. Then, the chemical liquid in the resin container 31 is supplied to the storage part provided in the discharge part 45 through the siphon pipe 33 and the conduit 37-2 by the siphon effect etc. according to pressurization, The chemical liquid is discharged from the application nozzle 47 according to the volume change or the like. Since the resin container 31 is pressurized from the inside and the outside, deformation by pressurization hardly occurs.

In addition, as described above, the resin container 31 is not sealed in the pressure-resistant outer container 35, but the outer circumference of the resin container 31 is covered with a pressure protector that is slightly larger than the resin container 31, The expansion and deformation of the resin container 31 in the case of directly pressing only the inside of the resin container 31 may be restrained. This example is illustrated in FIG. 11, and 51 is a pressure protector. In FIG. 11, the same code | symbol is attached | subjected about the element which has the same functional structure as FIG. 10, and description is abbreviate | omitted.

In the example of FIG. 11, gas, such as compressed air, is introduce | transduced into the inside of the resin container 31 containing chemical liquid by the pipe line 37-1. In addition, suction by the discharge pump 45 is performed. Then, the chemical liquid in the resin container 31 is supplied to the storage part provided in the discharge part 45 through the siphon pipe 33 and the conduit 37-2 by the siphon effect etc. according to pressurization, The chemical liquid is discharged from the application nozzle 47 according to the volume change or the like. Expansion and deformation due to pressurization of the resin container 31 are restrained by the pressure protector 51 on the outer side thereof.

The pressure-resistant outer container 35 and the pressure protector 51 are made of a material having excellent mechanical strength, such as stainless, and are effective for suppressing expansion or deformation of the container during pressurization.

However, since the diameter of the pressure-resistant outer container 35 is equal to or larger than the diameter of the main body of the resin container 31 loaded therein (a container having an inner diameter of about 200 to 300 mm is required even in a general gel container). When the large-capacity resin container 31 having a higher exchange efficiency in production is used, the diameter of the pressure-resistant outer container 35 also increases.

Therefore, when a high pressure, for example, about 100 kPa (atmospheric pressure reference or below) is applied in the pressure-resistant exterior container 35, the force applied to the lid or the like becomes very large. At this time, if the sealed part having a large cross-sectional area such as a cover is opened without performing the operation of purging the pressure-resistant outer container 35 in the pressurized state to atmospheric pressure, components such as the pressurized cover part and chemical liquid may be scattered, thereby ensuring safety. In order to do this, you need to be careful in handling. In addition, although the risk is reduced by providing an appropriate safety mechanism, there is a potential risk, so it is difficult to secure the safety of the worker in the use other than the assumed use.

On the other hand, in the method of supplying a chemical liquid by applying a pressing force directly into the resin container 31 while restraining the deformation of the resin container 31 using the pressure protector 51, the resin container 31 is subjected to plastic deformation by expansion. ) Is engaged with the pressure protector 51, so that the resin container 31 cannot be easily taken out during the replacement operation, or the stress of expansion and deformation is concentrated in a portion not in close contact with the pressure protector 51, causing partial tearing. There is a possibility of rupture, rupture, liquid leakage or fall, which may cause safety.

In addition, in the case of conveying the chemical liquid at a pressing pressure by a pressurized medium (a gas such as compressed air or compressed nitrogen), the amount of dissolved gas in the chemical liquid is increased by gradually dissolving the pressurized atmosphere into the chemical liquid with the passage of the pressurization time. When a high pressing force is applied, the amount of dissolved gas increases.

If there is a portion of the pipe path orifice such as the pipe line 37-2 where the pipe inner diameter rapidly decreases, the flow rate increases due to the Venturi effect, the pressure in the pipe path decreases, and the cavitation causes the chemical to enter the chemical liquid. Dissolved gas occurs as microbubbles, tiny bubbles that are invisible to the eye. These may become aggregates and grow by large foaming.

Influence of such bubble mixing causes the microbubble to deteriorate the uniformity of the refractive index and the film thickness of the coating film in the manufacturing process of the semiconductor and the liquid crystal display device, and this effect deteriorates the processing quality and lowers the productivity such as yield. do.

In addition, if large bubbles remain in the resist applied to the substrate, a difference in local surface tension is generated, which is one cause of deterioration in uniformity of the film thickness or uneven appearance. Moreover, when a bubble remains in a coating film and it is dried in a vacuum drying chamber in a vacuum drying process, a bubble may expand and burst and a quality may fall.

Further, in the die coat method, the slit at the tip of the coating nozzle 47 is transmitted as a compressive force to the chemical liquid in the pipe connected to the coating nozzle 47 by transferring the volume change of the bottom portion of the discharge portion 45 generated by the suction of the chemical liquid or the like. The chemical liquid is discharged from the portion in accordance with the volume change and the pressure change. For this reason, it is necessary to follow the discharge from the coating nozzle 47 without delay with respect to the volume change which arises by a suction operation. When small bubbles are collected and stagnated in the pipes, seams, or gaps to the slit portions of the discharge portion 45 or the application nozzle 47, the action of shrinking the bubbles remaining in the volume change caused by the suction operation at the start of the application operation. It may also be a factor that causes a time (response rate) delay in increasing the pressure of chemical liquid discharge in the piping path.

In the method of forming a coating film in the sheet type by the die coating method, the time delay of discharging the chemical liquid causes deterioration of the uniformity of the thickness near the start point of the coating or the completion of the coating, and the deterioration of quality such as lines and stains. Because it is not desirable.

As a countermeasure, it is also possible to reduce the coating treatment speed and to alleviate the influence of the response delay to some extent.However, the processing time becomes longer and the productivity is lowered. Fluctuations in the responsiveness make it difficult to maintain production quality with stable uniformity (reproducibility).

This invention is made | formed in view of the above problem, and an object of this invention is to provide the liquid supply system excellent in safety, economy, and productivity.

SUMMARY OF THE INVENTION In order to achieve the above object, a first invention is a liquid supply system for supplying a liquid to an application portion of a coating device, the storage portion for storing liquid, a first flow path, and the storage portion connected to the storage portion. A second flow passage for supplying a liquid to the portion, a third flow passage connected to the storage portion and for supplying gas to the storage portion, the storage portion and the application portion, and connected to the application portion from the storage portion. And a fourth flow path for supplying a liquid, wherein the first flow path and the second flow path can be detachably connected to a predetermined container, and the first flow path can supply gas to the connected predetermined container. It is a liquid supply system.

The storage part has an air opening means for air-opening the inside of the storage part, and the first, second, third, and fourth flow paths are provided with opening and closing means for opening and closing each flow path. Further, it is preferable that a liquid level detecting means for detecting the height of the liquid level is provided in the reservoir.

