JP3479318B2 - Method and apparatus for producing electrolyzed water - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for producing electrolyzed water.

[0002]

2. Description of the Related Art Japanese Patent Publication No.
As disclosed in Japanese Patent Publication No. 42077-42077, saline is electrolyzed in an anode chamber and a cathode chamber formed by arranging electrodes to which a DC voltage is applied in a chamber partitioned by a diaphragm. There is a method and a device for generating electrolyzed water that generates acidic water in the chamber and alkaline water in the cathode chamber.

[0003]

Of the electrolyzed water produced by the production method and the production apparatus, acidic water produced in the anode chamber side has a sterilizing action, and is therefore used in various fields as a treatment liquid for sterilization. Although widely used, the alkaline water generated on the cathode chamber side is strongly alkaline,
It is used in a special field as a processing liquid for fresh food, but it is generally discarded without being actively used. Therefore, in producing the electrolyzed water, it is preferable that the produced water on the cathode chamber side can be sufficiently utilized, and the object of the present invention is to make such produced water on the cathode chamber side suitable for drinking. Especially.

[0004]

According to the present invention, a salt solution to be electrolyzed in an anode chamber and a cathode chamber, which are formed by arranging electrodes to which a DC voltage is applied in a compartment partitioned by a diaphragm, is provided. In the method of producing electrolyzed water that is electrolyzed to generate acidic water in the anode chamber and strong alkaline water in the cathode chamber ,
A certain strong alkaline water is treated with a cation exchange resin that exchanges metal ions in the produced water for hydrogen ions,
It is characterized by generating 8 to 10 weakly alkaline water . In the method for producing the electrolyzed water, it is preferable to treat the cation exchange resin with acidic water that is the produced water on the anode chamber side to regenerate it.

Further, the present invention is an electrolyzed water producing apparatus suitably used in the producing method, which comprises an anode chamber formed by arranging electrodes to which a DC voltage is applied in a compartment partitioned by a diaphragm. An electrolytic cell that has a cathode chamber and uses salt water as electrolyzed water, and a strong alkaline that is the generated water on the cathode chamber side .
The metal ions in the water was replaced with hydrogen ions pH8~10
Is provided with a cation exchange tank for producing weakly alkaline water , and the cation exchange tank is connected to the cathode chamber side of the electrolytic cell.

In the electrolyzed water producing apparatus, it is preferable that the cation exchange tank is connected to both the cathode chamber side and the anode chamber side of the electrolysis tank, and the cation exchange tank flows out from the cation exchange tank. It is preferable to include a detection means for detecting the pH of the treatment liquid.

[0007]

In the method for producing electrolyzed water according to the present invention, the water produced on the cathode chamber side can be weak alkaline water or neutral water having a pH of about 8 to 10 due to the action of the cation exchange resin. Therefore, according to the method for producing electrolyzed water, acidic water having a bactericidal action, strong alkaline water having a special use as a fresh food positive treatment liquid, weak alkaline water suitable as drinking water, drinking water and other wide applications It is possible to obtain various kinds of water, such as neutral water having water, and the electrolyzed water can be used for various purposes without waste. Further, according to the electrolyzed water producing apparatus of the present invention, these various produced waters can be efficiently produced.

In the production of the electrolyzed water of the present invention, the cation exchange resin can be regenerated with the produced water in the anode chamber,
By adopting such means, it is not necessary to separately prepare acidic water for regenerating the cation exchange resin, and the cation exchange resin can be regenerated efficiently.

[0009]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows an electrolyzed water producing apparatus according to an embodiment of the present invention. The generator includes a dilute saline storage tank 11 (first storage tank), an electrolytic bath 12, a cation exchange bath 13, and a hydrochloric acid aqueous solution storage tank 14 (second storage tank). The electrolytic cell 12 has a cell body 12a partitioned by a diaphragm 12b, and electrodes 12c and 12d are provided in the respective compartments. Both electrodes 12
A direct current voltage is applied to c and 12d, one compartment is formed in the anode chamber Ra and the other compartment is formed in the cathode Rb.
Acid water containing hypochlorous acid is generated in the cathode chamber R
At b , alkaline water containing sodium hydroxide is produced.

