JP2016209864A - Electrolytic water generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a stably settable electrolytic water generator capable of generating electrolytic water including hypochlorite.SOLUTION: Provided is an electrolytic generator comprising: an electrolyzing part; and an electrolytic solution feed part, in which the electrolyzing part includes: an electrode pair having an anode and a cathode arranged oppositely to the anode; and a non-diaphragm type electrolytic solution flow passage between the anode and the cathode, the electrolytic solution flow passage being the one made of a unidirectionally tilted linear flow passage single row, the electrode pair are respectively arranged in such a manner that, in the respective planar anode and cathode, the anode is made into the upper side and the cathode is made into the lower side, the electrode pair is arranged in such a manner that the inclination angle to the vertical direction reaches 10 to 85°C, the electrode pair is provided in such a manner that the ratio between the anode and the cathode and the length in the longitudinal direction of the electrode face reaches 1:100 to 1:10, and the electrolytic solution feed part is provided with a pump feeding an electrolytic solution to the electrolytic solution flow passage.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an electrolyzed water generator.

  Hypochlorous acids such as hypochlorous acid and sodium hypochlorite are used as bleaching and disinfecting agents for water and sewage treatment, wastewater treatment, household kitchens and laundry. . Hypochlorite can be produced by reacting alkali hydroxide obtained by electrolysis of an aqueous solution of an alkali metal chloride such as saline and chlorine gas, or by using an alkali metal chloride in a diaphragm electrolyzer. This is performed by a method of electrolyzing an aqueous solution of the above and producing a hypochlorite aqueous solution in an electrolytic cell.

In the method of producing hypochlorous acid by electrolysis of an aqueous solution of an alkali metal chloride, an anodic reaction such as chemical reaction formulas (1) and (3) proceeds, and a cathodic reaction such as chemical reaction formula (4). Is considered to be in progress. Further, it is considered that the reaction between Cl ₂ generated by the anodic reaction and water proceeds as in chemical reaction formula (2).
2Cl ⁻ → Cl ₂ + 2e ⁻ (1)
Cl ₂ + H ₂ O → HCl + HClO (2)
H ₂ O → 1 / 2O ₂ + 2H ⁺ + 2e ⁻ (3)
2H ₂ O + 2e ⁻ → H ₂ + 2OH ⁻ (4)
In addition, when aqueous solution becomes strong acidity (pH is 3 or less), the reaction rate of chemical reaction formula (2) will become slow, and chlorine gas may be produced | generated by a reverse reaction.
Moreover, the method of manufacturing the electrolyzed water containing hypochlorous acid is known (for example, refer patent documents 1-6).

JP-A-4-74879 JP-A-5-237478 Japanese Patent Application Laid-Open No. 6-292892 JP 9-253650 A JP 2001-29955 A JP 2001-48199 A

However, in the conventional electrolyzed water production method, electrolyzed water is produced by arranging the anode and the cathode vertically in order to prevent chlorine gas and hydrogen gas from staying between the anode and the cathode. However, when the anode and the cathode are arranged vertically, the electrolyzed water generator may be increased in size, or the electrolyzed water generator may be high and easily fall over.
This invention is made | formed in view of such a situation, The electrolyzed water generator which can produce | generate electrolyzed water containing hypochlorous acid efficiently and can be installed stably is provided.

  The present invention includes an electrolysis unit, and the electrolysis unit includes an electrode pair having an anode and a cathode disposed opposite to the anode, and a diaphragm-type electrolyte flow path between the anode and the cathode. And the electrode pair is inclined so that the anode is on the upper side and the cathode is on the lower side, and the electrolyte flow path is configured such that the electrolyte flows into the electrolyte flow path from the lower side. And electrolyzed water containing hypochlorous acid produced by electrolysis of the electrode pair by the electrode pair flows out from the upper side of the electrolyte channel, and the electrode pair is inclined with respect to the vertical direction. Provided is an electrolyzed water generator characterized in that the angle is 10 degrees or more and 85 degrees or less.

The electrolyzed water generator of the present invention includes an electrolysis unit, and the electrolysis unit includes an electrode pair having an anode and a cathode disposed opposite to the anode, and a diaphragm-type electrolyte flow path between the anode and the cathode. Therefore, by applying a voltage to the electrode pair, the electrolytic solution flowing through the electrolytic solution flow path can be electrolyzed, and electrolytic water containing hypochlorous acid can be generated.
The electrode pair included in the electrolysis unit is disposed so that the anode is on the upper side and the cathode is on the lower side, and the electrolyte channel is provided so that the electrolyte flows into the electrolyte channel from below. In addition, since the electrolyzed water containing hypochlorous acid generated by electrolysis of the electrode pair is discharged from the upper side of the electrolyte channel, the electrolyzed water containing hypochlorous acid is efficiently used. Can be generated. This was verified by experiments conducted by the inventors.

