JP2021070842A - Electrolytic water generation apparatus - Google Patents

Abstract

To increase the content of a hypochlorous acid in an electrolytic water to be generated.SOLUTION: An electrolytic water generation apparatus of the present invention comprises: a raw-material liquid supply unit for supplying an electrolytic water raw-material liquid containing a chloride; an electrolytic tank for the electrolysis of the electrolytic water raw-material liquid; and a discharge-pipe arrangement for discharging acidic electrolytic water discharged from the electrolytic tank. It is a characteristic of the electrolytic water generation apparatus to provide a mixing tank for staying the acidic electrolytic water for 0.3-3.0 seconds on the discharge pipe arrangement.SELECTED DRAWING: Figure 1

Description

The present invention can be suitably applied to, for example, an electrolyzed water generator that produces acidic electrolyzed water.

Conventionally, electrolyzed water generators have been widely used in fields such as cleaning (see, for example, Patent Document 1).

Since electrolyzed water exhibiting acidity has a sterilizing effect, it is widely used, for example, for spraying on houses such as livestock and for washing vegetables and eggs. In particular, chlorine-based acidic electrolyzed water has excellent sterilizing and sterilizing power, and is approved by the Ministry of Health, Labor and Welfare as a sterilizing agent (hypochlorite water) under the Food Sanitation Law.

This sterilizing and bactericidal activity is mainly due to hypochlorous acid, and it is very important that chlorine contained in electrolyzed water exists as hypochlorous acid.

JP-A-2009-268997

By the way, in sterilization applications such as hand washing, electrolyzed water is diluted with tap water or the like before use. At this time, if the chlorine concentration of hypochlorous acid in the electrolyzed water is high, sufficient sterilizing power can be exhibited even with a small amount of electrolyzed water, which is preferable.

The present invention has been made to solve such a problem, and an object of the present invention is to provide an electrolyzed water generator capable of improving the chlorine concentration of hypochlorous acid in electrolyzed water.

In order to solve such a problem, the electrolyzed water generator of the present invention is used.
The raw material liquid supply unit that supplies the electrolyzed water raw material liquid containing chloride, and
An electrolytic cell that electrolyzes the electrolyzed water raw material liquid and
A discharge pipe for discharging the acidic electrolyzed water discharged from the electrolytic cell, and a discharge pipe for discharging the acidic electrolyzed water.
It is characterized by having a mixing tank provided on the discharge pipe and allowing the acidic electrolyzed water to stay for 0.3 to 3.0 seconds.

The invention of the present application is
The present invention has been made to solve such a problem, and an object thereof can realize an electrolyzed water generator capable of improving the chlorine concentration of hypochlorous acid in electrolyzed water.

It is a schematic diagram which shows the structure of the electrolyzed water supply device. It is a graph which provides the explanation of the composition ratio of pH and effective chlorine. It is a schematic diagram which shows the structure of a mixing tank.

Next, a mode for carrying out the present invention will be described with reference to the drawings.

<First Embodiment>
1 shown in FIG. 1 shows an electrolyzed water supply device as a whole. In the electrolyzed water supply device 1, a control unit 2 composed of an MPU (Micro Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory) (not shown) comprehensively controls the entire electrolyzed water supply device 1. It is done like this.

The electrolyzed water supply device 1 has a non-diaphragm type electrolyzed water tank as an electrolyzed water generation unit 11, electrolyzes an electrolyzed water raw material solution diluted with tap water to generate acidic electrolyzed water, and the acidic electrolysis The water is diluted with tap water and discharged from the electrolyzed water supply port 16. The raw material liquid supply unit 12 stores the electrolyzed water raw material liquid and supplies the electrolyzed water raw material liquid to the electrolyzed water generation unit 11.

By the way, in acidic electrolyzed water, chlorine contained in the electrolyzed water becomes hypochlorous acid and exerts a sterilizing effect. As shown in FIG. 2, it is known that the ratio of the presence form of chlorine changes depending on the pH of the aqueous solution.

