JP5210456B1 - Wash water generator - Google Patents

Abstract

To provide a washing water generating device capable of generating alkaline electrolyzed water and electrolytic hyponitrous acid individually or simultaneously by one device, and capable of reducing the size, saving the space and reducing the cost.
A cleaning water generating apparatus includes a casing, a cation exchange membrane, an anode provided on one surface of the cation exchange membrane, and a first cathode provided on the other surface. 23, a second cathode 24 provided at a predetermined distance from the surface of the anode 22 opposite to the cation exchange membrane 21, a raw water tank 41, a saline tank 42, and a controller 50. With. In the case where the alkaline electrolyzed water and the electrolytic hyponitrous water are simultaneously generated, the controller 50 supplies saline to the anode 22 and the first cathode 23, supplies raw water or saline to the first cathode 23, and supplies the anode 22, control is performed so that a DC voltage is applied to the first cathode 23 and the second cathode 24.
[Selection] Figure 1

Description

  The present invention relates to a washing water generating apparatus capable of generating alkaline electrolyzed water and electrolytic hyponitrous water.

In recent years, in the fields of food, agriculture, medical care, nursing care, etc., electrolyzed water generated by electrolysis of water is expected to have an excellent effect on sterilization, washing, and the like.
As such electrolyzed water, the following types of electrolyzed water are generally known, and these electrolyzed waters are the pH of each electrolyzed water and an electrolyzer for generating electrolyzed water (two-chamber type (with a diaphragm)). , One-chamber type (non-diaphragm membrane)), the generated electrode to be generated and the type of the electrolyte solution.
(1) Strongly acidic electrolyzed water: pH 2.2 to 2.7, a two-chamber type, the production electrode is an anode, and the saline solution is less than 0.2% (2) Alkaline electrolyzed water: pH 11 to 11.5, The two-chamber type cathode is a cathode, the electrolyte solution is less than 0.2% saline (3) weakly acidic electrolyzed water: pH 2.7-5, two-chamber type, the electrolyte solution is less than 0.1% salt Water (4) Slightly acidic electrolyzed water: pH 5 to 6.5, one-chamber type, dilute hydrochloric acid or hydrochloric acid / saline solution with an electrolyzed solution of 2 to 6% Type, saline solution with less than 0.1% electrolyte (6) Alkaline ionized water: pH 8 to 10, two-chamber type, cathode is formed, electrolyte solution is tap water

Moreover, as a device capable of generating strong acidic electrolyzed water and alkaline electrolyzed water, for example, a technique described in Patent Document 1 is known.
By the way, for example, in food washing and dental treatment, electrolytic hyponitrous acid excellent in organic substance removal and alkaline electrolyzed water excellent in oil removal may be used in combination. However, since electrolytic hyponitrous water is generated from a one-chamber type electrolytic cell and alkaline electrolytic water is generated from a two-chamber electrolytic cell, it generates electrolytic hyponitrous acid and alkaline electrolytic water. For this purpose, a separate generation device is required. Therefore, there is a problem that the installation location of the apparatus is secured and the cost is increased. Moreover, since it is necessary to operate two apparatuses of an electrolysis sub-sulfur generation apparatus and an alkaline electrolysis water generation apparatus, there exists a problem that operation becomes complicated.

Japanese Patent No. 3508409

  The present invention has been made in view of the above circumstances, and can generate alkaline electrolyzed water and electrolytic hyponitrous acid individually or simultaneously in one apparatus, and can be reduced in size, space-saving and cost-effective. An object of the present invention is to provide an apparatus for generating washing water that can be achieved.

According to the invention of claim 1,
A casing,
A cation exchange membrane provided in the casing;
An anode in pressure contact with one surface of the cation exchange membrane in the casing;
A first cathode in pressure contact with the other surface of the cation exchange membrane in the casing;
A second cathode provided in the casing so as to face the surface of the anode opposite to the cation exchange membrane at a predetermined distance;
Raw water tank containing raw water which is pure water or purified water ;
A saline tank containing saline,
When the alkaline electrolyzed water produced, the saline saline is supplied from the tank to the anode water supplies raw water to the said raw water for tanks or we first cathode, between the anode and the first cathode DC voltage is applied to
At the time of electrolytic hyponitrous generation, while supplying saline from the saline tank to the anode and the second cathode, a DC voltage is applied between the anode and the second cathode,
When simultaneously generating the alkaline electrolyzed water and electrolytic following Asui, saline is supplied from the brine tank to the anode and the second cathode, the raw water to the said raw water for tanks or we first cathode And a control unit that controls to apply a DC voltage to the anode, the first cathode, and the second cathode, and
The anode and the first cathode are conductive diamond electrodes;
Washing water, characterized in that a space between the anode and the second cathode is provided with a pressing member that is insulating and water-permeable and presses the anode toward the cation exchange side. A generating device is provided.

