JP2002336859A - Desalted water making method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a desalted water making method which is capable of well maintaining the quality of treated water in making the desalted water by using a flow-through type electric double layer capacitor. SOLUTION: A desalting process step of obtaining permeated water and concentrated water by passing feed water through the flow-through type electric double layer capacitor 2 and a reverse osmosis membrane apparatus 3 and a regenerating process step shorting or reverse connecting the electrodes of the anode side and cathode side of the flow-through type electric double layer capacitor 2 and supplying the concentrated water of the reverse osmosis apparatus 3 to the flow-through type electric double layer capacitor 2 through a concentrated water feed route 4 are performed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the supply of water for boilers of power plants, the production of semiconductors, the production of pure water used for fuel cell power generation, the production of water for cooling towers, the recycle use, and the collection of various wastewaters. The present invention relates to a method for producing demineralized water to be used.

[0002]

2. Description of the Related Art Conventionally, as this kind of demineralized water production method, there is a method using a deionization apparatus provided with an ion exchange membrane or an ion exchange resin. The method for producing desalinated water using an ion exchange membrane or an ion exchange resin usually requires regeneration and replacement of the membrane and the resin, so that there is a problem that the processing cost increases and a large amount of labor is required for the operation. However, improvement in work efficiency was desired. In recent years, a method using a deionization device called a flow-through type electric double layer capacitor has been proposed as a method for producing demineralized water capable of improving the inconvenience caused by such replacement or regeneration. As this liquid-permeation type electric double layer capacitor, those described in JP-A-6-325983 can be exemplified. The flow-through type electric double layer capacitor has a configuration in which two high-surface-area conductor layers are sandwiched by a fluid passage therebetween, and a collector is arranged outside these conductor layers. By applying a voltage to the conductive layer, the ionic substance in the supply water flowing through the liquid passage is electrically adsorbed on the conductor layer, and the treated water having a reduced ionic substance concentration can be obtained. Activated carbon is suitable as a conductor constituting the conductor layer. In a flow-through type electric double layer capacitor, a regeneration step in which the adsorbed ionic substance is desorbed by short-circuiting or reverse-connecting the anode side and the cathode side before the adsorption of ions to the conductor layer reaches saturation. Is performed regularly.

[0003]

However, in the conventional method for producing desalinated water, the efficiency of the desalination treatment may not be restored even after the regeneration step, and the quality of the treated water may be degraded. Also, a large amount of washing water was required in the regeneration step. The present invention has been made in view of the above circumstances, and in producing desalinated water using a flow-through type electric double layer capacitor, the quality of treated water can be kept good, and the amount of water required in the regeneration step can be reduced. It is an object of the present invention to provide a method for producing desalinated water.

[0004]

According to the method for producing desalinated water of the present invention, after supplying electricity to a liquid-flow type electric double layer condenser and passing water through it, the water is passed through a reverse osmosis membrane apparatus and the reverse osmosis membrane apparatus is used. Desalination process to obtain permeated water and concentrated water from water, short-circuit or reverse-connect the anode and cathode electrodes of the flow-through type electric double-layer capacitor, and concentrate the reverse osmosis membrane device on the flow-through type electric double-layer capacitor And a regeneration step of supplying water. Further, in the present invention, a desalination step of supplying electricity to the flow-through type electric double layer condenser and passing the supplied water, and then passing the water through the reverse osmosis membrane device to obtain permeated water and concentrated water from the reverse osmosis membrane device, A regenerating step of short-circuiting or reverse-connecting the anode side and the cathode side electrodes of the flow-through type electric double layer capacitor and supplying permeated water of the reverse osmosis membrane device to the flow-through type electric double layer capacitor. Can also be adopted. Also, in the present invention, a desalination step of supplying electricity to a first water treatment apparatus comprising a liquid-passing type electric double layer condenser to pass supply water, and then passing water to a second water treatment apparatus to obtain treated water. And a regenerating step of short-circuiting or reverse-connecting the anode side and the cathode side electrodes of the flow-through type electric double-layer capacitor and supplying the treated water to the flow-through type electric double-layer capacitor, and adopting a desalinated water production method. You can also.