That is, in order for chlorine contained in the electrolyzed water to effectively exhibit the sterilizing action as hypochlorous acid, it is necessary to control the pH of the electrolyzed water in the range of 2.7 to 6.5.

For example, when an aqueous solution using an electrolyte that becomes neutral when dissolved in water, such as sodium chloride, is electrolyzed, part of the hydrogen escapes from the cathode as hydrogen gas, so the pH of the electrolyzed water is weakly alkaline ( It will exhibit pH 9 to 10).

Therefore, in the present embodiment, in order to control the pH to the acidic side, an aqueous solution obtained by mixing sodium chloride and hydrochloric acid is used as the electrolyzed water raw material solution. This electrolyzed water raw material liquid is mixed with raw water, diluted, and then supplied to the electrolyzed water generation unit 11. Further, as the electrolyzed water raw material solution, an aqueous solution containing only hydrochloric acid may be used.

As the raw water, general tap water is preferably used. Tap water with few impurities that has passed through various filters may be used. The raw water used preferably has a hardness component such as organic matter, calcium, and magnesium of 10 ppm or less. This is because organic matter reacts with chlorine and the hardness component causes calcification.

Specifically, in the electrolyzed water supply device 1 (see FIG. 1), the user requests the supply of electrolyzed water via an operation unit (for example, a button press, a touch sensor, a non-contact sensor such as infrared rays, etc.) (not shown). Then, the pump 13 is driven to start supplying the electrolyzed water raw material liquid from the raw material liquid supply unit 12. Further, the control unit 2 starts supplying raw water by opening the valve of the raw water supply port 14 connected to the water supply RW.

The electrolyzed water raw material liquid supplied from the raw material liquid supply unit 12 through the pipe 22 and the raw water supplied from the raw water supply port 14 through the pipe 21 merge at the pipe 23 and pass through the raw material supply port 11A. It is supplied to the electrolyzed water generation unit 11.

The electrolyzed water generation unit 11 electrolyzes the electrolyzed water raw material liquid to produce electrolyzed water, and supplies the electrolyzed water to the mixing / discharging unit 7. As the electrolyzed water generating unit 11, a known one can be used, and for example, a diaphragmless type electrolytic cell can be used. Further, the acidic electrolyzed water generated in the two-chamber type or three-chamber type electrolytic cell may be used alone, or the acidic electrolyzed water and a part or all of the alkaline electrolyzed water may be mixed.

At this time, the control unit 2 controls the voltage value and the pump 13 so that the current value for the electrolyzed water generation unit 11 falls within a certain range. As a result, electrolyzed water that has been properly electrolyzed with a constant current value is generated.

The generated acidic electrolyzed water passes through the pipe 26 from the electrolyzed water discharge port 11B of the electrolyzed water generation unit 11, merges with the raw water supplied to the pipe 25 branched from the pipe 21, and passes through the pipe 27 and the pipe 28. It is supplied to the supply pipe 15 connected to the outside of the body 3 and discharged from the electrolyzed water supply port 16.

In addition to this configuration, in the electrolyzed water supply device 1 of the present invention, the chlorine concentration of the acidic electrolyzed water discharged from the electrolyzed water supply port 16 is increased by installing a mixing tank 30 in the subsequent stage of the electrolyzed water generation unit 11. It is done like this. In the present embodiment, the mixing tank 30 is installed on the pipes 27 and 28 connected from the housing 3 to the supply pipe 15 after the raw water and the acidic electrolyzed water have merged.

As shown in FIG. 3, the mixing tank 30 has a male screw formed on the main body 31 and a female screw formed on the cap 33 with the packing 32 sandwiched between the main body 31 and the cap 33. Form a cylindrical shape by being fitted with a screw method.

The outer diameters of the main body 31 and the cap 33 are 38 mm and 40 mm, respectively. When the cap 33 is upward and the main body 31 is downward, the upper portion (ceiling surface) of the cap 33 and the lower portion of the main body 31 are respectively. Protruding pipes 33A and 31A for connecting to the pipes 28 and 27 are formed on the (bottom surface), respectively.