It is preferable that the liquid supply system of 1st invention further has the container connection part which can detachably connect the said predetermined container, and the said 1st flow path and the said 2nd flow path can connect the said predetermined container through the said container connection part. Do.

In addition, it is preferable that the container connecting portion has a groove portion on an inner circumferential surface, and the container connecting portion and the predetermined container can be connected by screwing the convex portion provided on the outer circumferential surface of the opening of the predetermined container.

Moreover, it is preferable that the said 1st flow path supplies gas to the said predetermined container connected so that the pressure in the said predetermined container may be in the range of 5 kPa-100 kPa.

The coating device may be used for manufacturing a semiconductor device or a liquid crystal display device.

On the other hand, the application | coating part of an application device refers to the mechanism for apply | coating chemical liquids, such as an ejection part, such as a discharge pump, and an application nozzle.

According to the above configuration, the pressure state in the predetermined container and the pressure state in the storage part are independently controlled, and liquid such as a chemical liquid contained in the predetermined container is fed by pressurization, once filled in the storage part and applied while pressurizing the inside of the storage part. Liquid can be supplied to the applicator section of the device. In other words, when the liquid is fed into the coating unit without directly feeding the liquid from the inside of the container, the inside of the storage unit is pressurized. Therefore, the pressure applied in the container for the liquid feeding to the reservoir can be made low, for example, in the range of 5 kPa to 100 kPa. For this reason, it is not necessary to be able to withstand high pressing force as a container, and a container such as a resin container commonly used for transporting chemical liquids can be used as it is by detachably connecting to a flow path of a liquid supply system as a predetermined container. . After the chemical liquid in the container is used up, it can be separated and replaced with another container, which is excellent in economy. Since the pressure to apply in a container can be suppressed low, a replacement operation etc. of a container can be performed safely.

In addition, since the liquid is supplied to the reservoir in a state where the inside of the predetermined container is kept at a low pressure, the amount of dissolved gas in the liquid is not excessive. Therefore, generation | occurrence | production of the bubble, such as a micro bubble by cavitation, can be suppressed. For this reason, the above-mentioned bubble suppresses the influence on quality, and also, when applying the chemical liquid from the applicator, suppresses the delay time rise of the pressure in the pipe and reduces the shortage of the initial discharge amount, thereby achieving high quality with stable uniformity. It becomes possible to supply the product. In addition, since the suction operation by the discharge part, such as a pump, etc. and the liquid feed of the chemical liquid by pressurization in a storage part can be used together at the time of liquid feeding to an application part, even when a filtration filter etc. are installed in a piping path, a filtration filter etc. The negative pressure due to the pressure loss and the suction operation can be canceled, which also leads to suppression of bubble generation. In addition, it is possible to reduce the possibility of deterioration or damage of the discharge part such as the discharge pump or the motor part thereof due to the suction load.

Moreover, the predetermined container can also be connected to a flow path through a container connection part. At this time, if the groove on the inner circumferential surface of the container connecting portion is screwed with the convex portion provided on the outer circumference of the opening of the predetermined container to connect the predetermined container, airtightness is generated at the container connecting portion when the container is pressurized, causing looseness or gas leakage in the container connecting portion. This becomes difficult to occur. In the case of replacing the container, even if the container connection part becomes loose, the container can be caught by the convex part of the container and the groove part of the container connection part. Thus, the gap caused by loosening of the pressurized gas and the container or container connection part are not scattered. By exiting it, the inside of the container can be safely brought to atmospheric pressure. Therefore, the work of replacing the container becomes safer.

In addition, since the chemical liquid supply can be controlled according to the liquid surface position using a liquid level detecting means such as a sensor, the layer of gas can always be present in the reservoir. Thereby, the gas dissolved in the liquid may flow into the layer of gas in the reservoir and separate from the liquid. Therefore, the quantity of the gas mixed in the liquid supplied to an application part can be reduced, and generation | occurrence | production of bubbles, such as a micro bubble, can be suppressed further.

Therefore, it is possible to provide a liquid supply system for supplying liquid to an application portion of an application device, which is excellent in safety, economy and productivity, particularly in the manufacture of semiconductor devices or liquid crystal display devices.

In order to achieve the above object, a second invention includes a storage portion for storing liquid, a first flow passage, a second flow passage connected to the storage portion, and a liquid supply portion for supplying liquid to the storage portion, and the storage portion. A third flow passage connected to the storage portion and for supplying gas to the storage portion, and a fourth flow passage connected to the storage portion and the application portion of the coating apparatus and for supplying liquid from the storage portion to the application portion, The first flow path and the second flow path can be detachably connected to the predetermined container, and the first flow path supplies the liquid to the application portion of the coating apparatus using a liquid supply system capable of supplying gas to the connected predetermined container. A liquid supply method for supplying a liquid, wherein the inside of the predetermined container connected to the first flow path and the second flow path is pressurized by a gas supplied through the first flow path, and the inside of the predetermined container. A reservoir liquid supplying step of supplying liquid into the reservoir through the second flow path; and pressurizing the liquid in the reservoir to the fourth flow path by pressurizing the inside of the reservoir with the gas supplied through the third flow path. It is a liquid supply method characterized by including the coating part liquid supply process supplied to the said coating part via.

According to the above configuration, the pressure state in the predetermined container and the pressure state in the storage part are independently controlled, the liquid such as chemical liquid put into the predetermined container is fed by pressurization, once filled in the storage part, and the inside of the storage part is pressurized. The liquid can be supplied to the application portion of the application device. In other words, the liquid is not directly fed to the coating unit from the inside of the container. Therefore, the pressure applied in the container for the liquid feeding to the reservoir can be made low. For this reason, a container, such as a resin container normally used for transport of chemical liquids, is not required to be able to withstand high pressing force as a container, and can be used as it is by detachably connecting to a flow path of a liquid supply system as a predetermined container. After the chemical liquid in the container is used up, it can be separated and replaced with another container. Since the pressure to apply in a container can be suppressed low, a replacement operation etc. of a container can be performed safely.

In addition, since the liquid is supplied to the reservoir in a state where the inside of the predetermined container is kept at a low pressure, the amount of dissolved gas in the liquid is not excessive. Therefore, generation | occurrence | production of the bubble, such as a micro bubble by cavitation, can be suppressed. For this reason, the high quality with stable uniformity is suppressed by the above-mentioned bubble suppressing the influence on quality, and also suppressing the delay time rise of the pressure in piping at the time of chemical | medical solution application from an application part, and reducing the lack of initial discharge amount. It is possible to supply the products of. In addition, since the suction operation by the discharge part, such as a pump, etc. and the liquid feed of the chemical liquid by pressurization in a storage part can be used together at the time of liquid feeding to an application part, even when a filtration filter etc. are installed in a piping path, a filtration filter etc. The negative pressure due to the pressure loss and the suction operation can be canceled, which also leads to suppression of bubble generation. In addition, it is possible to reduce the possibility of deterioration or damage of the discharge part such as the discharge pump or the motor part thereof due to the suction load.