  According to the present invention, alkaline electrolyzed water and electrolytic hyponitrous water can be generated individually or simultaneously in one apparatus. Moreover, a cleaning effect can be heightened by using the produced | generated alkaline electrolyzed water and electrolytic hyponitrous acid. Furthermore, size reduction, space saving, and cost reduction can be achieved.

It is the washing water production | generation apparatus of 1st Embodiment, Comprising: It is the schematic which showed the case where alkaline electrolyzed water is produced | generated. It is the washing | cleaning water production | generation apparatus of 1st Embodiment, Comprising: It is the schematic which showed the case where an electrolytic hyponitrous acid is produced | generated. It is the washing water generating apparatus of a 1st embodiment, and is a schematic diagram showing the case where alkaline electrolyzed water and electrolytic hyponitrous water are generated simultaneously. It is an external appearance perspective view of a pressing member. It is the washing water production | generation apparatus of 2nd Embodiment, Comprising: It is the schematic which showed the case where alkaline electrolyzed water is produced | generated. It is the washing | cleaning water production | generation apparatus of 2nd Embodiment, Comprising: It is the schematic which showed the case where an electrolytic hyponitrous acid is produced | generated. It is the washing | cleaning water production | generation apparatus of 2nd Embodiment, Comprising: It is the schematic which showed the case where alkaline electrolyzed water and electrolytic hyponitrous water were produced | generated simultaneously. It is the washing water production | generation apparatus of 3rd Embodiment, Comprising: It is the schematic which showed the case where alkaline electrolyzed water is produced | generated. It is the washing | cleaning water production | generation apparatus of 3rd Embodiment, Comprising: It is the schematic which showed the case where an electrolytic hyponitrous acid is produced | generated. It is the washing | cleaning water production | generation apparatus of 3rd Embodiment, Comprising: It is the schematic which showed the case where alkaline electrolyzed water and electrolytic hyponitrous water were produced | generated simultaneously.

1 to 3 are schematic views of the cleaning water generating apparatus according to the first embodiment. FIG. 1 shows a case where alkaline electrolyzed water is generated, FIG. 2 shows a case where electrolytic hyponitrous water is generated, and FIG. The case where alkaline electrolyzed water and electrolyzed hyponitrous water are generated simultaneously is shown.
As shown in FIG. 1, the cleaning water generating apparatus 100 of the present invention is an apparatus that can generate and discharge alkaline electrolyzed water and electrolytic hyponitrous acid individually or simultaneously.
Specifically, the washing water generating apparatus 100 includes a casing 10, a cation exchange membrane 21 provided in the casing 10, an anode 22 pressed against one surface of the cation exchange membrane 21 in the casing 10, The first cathode 23 pressed against the other surface of the cation exchange membrane 21 in the casing 10 is opposed to the surface of the anode 22 opposite to the cation exchange membrane 21 in the casing 10 with a predetermined distance. The second cathode 24 provided in this manner, the pressing member 30 provided in the space between the anode 22 and the second cathode 24, the raw water tank 41 containing raw water, and the saline solution are stored. A saline tank 42, a controller 50, a power supply device 60, and the like are provided.
The control unit 50 supplies saline to the anode 22 from the saline tank 42 when generating alkaline electrolyzed water, and supplies raw water or saline from the raw water tank 41 or the saline tank 42 to the first cathode 23. While supplying, a DC voltage is applied between the anode 22 and the first cathode 23. Further, at the time of the generation of hypochlorous acid, saline is supplied from the saline tank 42 to the anode 22 and the second cathode 24, and a DC voltage is applied between the anode 22 and the second cathode 24. Further, when alkaline electrolyzed water and electrolyzed hyponitrous water are simultaneously generated, salt water is supplied from the salt water tank 42 to the anode 22 and the second cathode 24, and the raw water tank 41 or the salt water tank 42 supplies the first water. The raw water or the saline solution is supplied to the cathode 23 and the DC voltage is controlled to be applied to the anode 22, the first cathode 23 and the second cathode 24.
In the embodiment shown in FIG. 1, a case where raw water is supplied to the first cathode 23 will be described as an example.

Hereinafter, each component will be described in detail.
<Casing>
The casing 10 has a rectangular parallelepiped shape.
A first supply channel 11 and a second supply channel 12 are formed on the lower surface of the casing 10.
The first supply channel 11 is a channel for supplying raw water to the first cathode 23 in the casing 10 when generating alkaline electrolyzed water.
The second supply passage 12 supplies the anode 22 and the second cathode 24 when supplying saline to the anode 22 in the casing 10 when generating alkaline electrolyzed water or when generating electrolytic hyponitrous water. It is a flow path for supplying salt solution to water. Further, it is a flow path for supplying saline to the anode 22 and the second cathode 24 in the casing 10 when the alkaline electrolyzed water and the electrolytic hyponitrous water are simultaneously generated.
A first discharge channel 13 and a second discharge channel 14 are formed on the upper surface of the casing 10.
The first discharge channel 13 is a channel for discharging the alkaline electrolyzed water generated on the first cathode 23 side in the casing 10 when generating the alkaline electrolyzed water.
The second discharge flow path 14 discharges the strongly acidic electrolyzed water generated on the anode 22 side in the casing 10 when generating alkaline electrolyzed water, or generates the anode 22 when generating electrolytic hyponitrous acid. And a flow path for discharging the electrolyzed hyposulfite produced by the second cathode 24. Moreover, when producing | generating alkaline electrolyzed water and electrolysis hyponitrous acid simultaneously, it becomes a flow path for discharging | emitting strong acidic electrolyzed water and electrolysis hyposulfite.

