JP3568290B2 - Electrolyzed water generator - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an electrolyzed water generating apparatus for generating electrolyzed water having a bactericidal action and a disinfecting action by containing hypochlorous acid, sodium hypochlorite and the like as main components.
[0002]
[Prior art]
Japanese Patent Publication No. 7-8768 discloses a type of electrolyzed water generator for producing electrolyzed water having a bactericidal action and a disinfecting action by containing hypochlorous acid and sodium hypochlorite as main components. As described above, electrodes are arranged in a pair of compartments formed by partitioning the inside of the electrolytic cell with a diaphragm to form an anode compartment and a cathode compartment, and the dilute salt supplied to these two electrode compartments. There is an electrolyzed water generator for electrolyzing water between both electrodes. In the electrolyzed water generating apparatus, the generated water in the anode chamber generated in the anode chamber is mainly acidic water containing hypochlorous acid, and the generated water in the cathode chamber generated in the cathode chamber is alkaline water.
[0003]
By the way, in the electrolyzed water generator, since the diluted saline solution supplied to both electrode chambers flows out together with the electrolyzed water in an unelectrolyzed state, a large amount of salt is wasted. In addition, in the electrolyzed water generating apparatus, since a dilute saline solution is used to minimize the wasted salt as much as possible, there is a problem that electric conductivity is low, electrolysis efficiency is poor, and power consumption is increased. is there. To cope with these problems, Japanese Unexamined Patent Publication No. 7-155760 discloses that a saline solution having a higher concentration than the above-mentioned diluted saline solution is employed, and this high-concentration saline solution can be circulated and used during electrolysis. Thus, there has been proposed an electrolyzed water generation apparatus that reduces waste of salt and increases electrolysis efficiency to reduce power consumption.
[0004]
The electrolyzed water generating apparatus includes an electrolytic cell having a pair of ion-permeable membranes, the inside of which is partitioned into an intermediate chamber and first and second side chambers located on both sides of the intermediate chamber, and a first side chamber. It has an anode provided and a cathode provided in the second side chamber, and is configured to electrolyze high-concentration saline solution supplied to the intermediate chamber between the anode and the cathode.
[0005]
[Problems to be solved by the invention]
By the way, in the electrolyzed water generating apparatus, the high-concentration saline solution supplied to the intermediate chamber is ionized at the time of electrolysis, and the anions in the intermediate chamber permeate the diaphragm and move to the first side chamber, where the anions move. While chlorine ions are mainly electrolyzed, cations in the intermediate chamber permeate through the diaphragm and move to the second side chamber to mainly electrolyze hydrogen ions. Therefore, sodium ions gradually accumulate in the intermediate chamber as the electrolysis proceeds, and the alkalinity of the generated water in the intermediate chamber increases.
[0006]
As a result, trace amounts of calcium ions, magnesium ions, and the like present in the generated water in the intermediate chamber gradually become insoluble substances such as hydroxides and carbonates and are gradually precipitated. These insoluble substances cause problems such as clogging the pores of the diaphragm as a scale, adhering to each electrode to reduce electrolysis efficiency, and adhering to the inner surface of each conduit to increase conduit resistance.
[0007]
Therefore, an object of the present invention is to prevent or suppress the generation of scale in an intermediate chamber in an electrolyzed water generating apparatus of a type including an intermediate chamber defined by the pair of diaphragms and both chambers. It is in.
[0008]
[Means for Solving the Problems]
The present invention relates to an electrolyzed water generating apparatus. The first invention of the present invention is directed to a first invention, in which a pair of ion-permeable diaphragms partition the interior into an intermediate chamber and first and second side chambers located on both sides of the intermediate chamber. Having an electrolytic cell, an anode disposed in the first side chamber, a cathode disposed in the second side chamber, and a second anode disposed in the intermediate chamber. It is characterized by comprising a main electrolysis step of electrolyzing the supplied saline solution between the anode and the cathode, and a sub electrolysis step of electrolyzing between the second anode and the cathode.
[0009]
Further, a second invention of the present invention provides an electrolytic cell in which a pair of diaphragms having ion permeability have an interior partitioned into an intermediate chamber and first and second side chambers located on both sides of the intermediate chamber, An anode disposed in the first side chamber; a cathode disposed in the second side chamber; a second cathode disposed in series with the anode in the first side chamber; A main electrolysis step of electrolyzing a salt solution supplied to the intermediate chamber between the anode and the cathode, the main electrolysis step comprising: a second anode disposed opposite to the second cathode; And a sub-electrolysis step of electrolyzing between the anode and the second cathode.