Therefore, the liquid supply method which supplies a liquid to the application | coating part of the application | coating device excellent in safety, economy, and productivity can be provided.

In order to achieve the above object, the third invention is an application apparatus comprising the liquid supply system of the first invention.

According to the above configuration, the pressure state in the predetermined container and the pressure state in the storage part are independently controlled, the liquid such as chemical liquid put into the predetermined container is fed by pressurization, once filled in the storage part, and the inside of the storage part is pressurized. The liquid can be supplied to the application portion of the application device. In other words, the liquid is not directly fed to the coating unit from the inside of the container. Therefore, the pressure applied in the container for the liquid feeding to the reservoir can be made low, for example, in the range of 5 kPa to 100 kPa. For this reason, it is not necessary to be able to withstand high pressing force as a container, and a container such as a resin container commonly used for transporting chemical liquids can be used as it is by detachably connecting to a flow path of a liquid supply system as a predetermined container. . After the chemical liquid in the container is used up, it can be separated and replaced with another container. Since the pressure to apply in a container can be suppressed low, a replacement operation etc. of a container can be performed safely.

In addition, since the liquid is supplied to the reservoir in a state where the inside of the predetermined container is kept at a low pressure, the amount of dissolved gas in the liquid is not excessive. Therefore, generation | occurrence | production of the bubble, such as a micro bubble by cavitation, can be suppressed. For this reason, the above-mentioned bubble suppresses the influence on quality, and also suppresses the rise delay time of the pressure in a pipe at the time of chemical | medical solution application from an application part, and reduces the lack of initial discharge amount, and has the high quality which has stable uniformity. It becomes possible to supply the product. In addition, since the suction operation by the discharge part, such as a pump, etc. and the liquid feed of the chemical liquid by the pressure in a storage part can be used together at the time of the liquid feeding to an application part, even when a filtration filter etc. are installed in a piping path, a filtration filter etc. The negative pressure due to the pressure loss and the suction operation can be canceled, which also leads to suppression of bubble generation. In addition, it is possible to reduce the possibility of deterioration or damage of the discharge part such as the discharge pump or the motor part thereof due to the suction load.

Moreover, the predetermined container can also be connected to a flow path through a container connection part. At this time, if the groove on the inner circumferential surface of the container connecting portion is screwed with the convex portion provided on the outer circumference of the opening of the predetermined container to connect the predetermined container, airtightness is generated at the container connecting portion during pressurization in the container, causing looseness or gas Leakage will not occur. In addition, when the container is replaced, even if the container connection part is loosened, the container can be caught in the convex part of the container and the groove part of the container connection part. Therefore, the container or the container connection part is not scattered and the pressure is released through the gap caused by the loosened gas. By exiting, the inside of the container can be safely at atmospheric pressure. Therefore, the work of replacing the container becomes safer.

In addition, since the chemical liquid supply can be controlled according to the liquid surface position using a liquid level detecting means such as a sensor, the layer of gas can always be present in the reservoir. Thereby, the gas dissolved in the liquid may flow into the layer of gas in the reservoir and separate from the liquid. Therefore, the quantity of gas mixed in the liquid supplied to an application part can be reduced, and generation | occurrence | production of bubbles, such as a micro bubble, can be suppressed further.

Therefore, the coating device excellent in safety, economy, and productivity can be provided.

According to the present invention, it is possible to provide a liquid supply system having excellent safety, economy and productivity.

1 is a diagram showing an embodiment of a liquid supply system of the present invention.
2 is a diagram illustrating a flow of a liquid supplying method in a liquid supplying system.
3 is a diagram showing a flow of a liquid supplying method in the liquid supplying system.
4 is a diagram illustrating a flow of a liquid supply method in the liquid supply system.
5 is a diagram illustrating a flow of a liquid supplying method in the liquid supplying system.
6 is a diagram illustrating a flow of a liquid supplying method in the liquid supplying system.
7 is a view showing another embodiment of the liquid supply system of the present invention.
8 is a diagram illustrating an example of an attachment.
9 is a diagram illustrating an example of the configuration of the coating apparatus.
It is a figure which shows the example of a pressure-resistant outer container.
11 is a diagram illustrating an example of a pressure protector.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of the liquid supply system of this invention etc. is described with reference to drawings. First, the liquid supply system of this embodiment is demonstrated with reference to FIG. 1 and FIG.

The liquid supply system 1 of this embodiment is provided as a part of the coating apparatus 100 used for manufacture of a liquid crystal display device or a semiconductor device, as shown in FIG. In addition to the liquid supply system 1, the coating device 100 includes a control unit 110, an application unit 120, a substrate holding unit 130, and the like.

The control unit 110 is constituted by a central processing unit (CPU) or the like, and controls the operations of the liquid supply system 1, the coating unit 120, and the substrate holding unit 130.

The coating unit 120 includes, for example, a discharge unit such as a pump having a low liquid portion, an application nozzle (die), and the like, and a driving mechanism for driving them, and actually applies a chemical liquid such as a resist onto the substrate.

The substrate holding unit 130 includes, for example, a stage and the like that can hold a substrate and move back and forth, and a driving mechanism for driving the substrate.

As shown in FIG. 1, the liquid supply system 1 of this embodiment is the buffer tank 3 (storage part), the conduit 5 (flow path), the valve 7 (opening and closing means), and the regulator 9 And the like, and a chemical liquid (liquid) such as a resist and a pigment dispersion liquid in the resin container 17 (predetermined container) is supplied to the discharge portion 13 and the coating nozzle 14 (coating portion 120). The operation of the valve 7, the regulator 9, the discharge part 13, and the like can be controlled by the controller 110.

The buffer tank 3 is preferably made of a material and a structure having excellent strength against deformation even when a high pressure gas (compressed gas, compressed nitrogen or the like) of 100 kPa or more is supplied. Moreover, even if it is a pressurized state of at least 200 kPa, it is preferable that it consists of the container design which does not leak or deform | transform gas or chemical liquid, and can maintain pressure-resistant performance permanently. However, these do not limit the material or shape of a specific buffer tank. For example, as the material of the buffer tank 3, a metal such as stainless steel of stainless steel or aluminum such as SUS 304 may be used. When the solvent has a property of corrosive to the metal or stresses processability, the fluorine water may be used depending on conditions that satisfy the pressure resistance. Gina NC nylon etc. can be used as a material. Moreover, in order to provide chemical resistance, you may carry out resin coating or plating process.