  The reason why electrolyzed water containing hypochlorous acid can be efficiently generated is considered as follows. In the electrolyzed water generator of the present invention, hydrogen gas is generated by the cathode reaction at the cathode disposed on the lower side, so that bubbles are generated on the cathode, and the bubbles are formed on the anode disposed on the upper side so as to cross the fluid flow direction. Can be lifted up. By the flow of fluid generated by the rising of the bubbles, the fluid near the cathode and the fluid near the anode can be stirred and mixed, and the anodic reaction at the anode can be promoted. For this reason, the electrolyzed water containing hypochlorous acid can be produced | generated efficiently. In addition, by arranging the cathode on the lower side and generating a flow from the cathode to the anode, it is possible to prevent chlorine gas, oxidizing substances, hypochlorous acid, etc. generated by the anodic reaction from oxidizing the electrode surface of the cathode. It is considered that electrolyzed water containing hypochlorous acid can be generated efficiently. Moreover, since the oxidation of the electrode surface of the cathode can be suppressed, a Ti electrode can be used for the cathode, and the manufacturing cost of the electrolyzed water generator can be reduced.

  Since the electrode pair included in the electrolysis part is arranged so that the inclination angle with respect to the vertical direction is 10 degrees or more and 85 degrees or less, electrolyzed water containing hypochlorous acid can be efficiently generated. This was verified by experiments conducted by the inventors. In addition, since the electrode pair is disposed with a sufficient inclination, the height of the electrolyzed water generator can be reduced, and an electrolyzed water generator that can be stably installed can be realized. This can reduce the risk of the electrolytic water generator falling.

It is a schematic sectional drawing of the electrolyzed water generator of one Embodiment of this invention. (First embodiment) (A)-(e) is a schematic sectional drawing of a part of electrolyzed water generator of one Embodiment of this invention. (Second to sixth embodiments) It is a schematic sectional drawing of a part of electrolyzed water generator of one Embodiment of this invention. (Seventh embodiment) It is a graph which shows the measurement result of an effective chlorine concentration measurement experiment. It is a graph which shows the measurement result of an electrolyzed water detection experiment. It is a graph which shows the measurement result of an electrolyzed water detection experiment.

  The electrolyzed water generator of the present invention includes an electrolysis unit, and the electrolysis unit includes an electrode pair having an anode and a cathode disposed opposite to the anode, and a diaphragmless electrolysis between the anode and the cathode. And the electrode pair is inclined so that the anode is on the upper side and the cathode is on the lower side, and the electrolyte channel is configured such that the electrolyte flows from the lower side to the electrolyte flow. An electrolytic solution containing hypochlorous acid generated by electrolysis by the electrode pair and flowing out from the upper side of the electrolyte flow path, and the electrode pair The tilt angle with respect to the vertical direction is 10 degrees or more and 85 degrees or less.

The electrode pair included in the electrolyzed water generator of the present invention is preferably arranged so that the inclination angle with respect to the vertical direction is not less than 50 degrees and not more than 80 degrees.
Thereby, electrolyzed water containing hypochlorous acid can be efficiently generated. In addition, since the electrode pair is disposed with a sufficient inclination, the height of the electrolyzed water generator can be reduced, and an electrolyzed water generator that can be stably installed can be realized. This can reduce the risk of the electrolytic water generator falling.
The anode and cathode included in the electrolyzed water generator of the present invention have a substantially rectangular electrode surface, and one end in the longitudinal direction of the electrode surface is on the upper side and the other end is on the lower side. It is preferable to arrange | position to.
As a result, the electrolyte solution flow path can be lengthened and the electrolysis efficiency can be increased.

The electrode pair included in the electrolyzed water generator of the present invention is preferably provided such that the ratio between the distance between the anode and the cathode and the length in the longitudinal direction of the electrode surface is 1: 100 to 1:10.
As a result, bubbles generated by the cathodic reaction can float and approach the anode, and the electrolysis efficiency can be increased.
The cathode included in the electrolyzed water generator of the present invention is preferably a Ti electrode.
Since the Ti electrode can be manufactured at a relatively low cost, the manufacturing cost of the electrolyzed water generator can be reduced. Further, since the cathode is disposed below the electrode pair, hydrogen gas generated at the cathode can be prevented from being occluded by the Ti electrode, and the warpage of the Ti electrode can be suppressed.

The electrolytic solution used as the raw material for the electrolytic water is preferably an aqueous solution containing an acidic substance and an alkali metal chloride.
Thereby, electrolyzed water containing hypochlorous acid can be generated. Moreover, the electrolyzed water to produce | generate can be made into slightly acidic-neutrality, and the disinfection property of electrolyzed water can be made high.
It is preferable that the electrolyzed water generator of the present invention further includes a dilution unit that dilutes the electrolyzed water generated by the electrolysis unit.
By diluting the electrolyzed water produced by the electrolyzing unit in the diluting unit, the amount of electrolyzed water to be produced can be increased. Moreover, consumption of the electrolyte solution used as the raw material for the electrolyzed water can be suppressed.

The electrolyzed water generator of the present invention preferably further includes a cooling unit for cooling the electrode pair, and the cooling unit is preferably provided so as to cool the electrode pair with water for diluting the electrolyzed water.
Thereby, it can suppress that the temperature of an electrode pair becomes high with the reaction heat of an electrolysis reaction, and can suppress that electrolysis efficiency falls.
The electrolyzed water generator of the present invention preferably further includes an electrolyte solution supply unit and a detection unit, and the detection unit reduces the supply amount of the electrolyte solution supplied from the electrolyte solution supply unit to the electrolyte channel. It is preferable to detect. The electrolytic solution supply unit can be provided so as to supply the electrolytic solution stored in the tank to the electrolytic solution flow path.