[0010]
[Action and Effect of the Invention]
In the electrolyzed water generating apparatus according to the first aspect of the present invention, the operation is started in a state in which high-concentration saline is supplied to the intermediate chamber and water or diluted saline is supplied to each side chamber. . The high-concentration saline solution supplied to the intermediate chamber is subjected to a main electrolysis process between the anode of the first chamber and the cathode of the second chamber, and a secondary electrolysis between the second anode of the intermediate chamber and the cathode of the second chamber. Electrolyzed by the process.
[0011]
Thus, in the main electrolysis step, anions in the high-concentration saline solution supplied to the intermediate chamber move to the first side chamber, and chlorine ions are mainly converted to chlorine and dissolved as hypochlorous acid on the anode surface. Oxygen is generated, and acidic water is generated in the first side chamber. Further, the cations in the high-concentration saline solution in the intermediate chamber move to the second side chamber, where hydrogen ions are mainly generated as hydrogen on the cathode surface, and alkaline water is generated in the second side chamber. On the other hand, in the sub-electrolysis step, the intermediate chamber becomes the anode chamber and the second side chamber becomes the cathode chamber. In the intermediate chamber, chlorine and oxygen are generated, and the chlorine is dissolved in the water and the generated water in the intermediate chamber is transferred to the acidic side. Let it.
[0012]
Therefore, in the electrolyzed water generation device, the water generated in the intermediate chamber can be shifted to the acidic side by adjusting the degree of electrolysis in the sub electrolysis step. As means for adjusting the degree of electrolysis in the sub-electrolysis step, means for adjusting the amount of electricity applied in the main electrolysis step and the sub-electrolysis step using a variable resistor, the flow rate of water or saline supplied to both chambers Means for controlling by conductivity, means for selecting the type of diaphragm and adjusting ion permeability can be adopted.
[0013]
Therefore, according to the electrolyzed water generation device, by adopting any operating conditions, the generated water in the intermediate chamber can be shifted from alkaline to acidic, and the generation of scale due to alkalinity is prevented, Or can be suppressed.
[0014]
Also, in the electrolyzed water generating apparatus according to the second aspect of the present invention, the operation is started in a state where the high concentration saline is supplied to the intermediate chamber and the water or the dilute saline is supplied to each side chamber. Is done. The high-concentration saline solution supplied to the intermediate chamber is subjected to a main electrolysis process between the anode of the first chamber and the cathode of the second chamber, and between the second anode of the intermediate chamber and the second cathode of the first chamber. And the secondary electrolysis step.
[0015]
Thus, in the main electrolysis step, anions in the high-concentration saline solution supplied to the intermediate chamber move to the first side chamber, and chlorine ions are mainly converted to chlorine and dissolved as hypochlorous acid on the anode surface. Oxygen is generated, and acidic water is generated in the first side chamber. Further, the cations in the high-concentration saline solution in the intermediate chamber move to the second side chamber, where hydrogen ions are mainly generated as hydrogen on the cathode surface, and alkaline water is generated in the second side chamber.
[0016]
On the other hand, in the sub-electrolysis step, the intermediate chamber becomes the anode chamber and the first side chamber becomes the cathode chamber, and the cations in the water generated in the intermediate chamber move to the first side chamber, and the hydrogen ions are mainly converted to hydrogen on the second cathode surface. The water generated in the first side chamber is transferred to the alkaline side. In addition, anions in the generated water in the first side chamber move to the intermediate chamber, and on the surface of the second anode, mainly chlorine ions are converted into chlorine and dissolved as hypochlorous acid, and oxygen is generated. Water is transferred to the acidic side.
[0017]
For this reason, in the electrolyzed water generation device, by adjusting the degree of electrolysis in the sub-electrolysis step, the generated water in the intermediate chamber can be shifted to the acidic side, and the pH of the generated water in the first side chamber can be adjusted. Can be adjusted to the alkaline side. As means for adjusting the degree of electrolysis in the sub-electrolysis step, the same means as in the electrolyzed water generating apparatus according to the first invention can be employed. By adopting the conditions, the generated water in the intermediate chamber can be shifted from alkaline to acidic, so that the generation of scale due to alkalinity can be prevented or suppressed, and the acidic water generated in the first side chamber can be prevented. The pH can be easily adjusted to any value in the range of 3-7.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be described with reference to the drawings. FIG. 1 shows an example of an electrolyzed water generating apparatus according to the present invention. The electrolyzed water generator includes an electrolytic cell 11, first and second diaphragms 12a and 12b, first and second anodes 13a and 13b, and a cathode 14. Each of the diaphragms 12a and 12b has an ion permeable ability, and is disposed at a predetermined interval in the electrolytic cell 11 so that the inside of the electrolytic cell 11 is located between the intermediate chamber 15a and both sides of the intermediate chamber 15a. The first and second side chambers 15b and 15c are sectioned.