In the buffer tank 3, it is preferable to provide a sensor 4 as liquid level detecting means for detecting the liquid level of the chemical liquid in the tank. In order to ensure that there is always an air layer having a predetermined capacity or higher in the upper portion of the buffer tank 3, for example, the sensor 4 has a predetermined (less than the upper limit position) liquid level so that the liquid level does not become above the predetermined upper limit position. It is preferable that the opening and closing control of the valve provided in the conduit is carried out by detecting a, so that the supply of the chemical liquid is interrupted. As the sensor 4, for example, a capacitive sensor, a pressure sensor, a float sensor, an ultrasonic displacement sensor, or the like can be used.

Pipe line 5 (5-1, 5-2, 5-3, 5-4, 5-5) is a pipe line through which gas can be flowed for supplying gas or opening to the atmosphere (5-1, 5-3, 5- 4) and a gas or liquid flow path including the pipelines 5-2 and 5-5 through which the liquid for supplying the chemical liquid can flow. The material, shape, etc. can use what is normally used as such a pipeline.

The conduit 5-1 (first flow path) extends from the air supply portion (not shown) and is connected to the resin container 17. The conduit 5-1 is a piping path for supplying gas from the air supply portion into the resin container 17 to pressurize the inside of the resin container 17.

The conduit 5-2 (second flow path) is connected to the resin container 17 and the buffer tank 3. The conduit 5-2 is a piping path for supplying the chemical liquid in the resin container 17 to the buffer tank 3 by the siphon effect by pressurizing the inside of the resin container 17.

The conduit 5-3 is a piping path for connecting the outside and the buffer tank 3 to open the buffer tank 3 to the atmosphere to bring the inside of the buffer tank 3 to atmospheric pressure.

The conduit 5-4 (third flow path) branches from the conduit 5-1 and is connected to the buffer tank 3. The conduit line 5-4 connects the air supply section and the buffer tank 3 and is a piping path for supplying gas from the air supply section in the buffer tank 3 to pressurize the inside of the buffer tank 3.

The conduit 5-5 (fourth flow path) is connected to the buffer tank 3 and the discharge part 13 (coating part 120). The conduit 5-5 is a piping path for supplying a chemical liquid from the buffer tank 3 to the application part 120 such as the discharge part 13 and the application nozzle 14.

The valve 7 (7-1, 7-2, 7-3, 7-4, 7-5) is an opening and closing means for opening or blocking the flow of liquid or gas in the conduit 5, the structure and the like It does not specifically limit, Various things already known can be used. In addition, according to various conditions, the control unit 110 may automatically control the opening and closing of these valves using an air operation valve or the like as necessary. In addition, an operator or the like may open or close these valves by manual operation.

The valves 7-1 and V1 are in the conduit 5-1, the valves 7-3 and V3 are in the conduit 5-3, and the valves 7-4 and V4 are in the conduit 5-. 4), each of which adjusts the flow of gas flowing through the corresponding conduit 5 by its opening and closing.

In addition, the valve 7-3 controls the flow of gas through the conduit 5-3 by opening and closing the valve 7-3, and serves as an atmospheric opening means for performing atmospheric opening (and blocking) in the buffer tank 3. . However, the mechanism for atmospherically opening the inside of the buffer tank 3 is not limited to this. For example, if the outer surface of the buffer tank 3 is in direct contact with the atmosphere, only a part of the buffer tank 3 can be opened and closed to serve as an atmosphere opening means.

Further, the valves 7-2 and V2 are installed in the conduit 5-2, and the valves 7-5 and V5 are installed in the conduit 5-5, and the corresponding conduits 5 and 5 are respectively opened and closed. Adjust the flow of chemicals through

In addition, although not shown in particular, the above-mentioned buffer tank 3 may be connected to the pipeline for recovering the chemical liquid in a tank, and the pipeline for inject | pouring the solvent for washing | cleaning the inside of the buffer tank 3, and each pipeline is connected to the pipeline. A valve for controlling the flow of the liquid in the pipeline by opening and closing may be provided.

The regulator 9 (9-1, 9-2, 9-3) is the pressure of the gas supplied from the air supply unit so that the pressing force by the gas in the resin container 17 or the buffer tank 3 becomes arbitrary fixed pressure value. Pressure control means for adjusting and maintaining. As with the valve 7, the control can be automatically performed by the control unit 110 under various conditions, but may be performed by an operator or the like by manual operation.

The regulator 9-1 (REG1) is provided on the air supply portion side of the pipeline 5-1 rather than the branched portion with the pipeline 5-4 and supplied to the resin container 17 or the buffer tank 3. Adjust the pressure.

The regulator 9-2 (REG2) is installed on the resin container 17 side rather than the branched portion with the pipe line 5-4 in the pipe line 5-1, and the pressure of the gas supplied to the resin container 17. Adjust.

The regulator 9-3 (REG3) is installed in the conduit 5-4 to regulate the pressure of the gas supplied to the buffer tank 3.

The filtration filter 11 is installed in the conduit 5-5. As described above, the filtration filter 11 removes agglomerated particles, a gel-like foreign material, and the like, and is used by processing a filter such as a depth, a membrane, a fiber, etc. into a pleat or a disc or using a single body or a combination (pore). The size is about 0.1 to 10 mu m). It is also possible to further install a degassing module as described above.

The discharge part 13 is connected to the conduit 5-5. The discharge part 13 is a discharge pump, a dispenser, etc., for example, and is provided with the storage liquid part (not shown) which stores the chemical liquid supplied to the application | coating nozzle 14. The discharge part 13 sucks a chemical | medical solution into a storage liquid part, and sends the chemical liquid of the quantity according to the volume change of a storage liquid part to the application | coating nozzle 14.

The application nozzle 14 is a die head, a syringe needle, or the like, and is connected to the discharge portion 13 through a flow path. The application nozzle 14 applies the chemical liquid supplied from the discharge portion 13 onto the substrate through openings such as slits.

The discharge part 13 and the coating nozzle 14 function as the coating part 120 of the coating device 100, and actually apply | coat the chemical | medical solution on a board | substrate in the application | coating process in manufacture of a semiconductor or a liquid crystal display device. Do it.

The resin container 17 is a container for storing a chemical liquid such as a resist or a pigment dispersion, and uses a small deformation due to pressure. Specifically, in an environment in which 50 kPa gas pressure is continuously applied thereinto, a container capable of suppressing the volume change of the container due to deformation to 5% or less after 12 hours from the beginning is used. For this reason, it is preferable that it is suitably a resin container made from resin whose bending elastic modulus is 500 Mpa or more. However, this does not limit the material or shape of the resin container 17, and polyethylene or fluororesin can be used as the material.