[0005]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail.
FIG. 1 is a diagram showing an apparatus for producing desalinated water suitable for carrying out the first embodiment of the method for producing desalinated water of the present invention. Liquid electric double layer condenser 2 for electrically adsorbing and desalinating water, reverse osmosis membrane device 3 provided downstream of liquid permeation type electric double layer capacitor 2, and reverse osmosis membrane device 3 A concentrated water supply path 4 for supplying the concentrated water to the liquid-type electric double layer condenser 2 is provided.

[0006] The flow-through type electric double layer capacitor 2 is shown in FIG.
As shown in (a) and (b), activated carbon layers 6 and 6 which are conductor layers mainly composed of activated carbon having a high specific surface area are arranged with a separator 5 made of an electrically insulating porous liquid-permeable sheet interposed therebetween. Then, collecting electrodes 7 and 7 are arranged outside these activated carbon layers 6 and 6, and gaskets 8 and 7 are formed outside these collecting electrodes 7 and 7.
It has a flat plate shape in which pressing plates 9 and 9 are arranged via 8.

[0007] The separator 5 serves as a liquid flow path through which the supply water flows, and is made of an organic or inorganic material such as filter paper, a porous polymer membrane, woven fabric, or nonwoven fabric, which allows easy passage of liquid and has electrical insulation. The thickness is about 0.01 to 0.5 mm, particularly 0.02 to
About 0.3 mm is preferable.

The activated carbon layer 6 is formed by a layer mainly composed of activated carbon having a high specific surface area. The high specific surface area activated carbon has a BET specific surface area of 1000 m ² / g or more, preferably 1500 m ² / g or more, more preferably 200 m ² / g or more.
0 to 2500 m ² / g activated carbon. If the BET specific surface area is too small, the removal rate of the ionic substance when passing through a liquid (raw water) containing the ionic substance decreases. Note that B
If the ET specific surface area is too large, the removal rate of the ionic substance tends to be rather reduced, so that it is not preferable to increase the BET specific surface area more than necessary.

The activated carbon constituting the activated carbon layer 6 may be in any form, such as powder or granules, or fibrous.
In the case of a powdery or granular material, it is used after being formed into a flat plate or a sheet. In the case of a fibrous material, it is used after being processed into a woven or nonwoven fabric. When powdered and granular activated carbon is formed into a flat plate or sheet, it is significantly more advantageous in terms of cost than when fibrous activated carbon is processed into a woven or nonwoven fabric.

For forming the granular activated carbon into a flat plate or a sheet, for example, the granular activated carbon is mixed with a binder component (polytetrafluoroethylene, phenol resin, carbon black, etc.) and / or a dispersion medium (solvent, etc.). This can be carried out by forming into a plate shape and, if necessary, subjecting it to a heat treatment. When the activated carbon layers 6 and 6 are formed into a flat plate or a sheet, the perforations may be formed as necessary. The thickness of the activated carbon layer 6 is preferably about 0.1 to 3 mm, particularly about 0.5 to 2 mm, but is not necessarily limited to this range.

The collector 7 is made of a good electrical conductor such as a copper plate, an aluminum plate, a carbon plate, or foil-like graphite, and is formed and arranged in close contact with the activated carbon layer 6. The thickness of the collector 7 is not particularly limited, but is preferably about 0.1 to 0.5 mm. Note that each of the collector electrodes 7 is provided with a terminal (lead) 7a to facilitate application of a voltage.

As the holding plate 9, a flat plate made of a material such as resin which is electrically insulating and hardly deformed is used. A liquid inlet 10 through which supply water is introduced is formed in one of the holding plates 9, 9, and a liquid outlet 11 through which treated water is led out is formed in the other. A large number of fixing bolt holes 12 are formed in both holding plates 9, 9, and bolts 13 are inserted into these bolt holes 12, 12 and fastened by nuts 14. With such a configuration, the liquid-permeation type electric double layer capacitor 2 has a flat plate-like structure in which each member is pressed by the holding plates 9, 9. Gaskets 8, 8 provided between the collecting electrodes 7, 7 and the holding plates 9, 9 are frames for holding the gap between the collecting electrodes 7, 7 and the holding plates 9, 9 in a liquid-tight manner. Shape. Instead of providing the gaskets 8, 8, a member having a sealing function may be provided on the holding plates 9, 9.

Examples of the reverse osmosis membrane used in the reverse osmosis membrane device 3 include those made of materials such as cellulose acetate, polyamide, polyethyleneimine, and polyethylene oxide. As the reverse osmosis membrane, various types such as a hollow fiber type and a spiral type can be used.