In such a casing 10, the lower end portion of the cation exchange membrane 21 is located between the first supply channel 11 and the second supply channel 12, and the first discharge channel 13 and the second discharge channel 13. The cation exchange membrane 21 is held so that the upper end portion of the cation exchange membrane 21 is located between the flow paths 14.
An anode 22 is provided on one side (left side in FIG. 1) of the cation exchange membrane 21, and a first cathode 23 is provided on the other side (right side in FIG. 1).
Further, a grating 25 is provided on the surface of the anode 22 opposite to the cation exchange membrane 21 (left side surface in FIG. 1), and the surface of the first cathode 23 opposite to the cation exchange membrane 22 (in FIG. 1). A grating material 26 is provided on the right side surface. The grating material 26 is in contact with the right inner wall surface in the casing 10.
Further, a second cathode 24 is provided on the left inner wall surface in the casing 10 so as to face the anode 22 with a predetermined distance. The second cathode 24 is in contact with the left inner wall surface in the casing 10.
A pressing member 30 is provided between the second cathode 24 and the grating material 25 for appropriately pressing the anode 22, the cation exchange membrane 21, and the first cathode 23 through the grating material 25. ing.

Thus, the cation exchange membrane 21, the anode 22, the first cathode 23, and the second cathode 24 are provided in the casing 10, and when the alkaline electrolyzed water is generated, the anode 22 and the first cathode 24 are provided. Therefore, the inside of the casing 10 is divided by the cation exchange membrane 21 to form a two-chamber type.
On the other hand, when producing electrolytic hyponitrous acid, since the anode 22 and the second cathode 24 are used, it becomes a non-diaphragm and becomes a one-chamber type.

In such a casing 10, the raw water supplied from the first supply flow path 11 comes into contact with the first cathode 23 and the grating material 26, and the generated alkaline electrolyzed water is discharged first. It is discharged from the flow path 13.
The saline solution supplied from the second supply channel 12 is in contact with the anode 22, the grating material 25, and the second cathode 24, and the generated strong acidic electrolyzed water and electrolytic hyponitrous acid are the first. 2 are discharged from the two discharge passages 14.

  A valve V <b> 1 is provided on the downstream side of the first discharge channel 13. The valve V1 is opened when the alkaline electrolyzed water is generated, discharges the alkaline electrolyzed water generated on the first cathode 23 side, and closes when the electrolyzed hyponitrous water is generated, and the generated electrolytic secondary water is discharged. Do not discharge sub-water to the outside.

<Cation exchange membrane>
As the cation exchange membrane 21, a conventionally known one can be used, and a fluorine-based cation exchange membrane can be used. For example, a thickness in the range of 100 to 300 μm is preferable.

<Anode>
The anode 22 is not closely attached so as to completely cover the cation exchange membrane 21, but is provided with a large number of through holes and overlapped with the cation exchange membrane 21 with a contact portion and a non-contact portion. The shape of the shape is preferable. Specifically, the anode 22 can be a grating or punching metal. The grating shape is a lattice shape in which wires are welded, and the punching metal shape is a perforated plate shape in which a large number of through holes are formed in a flat plate.

In this embodiment, since the raw water is supplied to the first cathode 23 side, the anode 22 uses a conductive diamond electrode in which a boron-doped diamond film is formed on a silicon wafer.
As a film formation method for boron-doped diamond, for example, a film can be formed on a silicon wafer on which a large number of through holes 221 are formed by using a plasma CVD method or a thermal ferrite method.

<First cathode>
As the first cathode 23, it is preferable to use platinum, gold, or a coating metal thereof from the viewpoint of good stability. In particular, when a metal in which platinum is coated on titanium is used, the manufacturing cost can be reduced. Further, similarly to the anode 22, a conductive diamond electrode in which a diamond doped with boron is formed on a silicon wafer may be used. 1 to 3 show a case where a conductive diamond electrode is used.

<Second cathode>
As the second cathode 24, a metal having an electrolytic hypochlorite generation catalyst function is used. Specifically, it is preferable to use platinum, gold, or a coated metal thereof from the viewpoint of good stability. In particular, when a metal obtained by coating platinum on titanium is used, the manufacturing cost can be reduced. Alternatively, a conductive diamond electrode in which a boron-doped diamond film is formed on a silicon wafer may be used. 1 to 3 show a case where a conductive diamond electrode is used.

