JP7079130B2 - Gas-dissolved water supply system - Google Patents

Description

The present invention relates to a gas-dissolved water supply system that supplies gas-dissolved water in which gas is dissolved in water to be treated.

In the semiconductor or liquid crystal manufacturing process, semiconductor wafers and glass substrates are washed using pure water or ultrapure water from which impurities are highly removed. In particular, in order to suppress the generation of static electricity in cleaning semiconductor wafers, a gas (carbon dioxide gas, ozone, hydrogen, etc.) dissolved in water to be treated (pure water or ultrapure water) to adjust the specific resistance value to a low level. Dissolved water (functional water) is used as wash water and rinse water. Generally, the gas-dissolved water is supplied to the use point after the fine particles are removed by the filtration membrane device (filter). A microfiltration membrane device or an ultrafiltration membrane device is used as the filtration membrane device, and it is preferable to use the ultrafiltration membrane device in order to remove finer fine particles. Patent Document 1 discloses a cleaning device using carbon dioxide gas-dissolved water, which comprises a carbon dioxide gas dissolution film module and a fine particle removal film module (see FIG. 1 of Patent Document 1). Further, Patent Document 1 describes that it is preferable to use a microfiltration membrane (MF membrane) or an ultrafiltration membrane (UF membrane) as the fine particle removal membrane module (see paragraph [0038] of Patent Document 1). .. With such a cleaning device, highly clean gas-dissolved water can be supplied to the point of use.

Japanese Unexamined Patent Publication No. 2017-175075

When an ultrafiltration membrane device is used to remove fine particles contained in gas-dissolved water, there is a problem that the permeation flux of the gas-dissolved water that permeates the ultrafiltration membrane device gradually decreases. May occur.

Therefore, an object of the present invention is to provide a gas-dissolved water supply system capable of stably supplying gas-dissolved water having high cleanliness.

In order to achieve the above-mentioned object, the gas-dissolved water supply system for supplying the carbon dioxide-dissolved water in which the carbon dioxide gas is dissolved in the water to be treated is a gas dissolving device for dissolving the carbon dioxide gas in the water to be treated. , The carbon dioxide gas is dissolved by the gas dissolving device located between the extraneous filter membrane device that removes the fine particles in the water to be treated in which the carbon dioxide gas is dissolved by the gas dissolving device and the gas dissolving device and the extraordinary filtering membrane device. It has a mixing device for dissolving carbon dioxide gas existing as a bubble in the treated water to be treated, and the mixing device includes a filler filled in a container, and the filler is an ion exchange resin. The ion exchange resin is characterized by being a mixed bed resin of an H-type cation exchange resin and a carbon dioxide or hydrogen carbonate type (HCO ₃ / CO ₃ type ) anion exchange resin .

According to the gas-dissolved water supply system of the present invention, highly clean gas-dissolved water can be stably supplied.

It is a block diagram which shows typically the gas dissolution water supply system of 1st Embodiment of this invention. It is a block diagram schematically showing the gas-dissolved water supply system of the 2nd Embodiment of this invention. It is a graph which shows the initial differential pressure maintenance rate of the gas-dissolved water supply system of the Example and the comparative example of this invention. It is a graph which shows the initial flux maintenance rate of the gas-dissolved water supply system of the Example and the comparative example of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(First Embodiment)
The configuration of the gas-dissolved water supply system according to the first embodiment of the present invention will be described. FIG. 1 is a block diagram schematically showing the gas-dissolved water supply system of the present embodiment. The gas-dissolved water supply system 1 of the present embodiment is a system that supplies gas-dissolved water (functional water) in which gas is dissolved in water to be treated (pure water or ultrapure water), for example, for cleaning a semiconductor wafer. Is. The gas-dissolved water supply system 1 includes a storage tank 2 for storing primary pure water which is raw material water, a heat exchanger 6, a degassing device 7, an ultraviolet (UV) irradiation device 8, an ion exchange device 3, and the like. The gas melting device 4, the mixing device 13, and the ultrafiltration membrane device 5 are arranged in this order and connected in series. The heat exchanger 6 is a device that preliminarily adjusts the temperature of the raw material water so that the temperature of the gas-dissolved water becomes suitable when it is used for a desired treatment (for example, cleaning of a semiconductor wafer). The degassing device 7 is a device that removes gas (particularly oxygen) in the raw material water to prevent oxidation, for example. As the degassing device 7, a vacuum degassing device, a membrane degassing device, or the like is adopted, and the dissolved oxygen (DO) is reduced to, for example, less than 50 ppb. The ultraviolet irradiation device 8 is a device that sterilizes with ultraviolet rays.