On the other hand, the chemical liquid is often transported and supplied by a resist manufacturer in a state of being stored in a resin container, but the container at that time often satisfies the above strength due to safety during transportation. That is, the chemical liquid container used for the transportation can be applied to the liquid supply system 1 as it is, in which case, it is not necessary to use a special container for the liquid supply system 1, which is advantageous in terms of economy.

On the other hand, if the above conditions are satisfied, the material of the container is not limited to resin, and it is also possible to use a container such as metal instead of the resin container 17. However, as mentioned above, using the resin container 17 is excellent in the point which prevents damage from the exterior by the impact of falling, etc. by the elasticity which resin has. Moreover, when a resin container is manufactured from polyethylene etc., it is also advantageous from the point that environmental load can be reduced by material recycling and thermal recycling of the used container.

The resin container 17 is detachably connected to the conduit 5-1 and the conduit 5-2 via the attachment 15 (container connecting portion). As shown in FIG. 8, the side outer peripheral surface of the opening part 24 (inlet) of the upper part of the resin container 17 is convex part 25 which continues spirally along the outer periphery, and protrudes in the plane outward direction of the opening part 24. As shown in FIG. ) Is provided. The inner circumferential surface of the attachment 15 is provided with a groove portion 27 that continues in a spiral corresponding to the convex portion 25. The openings 24 of the upper part of the resin container 17 can be attached and fixed to the attachment 15 by engaging them. At the time of attachment, the resin container 17 and the attachment 15 are rotated relative to each other so that the convex portion 25 and the groove portion 27 are screwed to attach the opening 24 at the upper portion of the resin container 17 to the attachment ( 15).

The attachment 15 preferably has a pressure resistance and uses a material that is less deformed by pressure than the material of the resin container 17. For example, a metal such as aluminum or stainless steel of SUS304 may be used as the material or chemical resistance is required. Although the site | part is preferably manufactured by combining materials, such as Teflon (trademark), on this, it is not limited to these.

When the chemical liquid is supplied, if the inside of the resin container 17 is directly pressurized, the resin container 17 slightly expands from the inside. At this time, the convex part 25 of the outer peripheral surface of the opening part 24 of the resin container 17 presses the groove part 27 of the attachment 15 with high deformation strength from an inner side equally, and engages each other, and airtightness improves. Therefore, the looseness of the attachment 15 and the leakage of gas by this become difficult to occur.

In addition, since the looseness of the attachment 15 may be caught by the convex portion 25 of the resin container 17 and the groove portion 27 of the attachment 15, the convex portion 25 is a groove portion. The attachment 15 is not caught by the 27, and the inside of the resin container 17 can be safely at atmospheric pressure by escaping through the gap created by the loosening of the pressurized gas.

In addition, since the cross-sectional area of the attachment 15 can be suppressed to the extent of the cross-sectional area of the opening 24 (the diameter of which is reduced compared to the trunk) of the upper portion of the resin container 17, the force applied to the attachment 15 Compared with the cover part of the above-mentioned pressure-resistant outer container which becomes the size more than the diameter of the trunk | drum of the resin container 17, it can provide a small and safe working environment.

For example, if the diameter of the lid of a cylindrical pressure-resistant outer container (such as a stainless steel vessel) is 300 mm, the force applied to the entire lid is about 7065 N / m 2 when the inside is pressed at 100 kPa.

In addition, the diameter of the attachment 15 attached to the injection port of the resin container 17 can be about 80 mm. At this time, if the inside of the resin container 17 is pressurized to 10 kPa (although it will be described later, the liquid supply system 1 can make the inside of the resin container 17 low pressure), and the force applied to the attachment 15 is It is about 50.24 N / m 2, which is 1/100 or less in size, indicating that the safety is further improved.

In addition, the attachment 15 has at least one pressurization port 22 and a liquid feeding port 23, the pressurizing port 22 to the conduit 5-1, and the liquid feeding port 23 to the conduit 5-2. Are detachably connected to each other.

The pressurizing port 22 is a flow path connected to the conduit 5-1 at one end and penetrates the attachment 15 in the direction of the resin container 17, and the inside of the conduit 5-1 and the resin container 17. Connect the conductively.

The liquid feeding port 23 is a flow path connected to the conduit 5-2 at one end and penetrates the attachment 15 in the direction of the resin container 17. The liquid supply port 23 opens the conduit 5-2 and the inside of the resin container 17. Connect it electrically. The other end is a siphon tube 19. The siphon tube 19 is a tube extending to the lower part of the resin container 17.

Next, the flow of the liquid supply method in the liquid supply system 1 of this embodiment is demonstrated using FIGS.

When liquid is supplied in the liquid supply system 1, the conduit 5-1, the pressurization port 22, the conduit 5-2 and the liquid supply port 23 are connected to each other to the conduit 5-1 and the conduit. The opening part 24 of the upper part of the resin container 17 is attached to the attachment 15 previously attached to (5-2) as mentioned above. Alternatively, the resin container 17 is attached to the attachment 15, and the attachment 15 is attached to the conduit 5-1 and the conduit 5-2.

Subsequently, as shown in FIG. 2, a gas container for pressurization (compressed air, compressed nitrogen, etc.) is supplied into the resin container 17 through a conduit 5-1 or the like, and the chemical container in which the chemical liquid is stored ( 17) Pressurize the inside. At this time, the valve 7-1 is open. In this embodiment, the pressing force is adjusted and maintained at about 10 kPa by the regulator 9-1 and the regulator 9-2. Moreover, while closing the valve 7-4, the valve 7-3 is opened, and the inside of the buffer tank 3 is made into atmospheric pressure. In addition, the valve 7-5 is closed and the valve 7-2 is opened to allow the chemical liquid to be filled in the buffer tank 3. However, the inside of the buffer tank 3 should just be a pressure state lower than the inside of the resin container 17, and only this may be a pressure state higher than atmospheric pressure.

Then, the chemical liquid in the resin container 17 is connected to the conduit 5-2 by the siphon effect according to the pressure difference between the inside of the resin container 17 (10 kPa) and the inside of the buffer tank 3 (atmospheric pressure). The chemical liquid is supplied into the buffer tank 3 through the inside of the buffer tank 3 as shown in FIG. 3. Since the inside of the resin container 17 is in a low pressure state, the amount of gas dissolved in the chemical liquid does not become excessive.

On the other hand, under an atmospheric pressure environment, if a pressing force exceeding 100 kPa is normally applied to the sealed resin container 17 over a long period of time, expansion may occur over time, resulting in liquid leakage, bursting, and conduction. I'm concerned about this. Therefore, in the liquid supply system 1 of this embodiment, in order to ensure safety, the pressing force by the gas inside the resin container 17 shall be 5 kPa-100 kPa range. In addition, in order to ensure safety further, it is preferable to use a pressing force in the range of 5 kPa-50 kPa. However, depending on the strength of the resin container 17 or when another container is used instead of the resin container 17, as long as there is no fear of liquid leakage, rupture, or falling, and ensuring the safety of the worker is assured, The pressing force that can be applied may change.