<Grating material>
The grating materials 25 and 26 are provided on the surface of the anode 22 opposite to the cation exchange membrane 21 or the surface of the first cathode 23 opposite to the cation exchange membrane 21 to cause turbulence. For example, it is preferable to use titanium or the like.

<Pressing member>
The pressing member 30 is provided in a space between the second cathode 24 and the grating material 25, and appropriately presses the cation exchange membrane 21, the anode 22, and the first cathode 23, and the grating material 25 (anode). 22) and the second cathode 24 for securing a space for insulation. It is also for preventing warping of the grating material 25.
The pressing member 30 is made of a material that is insulative, has water permeability, and has resistance to electrolytic hypoxia. Specifically, those made of vinyl chloride or Teflon (registered trademark) are preferable.
Further, as described above, the pressing member 30 appropriately presses the cation exchange membrane 21, the anode 22, and the first cathode 23, and a space between the grating material 25 (anode 22) and the second cathode 24. For example, as shown in FIG. 4, it is preferable to have a structure in which a cross-shaped support portion 32 is provided inside a rectangular frame 31. Note that the structure is not limited to this, and it is only necessary to have at least the rectangular frame 31 in contact with the second cathode 24 and the grating material 25.

<Raw water tank>
The raw water tank 41 is connected to the first supply channel 11 via a valve V2.
The raw water tank 41, raw water is pure water or purified water is accommodated.
The valve V2 supplies raw water from the raw water tank 41 into the casing 10 by an opening / closing operation, and adjusts the supply amount. Examples of the valve V2 include an electromagnetic valve and an electric ball valve.
The valve V2 is electrically connected to the control unit 50, and the control unit 50 controls the opening / closing operation and the supply amount of raw water into the casing. Specifically, a flow meter and a pressure gauge (not shown) are provided in the valve V2, and the control unit 50 controls the opening and closing operation of the valve V2 and the raw water supply amount based on the flow meter and the pressure gauge.

<Saline tank>
The saline solution tank 42 is connected to the second supply flow path 12 via the valve V3.
The saline tank 42 contains saline. It is preferable that the salt solution has a concentration of less than 0.1%.
The valve V3 supplies or adjusts the supply amount of saline from the saline tank 42 into the casing 10 by an opening / closing operation. Examples of the valve V3 include an electromagnetic valve and an electric ball valve.
The valve V <b> 3 is electrically connected to the control unit 50, and the control unit 50 controls the opening / closing operation and the amount of saline solution supplied into the casing 10. Specifically, a flow meter and a pressure gauge (not shown) are provided in the valve V3, and the control unit 50 controls the opening / closing operation of the valve V3 and the amount of saline supplied based on the flow meter and the pressure gauge. .

<Power supply unit>
An output terminal of a power supply device 50 is electrically connected to the anode 22, the first cathode 23, and the second cathode 24, and a DC voltage is applied thereto. That is, the anode 22, the first cathode 23, and the second cathode 24 are connected to the power supply device 60 through the conductive wires to the electrodes 22, 23, and 24, respectively.
The DC voltage to be applied is preferably applied in the range of 1.5 to 4.0 volts, for example, between the anode 22 and the first cathode 23 when alkaline electrolyzed water is generated. Is preferably applied between the anode 22 and the second cathode 24 in the range of 1.5 to 4.0 volts, for example, when alkaline electrolyzed water and electrolytic hyponitrous water are generated simultaneously. Is preferably applied between the anode 22, the first cathode 23, and the second cathode 24, for example, in the range of 1.5 to 4.0 volts.

<Control unit>
When the alkaline electrolyzed water is generated, the control unit 50 opens the valve V3 so as to supply the saline from the saline tank 42 to the anode 22, and supplies the raw water to the first cathode 23, as shown in FIG. To open the valve V2. Further, the power supply device 60 is controlled to apply a predetermined voltage between the anode 22 and the first cathode 23. At this time, the valve V1 is opened.
On the other hand, in the case of generating electrolytic hyposulfite, as shown in FIG. 2, the valve V3 is opened so as to supply saline from the saline tank 42 to the anode 22 and the second cathode 24, and further, the power source The device 60 is controlled to apply a predetermined voltage between the anode 22 and the second cathode 24. At this time, the valve V1 and the valve V2 are closed.
Furthermore, when alkaline electrolyzed water and electrolytic hyponitrous water are generated simultaneously, as shown in FIG. 3, the valve V2 is opened so as to supply raw water from the raw water tank 41 to the first cathode 23,
Further, the valve V3 is opened so that the saline solution is supplied from the saline solution tank 42 to the anode 22 and the second cathode 24. In addition, the power supply device 60 is controlled to apply a predetermined voltage to the anode 22, the first cathode 23, and the second cathode 24. At this time, the valve V1 is opened.
As described above, the control unit 50 generates the valves V1 to V1 in the case of generating alkaline electrolyzed water, the case of generating electrolyzed hyposulfite, and the case of simultaneously generating alkaline electrolyzed water and electrolyzed hyposulfite. While controlling the opening and closing of V3, it controls to switch the application of the voltage to each electrode 22,23,24 suitably.