By the way, when the amount of the electrolytic solution in the electrolytic section decreases due to the decrease in the supply amount of the electrolytic solution, the area of the electrode that is substantially in contact with the electrolytic solution and contributes to electrolysis, that is, the effective area of the electrode may be decreased. In particular, when the electrode pairs for electrolysis are inclined to an extent that is not conceivable by conventional common sense as in the present invention, the rate of change in the effective area of the electrode increases with respect to the same amount of electrolyte solution.
Therefore, it is desirable to provide a detector that can detect an abnormality more quickly than a conventional electrolyzed water generator.
Therefore, the detection unit includes a detection electrode for measuring the electrical characteristics of the electrolytic substance (electrolytic solution), the electrolysis product (electrolyzed water), or a mixture of both, and is supplied to the electrolysis unit. It is preferable to detect a decrease in the supply amount of the electrolytic substance (electrolytic solution) or a decrease in the discharge amount of the electrolysis product (electrolyzed water) discharged from the electrolysis unit.
In the present specification, it is possible to replace the electrolytic solution as one of the electrolytic substances and the electrolytic water as one of the electrolysis products.

Further, the detection electrode can be provided above the electrolysis electrode.
Alternatively, the detection electrode can be provided upstream of the electrolysis electrode.
Alternatively, the detection electrode can be provided on the downstream side of the electrolysis electrode and can be provided in the electrolysis unit or in a pipe connected to the electrolysis unit.
Furthermore, the detection electrode includes at least one pair of electrode pairs, and one electrode of the detection electrode pair can be electrically connected to the electrolysis electrode.
Furthermore, the detection electrode includes at least one pair of electrodes, and one electrode of the detection electrode pair can be formed integrally with the electrolysis electrode.
Furthermore, it is preferable that the detection electrodes are provided so as to be inclined.
Further, the detection electrode is preferably installed so as to measure the electrical characteristics of the gas-liquid mixed fluid of the gas generated by electrolysis of the electrolytic solution and the electrolytic water.
Furthermore, it is preferable that the detection unit detects a decrease in the supply amount of the electrolytic substance supplied to the electrolysis unit based on a change amount with time of a current-voltage characteristic applied to the detection electrode.
Furthermore, the detection unit supplies the electrolytic substance supplied to the electrolysis unit based on the differential value of the change amount of the voltage applied to the detection electrode or the differential value of the change amount of the current flowing through the detection electrode. Can be detected.

Further, the detection unit may detect a decrease in the supply amount of the electrolytic substance (electrolyte) supplied to the electrolysis unit based on a change amount of the current-voltage characteristic applied to the electrolysis electrode with time. .
Furthermore, the detection unit is configured to supply an electrolytic substance supplied to the electrolysis unit based on a differential value of a change amount of a voltage applied to the electrolysis electrode or a differential value of a change amount of a current flowing through the electrolysis electrode. You may detect a decrease in. If it is this detection part, the electrode for electrolysis and the electrode for a detection can be shared.
Accordingly, it is possible to detect a decrease in the supply amount of the electrolytic substance supplied to the electrolysis unit by the detection unit, and to quickly stop the application of voltage to the electrode pair. As a result, it is possible to prevent the electrode for electrolysis and other members constituting the electrolysis part from abnormally generating heat, and to improve the safety of the electrolysis apparatus. Moreover, it can suppress that the electrode for electrolysis and other members which comprise an electrolysis part are damaged, and can improve the lifetime characteristic of an electrolysis apparatus.
Thereby, it can be detected by the electrode for detection whether the electrolyzed water is normally produced | generated in the electrolysis part.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. The configurations shown in the drawings and the following description are merely examples, and the scope of the present invention is not limited to those shown in the drawings and the following description.

The electrolyzed water generator of the present embodiment includes the electrolyzed water generator of the first to seventh embodiments. FIG. 1 is a schematic cross-sectional view of the electrolyzed water generator of the first embodiment.
The electrolyzed water generator 25 of the present embodiment includes an electrolysis unit 5, and the electrolysis unit 5 is provided between an electrode pair 1 having an anode 3 and a cathode 4 disposed to face the anode 3, and between the anode 3 and the cathode 4. The electrode pair 1 is disposed so as to be inclined so that the anode 3 is on the upper side and the cathode 4 is on the lower side. Is provided so as to flow into the electrolyte flow path 7 from below, and electrolyzed water containing hypochlorous acid generated by the electrolytic solution 12 being electrolyzed by the electrode pair 1 flows out from the upper side of the electrolyte flow path 7. The electrode pair 1 is arranged so that the inclination angle with respect to the vertical direction is not less than 10 degrees and not more than 85 degrees.
In addition, the electrolyzed water generator 25 of the present embodiment includes a diluting unit 18 that dilutes the electrolyzed water generated by the electrolyzing unit 5, a cooling unit 34 that cools the electrode pair 1, an electrolytic solution supplying unit 13, a detecting unit 27, or an agitation. A portion 19 can be included.
In FIG. 1, in order to make the main components of the generator easier to understand, the generator is illustrated so as not to overlap in the depth direction, but by providing the discharge port of the electrolysis unit 5 in a direction extending in the flow direction between the electrodes, The height of the flow path 26, the dilution section 18, the flow path 24, the stirring section 19, the discharge port 29 and the height of the electrolysis section 5 can be arranged from the valve 16 through which the dilution water flows. Furthermore, the supply port of the electrolysis unit 5 is also provided in a direction extending in the direction of the channel between the electrodes, so that the supply channel 23, the electrolyte solution supply unit 13 (pump 15), and the bottom surface of the tank 11 are placed at the top of the electrolytic unit 5. It can be almost the same as the low position. Concerning the tank 11, it is convenient to make the generator 25 main body compact by attaching it externally and to select a tank according to the use scene such as a large capacity tank or a small capacity tank.
Thereby, the height of the inside of the generator can be lowered to almost the height of the electrolysis unit 5. Furthermore, by installing the electrolysis unit of the present invention at 80 degrees, it is possible to realize a generator having a height that was impossible in the past.
Hereinafter, the electrolyzed water generator 25 of this embodiment will be described.