In this way, the temperature of the raw material water is adjusted, the amount of dissolved oxygen is adjusted, and sterilization is performed, and the ionic impurities are removed by the ion exchange device 3. The ion exchange device 3 removes ionic impurities contained in the raw material water by an ion exchange process, and has an ion exchange tower filled with an ion exchanger. The ion exchange device 3 is preferably a non-regenerative ion exchange device (cartridge polisher: CP) in order to maintain high processing performance. Specifically, it has an ion exchange tower filled with an anion exchange resin for removing anionic (anionic) impurities and a cation exchange resin for removing cation (cationic) impurities. .. The filling form of the anion exchange resin and the cation exchange resin in the ion exchange tower may be a mixed bed form in that a trace amount of impurities derived from the ion exchange resin can be efficiently removed to improve the cleanliness. preferable. That is, the ion exchange device 3 of the preferred embodiment is a non-regenerative mixed bed ion exchange device filled with a mixed resin of a cation (cation) exchange resin and an anion (anion) exchange resin.

The gas melting device 4 is a device that dissolves gas in pure water or ultrapure water supplied from the ion exchange device 3. By dissolving the gas in pure water or ultrapure water, the specific resistance value is adjusted to a desired range, thereby suppressing the generation of static electricity. The gas dissolving device 4 includes, for example, a device for dissolving gas using a gas permeable film made of hollow yarn, a device for bubbling gas directly in a pipe, and a device for dissolving gas by a dispersion means such as a static mixer after injecting gas. , A device that supplies gas to the upstream side of the pump that supplies pure water or ultra-pure water to the gas dissolution tank and dissolves the gas by stirring in the pump can be used. In particular, a gas-dissolving membrane-type device that dissolves gas using a gas-permeable membrane made of hollow yarn is preferable because the membrane area (gas-liquid contact area) is large and the gas can be efficiently dissolved. The gas can be supplied to the gas melting device 4 through a gas line (not shown). Examples of the gas to be dissolved include carbon dioxide gas, nitrogen gas, hydrogen gas, ozone gas and the like.

The mixing device 13 is a device that further dissolves the gas mixed in the gas dissolving device 4 into the liquid, which cannot be completely dissolved in the liquid (pure water or ultrapure water) and still exists as a bubble. As an example of the mixing device, a container in which a liquid enters and exits is filled with a filler (for example, resin) to increase the contact area between the liquid and the filler. In such a mixing device, the filling material is packed, so that the time required for the liquid to pass through the container becomes long, and the bubbles tend to dissolve in the liquid during that time.

The ultrafiltration membrane device 5 removes fine particles from gas-dissolved water (functional water) in which gas is dissolved in pure water or ultrapure water. The ultrafiltration membrane device 5 can remove very small fine particles having a diameter of about 0.001 μm to 0.01 μm, and makes it possible to supply highly clean gas-dissolved water to the use point 12. The gas-dissolved water treated by the ultrafiltration membrane device 5 is selectively supplied from the supply unit 10 to all or a part of the plurality of use points 12. At each use point 12, the gas-dissolved water is used, for example, as cleaning water or rinsing water for cleaning a semiconductor wafer (not shown). Further, the gas-dissolved water that is not used at the point of use is returned to the storage layer 2 by the circulation route 9.