Here, 21 is a gas-liquid separation surface, and is the upper liquid surface of chemical | medical solution. In the case of supplying the chemical liquid, bubbles may be mixed into the chemical liquid via a pipe or the like on the resin container 17 side, but in this manner, the buffer tank 3 is a gas liquid for separating and removing the bubbles and the chemical liquid mixed into the chemical liquid. The separating surface 21 is provided. That is, the upper portion of the chemical liquid does not reach the upper surface of the buffer tank 3 so that a space filled with gas such as air is always secured to a predetermined capacity or more. As a result, bubbles rise to the gas-liquid separation surface 21 and are discharged into the upper gas to be separated from the chemical liquid.

For this reason, it is preferable to provide the above-mentioned sensor 4 in the buffer tank 3. And in order to make the air layer more than predetermined volume always exist in the upper part in the buffer tank 3, the sensor 4 is suitable predetermined (below an upper limit position) so that the gas-liquid separation surface 21 may not become more than a predetermined upper limit position. I) By detecting the height of the gas-liquid separation surface 21, it is preferable to block the chemical liquid supply or the like by controlling the opening and closing of the valve.

On the other hand, when the gas-liquid separation capability in the single body of the buffer tank 3 is insufficient, another gas-liquid separation vessel or a bubble removing mechanism such as a degassing module may be added to the pipeline or the like.

Further, as an example of more efficient degassing in the buffer tank 3, for example, the chemical liquid supplied through the conduit 5-2 in the tangential direction of the inner wall tangential or inclined with respect to the inner wall of the cylindrical buffer tank 3 flows. The through-hole for sending may be provided in the buffer tank 3, and the chemical liquid may be discharged in the direction tangential to the inner wall tangential direction or inclined with respect to the inner wall of the buffer tank 3 through the through-hole. At this time, swirling flow of the chemical liquid occurs in the buffer tank 3, and a swirling effect is generated, whereby a liquid having a high density in the inner wall direction of the buffer tank 3 and a gas having a low density in the planar center direction are respectively moved. The gas moves from the plane center portion of the buffer tank 3 to the gas-liquid separation surface 21. In this way, it is also possible to improve gas-liquid separation.

In addition, when the amount of chemical liquid to be supplied and the flow rate are insufficient to obtain sufficient swirl flow for degassing as described above, swing blades such as a magnetic strut and a stirring screw are installed in the buffer tank 3, thereby forcibly A swirl flow of the chemical liquid may be provided. At this time, if the shape of the swinging blade is made to be wider, for example, upward, a cyclone-type swirling flow toward the gas-liquid separating surface 21 in the upward direction is preferable.

In addition, in order to collect the air bubbles moving in the planar center direction of the buffer tank 3 by swirling flow, to guide the gas-liquid separation surface 21 upward and to discharge the gas into the gas, a hole for collecting and collecting bubbles therein is provided. A collecting pipe, which is a pipe that is provided on the side, may be provided. Inside the collecting pipe, bubbles gather to form a large bubble, which facilitates movement upward.

When the sensor 4 detects that the liquid level (gas-liquid separation surface 21) has reached a predetermined position, the valve 7-2 is closed as shown in FIG. Shut off the liquid supply through. In addition, the valve 7-3 is closed to shut off the atmosphere, while the valve 7-4 is opened to supply the pressurized gas (compressed air, compressed nitrogen, etc.) into the buffer tank 3 to discharge the discharge portion ( 13) (Pressurization in the buffer tank 3 necessary for feeding the liquid to the coating unit 120 is performed. In this case, the valve 7-5 is in a closed state.

This pressurization pressure does not generate a differential pressure at the time of sucking the chemical liquid by the discharge portion 13, but the pressure loss in the conduit 5-5 by the filtration filter 11 or the like and the negative pressure according to the chemical liquid suction operation of the discharge portion 13. It is the pressing force necessary for chemical liquid feeding that can be offset. In the liquid supply system 1, although the necessary pressure is applied to the inside of the buffer tank 3 within the range of about 10 kPa to 200 kPa, it is not limited to this, It depends on the strength of the buffer tank 3, etc. The pressing force which can be applied is changed as needed.

After applying the predetermined pressing force to the chemical liquid in the buffer tank 3, as shown in FIG. 5, the valve 7-5 is opened, the chemical liquid is sucked by the discharge portion 13, and the discharge portion is sucked. The chemical liquid is filled into the bottom liquid portion of (13) to apply the chemical liquid onto the substrate through the application nozzle 14.

Pressure loss occurs in the conduit 5-5 by the filtration filter 11 or the like provided in the conduit 5-5. In addition, a low liquid portion negative pressure is generated in accordance with the suction operation by the discharge portion 13, resulting in a suction load. In addition, a differential pressure is also generated in the flow path between the filtration filter 11 and the like having a high pressure loss, and the dissolved gas remaining in the chemical liquid may foam due to the cavitation inside the conduit 5-5 or the reservoir. There is.

However, in the liquid supply system 1, the chemical liquid suction by the discharge part 13 is performed, and the pressure loss and the negative pressure generated by the filtration filter 11 and the like can be canceled by pressurizing the inside of the buffer tank 3. Since the liquid supply is assisted by applying a sufficient pressure, foaming in the pipe line 5-5 and the bottom liquid portion as described above can be prevented. In addition, it is possible to suppress the deterioration and damage of parts due to excessive load on the discharge part 13, such as the motor of the discharge pump, at the time of suction.

On the other hand, when a slight residual pressure is generated in the liquid storage part by assist pressurization in the buffer tank 3, and the chemical liquid is overshooted at the start of coating or the chemical liquid leaks (possibly) from the coating nozzle 14 or the like, By performing the pre-dispensing operation before the main coating process, the coating section 120 (the flow path from the bottom liquid section to the opening of the coating nozzle 14) is returned to atmospheric pressure, or the valve 7-3 is opened to open the buffer tank. (3) By opening the inside of the atmosphere and then opening the valve 7-5, the residual pressure in the reservoir can be removed, so that the coating part 120 can be set equal to the atmospheric pressure.

It is also possible to simultaneously supply the chemical liquid into the buffer tank 3 and the chemical liquid supply from the buffer tank 3 to the application unit 120. In this case, when the gas-liquid separation surface 21 reaches a predetermined position, the discharge part 13 and the application nozzle (from the pressurization and buffer tank 3 in the buffer tank 3 with the valve 7-2 open) ( The chemical liquid supply to the application part 120, such as 14), is performed.