The electrolyte solution supply unit 13 can be provided so as to supply the electrolyte solution 12 stored in the tank 11 to the electrolyte channel 7 by the pump 15. The tank 11 may be built in the electrolyzed water generator 25 or may be externally attached to the electrolyzed water generator 25. When the tank 11 is externally attached to the electrolyzed water generator 25, the electrolyzed water generator 25 can have an electrolyte inlet. Thus, the electrolyte solution inlet and the external tank 11 can be connected by piping. The electrolyte supply unit 13 may include at least one of a large capacity tank 11 and a normal capacity tank 11. Thereby, the capacity | capacitance of the tank 11 can be changed according to the use of the electrolyzed water generator 25. FIG.
In addition, when the tank 11 is arrange | positioned in the part higher than the electrolysis part 5, and the electrolyte solution 12 can be supplied to the electrolysis part 5 by gravity, a valve can be provided instead of the pump 15.

  The electrolyte solution 12 supplied from the electrolyte solution supply unit 13 to the electrolyte channel 7 can be an aqueous solution containing an acidic substance and an alkali metal chloride. Moreover, the electrolyte solution 12 may be an aqueous solution containing hydrochloric acid, acetic acid or citric acid and at least one of sodium chloride and potassium chloride. Thus, electrolyzed water containing hypochlorous acid (HClO), hypochlorite (NaClO, KClO, etc.) and alkali metal chloride can be generated by the electrolysis unit 5.

  The electrolysis unit 5 includes an electrode pair 1 having an anode 3 and a cathode 4 disposed opposite to the anode 3. The anode 3 and the cathode 4 can each be plate-shaped, and are provided so that the electrode surface 8 of the anode 3 and the electrode surface 9 of the cathode 4 are opposed to each other by a non-transparent film. Further, an electrolyte flow path 7 is formed between the electrode surface 8 of the anode 3 and the electrode surface 9 of the cathode 4. By providing the anode 3 and the cathode 4 in this way, the distance between the electrodes can be shortened and the electrolysis efficiency can be improved. Moreover, the anode 3 and the cathode 4 can be arrange | positioned so that it may become substantially parallel and the distance between electrodes may be in the range of 1 mm-10 mm. The electrode surface 8 of the anode 3 and the electrode surface 9 of the cathode 4 may be provided such that the planar electrode surfaces face each other, or the curved electrode surfaces may face each other.

The electrode pair 1 may be provided so that one anode 3 and one cathode 4 face each other, or the anode 3 and the cathode 4 may be provided so as to be alternately stacked. Alternatively, a plurality of electrodes may be stacked so that one surface of the intermediate electrode becomes the anode 3 and the other surface becomes the cathode 4.
For example, the electrode pair 1 can include an electrode made of a titanium plate (referred to as a Ti electrode) and an electrode obtained by coating a titanium plate with platinum and iridium by a sintering method (referred to as a Pt—Ir-coated Ti electrode). Further, the power supply unit and the electrode pair 1 can be connected such that the Ti electrode becomes the cathode 4 and the Pt—Ir-coated Ti electrode becomes the anode 3.

As in the electrolyzed water generator 25 shown in FIG. 1, the electrode pair 1 so that the supply flow path 23 of the electrolytic solution 12 is connected to the electrolytic solution flow path 7 and the electrolytic solution flow path 7 is connected to the electrolytic water flow path 24. May be provided. Further, the electrolysis unit 5 has an inlet through which the electrolyte 12 supplied from the electrolyte supply unit 13 flows into the electrolyte channel 7 and an outlet through which the electrolytic water flowing through the electrolyte channel 7 flows out. be able to. Thus, electrolyzed water can be continuously produced by the electrolysis unit 5. The electrolyzed water that has flowed out of the outlet may flow into the dilution section 18.
The electrode pair 1 may be immersed in the electrolytic solution 12 of the electrolytic bath or the dilution bath. In this case, the flow of the electrolytic solution 12 is generated by the rising of bubbles generated by the electrolysis in the electrode pair 1, and the electrolytic solution flow path 7 is formed.