According to such a configuration, gas-dissolved water having high cleanliness and desired water quality can be circulated along the circulation path 9, and the required amount of gas-dissolved water can be supplied to the use point 12 when necessary. Can be done. That is, it is possible to stably supply the gas-dissolved water having high cleanliness and desired water quality to the use point 12. Further, according to the present embodiment, the gas-dissolved water supply system 1 can be continuously operated regardless of the usage status of the gas-dissolved water at the use point 12. Due to the continuous operation of the gas-dissolved water supply system 1, only a small amount of gas-dissolved water with insufficient cleanliness and water quality, which may be generated immediately after the start of the gas-dissolved water supply system 1, is generated, and the gas is generated. Wasteful consumption of dissolved water can be suppressed. In particular, according to the present embodiment, by circulating the gas-dissolved water, impurities can be further reduced, and a gas-dissolved water having a higher degree of cleanliness can be obtained. When the amount of gas-dissolved water used at the use point 12 is large and the amount of circulating gas-dissolved water decreases, the raw material water may be replenished to the storage tank 2 from a replenishment line (not shown). The storage tank 2 has a gas introduction line for introducing nitrogen gas and clean air (not shown) and a gas discharge line for discharging nitrogen gas and clean air from the storage tank 2 to the outside (not shown). And are connected.

Further, although not shown, it is also possible to recover the gas-dissolved water used as, for example, washing water or rinsing water at the use point 12, merge it with the return path toward the reservoir 2, and reuse it. However, in that case, the recovered gas-dissolved water may be allowed to flow into the storage layer 2 after passing through a water quality adjusting means (for example, a filter) (not shown) in order to adjust the water quality. Alternatively, the gas-dissolved water used at use point 12 (see FIG. 1) may be recovered, purified to the level of primary pure water, and then returned to the storage tank 2. By reusing the gas-dissolved water in this way, the amount of replenishment of the raw material water and the gas to be dissolved therein (for example, carbon dioxide gas) can be reduced, and the amount of the raw material water and the gas used can be further reduced. In this way, it is a centralized supply system that supplies gas-dissolved water from one gas-dissolved water supply system to a plurality of use points 12, and is a circulation method that supplies the gas-dissolved water to the use points 12 while circulating the gas-dissolved water (so-called). In the ultrapure water subsystem), the present invention that suppresses the decrease in the permeation flux of the ultrafiltration membrane device 5 over time is particularly effective.

The technical significance of the mixing device 13 of the present embodiment will be described below. As described above, by passing the gas-dissolved water through the ultrafiltration membrane device 5, it is possible to obtain gas-dissolved water having high cleanliness, which is effective for cleaning semiconductor wafers and the like. However, there has been a problem that the permeation flux in the ultrafiltration membrane device is reduced. On the other hand, in the present embodiment, by interposing the mixing device 13 between the gas dissolving device 4 and the ultrafiltration membrane device 5, the decrease in the permeation flux in the ultrafiltration membrane device 5 is suppressed. I found that I could do it.

Normally, the gas mixed in the gas melting device 4 (for example, carbon dioxide gas) does not completely dissolve in the liquid, and it is inevitable that a part of the gas remains as a bubble. Then, this bubble may cause a decrease in the amount of water passing through the ultrafiltration membrane device 5 and an increase in the differential pressure. That is, in the configuration in which the mixing device 13 is not provided, bubbles that are mixed in the gas dissolving device 4 and still exist without being completely dissolved in the water to be treated are holes in the ultrafiltration membrane of the ultrafiltration membrane device 5. It can get in and be captured. The bubbles captured in this way substantially block the holes, making it impossible for the liquid to permeate. As the ultrafiltration membrane device 5 continues to be used, the holes closed by the bubbles gradually increase, and the amount of liquid flowing out through the ultrafiltration membrane device 5 decreases. That is, the permeation flux in the ultrafiltration membrane device is reduced. Bubbles in the liquid are particularly likely to occur in the circulation path 9 as shown in FIG. That is, bubbles are likely to occur due to water flow to the reservoir 2 in the circulation path 9, entrainment of gas, cavitation during suction of a pump (not shown), various pressure changes and fluctuations, and the like. The bubbles generated in this way include not only large visible bubbles but also invisible microbubbles and nanobubbles. And it is said that microbubbles and nanobubbles exist stably in liquids. When microbubbles and nanobubbles that are stably present in the liquid enter the holes on the surface of the ultrafiltration membrane device and its interior and are captured, the ultrafiltration membrane device is locally dried (partially by gas). The water flow differential pressure rises over time.