Next, a method of generating alkaline electrolyzed water and electrolytic hyponitrous water using the cleaning water generating apparatus 100 having the above-described configuration will be described.
<When producing alkaline electrolyzed water>
As shown in FIG. 1, first, the valve V2 is opened to supply raw water into the casing 10 from the raw water tank 41 via the first supply flow path 11, and the valve V3 is opened to open the saline tank 42. To supply the salt solution into the casing 10 through the second supply channel 12. At this time, the valve V1 is opened.
The supplied raw water comes into contact with the first cathode 23 in the casing 10, and the saline comes into contact with the anode 22 in the casing 10. Further, the power supply device 60 is driven to apply a predetermined voltage between the anode 22 and the first cathode 23. By this energization, the saline solution is electrolyzed, and alkaline electrolyzed water is generated on the first cathode 23 side, discharged through the first discharge channel 13, and strongly acidic electrolyzed water is generated on the anode 22 side. Then, it flows through the second discharge channel 14 and is discharged. Note that the saline supplied from the second supply channel 12 contacts the second cathode 24, but no voltage is applied to the second cathode 24. Not decomposed.

<When producing electrolytic hyponitrous acid>
As shown in FIG. 2, first, the valve V <b> 3 is opened, and saline is supplied into the casing 10 from the saline tank 42 through the second supply channel 12. At this time, the valve V1 and the valve V2 are closed.
The supplied saline solution passes through the grating material 25 and contacts the anode 22 and the second cathode 24 in the casing 10. Further, the power supply device 60 is driven to apply a predetermined voltage between the anode 22 and the second cathode 24. By this energization, the saline solution is electrolyzed, becomes electrolytic hyponitrous acid, and flows through the second discharge channel 14 and is discharged. The saline supplied from the second supply channel 12 also contacts the first cathode 23 via the cation exchange membrane 21, but no voltage is applied to the first cathode 23. The first cathode 23 is not electrolyzed.

<When alkaline electrolyzed water and electrolyzed hyponitrogen are generated simultaneously>
As shown in FIG. 3, first, the valve V2 is opened to supply raw water into the casing 10 from the raw water tank 41 through the first supply flow path 11, and the valve V3 is opened to start the saline tank 42. To supply the salt solution into the casing 10 through the second supply channel 12. At this time, the valve V1 is opened.
The supplied raw water contacts the first cathode 23 in the casing 10, and the supplied saline contacts the anode 22 and the second cathode 24 in the casing 10. Further, the power supply device 60 is driven to apply a predetermined voltage to the anode 22, the first cathode 23, and the second cathode 24. By this energization, the saline solution is electrolyzed, and alkaline electrolyzed water is generated on the first cathode 23 side, discharged through the first discharge channel 13, and strongly acidic electrolyzed water and electrolyzed on the anode 22 side. Hyponitrous acid is generated and flows through the second discharge channel 14 and is discharged.

As described above, according to the first embodiment of the present invention, the casing 10, the cation exchange membrane 21, the anode 22, the first cathode 23 and the second cathode 24 provided in the casing 10, and the raw water tank. 41, a salt water tank 42, and a control unit 50. When alkaline electrolyzed water is generated, the control unit 50 supplies saline to the anode 22 and supplies raw water to the first cathode 23. In addition, a DC voltage is applied between the anode 22 and the first cathode 23. In addition, when generating electrolytic hyponitrous acid, the control unit 50 supplies saline to the anode 22 and the second cathode 24 and applies a DC voltage to the anode 22 and the second cathode 24. Further, when alkaline electrolyzed water and electrolytic hyponitrous water are generated simultaneously, raw water is supplied to the first cathode 23, saline is supplied to the anode 22 and the second cathode 24, and the anode 22, A DC voltage is applied to the first cathode 23 and the second cathode 24.
In this way, the water supplied to the casing 10 is appropriately switched between the case where the alkaline electrolyzed water and the electrolyzed hyposulfite are individually generated and the case where the alkaline electrolyzed water and the electrolyzed hyposulfite are simultaneously generated, and the voltage The desired washing water can be easily generated by appropriately switching the electrodes 22 to 24 to which the liquid is applied.
Therefore, oil can be removed by alkaline electrolyzed water, and organic substances can be removed by electrolytic hyponitrogen, so that the cleaning effect can be obtained by using the generated alkaline electrolyzed water and electrolyzed hyponitrogen alternately or simultaneously. Can be increased. In particular, when alkaline electrolyzed water and electrolytic hyponitrous water are used as washing water at the same time, a washing effect can be obtained at a time and efficiency is good.
Moreover, since the electrodes 22 to 24 and the cation exchange membrane 21 are provided in one casing 10, the apparatus can be downsized. Furthermore, since it is not necessary to use separate generators for alkaline electrolyzed water and electrolyzed hyponitrous water, space saving and cost reduction can be achieved. Furthermore, since only one device needs to be operated, the operation surface is also excellent.