For example, in the electrolytic treatment in the electrolysis unit 5, it is considered that the anodic reaction as in the chemical reaction formulas (1) and (3) proceeds and the cathodic reaction as in the chemical reaction formula (4) proceeds. Further, it is considered that the reaction represented by the chemical reaction formula (2) proceeds in the electrolysis unit 5, the dilution unit 18, the electrolyzed water flow path 24, the stirring unit 19, and the like. Therefore, the electrolyzed water generated in the electrolysis unit 5 becomes a gas-liquid mixed fluid in which bubbles such as chlorine gas and hydrogen gas are mixed with the electrolyzed water. Moreover, when the reaction of the chemical reaction formula (2) proceeds, bubbles are reduced and the concentration of hypochlorous acid in the electrolyzed water is increased. Since the reaction (2) is relatively quick, most of the generated chlorine molecules are converted into hypochlorous acid in the electrolysis unit 5. Since unconverted chlorine molecules are exposed to a large amount of water (H ₂ O) in the diluting section 20, the bubbles of chlorine gas almost disappear while flowing through the electrolytic water flow path.
Electrolysis of an aqueous solution containing an alkali metal chloride may produce hypochlorite such as sodium hypochlorite and potassium hypochlorite, and the electrolyzed water may become alkaline. Since 12 contains an acidic substance, the electrolyzed water is almost neutral.
The pH of the electrolyzed water produced by the electrolyzed water generator 25 can be set to 6.5 to 7.5, for example. Moreover, the ratio of the alkali metal chloride of the electrolyte solution 12 and an acidic substance can be adjusted so that pH of electrolyzed water may be 6.5-7.5.
Furthermore, when it is desired to make the pH more acidic, the ratio of the acidic substance contained in the electrolytic solution, the supply amount of the electrolytic solution to the electrolysis part, the voltage applied to the electrode for electrolysis, the amount of current flowing through the electrode for electrolysis, By adjusting, the pH of the electrolyzed water can be adjusted.

The electrode pair 1 is inclined and arranged so that the anode 3 is on the upper side and the cathode 4 is on the lower side. The electrolyte flow path 7 formed between the electrode surface 8 of the anode 3 and the electrode surface 9 of the cathode 4 is provided so that the electrolyte 12 flows into the electrolyte flow path 7 from below, and Electrolyzed water containing hypochlorous acid generated by electrolyzing the electrolyte solution 12 with the electrode pair 1 is provided so as to flow out from the upper side of the electrolyte channel 7. As a result, the fluid in the vicinity of the cathode 4 and the fluid in the vicinity of the anode 3 can be agitated and mixed by the flow of fluid caused by the rising of bubbles generated on the electrode surface 9 of the cathode 4, and the electrode reaction at the anode 3 is promoted. It is considered possible. For this reason, electrolyzed water with a high effective chlorine concentration can be produced.
Further, by disposing the cathode 4 on the lower side and generating a flow from the cathode 4 to the anode 3, chlorine gas, an oxidizing substance, hypochlorous acid, etc. generated by the anode reaction oxidize the electrode surface 9 of the cathode 4. It is considered that electrolyzed water containing hypochlorous acid can be efficiently generated. Moreover, since the oxidation of the electrode surface 9 of the cathode 4 can be suppressed, a Ti electrode can be used for the cathode 4, and the manufacturing cost of the electrolyzed water generator 25 can be reduced.
Further, since the hydrogen gas generated by the cathode reaction is easily desorbed from the electrode surface 9 of the cathode 4 by disposing the cathode 4 on the lower side, the effective area of the cathode is reduced due to bubbles remaining on the electrode surface 9 of the cathode 4. Can be suppressed, and a decrease in electrolytic efficiency can be suppressed. Further, when a Ti electrode is used for the cathode 4, it can be suppressed that hydrogen molecules are occluded in the Ti electrode and the cathode 4 is warped.

The electrode pair 1 is disposed such that the inclination angle with respect to the vertical direction is not less than 10 degrees and not more than 85 degrees. Moreover, it is preferable that the electrode pair 1 is arrange | positioned so that the inclination | tilt angle with respect to a perpendicular direction may be 50 to 80 degree | times. For this reason, the electrolyzed water containing hypochlorous acid can be produced | generated efficiently. This was verified by experiments conducted by the inventors. In addition, since the electrode pair 1 is sufficiently inclined, the height of the electrolyzed water generator 25 can be reduced, and the electrolyzed water generator 25 that can be stably installed can be realized. This can reduce the risk of the electrolyzed water generator 25 falling.
For example, an electrolytic part provided with a Pt—Ir-coated Ti electrode having a size of 50 mm × 100 mm × 0.5 mm and a Ti electrode at an interval of 4 mm was made as an experiment. The thickness of the entire electrolysis part was 16 mm, the length was 140 mm, and the electrode could be loaded by being divided almost in the vicinity of the center so that the flange was provided in the center, so the thickness of the flange part was 34 mm. When this electrolysis part was installed and installed at an angle of 80 degrees to produce an electrolyzed water generator, the height of the flange part was the highest and a height of 36 mm was required. If there is no flange, the height can be as high as 35 mm. When the other constituent members of the electrolyzed water generator were combined and housed in a resin housing having a thickness of 2 mm, an extremely thin generator of about 40 mm was achieved although the occupied area was relatively large.