A cation exchange resin is accommodated in the cation exchange tank 13 to exchange hydrogen ions in the ion exchange resin with sodium ions in alkaline water to make the strongly alkaline produced water weakly alkaline. The cation exchange resin is of a cartridge type, and can be easily exchanged.

The first storage tank 11 is connected to the anode chamber Ra and the cathode Rb of the electrolytic cell 12 by the first and second supply pipelines 21a and 21b. The anode chamber Ra and the cathode Rb of the electrolytic cell 12 are connected to the first and second connecting conduits 22a, 2
It is connected to the cation exchange tank 13 by 2b. First and second solenoid valves 22c and 22d for switching are arranged in the respective connecting pipes 22a and 22b, and the first connecting pipe 22
An adsorption tank 22e is provided in a. Activated carbon is stored in the adsorption tank 22e.

The first solenoid valve 22c operates by switching the supply of the acidic water, which is the water produced on the Ra side of the anode chamber, to an acidic water tank (not shown) and the cation exchange tank 13. The second solenoid valve 22d operates to switch the supply of the strong alkaline water, which is the produced water on the cathode chamber Rb side, to a tank for strong alkaline water (not shown) and the cation exchange tank 13. The adsorption tank 22e acts to adsorb chlorine in the produced water on the Ra side of the anode chamber.

The cation exchange tank 13 is connected to the anode chamber Ra side of the electrolytic cell 12 and the second storage tank 14, and the cation exchange resin in the exchange tank 13 is acidic water that is produced water in the anode chamber Ra side. Alternatively, it is regenerated by the hydrochloric acid aqueous solution stored in the second storage tank 14. An outflow line 23a is connected to the cation exchange tank 13, and the outflow line 23a is connected to the outflow line 23a.
A pH sensor 23b and a third solenoid valve 23c are provided.
The pH sensor 23b detects the pH of the produced water flowing out from the cation exchange tank 13. The third solenoid valve 23c discharges the generated water flowing out of the cation exchange tank 13 from an outlet pipe line 23d and an outlet pipe line 2d to which a beverage tank (not shown) is connected.
Switch to 3e and operate.

The electrolyzed water producing device is provided with a control device 24. The control device 24 controls each solenoid valve 22c, 22d, 2
3c and the pH sensor 23b, each of the solenoid valves 22c, 22d, by the detection signal from the pH sensor 23b,
23c is operated by switching.

In the apparatus for producing electrolyzed water having such a structure, 0.05 to 0.15 wt% of dilute saline is stored in the first storage tank 11, and the saline is supplied to the electrolytic cell 12 by driving the pump 21c. The operation is started. Electrolyzer 1
40 to both electrodes 12, 13 due to the supply of saline solution to 2
DC voltage of 50V is applied. In this state, each solenoid valve 22c, 22d, 23c is controlled to the set switching state, the anode chamber Ra is connected to the acidic water tank,
The cathode chamber Rb is connected to the cation exchange tank 13, and the cation exchange tank 13 is connected to the drinking water tank.
Therefore, the dilute saline solution in the first storage tank 11 is supplied to the anode chamber Ra and the cathode chamber Rb of the electrolytic cell 12, and the following reactions take place in the chambers Ra and Rb.

[0016]

[Chemical 1]

Therefore, the water produced on the side of the anode chamber Ra flows out to the acidic water tank and is used as treated water for sterilization.
Further, the water produced on the cathode chamber Rb side flows into the cation exchange tank 13, and Na ⁺ and H are exchanged with the ion exchange resin in the cation exchange tank 13.
^After ion exchange with ^+, it flows out as weak alkaline water through the pH sensor 23b to the drinking water tank and is used as drinking water. During this time, the pH of the produced water flowing out from the ion exchange tank 13 is detected by the pH sensor 23b, and the treated water is
It is kept in weakly alkaline water suitable for drinks with a pH of about 8-10.

During the operation of the electrolyzed water generator, the ion exchange capacity of the cation exchange resin gradually decreases, and the pH of the treated water flowing out from the ion exchange tank 13 gradually increases. pH
The sensor 23b detects when the pH of the treated water becomes higher than an arbitrary set value in the range of 8 to 10, and outputs this detection signal to the control device 24. The control device 24 switches the solenoid valves 22c, 22d and 23c based on the detection signal to connect the anode chamber Ra of the electrolytic cell 12 to the cation exchange tank 13 through the adsorption tank 22e and the cation of the cathode chamber Rb. The connection with the exchange tank 13 is cut off, and the treated water from the cation exchange tank 13 is discharged.