The inner diameter of the cap portion 33 is 40 mm, the inner diameter UIφ of the protruding pipe inner port 33Ab on the lower side of the protruding pipe 33A is 6 mm, and the inner diameter UOφ of the protruding pipe outer port 33Aa on the upper side of the protruding pipe 33A is 4 mm. The diameter gradually decreases toward the protruding pipe outer port 33Aa.

The packing 32 has a ring shape, has an outer diameter of 38 mm, an inner diameter PDφ of 30 mm, a width of 4 mm, and a thickness of PT of 2 mm.

The main body 31 has an outer diameter of 38 mm, which is a cylinder with no difference between the upper and lower sides, but the inner diameter is 28 mm on the lower side and 32 mm on the upper side. It has a shape. The inside of the main body 31 is merely a cavity, and no flow path or the like is formed. In addition, it does not have anything that applies physical stimuli such as ultrasonic waves. Although the inner wall surface of the main body 31 is not formed with irregularities in FIG. 3, for example, irregularities having a height of less than 1/10 of the inner diameter may be formed.

The protruding pipe 31A has a cylindrical shape as a whole and protrudes from the main body 31. The protruding height is about 18 mm, and a non-slip groove is formed on the tip side thereof. The inner diameter DOφ of the protruding pipe outer opening 31Aa on the lower side of the protruding pipe 31A is 4 mm, the inner diameter DIφ of the protruding pipe inner opening 31Ab on the upper side of the protruding pipe 31A is 6 mm, and gradually from the protruding pipe outer opening 31Aa toward the protruding pipe inner opening 31Ab. The diameter is large.

The main body 31 is fitted into the cap 33 up to the vicinity of the ceiling surface, and the packing 32 sandwiched between the caps 33 closes the gap between the cap 33 and the main body 31 to prevent water leakage. The protruding tube 33A has a truncated cone shape that becomes slightly thinner toward the tip, and has a shape like a stack of flat truncated cones. The protruding height is about 20 mm.

Piping hoses having an inner diameter of 8 mm are connected to the protruding pipes 31A and 33A as pipes 27 and 28. In the pipes 26, 27, and 28, which are located after the electrolyzed water generating unit 11, the inner diameter is the smallest in the pipe 26 and the pipe 25 and the connection portion between the pipe 27 and the pipe 25, and the inner diameter thereof is 6 mm. ..

Therefore, the acidic electrolyzed water supplied to the mixing tank 30 through the pipe 27 having an inner diameter of 8 mm has a protruding pipe outer port 31Aa having an inner diameter of DOφ4 mm, which is the minimum diameter in the stage (pipes 26, 27, 28) after the electrolyzed water generating unit 11. It passes through the protruding pipe inner port 31Ab having an inner diameter DI of φ6 mm and enters the main body 31 having an inner diameter of CDφ28 mm to 32 mm. The acidic electrolyzed water that has entered the inside of the main body 31 is agitated by turbulent flow inside the main body 31 having a hollow structure.

After that, the acidic electrolyzed water inside the main body 31 is sent from the protruding pipe inner port 33Ab having an inner diameter UI of φ6 mm to the pipe 28 having an inner diameter of 8 mm through the protruding pipe outer port 33Aa having an inner diameter of UO φ6 mm.

As described above, in the electrolyzed water supply device 1, although the electrolyzed water raw material liquid is supplied from the raw material liquid supply unit 12 to the electrolyzed water generation unit 11 via the pump 13, the electrolyzed water drainage of the electrolyzed water generation unit 11 No pump is installed after the outlet 11B. Further, in the electrolyzed water generation unit 11, the electrolyzed water generated from the electrolyzed water discharge port 11B due to the overflow is discharged.