The anode 3 preferably has a substantially rectangular electrode surface 8 and is disposed so that one end in the longitudinal direction of the electrode surface 8 is on the upper side and the other end is on the lower side. The cathode 4 preferably has a substantially rectangular electrode surface 9 and is arranged so that one end in the longitudinal direction of the electrode surface 9 is on the upper side and the other end is on the lower side. . Thereby, the electrolyte flow path 7 can be lengthened, and the electrolysis efficiency can be increased.
The electrode pair 1 is preferably provided so that the ratio between the distance between the anode 3 and the cathode 4 and the length in the longitudinal direction of the electrode surface 8 or 9 is 1: 100 to 1:10. As a result, bubbles generated by the cathodic reaction can float and approach the anode 3, and the electrolysis efficiency can be increased.

The detection unit 27 can be provided on the downstream side of the electrode pair 1. The detection unit 27 is provided so as to detect a decrease in the supply amount of the electrolyte solution 12 supplied from the electrolyte solution supply unit 13 to the electrolyte channel 7. The detection unit 27 can be provided at a position higher than the electrode pair 1.
The detection unit 27 may be a detection electrode 28 that measures the electrical characteristics (current, voltage, resistance, capacitance, etc.) of the electrolyzed water, and is a light detection unit that optically detects the state of the electrolyzed water. There may be. However, the detection unit 27 is preferably a simple system. Since the capacitance and optical detection methods are non-contact and do not need to consider the influence of electrolyzed water, they can be easily adopted as detection means, but require special parts and control circuits. In the case of a detection electrode, the conditions of appropriate voltage and current differ depending on the target.In addition, in the present invention, since an electrolyte solution containing an electrolyte is a target, detection by the electrode is considered to be difficult as a general knowledge of those skilled in the art. It was not converted. In other words, since the electrolytic solution is electrolyzed by the voltage or current for detection, the electrical characteristics of the electrolytic solution itself cannot be obtained, and the electrolytic water generated by electrolysis is a reactive liquid (for example, hypochlorous acid water). In the case of an oxidative liquid such as hypochlorite water), it is thought that the electrode itself is oxidized and changes, so that it is not stable or a practical life cannot be secured. It was. For this reason, it has been considered that it is difficult to realize an inexpensive and long-life detector using an electrode for use in a generator for regular use for a long period of time. Actually, even in the examination by the inventors, the installation position of the electrode and the size of the flow path at the installation position have to be selected appropriately, and the invention has not been easily achieved. For example, when a detection area with a relatively large cross-sectional area of the flow path is provided in order to install an electrode in the flow path, the gas-liquid is separated and a liquid film is not formed. Liquid film) could not be detected. If the flow path diameter is relatively small so that the liquid film does not break, or if the electrodes are relatively narrowly installed, the liquid film remains stretched between the electrodes due to surface tension, and bubbles are detected. could not. In any case, a clear current peak could not be detected, and the steady state and the abnormal state could not be distinguished early.

When the electrolytic solution 12 stored in the tank 11 is supplied to the electrolysis unit 5 by the pump 15 to produce electrolytic water, if the electrolytic water is continuously produced, the electrolytic solution 12 stored in the tank 11 gradually decreases, Become empty. When the tank 11 is emptied, the electrolytic solution 12 may not be supplied to the electrolysis unit 5, and the electrolytic solution 12 may decrease or disappear between the electrode pairs 1. Alternatively, even if the tank 11 is not empty, the pump 15 fails or a liquid leak occurs between the tank 11 and the electrolysis unit 5, so that the electrolytic solution 12 is not sufficiently supplied to the electrolysis unit 5, and the electrode pair 1 There may be a case where the electrolyte 12 decreases or disappears in the meantime. When a voltage is applied to the electrode pair 1 in such a state, the cooling effect by the electrolyte supplied continuously and the heat released together with the generated electrolyzed water disappear, so the heat in the electrolysis unit 5 rises. Since the current flows only in a part of the electrodes, in the case of a constant current, the current density may increase and the electrode pair 1 may be damaged. Therefore, it is necessary to detect that the supply of the electrolyte solution 12 between the electrode pair 1 is insufficient and to stop applying the voltage to the electrode pair 1.
When the detection unit 27 is provided, the detection unit 27 can detect that the tank 11 is emptied, the pump 15 is malfunctioning, or the pipe between the tank and the electrolysis unit is leaked or clogged. Application of voltage to can be stopped early. For this reason, it can suppress that the electrode pair 1 is damaged.
Note that when the electrolytic solution 12 is not sufficiently supplied to the electrolysis unit 5, the electrolytic solution 12 or the electrolytic water disappears from a portion where the flow path is high. Therefore, by providing the detection unit 27 at a position higher than the electrode pair 1, it can be detected early that the electrolytic solution 12 is not sufficiently supplied to the electrolysis unit 5.