Therefore, in the present embodiment, the mixing device 13 is provided between the gas dissolving device 4 and the ultrafiltration membrane device 5, that is, on the downstream side of the gas dissolving device 4 and on the upstream side of the ultrafiltration membrane device 5. .. The mixing device 13 has an action of dissolving bubbles that have not been dissolved in the liquid into the liquid. Therefore, due to the action of the mixing device 13, the amount of bubbles carried to the ultrafiltration membrane device 5 without being dissolved in the liquid is reduced. As a result, the number of bubbles that enter the pores of the ultrafiltration membrane device 5 and are captured is reduced, and the number of holes that are blocked by the bubbles is reduced, so that the permeation flux in the ultrafiltration membrane device 5 is reduced. It can be suppressed and the increase in differential pressure is suppressed.

As described above, reducing the possibility that the pores on the surface of the ultrafiltration membrane device 5 are blocked by bubbles is a factor that suppresses the decrease in the permeation flux of the ultrafiltration membrane device 5 by the present invention. It is considered to be one. However, based on other factors, it is possible that the present invention has realized the effect of suppressing the decrease in the permeation flux of the ultrafiltration membrane device 5.

As the mixing device 13 for dissolving the bubble in the liquid, the one having the following configuration can be considered. First, a device that pressurizes the inflowing liquid can be considered. In such a mixing device 13, the dissolution rate can be increased by pressurizing the inflowing liquid, and the bubbles can be dissolved in the liquid. However, in this case, it is necessary to prevent bubbles from being generated in the liquid again even if the pressure of the liquid flowing out of the mixing device decreases.

A device having a long pipe for flowing the inflowing liquid can also be used as the mixing device 13. In such a mixing device 13, it takes a relatively long time for the liquid to pass through, and it can be expected that the bubbles gradually dissolve in the liquid during that time. That is, since it can be expected that the bubbles will dissolve in the liquid over time without exerting any special action, it is effective to provide a long pipe through which the liquid passes. However, in order to provide long pipes, it is necessary to increase the size of the entire device or to make the elongated pipes meander.

A so-called mixer manufactured for the purpose of mixing fluids with each other can also be used as a mixing device. As the mixer, for example, a resin ejector of IBS Co., Ltd., a static mixer of Noritake Company Limited, a vortex turbo mixer of Nikuni Co., Ltd., and the like can be used. Since these mixers are designed to mix gas and liquid, they have a great effect of dissolving bubbles in the liquid. However, the configuration can be complex and costly. In addition, it is necessary to prevent the liquid from being contaminated when passing through a complicated mechanism so that the cleanliness suitable for cleaning water or rinsing water for cleaning semiconductor wafers, glass substrates, etc. can be maintained.

Further, as described above, the container filled with the filler can also be used as the mixing device 13. According to this configuration, since the contact area between the filler and the liquid is large and the contact time is long, it takes a relatively long time for the liquid to pass, and the bubbles gradually dissolve in the liquid during that time. In this configuration, it is necessary to prevent the filler from contaminating the liquid. In that respect, it is preferable to use a resin (for example, an ion exchange resin) as a filler rather than activated carbon or zeolite. When an ion exchange resin is used as a filler, not only does it not contaminate the liquid, but it can also be expected to have the effect of further removing impurities. That is, the mixing device 13 is not particularly limited as long as it changes the state of the bubble after the gas is dissolved, but if it is a filtration device (CP: cartridge polisher) filled with a non-regenerative ion exchange resin, impurities can be removed. It is preferable because it is possible to produce and supply high-purity gas-dissolved water that does not contain as much as possible. The ion exchange resin is a mixed bed resin of non-regenerative H-type cation exchange resin and OH-type anion resin, non-regenerative H-type cation exchange resin and carbonic acid or hydrogen carbonate type (HCO ₃ / CO ₃ type). It may be a mixed bed resin of anion resin, a single bed resin of H-type cation exchange resin, a single bed resin of carbonic acid or hydrogen carbonate type anion exchange resin, or the like.