[0019]
In the electrolytic cell 11, the supply pipe 11a and the outflow pipe 11b communicating with the intermediate chamber 15a, the supply pipe 11c and the outflow pipe 11d communicating with the first side chamber 15b, and the supply communicating with the second side chamber 15c. A first anode 13a is provided in the first side chamber 15b, a cathode 14 is provided in the second side chamber 15c, and a second anode is provided in the intermediate chamber 15a. 13b is provided. These anodes 13a, 13b and cathode 14 are located opposite to each other.
[0020]
For the DC power supply 16, the first anode 13a and the second anode 13b are connected to the positive electrode, and the cathode 14 is connected to the negative electrode, and the connection circuit between the second anode 13b and the DC power supply 16 has a variable resistor. A vessel 17 is interposed. Thus, a main electrolysis step is formed between the first anode 13a and the cathode 14, and a sub electrolysis step is formed between the second anode 13b and the cathode 14.
[0021]
In the electrolyzed water generator configured as described above, the operation is started in a state in which high-concentration saline is supplied to the intermediate chamber 15a, and water or diluted saline is supplied to each of the side chambers 15b and 15c. However, since an aqueous solution having high electric conductivity is advantageous in electrolysis, it is preferable to supply a dilute saline solution to each of the side chambers 15b and 15c. The high-concentration saline solution supplied to the intermediate chamber 15a is subjected to a main electrolysis step between the first anode 13a of the first side chamber 15b and the cathode 14 of the second side chamber 15c, and to the second anode 13b and the second anode 13b of the intermediate chamber 15a. Electrolysis is performed by the sub-electrolysis step between the cathodes 14 in the side chamber 15c.
[0022]
Thus, in the main electrolysis step, anions in the high-concentration saline solution supplied to the intermediate chamber 15a move to the first side chamber 15b, and on the surface of the first anode 13a, chlorine ions are mainly converted into chlorine and hypochlorite. Oxygen is generated while dissolving as chloric acid, and acidic water is generated in the first side chamber 15b. Also, the cations in the saline solution having a high concentration in the intermediate chamber 15a move to the second side chamber 15c, and hydrogen ions are mainly generated as hydrogen on the surface of the cathode 14, and alkaline water is generated in the second side chamber 15c. . On the other hand, in the sub-electrolysis step, the intermediate chamber 15a serves as an anode chamber and the second side chamber 15c serves as a cathode chamber. Chlorine and oxygen are generated in the intermediate chamber 15a, and chlorine is dissolved in water to produce water generated in the intermediate chamber 15a. Move to the acidic side.
[0023]
For this reason, in the electrolyzed water generating apparatus, the generated water in the intermediate chamber 15a can be shifted to the acidic side by adjusting the degree of electrolysis in the sub electrolysis step. As means for adjusting the degree of electrolysis in the sub electrolysis step, means for adjusting the amount of electricity applied in the main electrolysis step and the sub electrolysis step by changing the resistance value using the variable resistor 17 is employed. You. Therefore, according to the electrolyzed water generating apparatus, by adopting any operating conditions, the generated water in the intermediate chamber 15a can be shifted from the alkaline side to the acidic side, and the scale caused by the alkalinity in the intermediate chamber 15a can be obtained. Can be prevented or suppressed.
[0024]
FIG. 2 shows another example of the electrolyzed water generation device according to the present invention. The electrolyzed water generator includes an electrolytic cell 21, first and second diaphragms 22a and 22b, first and second anodes 23a and 23b, and first and second cathodes 24a and 24b. Each of the diaphragms 22a and 22b has ion permeability, and is disposed at a predetermined interval in the electrolytic cell 21 so that the inside of the electrolytic cell 21 is located between the intermediate chamber 25a and both sides of the intermediate chamber 25a. The first and second side chambers 25b and 25c are sectioned.
[0025]
In the electrolytic cell 21, the supply pipe 21a and the outflow pipe 21b communicating with the intermediate chamber 25a, the supply pipe 21c and the outflow pipe 21d communicating with the first side chamber 25b, and the supply communicating with the second side chamber 25c. The first side chamber 25b is provided with a first anode 23a and a second cathode 24b upright, and the second side chamber 15c is provided with a first cathode 24a. A second anode 23b is disposed in the intermediate chamber 25a. Among these electrodes, the first anode 23a and the first cathode 24a face each other in parallel with both diaphragms 22a and 22b interposed therebetween, and the second anode 23b and the second cathode 24b sandwich the first diaphragm 22a. And face each other in parallel.
[0026]
In the electrolyzed water generator, two first and second power supplies 26a and 26b are employed as DC power supplies, and a first anode 23a is connected to a positive electrode of the first power supply 26a. At the same time, the first cathode 24a is connected to the negative electrode, and for the second power supply 16b, the second anode 23b is connected to the positive electrode, and the second cathode 24b is connected to the negative electrode. Thereby, a main electrolysis step is formed between the first anode 23a and the first cathode 24a, and a sub electrolysis step is formed between the second anode 23b and the second cathode 24b.