The concentrated water supply path 4 has one end connected to the concentrated water side 3 a of the reverse osmosis membrane device 3 and the other end connected to the inlet side 2 a of the liquid-flow type electric double layer condenser 2. The concentrated water in which the ionic substance is concentrated in the device 3 can be supplied to the flow-through type electric double layer condenser 2. The concentrated water supply path 4 is provided with a concentrated water storage tank 4a for temporarily storing concentrated water.

Next, a first embodiment of the method for producing desalinated water according to the present invention will be described by taking as an example the case where the above desalinated water production apparatus 1 is used. Using the water supply pump P1, supply water such as city water is introduced into the flow-through type electric double layer capacitor 2 through the introduction path 15, and current supply to the collector electrode 7 is started. Of ionic substances.

FIG. 3 (a) shows an example in which the ionic substance contained in the feed water is sodium chloride and the high-surface-area conductor layer is an activated carbon layer 6.
This will be described with reference to FIG. As shown in FIG. 3A, at the time of voltage application, sodium ions in the supply water are electrically adsorbed on the activated carbon layer 6 in contact with the collector electrode 7 on the cathode side,
The chlorine ions are electrically adsorbed on the activated carbon layer 6 in contact with the collector electrode 7 on the anode side. Therefore, the treated water (intermediate treated water) obtained from the outlet has a reduced sodium chloride concentration (desalting step). In the desalting step, the particulate matter in the feed water is also adsorbed on the activated carbon layer 6. The intermediate treated water is supplied to the reverse osmosis membrane device 3 through the intermediate treated water path 16.
Will be introduced.

In the reverse osmosis membrane device 3, ionic substances in the intermediate treatment water are removed by the membrane separation using the reverse osmosis membrane, and the permeated water having a further reduced concentration of the ionic substances passes through the lead-out passage 17 as final treatment water. It is led out of the system. In the reverse osmosis membrane device 3, the water recovery rate, that is, the amount of permeated water with respect to the amount of supplied water is preferably set to 50 to 80%. At this time, the removed ionic substance is concentrated in the concentrated water.
The pH of the concentrated water is usually 7 to 9. Further, an alkaline substance (such as sodium hydroxide) can be added upstream of the reverse osmosis membrane device 3. In this case,
An alkaline substance is added to the intermediate treatment water so that the pH becomes 8 to 12. Thereby, the pH of the concentrated water is 9 to 13
Becomes

In the flow-through type electric double layer capacitor 2, if the water flow is continued for a long time, the adsorption of ions to the activated carbon layers 6, 6 approaches saturation, and the concentration of sodium chloride in the treated water (intermediate treated water) increases. . Therefore, before reaching the adsorption saturation, the activated carbon layers 6 and 6 are connected by short-circuiting or reverse-connecting the collector electrodes 7 and 7 on the anode side and the cathode side.
A regenerating step of weakening the adsorption power of the sodium ions and the chlorine ions adsorbed on the activated carbon layer 6 and desorbing and discharging these ions from the activated carbon layer 6 is performed.

In this regeneration step, the reverse osmosis membrane device 3
Is supplied to the flow-through type electric double layer condenser 2 as washing water using the concentrated water supply path 4. In supplying the concentrated water, the concentrated water previously stored in the concentrated water storage tank 4a can be used. As a result, FIG.
As shown in (b), the adsorbate adsorbed on the activated carbon layers 6, 6 is promoted to be desorbed from the activated carbon layer 6, and the adsorbate can be discharged together with the concentrated water through the discharge path 18 on the outlet side 2b. . In the regeneration step, in addition to the concentrated water,
Cleaning water separately prepared can also be used. After the regenerating step, the power supply to the collecting electrode 7 is restarted, and the desalting process is performed in the above-described process (desalting step).

In the method for producing desalinated water of the present embodiment, in the regeneration step, the concentrated water of the reverse osmosis membrane device 3 is supplied to the flow-through type electric double layer condenser 2, so that the efficiency of desorbing adsorbates can be improved. it can. Therefore, it is possible to prevent the efficiency of the desalination treatment from lowering after the regeneration step, and to maintain a high quality of the treated water.