When using a mixed bed resin of H-type cation exchange resin and OH-type anion resin, which is a general CP resin for ultrapure water production, when carbon dioxide gas-dissolved water is treated, the anion exchange resin is carbonated from OH-type. Or it changes to hydrogen carbonate form. Since the carbonic acid concentration at the outlet of the mixing device 13 is low from the start of water flow to the change of the anion exchange resin from the OH type to the carbonic acid or hydrogen carbonate type as described above, the carbonic acid gas containing the desired carbonic acid concentration It is difficult to supply dissolved water. In order to supply the carbon dioxide-dissolved water having an appropriate concentration to the use point in that state, it is necessary to increase the amount of carbon dioxide gas to be dissolved by the gas dissolving device 4. In that case, after the anion exchange resin changes from the OH type to the carbonic acid or hydrogen carbonate type, the carbon dioxide gas concentration may become too high.

On the other hand, a mixed bed resin of H-type cation exchange resin and carbonic acid or hydrogen carbonate anion exchange resin, a single bed resin of H-type cation exchange resin, or a single bed resin of carbonic acid or hydrogen carbonate anion exchange resin is used. In this case, it is preferable in that it is possible to supply carbon dioxide gas-dissolved water containing a desired carbon dioxide concentration from the beginning of water flow. A clean non-renewable H-type cation exchange resin can be easily obtained, and even if it comes into contact with carbon dioxide ^- dissolved water, it is the main component of carbon dioxide-dissolved water, HCO _3- , CO ₃ ^-2 . It does not react with and the carbon dioxide concentration does not change. Further, it is preferable in that it is possible to remove problematic metal impurities such as Na and Ca. Since the carbon dioxide gas-dissolved water is acidic, the H-type cation exchange resin is preferably a strong ion exchange resin.

The mixing device 13 of the present invention may adopt any of these configurations, but in the above-described embodiment, the mixing device 13 having a structure in which a filler is packed in a container is used. A preferred example of this filler is an ion exchange resin, which may be similar to the ion exchange resin of the ion exchange device 3.

(Second embodiment)
In FIG. 2, the second embodiment of the present invention shows that the treatment using the water to be treated (pure water or ultrapure water) in which the gas is not dissolved and the treatment using the gas-dissolved water can be performed in parallel. A form of gas-dissolved water supply system 14 is shown. The same reference numerals are given to the same parts as those of the dissolved water supply system 1 of the first embodiment. In the gas-dissolved water supply system 14 of the present embodiment, from the storage tank 2 for storing the primary pure water which is the raw material water, the heat exchanger 6, the degassing device 7, the ultraviolet irradiation device 8, the ion exchange device 3, and the ultrafiltration membrane are used. The devices 5 are arranged in this order and connected in series. This path does not include gas melting and mixing equipment. That is, the supply path 17 for supplying the water to be treated in which the gas is not dissolved is connected to the first ultrafiltration membrane device 5, and the first ultrafiltration membrane device 5 is supplied from the supply path 17. Removes fine particles in the water to be treated in which the gas is not dissolved. Then, a part of the water to be treated (pure water or ultrapure water) treated by the first ultrafiltration membrane device 5 is used from the supply unit 10 to use point 15 (pure water or ultrapure water containing no gas). It is supplied to the part to be treated). The remaining portion of the water to be treated (pure water or ultrapure water) treated by the first ultrafiltration membrane device 5 is returned to the storage layer 2 via the pressure regulating valve 11.