That is, from the rear stage of the electrolyzed water discharge port 11B, the supply pressure of the electrolyzed water raw material liquid to the electrolyzed water generation unit 11 by the pump 13 and the supply pressure of the raw water (tap water) (tap water pressure of the tap water RW) are directly applied to the pipe 26, It becomes the discharge pressure at 27 and 28.

In the mixing tank 30, the inner diameter of the protruding pipe outer port 31Aa of the main body 31 and the protruding pipe outer port 33Aa of the cap portion 33 is 4 mm, which is the minimum diameter.

Therefore, since the inlet is narrowed by the protruding pipe outer port 31Aa, the acidic electrolyzed water can be vigorously introduced into the mixing tank 30 and the residence time until the discharge of the acidic electrolyzed water can be lengthened. As a result, the dissolution of chlorine in acidic electrolyzed water can be promoted, and the chlorine concentration can be increased.

Here, the area ratio of the inner diameters (8 mm) of the pipes 27 and 28 to the minimum diameter (4 mm) of the entrance / exit in the mixing tank 30 is 1: 4. The area ratio of the minimum diameter of the entrance / exit in the mixing tank 30 to the inner diameters of the pipes 27 and 28 is preferably 1: 2 to 1:10. This is to increase the momentum when introduced into the mixing tank 30 and prevent the pressure in the front stage portion from becoming too large. The minimum diameter of the entrance / exit in the mixing tank 30 and the minimum diameter portion (6 mm) of the pipes 25, 26 and the pipes 27, 26 are 1: 2.25.

The internal volume of the mixing tank 30 is 22.65 cm3, and when the assumed discharge amount in the electrolyzed water supply device 1 is 2700 cm3 / min (45 cm3 / sec), the acidic electrolyzed water enters the mixing tank 30 for about 0.5 seconds. Can stay.

The residence time in the mixing tank 30 is preferably 0.3 to 3.0 seconds, particularly preferably 0.4 to 1.0 seconds. If the residence time is too short, the effect of increasing the chlorine concentration becomes low, and if the residence time is too long, the chlorine once dissolved may be separated or a gas pool may be generated in the mixing tank 30, which is not preferable.

<Example 1>
Next, an embodiment will be described.
In Comparative Example 1, when tap water was used as raw water and the mixing tank 30 was not installed, the mixing tank 30 (vertical direction connecting the protruding pipes 31A and 33A) was installed diagonally (about 45 °) with respect to the vertical direction. The case was defined as Example 1, and the case where the mixing tank 30 (vertical direction connecting the protruding pipes 31A and 33A) was installed in parallel with the vertical direction was defined as Example 2.

When the voltage value is constant (2.75 to 2.8 V), the electrolyzed water raw material liquid is controlled to be supplied so that the current value is within a constant range (5.9 to 6.3 A). It was operated for 10 minutes. As the electrolyzed water raw material solution, an aqueous solution obtained by mixing sodium chloride and hydrochloric acid was used.

The acidic electrolyzed water generated 1 minute, 5-6 minutes, and 9-10 minutes after the start of operation was collected, and the chlorine (hypochlorous acid) concentration, pH, and water temperature were measured. In addition, the voltage value, current value, raw material liquid usage amount, and flow rate at that time were recorded.

The results are shown in Table 1.

As can be seen from Table 1, the chlorine concentration in Example 1 and Example 2 was improved by about 10% as compared with Comparative Example 1. On the other hand, the amount of electrolyzed water raw material used increased only slightly (1 to 4%). Therefore, it is considered that the increase in the chlorine concentration in Examples 1 and 2 is due to the efficient dissolution of chlorine in the acidic electrolyzed water, not the amount of the electrolyzed water raw material liquid.

That is, it was confirmed that in Examples 1 and 2, the amount of the electrolyzed water raw material used was almost the same, and only the chlorine concentration in the acidic electrolyzed water could be improved.

<Operation and effect>
Hereinafter, the characteristics of the invention group extracted from the above-described embodiments will be described while showing issues, effects, and the like as necessary. In the following, for ease of understanding, the corresponding configurations in the above embodiments are appropriately shown in parentheses or the like, but the present invention is not limited to the specific configurations shown in the parentheses or the like. In addition, the meanings and examples of terms described in each feature may be applied as meanings and examples of terms described in other features described in the same wording.