[0027]
In the electrolyzed water generator configured as described above, the operation is started in a state where the high-concentration saline solution is supplied to the intermediate chamber 25a and the diluted saline solution is supplied to each of the side chambers 25b and 25c. The high-concentration saline solution supplied to the intermediate chamber 25a is supplied to the main electrolysis step between the first anode 23a of the first side chamber 25b and the first cathode 24a of the second side chamber 25c, and to the second anode 23b of the intermediate chamber 25a. Electrolysis is performed by the sub-electrolysis step between the second cathodes 23d of the first side chamber 25b.
[0028]
Thus, in the main electrolysis step, the anions in the high-concentration saline solution supplied to the intermediate chamber 25a move to the first side chamber 25b, and on the surface of the first anode 23a, mainly chlorine ions are converted into chlorine and hypochlorite. While dissolving as chloric acid, oxygen is generated, and acidic water is generated in the first side chamber 25b. Further, the cations in the saline solution having a high concentration in the intermediate chamber 25a move to the second side chamber 25c, and hydrogen ions are mainly generated as hydrogen on the surface of the first cathode 24a, and alkaline water is generated in the second side chamber 25c. Is done.
[0029]
On the other hand, in the sub-electrolysis step, the intermediate chamber 25a becomes an anode chamber and the first side chamber 25b becomes a cathode chamber, and electrolysis occurs between the second anode 23b of the intermediate chamber 25a and the second cathode 24b of the first side chamber 25b. Positive ions in the water generated in the intermediate chamber 25a move to the first side chamber 25b, and mainly hydrogen ions are generated as hydrogen on the surface of the second cathode 24b, and the water generated in the first side chamber 25b is shifted to the alkaline side. . Further, anions in the water generated in the first side chamber 25b move to the intermediate chamber 25a, and mainly chlorine ions are converted to chlorine and dissolved as hypochlorous acid on the surface of the second anode 23b, and oxygen is generated. The generated water in the chamber 25a is transferred to the acidic side.
[0030]
For this reason, in the electrolyzed water generating apparatus, the generated water in the intermediate chamber can be shifted to the acidic side by adjusting the degree of electrolysis in the sub-electrolysis step, and the generated water in the first side chamber 25b can be transferred. Can be adjusted to the alkaline side. As means for adjusting the degree of electrolysis in the sub-electrolysis step, the power sources 26a and 26b are selected with appropriate electric capacity and the amount of electricity applied to both electrolysis steps is adjusted.
[0031]
Thereby, according to the electrolyzed water generation device, by adopting arbitrary operation conditions, the generated water in the intermediate chamber 25a is shifted from the alkaline to the acidic side, and the generation of scale due to the alkali is prevented or suppressed. In addition, the pH of the acidic water generated in the first side chamber 25b can be easily adjusted to any value in the range of 3 to 7.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram illustrating an example of an electrolyzed water generation device according to the present invention.
FIG. 2 is a schematic configuration diagram showing another example of the electrolyzed water generation device according to the present invention.
[Explanation of symbols]
11, 21 ... electrolytic bath, 12a, 12b, 22a, 22b ... diaphragm, 13a, 23a ... first anode, 13b, 23b ... second anode, 14 ... cathode, 24a ... first cathode, 24b ... second cathode, 15a , 25a: intermediate chamber, 15b, 25b: first side chamber, 15c, 25c: second side chamber, 16, 26a, 26b: power supply, 17: variable resistor.

Claims (2)

An electrolytic cell partitioned into an intermediate chamber and first and second side chambers located on both sides of the intermediate chamber and a pair of ion-permeable membranes, and an anode disposed in the first side chamber; A main electrolysis step having a cathode disposed in the second side chamber and a second anode disposed in the intermediate chamber, and electrolyzing a salt solution supplied to the intermediate chamber between the anode and the cathode; And a sub-electrolysis step of electrolyzing between the second anode and the cathode. An electrolytic cell partitioned into an intermediate chamber and first and second side chambers located on both sides of the intermediate chamber and a pair of ion-permeable membranes, and an anode disposed in the first side chamber; A cathode disposed in the second side chamber, a second cathode disposed in series with the anode in the first side chamber, and facing the second cathode in the intermediate chamber. A main electrolysis step having a second anode disposed therein and electrolyzing a salt solution supplied to the intermediate chamber between the anode and the cathode; and electrolyzing between the second anode and the second cathode. An electrolyzed water generating apparatus characterized by comprising a sub-electrolysis step.

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