The space between the anode 22 and the second cathode 24 is provided with a pressing member 30 that is insulative and water-permeable and presses the anode 22 toward the cation exchange membrane 21. The membrane 21, the anode 22, and the first cathode 23 can be pressed uniformly and reliably, and the alkaline electrolyzed water generation efficiency can be improved. In addition, the second cathode 24 and the anode 22 can be reliably insulated.
Further, since a conductive diamond electrode is used for the anode 22, the water supplied to the first cathode 23 side can be used as raw water, and there is no need to use a saline solution, so that the apparatus can be miniaturized. Is preferable. Moreover, since electrical conductivity becomes large and current efficiency improves, alkaline electrolyzed water can be produced | generated with high efficiency.

[Second Embodiment]
5 to 7 are schematic views of the washing water generating apparatus according to the second embodiment. FIG. 5 shows a case where alkaline electrolyzed water is generated, FIG. 6 shows a case where electrolyzed hyponitrous water is generated, and FIG. The case where alkaline electrolyzed water and electrolyzed hyponitrous water are generated simultaneously is shown.
The cleaning water generation device 100A of the second embodiment is a reference example, and is configured to supply saline to the first cathode 23 side, unlike the cleaning water generation device 100 of the first embodiment. Yes.
That is, the first supply channel 11 is connected to the saline tank 42 via the valve V2A.
As the anode 22, a conductive diamond electrode may be used as in the first embodiment, or platinum, gold, or a coating metal thereof may be used. In particular, the use of a metal in which platinum is coated on titanium is preferable in that the manufacturing cost can be kept low.
Since other configurations are the same as those in the first embodiment, the same reference numerals are given to the same configurations, and descriptions thereof are omitted.

When the alkaline electrolyzed water is generated using the washing water generating apparatus 100A of the second embodiment, as shown in FIG. 5, the first from the saline tank 42 through the first supply flow path 11 is used. The saline solution is supplied to the cathode 23 side, and the saline solution is supplied from the salt solution tank 42 to the anode 22 side via the second supply channel 11, and a predetermined voltage is applied to the anode 22 and the first cathode 23. Apply.
In the case of generating electrolytic hyponitrous acid, as shown in FIG. 6, the saline solution is supplied from the saline solution tank 42 to the anode 22 and the second cathode 24 side via the second supply channel 12, A predetermined voltage is applied to the anode 22 and the second cathode 24.
In the case where alkaline electrolyzed water and electrolytic hyponitrous water are generated simultaneously, as shown in FIG. 7, salt water is supplied from the saline tank 42 to the first cathode 23 side via the first supply channel 11. The saline solution is supplied to the anode 22 and the second cathode 24 side through the second supply channel 12, and a predetermined voltage is applied to the anode 22, the first cathode 23 and the second cathode 24.

  As described above, according to the second embodiment of the present invention, as in the first embodiment, when alkaline electrolyzed water and electrolytic hyposulfite are individually generated, and alkaline electrolyzed water and electrolytic hyponitrous water are simultaneously generated. In this case, it is possible to easily generate desired washing water by appropriately switching the water supplied into the casing 10 and appropriately switching the electrodes 22 to 24 to which a voltage is applied. As a result, the cleaning effect can be enhanced by using the generated alkaline electrolyzed water and electrolytic hyponitrous acid alternately or simultaneously. In addition, the apparatus can be reduced in size, space saving, and cost reduction. Furthermore, it is excellent in terms of operation.

  Further, since the saline solution is supplied to the first cathode 23 side, it is not necessary to use a conductive diamond electrode as the anode 22, and the cost can be reduced as compared with the first embodiment. .

[Third Embodiment]
FIGS. 8 to 10 are schematic views of the cleaning water generator of the third embodiment. FIG. 8 shows a case where alkaline electrolyzed water is generated, FIG. 9 shows a case where electrolyzed hyponitrous water is generated, and FIG. The case where electrolyzed water and electrolyzed hyponitrous water are produced | generated simultaneously is shown.
Unlike the cleaning water generators 100 and 100A of the first and second embodiments, the cleaning water generator 100B of the third embodiment includes a space 17B between the anode 22 and the second cathode 24. The pressing member 30 is not provided as in the first and second embodiments.
The cation exchange membrane 21, the anode 22, and the first cathode 23 are configured to be pressed by fitting the outer periphery of the grating material 25 into the holding portion 18 </ b> B provided on the inner peripheral surface of the casing 10. Further, the second cathode 24 is provided in the casing 10 so that a space 19 </ b> B is also formed between the left side surface of the second cathode 24 and the left side wall surface of the casing 10.
This will be specifically described below.