In the above configuration, the electrolyzed water generator (electrolyzed water supply device 1) of the present invention is
A raw material liquid supply unit (raw material liquid supply unit 12) that supplies an electrolyzed water raw material liquid containing chloride, and
An electrolytic cell (electrolyzed water generation unit 11) that electrolyzes the electrolyzed water raw material liquid, and
Discharge pipes (pipes 27 and 28) for discharging acidic electrolyzed water discharged from the electrolytic cell and
It is characterized by having a mixing tank (mixing tank 30) provided on the discharge pipe and allowing the acidic electrolyzed water to stay for 0.3 to 3.0 seconds.

As a result, the residence time of acidic electrolyzed water can be effectively extended in a small space with a simple configuration that only installs a small mixing tank, so chlorine gas generated by electrolysis can be efficiently dissolved in electrolyzed water. Can be done.

In the electrolyzed water generator, the mixing tank is
The area ratio between the minimum diameter of the inlet connecting portion and the discharge pipe is 1: 2 to 1:10.

As a result, the acidic electrolyzed water narrowed at the inlet connection portion can be vigorously introduced into the mixing tank, and the stirring effect in the mixing tank can be enhanced.

In the electrolyzed water generator, the minimum diameter of the mixing tank at the inlet connection portion is
The diameter is the smallest between the electrolytic cell and the tip of the discharge pipe.

As a result, the pressure can be increased immediately before the mixing tank, and the momentum when the acidic electrolyzed water is introduced into the mixing tank can be efficiently increased.

In the electrolyzed water generator, the mixing tank is
It is characterized in that the internal shape has a substantially cylindrical shape.

As a result, the water flow in the mixing tank can be smoothed.

In the electrolyzed water generator, the mixing tank is
It is characterized in that the minimum diameters at the inlet and the outlet are the same or substantially the same.

As a result, the pressure inside the mixing tank is not significantly increased, so that the pressure in the pipes 27 and 28 does not become too high, and the supply amount of acidic electrolyzed water is hardly affected. In addition, it is not necessary to cause a load or an adverse effect on the electrolyzed water generating part due to the increase in pressure.

In the electrolyzed water generator, the electrolyzed water raw material liquid is
It is characterized by containing hydrochloric acid as the chloride.

As a result, the electrolyzed water generator can produce good acidic electrolyzed water whose pH is stable on the acidic side.

<Other embodiments>
According to the above-described embodiment, the electrolyzed water raw material liquid is diluted with tap water and electrolyzed, and the generated acidic electrolyzed water is diluted with tap water, but the present invention is not limited to this. For example, the electrolyzed acidic electrolyzed water obtained by diluting the electrolyzed water raw material liquid with tap water may be supplied at the same concentration, or the electrolyzed acidic electrolyzed water without diluting the electrolyzed water raw material liquid may be diluted with tap water. It is also possible to electrolyze the electrolyzed water raw material solution without diluting it and supply it without diluting it. Even in this case, the same effect as that of the above-described embodiment can be obtained by installing the mixing tank.

According to the above embodiment, the area ratio between the minimum diameter of the entrance / exit in the mixing tank 30 and the inner diameters of the pipes 27 and 28 is set to 1: 2 to 1:10, but the area ratio is not essential. For example, the same effect as that of the present invention can be obtained with a mixing tank having a shape (drop shape, etc.) that gradually increases from the entrance / exit. In this case, it is preferable that the ratio of the cross-sectional area of the minimum diameter of the entrance / exit and the maximum diameter portion of the mixing tank is within the range of 1: 2 to 1:10.

In the above-described embodiment, the inlet of the mixing tank has the minimum diameter in the discharge path after the electrolyzed water generation unit 11, but this configuration is not essential. There may be a portion with the smallest diameter on the pipe.