It is considered that the reason why the quality of the desalination water after the regeneration step can be increased by using the concentrated water of the reverse osmosis membrane device 3 in the regeneration step is as follows. In the flow-through type electric double layer capacitor 2 in the desalination step, not only the ionic substance in the feed water is electrically adsorbed to the activated carbon layer 6 but also the particulate substance is
Adsorb to. In the regeneration step, the application of the voltage to the collector electrode 7 is stopped, so that the ionic substance is desorbed, but the particulate substance remains, thereby reducing the desalination efficiency in the desalination step. The use of the concentrated water can increase the quality of the desalted water after the regeneration step because the adsorption force between the particulate matter and the activated carbon layer 6 is weakened by ions present at a high concentration in the concentrated water. It is thought that it is. When an alkaline substance is added on the upstream side of the reverse osmosis membrane device, the pH becomes high, so that the particulate silica or the like adsorbed on the activated carbon layer 6 is dissolved, and the particulate silica is dissolved in the activated carbon layer 6. Detached from

Further, in the method for producing desalinated water of the present embodiment, since the concentrated water is used in the regeneration step, the amount of water required for the regeneration step can be minimized.

FIG. 4 is a diagram showing an apparatus for producing desalinated water which can carry out the second embodiment of the method for producing desalinated water of the present invention.
The demineralized water production apparatus 21 shown here is different from the demineralized water production apparatus 1 shown in FIG.
In that it is provided with One end of the permeated water path 22 is connected to the outlet path 17, and the other end is connected to the inlet side 2 a of the liquid-permeation type electric double layer capacitor 2. Water can be supplied to the liquid-type electric double layer capacitor 2. The permeated water path 22 is provided with a permeated water storage tank 22a for temporarily storing permeated water.

In the desalinated water producing apparatus 21, the following operation can be performed. In the regeneration step, the concentrated water of the reverse osmosis membrane device 3 is supplied to the liquid-flow type electric double layer condenser 2 through the concentrated water supply path 4 to wash the activated carbon layer 6. Next, the permeated water of the reverse osmosis membrane device 3 is supplied to the liquid-permeation type electric double layer condenser 2 through the permeation water path 22, and the liquid permeation type electric double layer condenser 2 is washed. In supplying the permeated water, the permeated water previously stored in the permeated water storage tank 22a can be used. Since this permeated water has a very low ionic substance concentration by the reverse osmosis membrane device 3,
In the regeneration step, the elution of the ionic substance adsorbed on the activated carbon layer 6 is promoted, and the desorption efficiency of the ionic substance can be increased. Further, since the concentration of the ionic substance, fine particle substance, and organic substance in the permeated water is low, they are prevented from being newly adsorbed to the activated carbon layer 6, and the cleanliness of the activated carbon layer 6 can be increased.

According to the desalinated water producing apparatus 21, the ionic substance and the particulate substance adsorbed on the activated carbon layer 6 are efficiently desorbed by the concentrated water by employing the above-mentioned operation method, and then the permeated water Thereby, desorption of the ionic substance remaining in the activated carbon layer 6 is promoted, and the activated carbon layer 6 can be cleaned. For this reason, the desorption efficiency of the adsorbate in the regeneration step can be improved, and the cleanliness of the activated carbon layer 6 can be increased. Therefore, it is possible to prevent the efficiency of the desalination treatment from lowering after the regeneration step, and to reliably maintain the quality of the treated water high. Further, in the regeneration step, the ionic substance can be discharged using the concentrated water and the permeated water, so that the amount of water required for the regeneration step can be reduced.

FIG. 5 is a diagram showing an apparatus for producing desalinated water in which the third embodiment of the method for producing desalinated water of the present invention can be carried out.
The demineralized water production device 31 shown here differs from the demineralized water production device 21 shown in FIG. 4 in that the concentrated water supply path 4 is not provided.

In the desalinated water producing apparatus 31, in performing the regeneration step, the permeated water (final treated water) of the reverse osmosis membrane apparatus 3 is supplied to the liquid-permeable electric double layer condenser 2 through the permeated water path 22, The desorption of the toxic substance from the activated carbon layer 6 is promoted, and the desorbed substance is discharged through the discharge path 18.