In the present embodiment, a branch path 18 branching from the supply path 17 is provided on the upstream side in the flow direction toward the first ultrafiltration membrane device 5 of the water to be treated in which the gas is not dissolved. The branch path 18 is connected to the storage layer 2 of the path for supplying gas-dissolved water via the supply amount control valve 16. Therefore, the water to be treated from which the ionic impurities have been removed by the ion exchange device 3 is not only sent to the first ultrafiltration membrane device 5, but also gas-dissolved water from the branch path 18 via the supply amount control valve 16. It is also sent to the reservoir 2 of the supply route. The water to be treated is sent from the storage layer 2 of the path for supplying the gas-dissolved water to the gas-dissolving device 4 via the heat exchanger 6, the ultraviolet irradiation device 8, and the ion exchange device 3. That is, the branch path 18 branching from the supply path 17 on the upstream side of the first ultrafiltration membrane device 5 is gas-dissolved via the storage layer 2, the heat exchanger 6, the ultraviolet irradiation device 8, and the ion exchange device 3. It is connected to the device 4. The gas melting device 4 dissolves the gas in the water to be treated in which the gas supplied from the branch path 18 is not dissolved. Then, the gas-dissolved water (functional water) in which the gas is dissolved by the gas-dissolving device 4 is sent to the second ultrafiltration membrane device 5 after passing through the mixing device 13. At least a part of the gas-dissolved water from which the fine particles have been removed by the second ultrafiltration membrane device 5 is supplied from the supply unit 10 to the use point 12. The remaining portion of the gas-dissolved water from which the fine particles have been removed is returned to the storage layer 2 via the pressure regulating valve 11 and circulates. In this path for supplying gas-dissolved water, in order to prevent gas bubbles injected into the water to be treated by the gas-dissolving device 4 from entering the holes on the surface of the second ultrafiltration membrane device 5 and being captured. , A mixing device 13 is provided. For example, as described above, it takes a long time to pass through while contacting the filler (for example, resin) filled in the mixing device 13, during which the bubbles dissolve in the water to be treated. As a result, it is possible to suppress a decrease in the permeation amount of the gas-dissolved water and suppress an increase in the differential pressure. The degassing device 7 is not provided in the path for supplying the gas-dissolved water, but the heat exchanger 6, the ultraviolet irradiation device 8, and the ion exchange device 3 are provided. In the present embodiment, which device is arranged in the path for supplying gas-dissolved water and which device is omitted should be determined by appropriately determining whether or not it is desirable to perform the processing by each device in duplicate. Just do it. In the example shown in FIG. 2, heat exchange, ultraviolet irradiation, and ion exchange (removal of ionic impurities) are performed twice before and after introduction into the path for supplying gas-dissolved water. There is.

According to this configuration, gas-free pure water or ultrapure water and gas-dissolved water can be supplied to the respective use points 12 and 15, depending on the application, and the second ultrafiltration The decrease in the permeation flux in the membrane device 5 can be suppressed to a small extent.

(Example)
In the system shown in FIG. 1, the mixing device 13 having a structure in which an ion exchange resin (EG-4A-HG manufactured by Organo Co., Ltd .: trade name) is filled in a container is a gas dissolving device 4 and an ultrafiltration membrane device 5. The inlet pressure, permeation pressure, concentration pressure, and permeation flow rate of the ultrafiltration membrane device 5 in the configuration (example) arranged between them and the configuration without the mixing device (comparative example not shown) are measured. The changes over time in the differential pressure and the permeation flux (flux) were determined. The amount of resin in the mixing device 13 is 70 L, the flow rate passing through the mixing device is 4.9 m ³ / h, and the space velocity SV is 70 / h. The differential pressure is the difference in the pressure of the liquid between the primary side and the secondary side of the ultrafiltration membrane device, and the differential pressure = (inlet pressure + concentrated pressure) / 2-permeation pressure. In FIG. 3, the initial differential pressure is set to 100%, and the fluctuation of the differential pressure over time is expressed as a percentage (initial differential pressure maintenance rate). The permeation flux is the amount of permeated water that permeates the ultrafiltration membrane device (the total amount of permeated water when the gas-dissolved water supply system is operated for one day (24 hours)) and the membrane area of the ultrafiltration membrane device. It is a value divided by the differential pressure, and the flux = the amount of permeated water per day / (membrane area x differential pressure). In FIG. 4, the flux in the initial state is taken as 100%, and the fluctuation of the flux over time is expressed as a percentage (initial flux maintenance rate).