In the above-described embodiment, the mixing tank has a cylindrical shape, but the present invention is not limited to this. The shape is not limited, and a mixing tank having various shapes such as a hexagonal column, a rectangular parallelepiped, and a conical trapezoid can be used.

In the above-described embodiment, the minimum diameters of the inlet side (protruding pipe outer port 31Aa) and the outlet side (protruding pipe outer port 33Aa) of the mixing tank are the same, but the present invention is not limited to this and is not necessarily the same. Is also good. For example, the inlet side may have the minimum diameter. Further, the protruding pipe outer opening 31Aa and the protruding pipe inner opening 31Ab may be gradually reduced or the same. The height of the protruding pipes 31A and 33A is not limited, but it should be 2/3 or less, more preferably 1/2 or less of the height of the main body 31 of the mixing tank 30 so as not to limit the space and increase the pressure too much. Is preferable.

In the above-described embodiment, the mixing tank 30 is installed on the pipes 27 and 28 (that is, between the pipes 27 and 28) as the discharge pipe, but the present invention is not limited to this. The mixing tank 30 may be installed after the electrolyzed water generating unit 11, for example, in the pipe 26. Further, a pump may be installed after the electrolyzed water generation unit 11. Even in this case, the same effect as that of the above-described embodiment can be obtained.

In the above-described embodiment, the present invention is applied to the electrolyzed water generator for hand washing, but the present invention is not limited to this, and the present invention can be used for various types of electrolyzed water generators.

In the above-described embodiment, the electrolyzed water is provided by the raw material liquid supply unit 12 as the raw material liquid supply unit, the electrolyzed water generation unit 11 as the electrolytic cell, the pipes 27 and 28 as the discharge pipes, and the mixing tank 30 as the mixing tank. The electrolyzed water supply device 1 as a generator is configured, but the electrolyzed water generator of the present invention is configured by a raw material liquid supply unit having various other configurations, an electrolytic cell, a discharge pipe, and a mixing tank. You may.

The present invention can be applied to a diluted electrolyzed water supply device installed in a hand-washing space such as a hospital or a long-term care facility.

1: Electrolyzed water supply device, 2: Control unit, 3: Housing, 7: Mixed discharge unit, 11: Electrolyzed water generation unit, 11A: Raw material supply port, 11B: Electrolyzed water discharge port, 12: Raw material liquid supply unit, 13: Pump, 14: Raw water supply port, 15: Supply pipe, 16: Electrolyzed water supply port, 21,22,23,25,26,27,28: Piping, 30: Mixing tank, 31: Main body, 31A, 33A: protruding pipe, 31Aa, 33Aa: protruding pipe outer port, 31Ab, 33Ab: protruding pipe inner port, 32: packing, 33: cap portion,

Claims (6)

The raw material liquid supply unit that supplies the electrolyzed water raw material liquid containing chloride, and
An electrolytic cell that electrolyzes the electrolyzed water raw material liquid and
A discharge pipe for discharging the acidic electrolyzed water discharged from the electrolytic cell, and a discharge pipe for discharging the acidic electrolyzed water.
An electrolyzed water generator provided on the discharge pipe and having a mixing tank for accumulating the acidic electrolyzed water for 0.3 to 3.0 seconds. The mixing tank is
The electrolyzed water generator according to claim 1, wherein the area ratio between the minimum diameter of the inlet connecting portion and the discharge pipe is 1: 2 to 1:10. The minimum diameter at the inlet connection portion is
The electrolyzed water generator according to claim 2, wherein the diameter is the smallest between the electrolytic cell and the tip of the discharge pipe. The mixing tank is
The electrolyzed water generator according to claim 3, wherein the internal shape has a substantially cylindrical shape. The mixing tank is
The electrolyzed water generator according to claim 1, wherein the minimum diameters at the inlet and the outlet are the same or substantially the same. The electrolyzed water raw material liquid is
The electrolyzed water generator according to claim 1, wherein hydrochloric acid is contained as the chloride.

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