As a result, the water produced in the anode chamber Ra flows into the cation exchange tank 13, H + in the produced water is exchanged with Na + in the cation exchange resin, and the cation exchange resin is regenerated. It This regeneration degree is detected by the pH sensor 23b, and when the pH of the produced water of the anode chamber Ra side that has passed through the cation exchange tank 13 during regeneration reaches a range of 4 or less, this is detected, and this detection signal is detected. Is output to the control device 24. The control device 24 controls each solenoid valve 2 based on this detection signal.
2c, 22d, and 23c are switched to operate, and electrolytic cell 12
The anode chamber Ra is disconnected from the cation exchange tank 13, the cathode chamber Rb is connected to the cation exchange tank 13, and the cation exchange tank 13 is connected to the drinking water tank.

In the generator, since the ion exchange resin in the cation exchange tank 13 is of a cartridge type, the exchange operation is easy. In the regeneration of the ion exchange resin, the hydrochloric acid aqueous solution in the second storage tank 14 can be used when the produced water in the anode chamber Ra side is abnormal.

As described above, according to the method for producing electrolyzed water according to this embodiment, the produced water on the cathode chamber Rb side can be weak alkaline water having a pH of about 8 to 10 due to the action of the cation exchange resin. Therefore, according to the method for producing electrolyzed water, it is possible to obtain various types of water such as acidic water having a bactericidal action, strong alkaline water having a special use as a treatment liquid for fresh food, and weak alkaline water suitable as drinking water. Therefore, the electrolyzed water can be used for various purposes without waste. Further, according to the electrolyzed water producing apparatus of the present embodiment, these various kinds of water can be produced efficiently, but in particular, the cation exchange resin can be regenerated with the produced water on the anode chamber Ra side. By adopting the means, there is an effect that the cation exchange resin can be efficiently regenerated without the need to separately prepare acidic water.

[Brief description of drawings]

FIG. 1 is a schematic view showing an apparatus for producing electrolyzed water most suitable for carrying out the production method according to the present invention.

[Explanation of symbols]

11 ... 1st storage tank, 12 ... Electrolyte tank, 12a ... Tank main body 12, 12b ... Diaphragm, 12c, 12d ... Electrode, 13 ... Cation exchange tank, 14 ... 2nd storage tank, Ra ... Anode chamber, Rb ... Cathode Room.

Claims (5)

(57) [Claims] 1. A salt solution, which is electrolyzed water, is electrolyzed in an anode chamber and a cathode chamber, which are formed by arranging electrodes to which a DC voltage is applied in a compartment partitioned by a diaphragm, In the method for producing electrolyzed water, which produces acidic water and strongly alkaline water in the cathode chamber,
The strongly alkaline water that is the water produced on the cathode chamber side is treated with a cation exchange resin that exchanges metal ions in the produced water for hydrogen ions, and weak alkaline water having a pH of 8 to 10 is treated.
A method for producing electrolyzed water, which is characterized by producing. 2. The production method according to claim 1, wherein the cation exchange resin is an acid produced from the water produced in the anode chamber.
A method for producing electrolyzed water, characterized by treating with water and regenerating. 3. An electrolytic cell having an anode chamber and a cathode chamber formed by arranging electrodes to which a DC voltage is applied in a chamber partitioned by a diaphragm and using salt water as electrolyzed water, and the cathode chamber. raw weak alkaline water pH8~10 replace the metal ions of the strongly alkaline water is a side product water into hydrogen ions
An apparatus for producing electrolyzed water, comprising a cation exchange tank for forming the cation exchange tank, the cation exchange tank being connected to a cathode chamber side of the electrolysis tank. 4. The generator for electrolyzed water according to claim 3, wherein the cation exchange tank is connected to a cathode chamber side and an anode chamber side of the electrolytic cell. 5. The electrolyzed water production apparatus according to claim 3 or 4, further comprising detection means for detecting the pH of the treatment liquid flowing out from the cation exchange tank.