  Fig.2 (a) is a schematic sectional drawing of a part of the electrolyzed water generator 25 of 2nd Embodiment. FIG.2 (b) is a schematic sectional drawing of a part of the electrolyzed water generator 25 of 3rd Embodiment. FIG.2 (c) is a schematic sectional drawing of a part of the electrolyzed water generator 25 of 4th Embodiment. FIG.2 (d) is a schematic sectional drawing of a part of the electrolyzed water generator 25 of 5th Embodiment. FIG.2 (e) is a schematic sectional drawing of a part of the electrolyzed water generator 25 of 6th Embodiment. The detection electrode 28 may be, for example, an electrode pair provided in a pipe between the electrolysis unit 5 and the dilution unit 18 as in the second embodiment shown in FIG. The electrode pair provided in the flow path in the electrolysis unit 5 may be used as in the third embodiment shown in FIG. 2), and the electrode pair 1 may be placed above the electrode pair 1 as in the fourth embodiment shown in FIG. It may be an electrode pair provided. As in the fifth embodiment shown in FIG. 2D, the detection unit 27 measures the electrical characteristics of the electrolyzed water with one electrode included in the electrode pair 1 and the detection electrode 28. Also good. Further, the detection unit 27 measures the electrical characteristics of the electrolyzed water with one electrode included in the electrode pair 1 and the detection electrode 28 as in the sixth embodiment shown in FIG. There may be.

When the electrolytic solution 12 is electrolyzed by the electrode pair 1, chemical reactions such as the above chemical reaction formulas (1) to (4) proceed, so that the electrolytic water generated by the electrode pair 1 is mixed with the gas-liquid mixed fluid. Become. When the electrical characteristics of the gas-liquid mixed fluid are measured by the detection electrode 28, when bubbles pass through the detection electrode 28, the electrical resistance between the electrodes increases and the current flowing between the electrodes increases. Further, when the liquid passes through the detection electrode 28, the electrical resistance between the electrodes becomes small and the current flowing between the electrodes becomes small. For this reason, when electrolyzed water is normally generated by the electrode pair 1, the electrical resistance measured by the detection electrode 28 moves up and down. Therefore, it can be confirmed that the electrolyzed water is normally generated by detecting this vertical movement. Also, by detecting that this vertical movement has been lost, it is possible to detect abnormalities such as whether the tank has been emptied, the liquid pump has failed, piping has been clogged, or liquid leakage has occurred. it can.
The width between the electrodes of the detection electrode 28 can be set to 1 mm to 5 mm, for example. Thereby, the flow of electrolyzed water can be confirmed.
Here, although the flow of electrolyzed water is detected using the detection electrode 28, the detection unit 27 may be a light detection unit that optically detects the flow of electrolyzed water.

  In addition to the permissible range (set value) of the voltage or current of the electrode for electrolysis, the detection unit provides a permissible range for the amount of change with time of the voltage or current of the electrode for electrolysis or both. The detection unit can detect an abnormality based on a differential value of the voltage value or current value of the electrode for electrolysis (here, the differential value indicates an average change amount per time). In this case, the detection unit is included in the control unit. Even in the detection unit of another detection system, it is preferable that the detection unit is included in the control unit because it can be integrated into one substrate circuit, and the size and cost can be reduced.

  For example, a constant current source or a constant voltage source is connected to the electrode for detection, and abnormalities are detected by distinguishing the amount of change in the voltage or current value within a certain period of time between normal and abnormal conditions. To do. An allowable range is provided for the amount of change with time of voltage and / or current. That is, the differential value of the voltage value or the current value (here, the differential value refers to an average change amount per time and can also be called a slope) is detected. The voltage value or current value can be detected by a conventional method. The differential value can be made a differential value by sampling the voltage value or the current value at a certain time interval and taking the difference. However, if the time is too short, an abnormality is erroneously detected due to the influence of noise or the like, and therefore it is preferable to calculate the difference in a time such as 10 seconds to 1 minute.

  The detection electrode of this detection system utilizes the fact that the differential value is almost zero in a steady state. For example, if the detection electrode is provided at a position closer to the electrolytic solution supply port than the electrolytic electrode, the relationship between the voltage and the current according to the electrical characteristics of the electrolytic solution is maintained. For example, when the supply of electrolyte is abnormally stopped, if the electrode is provided at a position close to the electrolyte supply port in the electrolysis unit, the electric voltage of the electrolyzed water in which the electrolyte has been electrolyzed by the electrode for electrolysis Get closer to the relationship. In this process, a state where the differential value is not 0 occurs, so that an abnormality can be detected. In the case where a detection electrode is provided in the pipe closer to the electrolytic solution tank or in the middle of the pipe than the electrolysis section, the differential value is not zero as the electrolysis proceeds near the detection electrode through the detection electrode. Can be detected.

  If the detection electrode is provided at a position closer to the electrolyte outlet than the electrolysis electrode, the relationship between the voltage and the current according to the electrical characteristics of the electrolyzed water is maintained. For example, when the supply of the electrolyte is abnormally stopped, if it is provided in the electrolytic section and at a position close to the discharge port of the electrolyte, the electrode for electrolysis causes an electrical specific voltage of the electrolyzed water that is excessively electrolyzed by the electrolyte. It approaches the relationship of current. In this process, a state where the differential value is not 0 occurs, so that an abnormality can be detected. If the electrode for detection is provided in the piping near the discharge port of electrolytic water further than the electrolysis section or in the middle of the piping, the electrolysis water near the detection electrode is interrupted or the electrolysis proceeds further by the detection electrode. Abnormalities can be detected because a non-zero value occurs.