<Casing>
The casing 10 has a rectangular parallelepiped shape.
A first supply channel 11 and a second supply channel 12 are formed on the lower surface of the casing 10.
The first supply channel 11 is a channel for supplying raw water to the first cathode 23 in the casing 10 when generating alkaline electrolyzed water.
The second supply channel 12 supplies the saline solution to the anode 22 in the casing 10 when generating alkaline electrolyzed water, and the anode 22 and the second electrode in the casing 10 when generating electrolytic hyponitrous water. 2 is a channel for supplying saline to the cathode 24 of the second electrode. Further, it is a flow path for supplying saline to the anode 22 and the second cathode 24 in the casing 10 when the alkaline electrolyzed water and the electrolytic hyponitrous water are simultaneously generated.
A first discharge channel 13 and a second discharge channel 14 are formed on the upper surface of the casing 10.
The first discharge channel 13 is a channel for discharging the alkaline electrolyzed water generated on the first cathode 23 side in the casing 10 when generating the alkaline electrolyzed water.
The second discharge flow path 14 discharges the strongly acidic electrolyzed water generated on the anode 2 side in the casing 10 when generating alkaline electrolyzed water or the casing 10 when generating electrolytic hyposalted water. When the electrolyzed hypochlorite produced by the anode 22 and the second cathode 24 in the inside is discharged, or when the alkaline electrolyzed water and the electrolyzed hyposulfite are produced at the same time, they are produced by the anode 22 and the second cathode 24. It is a flow path for discharging electrolyzed hyponitrous acid and strongly acidic electrolyzed water.

In such a casing 10, the lower end portion of the cation exchange membrane 21 is located between the first supply channel 11 and the second supply channel 12, and the first discharge channel 13 and the second discharge channel 13. The cation exchange membrane 21 is held so that the upper end portion of the cation exchange membrane 21 is located between the flow paths 14.
An anode 22 is provided on one side (left side in FIG. 6) of the cation exchange membrane 21, and a first cathode 23 is provided on the other side (right side in FIG. 6).
Further, a grating material 25 is provided on the surface of the anode 22 opposite to the cation exchange membrane 21 (left side surface in FIG. 6), and the surface of the first cathode 23 opposite to the cation exchange membrane 21 (in FIG. 6). A grating material 26 is provided on the right side surface. The grating material 26 is in contact with the right inner wall surface in the casing 10.
The grating material 25 is held by fitting the outer periphery of the grating material 25 into a holding portion 18B provided on the inner peripheral surface of the casing 10, and the grating material 25 is held in the cation exchange membrane 21, the anode 22, and the second electrode. 1 cathode 23 is pressed to the grating material 26 side.

Further, the second cathode 24 is provided on the left inner wall surface in the casing 10 so as to face the anode 22 with a predetermined distance, and is also opposed to the left inner wall surface in the casing 10 with a predetermined distance. Is provided. That is, the second cathode 24 is held by inserting the upper and lower end portions thereof into insertion holes formed on the upper and lower surfaces of the casing 10.
A space 17B is formed between the second cathode 24 and the grating material 25 so that the grating material 25 and the anode 22 are insulated from the second cathode 24. Further, the left side surface of the second cathode 24 is held at a predetermined distance so as not to contact the left inner wall surface of the casing 10, and the left side surface of the second cathode 24 and the left inner wall surface of the casing 10 are held. Since the space 19B is formed between them, the saline solution reliably contacts not only the right side surface of the second cathode 24 but also the left side surface, and as a result, the generation efficiency of electrolytic hyponitrous acid is improved. It has become.

Thus, the cation exchange membrane 21, the anode 22, the first cathode 23, and the second cathode 24 are provided in the casing 10, and when the alkaline electrolyzed water is generated, the anode 22 and the first cathode 24 are provided. Therefore, the inside of the casing 10 is divided by the cation exchange membrane 21 to form a two-chamber type.
On the other hand, when producing electrolytic hyponitrous acid, since the anode 22 and the second cathode 24 are used, it becomes a non-diaphragm and becomes a one-chamber type.

In such a casing 10, the raw water supplied from the first supply flow path 11 comes into contact with the first cathode 23 and the grating material 26, and the generated alkaline electrolyzed water is discharged first. It is discharged from the flow path 13.
The saline solution supplied from the second supply channel 12 is in contact with the anode 22, the grating material 25, and the second cathode 24, and the generated strong acidic electrolyzed water and / or electrolytic sub-aqueous water. Is discharged from the second discharge flow path 14.

<Raw water tank>
The raw water tank 41 is connected to the first supply channel 11 via a valve V2.

<Saline tank>
The saline solution tank 42 is connected to the second supply flow path 12 via the valve V3.