In the method for producing desalinated water of the present embodiment, the permeated water of the reverse osmosis membrane device 3 is supplied to the liquid-type electric double layer condenser 2, so that the ionic substance adsorbed on the activated carbon layer 6 is removed in the regeneration step. It can be discharged using permeated water having a low impurity concentration. Therefore, in the regeneration step, the elution of the ionic substance adsorbed on the activated carbon layer 6 is promoted, the desorption efficiency of the ionic substance is increased, and the ionic substance,
It is possible to prevent particulate matter and organic matter from adsorbing to the activated carbon layer 6, and to increase the cleanliness of the activated carbon layer 6. Therefore, it is possible to prevent the efficiency of the desalination treatment from lowering after the regeneration step, and to maintain a high quality of the treated water. Furthermore, since the ionic substance can be discharged using the permeated water in the regeneration step, the amount of water required for the regeneration step can be reduced.

FIG. 6 is a diagram showing an apparatus for producing desalinated water in which a fourth embodiment of the method for producing desalinated water of the present invention can be carried out.
The demineralized water producing apparatus 41 shown here includes a liquid-flow type electric double layer condenser 2, a water treatment device 42 provided on the downstream side of the liquid flow type electric double layer capacitor 2, and water treated by the water treatment device 42. The water treatment apparatus is provided with a treated water path 43 for supplying to the flow-through type electric double layer condenser 2. In the device shown here, the flow-through type electric double layer condenser 2 corresponds to a first water treatment device, and the water treatment device 42 corresponds to a second water treatment device.

Examples of the water treatment device 42 include an ion exchange device, an activated carbon adsorption device, and an ultrafiltration membrane device. The water treatment device 42 may be two or more of these. The treated water passage 43 is provided with a treated water storage tank 43a for temporarily storing treated water.

In the desalinated water producing apparatus 41, in the regeneration step, the treated water of the water treating apparatus 42 is supplied to the flow-through type electric double layer condenser 2 through the treated water path 43 of the water treating apparatus, and the treated water is used for ionizing. Substances can be desorbed and discharged. In supplying the treated water, treated water previously stored in the treated water storage tank 43a can be used. Since the concentration of the ionic substance, the particulate substance, and the organic substance is extremely low in the treated water, the desalinated water production device 41 promotes the elution of the ionic substance adsorbed on the activated carbon layer 6 in the regeneration step, An ionic substance, a particulate substance, and an organic substance can be prevented from being newly adsorbed to the activated carbon layer 6, and the cleanliness of the activated carbon layer 6 can be increased. Therefore, it is possible to prevent the efficiency of the desalination treatment from lowering after the regeneration step, and to maintain a high quality of the treated water. Furthermore, in the regeneration step, the ionic substance can be discharged using the above treated water, so that the amount of water required for the regeneration step can be suppressed.

In the present invention, the one shown in FIG. 7 can be used as the liquid-permeation type electric double layer capacitor. The flow-through type electric double layer capacitor shown here has an end plate 23.
1, 232, insulating layers 235, 236, single-sided terminal electrodes 233, 234, and double-sided intermediate electrodes 237 to 243. One-sided terminal electrodes 233, 234, double-sided intermediate electrode 23
Nos. 7 to 243 are formed by bonding a conductor (activated carbon or the like) sheet to one or both surfaces of a collector electrode made of a titanium sheet with a binder such as a conductive epoxy. When using this liquid-flow type electric double layer capacitor, these electrodes are alternately used as a cathode and an anode in the arrangement direction, and the supply water is
Through the holes 261 and 262, the liquid flows into the first processing chamber 250 (arrow A), and the ionic substance is adsorbed on the electrodes 233 and 237.
Through the holes 263, 265, 266, 265, and 266, and flows into each of the processing chambers continuously as shown by arrows C to G, and the treated water is drawn out through the holes 264, 265, and 266. (Arrow H).