At this time, if bubbles separated from the chemical liquid are sucked into the pipeline 5-5 together with the chemical liquid, or if the chemical liquid before the gas is sufficiently separated is sucked into the pipeline 5-5 (possibly), First, after supplying the chemical liquid into the buffer tank 3, the gas is separated and the air bubbles are discharged upwards, and the valve 7-5 is opened after the time interval required for the gas liquid separation to be completed. It is sufficient to supply the chemical liquid to the coating unit through the < RTI ID = 0.0 > The antifoaming property may be different depending on the viscosity of the chemical liquid or the influence of the surfactant added to the chemical liquid, and the waiting time at this time is not particularly specified.

By the above operation, the inside of the resin container 17 is pressurized at low pressure, the dissolved amount of the gas in the chemical liquid is suppressed, and in the buffer tank 3, the air bubbles are separated from the chemical liquid and the coating portion ( 120 only selectively supplies liquid. In addition, by the assist pressurization in the buffer tank 3, the chemical liquid can be supplied to the application part 120 by offsetting the negative pressure resulting from the pressure loss and the suction operation generated in the filtration filter 11 or the like. Thereby, the influence on the quality by the bubble mentioned above can be suppressed. In addition, when discharging the chemical liquid from the coating nozzle 14 by the discharge unit 13, a high quality product having stable uniformity can be obtained by reducing the delay time of rise in the pressure in the pipe and the shortage of the initial discharge amount accompanying it. It becomes possible to supply.

On the other hand, when the filling to the liquid storage part is completed by the pump 13, as shown in FIG. 6, the valve 7-4 and the valve 7-5 are closed, and the valve 7-3 is thereafter. To open the atmosphere inside the buffer tank (3). The closing of the valve 7-5 prior to the valve 7-3 is to prevent the backflow of the chemical liquid into the buffer tank 3 at the time of atmospheric opening.

When the valve 7-2 is opened, as shown in FIG. 6, the chemical liquid in the resin container 17 is again caused by the siphon effect according to the differential pressure in the resin container 17 and the buffer tank 3. The chemical solution is filled into the buffer tank 3 by being pumped into the buffer tank 3 through the siphon pipe 19, the liquid feeding port 23, and the conduit 5-2.

As explained above, the liquid supply system 1 of this embodiment can isolate | separate and control the inside of the resin container 17 and the buffer tank 3 to an independent pressure state. Thereby, while maintaining the low pressing force (for example, the range of 5 kPa-100 kPa) with respect to the resin container 17, the inside of the buffer tank 3 was made into atmospheric pressure, and then the valve 7 of the conduit line 5-2. By opening -2), the chemical liquid can be supplied to the buffer tank 3 by the siphon effect.

Therefore, it is not necessary to use the resin container 17 in combination with a pressure-resistant outer container or a pressure protector, or use a resin container having a particularly high strength, and use a resin container commonly used for transportation as the resin container 17. Since it can be used alone, it leads to a reduction in equipment cost and a simplification of a safety device mechanism, thereby improving economic efficiency. In addition, workability such as container replacement or cleaning when the residual liquid in the chemical liquid container is consumed is also improved, thereby enabling efficient operation. Moreover, it is also suitable for recycling. Moreover, since the pressure applied in a container is suppressed low, the operation | work of a container replacement, etc. can be performed safely.

In addition, since the liquid is supplied to the buffer tank 3 in a state where the inside of the resin container 17 is kept at a low pressure, the amount of dissolved gas in the chemical liquid does not become excessive. Therefore, foaming in the conduit 5-5 or the bottom liquid portion can be suppressed. In addition, when supplying the chemical liquid in the buffer tank 3 to the applicator 120, a discharge pump (cylinder, tube diaphragm, diaphragm) is applied by applying a weak pressing force such that the pressure loss generated in the filtration filter 11 or the like is offset. Since the suction operation of the chemical liquid by the discharge part 13, etc.) is assisted, even if the filtration filter 11 or the like is installed in the conduit 5-5, the pressure loss or suction by the filtration filter 11 or the like is prevented. The negative pressure due to the operation is canceled, which leads to suppression of foaming in the conduit 5-5 or the reservoir.

Thereby, the influence on the quality by the bubble mentioned above can be suppressed. In addition, the delay of the pressure rise time at the start of coating can be eliminated by bubbles, so that a precise and uniform coating treatment by the stable liquid feeding can be achieved. Therefore, it is easy to maintain high quality with stable uniformity, and the productivity can be improved. In addition, it is possible to suppress the deterioration and damage of parts due to excessive load on the discharge part 13 such as a motor of the discharge pump at the time of suction.

Moreover, in the liquid supply system 1, although the inside of the resin container 17 is directly pressurized, the pipe line 5-1, the pipe line 5-2, and the resin container 17 are attached to the attachment 15 at that time. Connect via The resin container 17 is screwed into the convex portion 25 of the outer circumferential surface of the opening portion 24 (inlet) and the groove portion 27 of the inner circumferential portion of the attachment 15 provided to correspond to the convex portion 25, Attached to attachment 15. Therefore, when the resin container 17 expands slightly by pressurization, since the convex part 25 of the outer peripheral surface of the opening part 24 engages with the groove part 27 of the attachment 15, airtightness becomes high and loose. However, the risk of leakage is lowered.

In addition, even when the attachment 15 is loose when the container is replaced, the convex portion 25 of the resin container 17 and the groove portion 27 of the attachment 15 can be caught. The part 25 is caught by the groove part 27, and the attachment 15 is not scattered, and the inside of the resin container 17 can be safely at atmospheric pressure by escaping through the gap caused by the loosening of the pressurizing gas. have. Moreover, the cross-sectional area of the attachment 15 can be made as small as the opening part 24 of the resin container 17, and the force applied to the attachment 15 becomes small by this. Thus, it becomes possible to provide a safer working environment.

In addition, a sensor 4 is provided in the buffer tank 3, whereby control of the chemical liquid supply according to the liquid surface position can be carried out so that a constant volume of gas layer is always present in the buffer tank 3. Therefore, it is possible to separate from the chemical liquid by floating the air bubbles by the gas mixed into the chemical liquid through the conduit 5-2 and discharging it from the gas-liquid separation surface 21. Thereby, it can suppress that a bubble mixes in the conduit 5-5 of the application part 120 side, such as the discharge part 13 and the application | coating nozzle 14, and this suppresses generation | occurrence | production of bubbles, such as a micro bubble. It leads to.

Furthermore, excessive pressure is not accumulated in the chemical liquid of the liquid storage portion of the discharge portion 13, and the liquid storage is performed by performing the pre-dispensing operation before the main coating process or by opening the valve 7-5 and the valve 7-3. By removing the residual pressure in the portion and making it equal to the atmospheric pressure, it is possible to suppress the chemical liquid inside the application nozzle 14 from being extruded or overshooted at the start of discharge before application.