<Control unit>
When the alkaline electrolyzed water is generated, the control unit 50 opens the valve V3 so as to supply the saline from the saline tank 42 to the anode 22 as shown in FIG. The valve V2 is opened so as to supply raw water to the cathode 23. Further, the power supply device 60 is controlled to apply a predetermined voltage between the anode 22 and the first cathode 23. At this time, the valve V1 is opened.
On the other hand, in the case of producing electrolytic hyposulfite, as shown in FIG. 9, the valve V3 is opened so as to supply the saline from the saline tank 42 to the anode 22 and the second cathode 24, and further, the power source The device 60 is controlled to apply a predetermined voltage between the anode 22 and the second cathode 24. At this time, the valve V1 and the valve V2 are closed.
Further, in the case where alkaline electrolyzed water and electrolytic hyponitrous water are generated simultaneously, as shown in FIG. 10, the valve V2 is opened so as to supply raw water from the raw water tank 41 to the first cathode 23, and for saline solution. The valve V <b> 3 is opened so as to supply saline from the tank 42 to the anode 22 and the second cathode 24. Further, the power supply device 60 is controlled to apply a predetermined voltage to the anode 22, the first cathode 23, and the second cathode 24. At this time, the valve V1 is opened.
As described above, the control unit 50 generates the valves V1 to V1 in the case of generating alkaline electrolyzed water, the case of generating electrolyzed hyposulfite, and the case of simultaneously generating alkaline electrolyzed water and electrolyzed hyposulfite. While controlling opening and closing of V3, it controls so that the application of the voltage to each electrode 22-24 may be switched suitably.

  <Cation exchange membrane 21>, <Anode 22>, <First cathode 23>, <Second cathode 24>, <Grating material 25, 26>, <Power supply device 60> Since it is the same as that of embodiment, the same code | symbol is attached | subjected about the same structure and the description is abbreviate | omitted.

In the case where alkaline electrolyzed water is generated using the cleaning water generating apparatus 100B of the third embodiment, the anode 22 is supplied from the saline tank 42 via the second supply channel 12 as shown in FIG. The saline solution is supplied to the side, the raw water is supplied from the raw water tank 41 to the first cathode 23 side through the first supply flow path 11, and a predetermined voltage is applied to the anode 22 and the first cathode 23. To do.
In the case of generating electrolytic hyponitrous acid, as shown in FIG. 9, while supplying saline to the anode 22 and the second cathode 24 from the saline tank 42 via the second supply channel 12, the anode A predetermined voltage is applied to 22 and the second cathode 24.
In the case where alkaline electrolyzed water and electrolytic hyponitrous water are generated simultaneously, as shown in FIG. 10, raw water is supplied from the raw water tank 41 to the first cathode 23 via the first supply flow path 11, and the saline solution The saline solution is supplied from the tank 42 to the anode 22 and the second cathode 24 through the second supply channel 12, and a predetermined voltage is applied to the anode 22, the first cathode 23 and the second cathode 24. To do.

  As described above, according to the third embodiment of the present invention, as in the first embodiment, when alkaline electrolyzed water and electrolytic hyposulfite are individually generated, and alkaline electrolyzed water and electrolytic hyponitrous water are simultaneously generated. In this case, it is possible to easily generate desired washing water by appropriately switching the water supplied into the casing 10 and appropriately switching the electrodes 22 to 24 to which a voltage is applied. As a result, the cleaning effect can be enhanced by using the generated alkaline electrolyzed water and electrolytic hyponitrous acid alternately or simultaneously. In addition, the apparatus can be reduced in size, space saving, and cost reduction. Furthermore, it is excellent in terms of operation.

  Moreover, since it is the structure which does not provide the press member 30 like the 1st and 2nd embodiment, a member number reduces and it can aim at cost reduction more.

  Although not shown, the third embodiment may be configured to supply saline to the first cathode 23 side in the same manner as in the second embodiment.

DESCRIPTION OF SYMBOLS 10 Casing 21 Cation exchange membrane 22 Anode 23 1st cathode 24 2nd cathode 30 Pressing member 41 Tank for raw | natural water 42 Tanks for salt water 100, 100A, 100B Washing water production | generation apparatus

Claims (1)

A casing,
A cation exchange membrane provided in the casing;
An anode in pressure contact with one surface of the cation exchange membrane in the casing;
A first cathode in pressure contact with the other surface of the cation exchange membrane in the casing;
A second cathode provided in the casing so as to face the surface of the anode opposite to the cation exchange membrane at a predetermined distance;
Raw water tank containing raw water which is pure water or purified water ;
A saline tank containing saline,
When the alkaline electrolyzed water produced, the saline saline is supplied from the tank to the anode water supplies raw water to the said raw water for tanks or we first cathode, between the anode and the first cathode DC voltage is applied to
At the time of electrolytic hyponitrous generation, while supplying saline from the saline tank to the anode and the second cathode, a DC voltage is applied between the anode and the second cathode,
When simultaneously generating the alkaline electrolyzed water and electrolytic following Asui, saline is supplied from the brine tank to the anode and the second cathode, the raw water to the said raw water for tanks or we first cathode And a control unit that controls to apply a DC voltage to the anode, the first cathode, and the second cathode, and
The anode and the first cathode are conductive diamond electrodes;
Washing water, characterized in that a space between the anode and the second cathode is provided with a pressing member that is insulating and water-permeable and presses the anode toward the cation exchange side. Generator.

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