[0033]

The effects of the present invention will be clarified below with reference to specific examples. (Example 1) Demineralized water was produced using the desalinated water producing apparatus 1 shown in FIG. The equipment specifications and processing conditions were as follows. (1) Flow type electric double layer capacitor Flow type electric double layer capacitor 2: Electrode area: 13000
cm ² × 250 sheets (the anode side and the cathode side are 12
Applied voltage: 1.3 V (current value: 5 to 12 A) Short-circuit frequency in the regeneration step (frequency of short-circuiting the anode-side collector electrode 7 and the cathode-side collector electrode 7): once / 90 minutes ( (2) Reverse osmosis membrane device Nitto Denko Corporation's ES-20 (membrane diameter: 4 inches) Operating pressure: 78.4 kPa (8.0 kg / cm ² ) Supply water: Permeate: brine water ratio = 160 L: 80
L: 80L (every hour)

In the present embodiment, demineralized water was produced using city water as the supply water. In the regeneration step, the concentrated water of the reverse osmosis membrane device 3 is supplied to the liquid-type electric double layer condenser 2 by using the concentrated water supply path 4, and the concentrated water is used to desorb and discharge ionic substances. went. At this time, the supply amount of the concentrated water was set to 5 times the internal capacity of the flow-through type electric double layer capacitor 2. The feed water has a conductivity of 14.8 mS / m
Was used.

The results of measuring the conductivity of the effluent from the liquid-flow type electric double layer condenser 2 and the inflow water (supply water) into the liquid-flow type electric double layer condenser 2 at one month after the start of water flow. Are shown in Table 1. Table 1 also shows the ionic substance removal rates calculated from the conductivity. The conductivity was measured at the time when 5 minutes had elapsed after the regeneration step.

(Embodiment 2) Desalinated water producing apparatus 2 shown in FIG.
Example 1 was used to produce demineralized water. The device specifications and the processing conditions were determined according to the first embodiment. In the present embodiment, in the regeneration step, after ionic substances were desorbed and discharged using concentrated water, the permeated water supplied from the permeated water path 22 was supplied to the liquid-type electric double layer capacitor 2. At this time, the supply amounts of the condensed water and the permeated water were each five times the internal capacity of the liquid-pass type electric double layer capacitor 2. The results are shown in Table 1.

(Embodiment 3) Desalted water producing apparatus 3 shown in FIG.
Example 1 was used to produce demineralized water. The device specifications and the processing conditions were determined according to the first embodiment. In the present embodiment, in the regeneration step, ionic substances are desorbed and discharged using permeated water supplied from the permeated water path 22. The results are shown in Table 1.

(Embodiment 4) Desalinated water producing apparatus 4 shown in FIG.
Example 1 was used to produce demineralized water. As the water treatment device 42, an activated carbon adsorption tower was used. As an activated carbon adsorption tower,
The following specifications were used. Activated carbon: manufactured by Nippon Norit Co., Ltd., particle size: 30-40 mesh Tower diameter: 200 mm Height: 350 mm Backwash frequency: once / 120 minutes Water flow rate: 165 L / hr Other equipment specifications and processing conditions are the same as in Example 1. I decided.

In the present embodiment, in the regeneration step, ionic substances are desorbed and discharged using the treated water of the water treatment unit 42. The results are shown in Table 1.

Example 5 Desalted water was produced in the same manner as in Example 4 except that an ion exchange tower was used as the water treatment device 42. The ion exchange tower having the following specifications was used. Ion exchange resin: "EX-MG" manufactured by Kurita Kogyo Tower diameter: 150 mm Height: 350 mm Water flow rate: 165 L / hr Other equipment specifications and processing conditions were determined according to Example 1.

In the method of this embodiment, in the regeneration step,
Desorption of ionic substances using the treated water of the water treatment device 42,
Discharge was performed. The results are shown in Table 1.

(Comparative Example) Example 1 except that ionic substances were desorbed and discharged using city water in the regeneration step.
Demineralized water was produced in the same manner as described above. The results are shown in Table 1.

[0043]

[Table 1]

As can be seen from Table 1, in the embodiment using the concentrated water, permeated water and treated water in the downstream apparatus, the efficiency of the desalination treatment was prevented from lowering as compared with the comparative example using city water in the regeneration step. It can be seen that the water quality could be maintained at a high level. In particular, it can be seen that in Example 2 in which ionic substances were desorbed and discharged using concentrated water, and washing was performed using permeated water, the effect of maintaining the quality of treated water was high.

[0045]

According to the method for producing desalinated water of the present invention, there is provided a desalination step of passing feed water through a liquid-type electric double layer condenser and a reverse osmosis membrane device to obtain permeated water and concentrated water from the reverse osmosis membrane device. A short-circuit or reverse connection between the anode and cathode electrodes of the flow-through type electric double-layer capacitor, and a regeneration step of supplying concentrated water of the reverse osmosis membrane device to the flow-through type electric double-layer capacitor. In the process, the desorption efficiency of the adsorbate can be improved. Therefore, it is possible to prevent the efficiency of the desalination treatment from lowering after the regeneration step, and to maintain the quality of the treated water high.