Looking at FIGS. 3 and 4, it can be seen that in the comparative example in which the mixing device is not provided, the differential pressure increases with time and the amount of permeated water decreases. That is, even if a certain amount of raw material water is continuously supplied, the amount of gas-dissolved water obtained from this gas-dissolved water supply system decreases, so that the amount of gas required for processing (for example, cleaning of a semiconductor wafer) is reduced. It becomes difficult to obtain dissolved water. For example, after about 800 hours have passed since the operation of the gas-dissolved water supply system was started, only about half the amount of gas-dissolved water in the initial stage can be obtained. By increasing the supply pressure of the raw material water, particularly the supply pressure to the ultrafiltration membrane device 5 (UF supply pressure), a required amount of gas-dissolved water can be obtained. However, in that case, the differential pressure further increases. Since the ultrafiltration membrane has allowable values for the supply pressure and the differential pressure, it is necessary to replace the ultrafiltration membrane when the allowable values are reached. If the rate of increase in differential pressure or decrease in flux is large, the life of the ultrafiltration membrane will be shortened, and the frequency of membrane replacement will increase, leading to higher costs. On the other hand, in the example, the differential pressure almost the same as that in the initial stage and the flux of about 90% in the initial stage can be maintained even after about 800 hours have passed. Therefore, according to the embodiment, the amount of gas-dissolved water required for processing (for example, cleaning of a semiconductor wafer) can be easily obtained without the need to increase the UF supply pressure in particular, so that the increase in the differential pressure is kept moderate and limited. The life of the outer filtration membrane can be extended. As a result, the frequency of replacement of the ultrafiltration membrane is reduced, and cost increase can be avoided. As described above, in the configuration in which the mixing device 13 is provided between the gas dissolving device 4 and the ultrafiltration membrane device 5 (Example), compared with the configuration in which the mixing device 13 is not provided (Comparative Example). It can be seen that the increase in differential pressure and the decrease in the amount of permeated water over time can be suppressed to a low level.

1 Gas-dissolved water supply system 2 Storage tank 3 Ion exchange device 4 Gas-dissolving device 5 Ultrafiltration membrane device (1st and 2nd ultrafiltration membrane device)
6 Heat exchanger 7 Degassing device 8 Ultraviolet irradiation device 9 Circulation path 10 Supply section 11 Pressure control valve 12 Use point 13 Mixing device 14 Gas-dissolved water supply system 15 Use point 16 Supply amount control valve 17 Supply path 18 Branch path

Claims (4)

It is a gas-dissolved water supply system that supplies carbon dioxide-dissolved water in which carbon dioxide is dissolved in the water to be treated.
A gas dissolving device that dissolves carbon dioxide gas in the water to be treated, an extraneous filtration membrane device that removes fine particles in the water to be treated in which carbon dioxide gas is dissolved by the gas dissolving device, the gas dissolving device, and the extraordinary It has a mixing device which is located between the filter membrane device and dissolves carbon dioxide gas by the gas dissolving device, and dissolves the carbon dioxide gas existing as a bubble in the treated water into the treated water.
The mixing device includes a filler filled in a container, the filler is an ion exchange resin, and the ion exchange resin is an H-type cation exchange resin and a carbonic acid or hydrogen carbonate type (HCO ₃ / CO ₃ ). Shape) A gas-dissolved water supply system characterized by being a mixed bed resin of anion exchange resin . The gas-dissolved water supply system according to claim 1 , further comprising an ion exchange device on the upstream side of the gas-dissolving device. The gas-dissolved water supply according to claim 1 or 2, further comprising a storage tank for storing primary pure water and a circulation path for returning the carbon dioxide-dissolved water not used at the point of use to the storage tank . system. It is a gas-dissolved water supply method that supplies carbon dioxide-dissolved water in which carbon dioxide is dissolved in water to be treated.
The carbon dioxide gas existing as a bubble in the water to be treated in which the carbon dioxide gas is dissolved in the step of dissolving the carbon dioxide gas in the water to be treated and the step of dissolving the carbon dioxide gas is dissolved in the water to be treated by a mixing device. The step includes a step of dissolving the carbon dioxide gas and removing fine particles in the water to be treated in which the carbon dioxide gas existing as a bubble is dissolved.
The mixing device includes a filler filled in a container, the filler is an ion exchange resin, and the ion exchange resin is an H-type cation exchange resin and a carbonic acid or hydrogen carbonate type (HCO ₃ / CO ₃ ). Shape) A method for supplying gas-dissolved water, which is a mixed bed resin of an anion exchange resin .

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