Another embodiment of the liquid supply system of this invention is described using FIG. In FIG. 7, the same code | symbol is attached | subjected about the element which has the same functional structure as FIG. 1, and description is abbreviate | omitted.

In the liquid supply system 30 of this embodiment, the conduit 5-6 (first flow path) extends from the air supply portion (not shown) and connects to the resin container 17. The conduit line 5-6 supplies gas from the air supply part in the resin container 17 to pressurize the inside of the resin container 17.

In addition, the conduit 5-7 (third flow path) extends from the air supply portion (not shown) and is connected to the buffer tank 3. The conduit 5-7 supplies gas from the air supply in the buffer tank 3 to pressurize the inside of the buffer tank 3.

That is, in this embodiment, the pipe line (pipe line 5-7) which supplies pressurized gas to the buffer tank 3 is the pipe line which supplies pressurized gas to the resin container 17 (pipe line 5-6). Are not branched from), they are independently piped to connect with the air supply. A valve 7-1 and a regulator 9-2 are provided in the middle of the conduit 5-6, and a valve 7-4 and a regulator 9-3 are respectively provided in the middle of the conduit 5-7. The pressurized state in the 1st container 17 and the buffer tank 3 is controlled independently.

Also in this case, chemical | medical solution can be supplied and apply | coated to the application | coating part 120, such as the discharge part 13 and the application | coating nozzle 14, in the same method and procedure as mentioned above, and the effect at that time is also the same as that mentioned above. . That is, after arranging a pipe, a valve, a regulator, or the like, the gas is introduced into the resin container 17 (at low pressure), pressurized, and the chemical liquid is supplied into the buffer tank 3 by the differential pressure between the buffer tank 3. The chemical liquid is fed to the coating unit 120 while introducing gas into the buffer tank 3 and applying a predetermined pressing force to the chemical liquid in the buffer tank 3 (in combination with the chemical liquid suction operation by the discharge unit 13). As long as possible, it is not limited to what was shown in embodiment.

As explained above, according to this embodiment, the liquid supply system etc. which were excellent in safety, economy, and productivity can be provided.

In addition, the chemical liquid which is preferably in the application range of the liquid supply system 1 is a liquid having a viscosity of about 1 to 100 mPa · s, suitably about 1 to 10 mPa, and more preferably Newtonian fluid. Although these are the physical properties of the chemical | medical solution suitable for the single-sheet application | coating process by a die-coat method, the chemical liquid of the non-Newtonian fluid which has thixotropy property etc. can be applied.

In another aspect, the chemical liquids which are preferably in the application range are chemical liquids using PGMEA, PGME, EEP, MBA, EDM, DMDG, butyl acetate, ethyl lactate, etc. as a main solvent. Examples of specific applications include semiconductors and liquid crystal displays. Photolithography for semiconductors, active matrix elements, photolithography for wiring formation, photolithography for color filter formation, and the like, for example, in the case of a photolithography process for color filter formation. Forming, coloring RGBY or CMY color pixel formation, white layer or scattering layer formation, alignment regulation protrusion formation, photospacer formation, overcoat layer formation, and the like.

Moreover, as a to-be-coated base material which apply | coats a chemical | medical solution, a silicon wafer, glass, a metal, a plastic, a film, etc. are mentioned.

As mentioned above, although preferred embodiment, such as the liquid supply system which concerns on this invention, was described referring an accompanying drawing, this invention is not limited to such an example. It will be apparent to those skilled in the art that various modifications or modifications can be conceived within the scope of the technical idea disclosed in the present application, and naturally these belong to the technical scope of the present invention.

1: liquid supply system 3: buffer tank
4: Sensor 5 (5-1, 5-2, 5-3, 5-4, 5-5): pipeline
7 (7-1, 7-2, 7-3, 7-4, 7-5): valve 9 (9-1, 9-2, 9-3): regulator
11: filtration filter 13: pump
14: application nozzle 15: attachment
17: resin container 19: siphon tube
21: gas-liquid separation surface 22: pressurization port
23: liquid feed port 25: convex portion
27: groove 100: coating device
120: applicator

Claims (9)

A liquid supply system for supplying liquid to an application portion of an application device,
A reservoir for storing a liquid;
A first flow path;
A second flow path connected to the reservoir and for supplying a liquid to the reservoir;
A third flow path connected to the reservoir and for supplying gas to the reservoir; and
A fourth flow path connected to the reservoir and the applicator, for supplying a liquid from the reservoir to the applicator,
The first flow path and the second flow path can be detachably connected to a predetermined container, and the first flow path is capable of supplying gas to the connected predetermined container. The method of claim 1,
The storage portion includes an air opening means for air opening the inside of the storage portion,
The first, second, third, and fourth flow path is a liquid supply system, characterized in that the opening and closing means for opening and closing each flow path. The method of claim 1,
And said reservoir comprises liquid level detecting means for detecting the height of the liquid level. The method of claim 1,
Further comprising a container connecting portion capable of detachably connecting the predetermined container,
The said 1st flow path and said 2nd flow path can connect the said predetermined container through the said container connection part, The liquid supply system characterized by the above-mentioned. The method of claim 4, wherein
And the container connecting portion has a groove portion on an inner circumferential surface thereof, and the container connecting portion and the predetermined container can be connected by screwing with the convex portion provided on the outer circumferential surface of the opening portion of the predetermined container. The method of claim 1,
And the first flow passage supplies gas into the connected predetermined containers so that the pressure in the predetermined container is in a range of 5 kPa to 100 kPa. The method of claim 1,
And the coating device is used for manufacturing a semiconductor device or a liquid crystal display device. A reservoir for storing a liquid; A first flow path; A second flow path connected to the reservoir and for supplying a liquid to the reservoir; A third flow passage connected to the storage portion and for supplying gas to the storage portion; and a fourth flow passage connected to the application portion of the storage portion and the coating device and for supplying liquid from the storage portion to the application portion. The first flow path and the second flow path may be detachably connected to a predetermined container, and the first flow path may be connected to the applicator of the coating apparatus using a liquid supply system capable of supplying gas to the connected predetermined container. As a liquid supply method for supplying a liquid,
The storage part which pressurizes the inside of the said predetermined container connected to the said 1st flow path and the said 2nd flow path by the gas supplied through the said 1st flow path, and supplies the liquid in the said predetermined container to the said storage part through the said 2nd flow path. Liquid supply process; and
An application part liquid supplying step of pressurizing the inside of the storage part by the gas supplied through the third flow path to supply the liquid in the storage part to the applicator through the fourth flow path;
Liquid supply method comprising the. An application apparatus comprising the liquid supply system according to any one of claims 1 to 7.

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