In the regeneration step, by supplying the permeated water of the reverse osmosis membrane device to the flow-through type electric double layer condenser, the efficiency of desorbing adsorbed substances can be increased and impurities can be prevented from being newly adsorbed. it can. Therefore, it is possible to prevent the efficiency of the desalination treatment from lowering after the regeneration step, and to maintain the quality of the treated water high. Also, the amount of water required for the regeneration step can be kept low.

Also, in the regeneration step, the treated water of the second water treatment device provided downstream of the liquid-flow type electric double layer condenser is supplied to the liquid-type electric double layer condenser to remove adsorbed substances. Separation efficiency can be increased and impurities can be prevented from being newly adsorbed. Therefore, it is possible to prevent the efficiency of the desalination treatment from lowering after the regeneration step, and to maintain the quality of the treated water high. Also, the amount of water required for the regeneration step can be kept low.

[Brief description of the drawings]

FIG. 1 is a diagram showing a schematic configuration of a desalinated water production apparatus capable of implementing a first embodiment of a desalinated water production method of the present invention.

FIGS. 2A and 2B are diagrams showing a schematic configuration of a flow-through type electric double layer capacitor, wherein FIG. 2A is an exploded perspective view and FIG. 2B is a side sectional view.

3 (a) and 3 (b) are diagrams for explaining the processing principle of the liquid-permeation type electric double layer capacitor shown in FIG. 2.

FIG. 4 is a diagram showing a schematic configuration of a desalinated water producing apparatus capable of implementing a second embodiment of the desalinated water producing method of the present invention.

FIG. 5 is a diagram showing a schematic configuration of a desalinated water production apparatus capable of implementing a third embodiment of the desalinated water production method of the present invention.

FIG. 6 is a diagram showing a schematic configuration of a desalinated water production apparatus capable of implementing a fourth embodiment of the desalinated water production method of the present invention.

FIG. 7 is a schematic configuration diagram showing another example of the flow-through type electric double layer capacitor.

[Explanation of symbols]

1, 21, 31, 41: desalinated water production device, 2: liquid-flow type electric double layer condenser (first water treatment device), 3: reverse osmosis membrane device, 4: concentrated water Supply path, 22: Reverse osmosis membrane apparatus permeated water path, 42: Water treatment apparatus (second water treatment apparatus), 43: Water treatment apparatus treated water path

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Keihiro Matsushita F-term (reference) 4-3-6 Nishi-Shinjuku, Shinjuku-ku, Tokyo 4F006 GA03 HA01 HA61 KB61 MC18 MC51 MC54 PA01 PB02 PC01 PC31 4D061 DA01 DB13 EA02 EB05 EB13 EB17 EB19 FA06 FA08 FA09

Claims (3)

[Claims] 1. A desalination step of supplying electricity to a flow-through type electric double layer condenser to feed water, and then passing the water through a reverse osmosis membrane device to obtain permeate and concentrated water from the reverse osmosis membrane device. A short-circuit or reverse connection between the anode and cathode electrodes of the flow-through type electric double-layer capacitor, and a regeneration step of supplying the concentrated water of the reverse osmosis membrane device to the flow-through type electric double-layer capacitor, To produce desalinated water. 2. A desalination step of supplying electricity to the flow-through type electric double layer condenser to feed water, and then passing the water through a reverse osmosis membrane device to obtain permeate and concentrated water from the reverse osmosis membrane device. A short-circuit or reverse connection between the anode and cathode electrodes of the liquid-permeation type electric double-layer capacitor, and a regeneration step of supplying permeated water of the reverse osmosis membrane device to the liquid-permeation type electric double-layer capacitor, To produce desalinated water. 3. A desalination step of supplying electricity to a first water treatment apparatus comprising a liquid-passing type electric double layer condenser to supply water, and then passing the water to a second water treatment apparatus to obtain treated water. And a regeneration step of short-circuiting or reverse-connecting the anode and cathode electrodes of the flow-through type electric double layer capacitor and supplying the treated water to the flow-through type electric double layer capacitor. Salt water production method.