If the detection electrode is provided at the same position as the electrode for electrolysis, the relationship between the voltage and the current according to the electrical characteristics of the electrolyte during electrolysis is maintained. For example, when the supply of the electrolyte is abnormally stopped, the relationship between the electrical specific voltage and current of the electrolyzed water in which the electrolysis of the electrolyte is excessively increased by the electrode for electrolysis is approached. In this process, a state where the differential value is not 0 occurs, so that an abnormality can be detected.
In addition, when providing the electrode for a detection in an electrolysis part, a part or all can be shared with the electrode for electrolysis, and it can also share a power supply also with the power supply for electrolysis.

  As another example of the detection unit, a detection electrode different from the electrode for electrolysis is provided as the detection unit. The detection electrode is provided above the electrolysis electrode. When the supply of the electrolyte is interrupted or insufficient, a change in electrical conductivity or the like in the vicinity of the detection electrode is detected. Specifically, a decrease in current value when the water level of the electrolytic solution in the electrolysis section decreases is detected. A pair of detection electrodes may be provided, but if one of the electrolysis electrodes is shared by the electrolysis electrode and the detection electrode, the number of parts can be reduced. Furthermore, if the power supply unit is shared, the power supply for the detection unit can be omitted. Even in the electrode for electrolysis, the effective area of the electrode decreases due to a decrease in the water level, so that the current value decreases or the voltage value increases. However, the rate of change (ratio of change value to the total value) and S / N value are small, and the conventional There is a problem similar to the method. Therefore, for example, an abnormality can be detected by providing a slit on the upper side of the electrode for electrolysis and separating a part thereof, providing a separate wiring, and measuring a current value flowing through the wiring. The current value can be measured by various conventional methods such as measuring the voltage of the shunt resistor.

  As yet another example of the detection unit, the detection unit similarly includes a detection electrode as a detector, but is closer to the supply port of the electrolytic substance (electrolyte) than the electrode for electrolysis (electrolyte supply port of the electrolysis unit). Get ready. Thus, by detecting the difference between the electrical characteristics of the electrolytic substance and the electrical characteristics of the electrolytic product (electrolyzed water), it is possible to detect whether the supply of the electrolytic substance (electrolytic solution) is interrupted or insufficient. In a steady state, a value relatively close to the electrical characteristics of the electrolytic substance (electrolytic solution) can be obtained, but in an abnormal state, a value relatively close to the electrical characteristics of the electrolytic product (electrolyzed water) can be obtained, and an abnormality can be detected.

In another example of the detection unit, the detection unit similarly includes a detection electrode as a detector, but is closer to the discharge port of the electrolysis product than the electrolysis electrode (discharge port of the electrolysis unit 5 in the case of electrolysis). Or it is provided in the middle of the discharge port, the piping connected to the discharge port, or the piping.
In this way, by detecting the difference between the electrical characteristics when the electrolytic product (electrolyzed water) is continuously sent to the detector and when it is not (that is, when electrolyzed water is not sent), It is possible to detect that the supply of electrolytic substance (electrolytic solution) has stopped. In addition, even when the electrolyte is being sent, abnormalities such as the amount of electrolyzed water being discharged from the electrolysis unit less than usual or not being discharged at all due to damage to the electrolysis unit are also detected. it can.
Furthermore, by detecting the difference between the normal electrical characteristics when the electrolytic product (electrolyzed water) is continuously sent to the detector and the electrical characteristics when the electrolytic substance (electrolyte) is being sent. Even if the supply of the electrolytic substance (electrolytic solution) is normal, an abnormality such as insufficient electrolysis or electrolysis can be detected.

Further, the detection electrode can also serve as at least a part of the electrode for electrolysis. In this case, since the number of parts is reduced and the cost is reduced, the practicality is increased, which is preferable. Furthermore, it is preferable to provide the detection electrode pair with an inclination because the detection sensitivity is improved. It is further preferred that the electrolysis unit comprises a cooling system, in particular a water cooling system.
If the electrode section for detection and the electrode pair for electrolysis are provided in parallel in the electrolysis section, the holding section for holding the electrode pair for detection and the electrode pair for electrolysis can be simultaneously molded as the electrolysis section, so that the cost is low. Can be Further, it is preferable to install the electrolysis part having both the detection electrode pair and the electrolysis electrode pair in parallel, since the detection sensitivity can be improved and the electrolysis efficiency can be improved at the same time. Furthermore, since the temperature of the detection electrode and the electrode for electrolysis is stabilized by providing the water cooling system, a highly reliable detection system and electrolysis system can be realized. This is due to the fact that the electrical properties and chemical reactions of substances generally have temperature dependence. A detector using an electrode uses the electrical characteristics of a substance, and electrolysis uses an electrochemical reaction. Therefore, it is preferable that the temperature is stable, and it is preferable to provide a cooling system.

The dilution unit 18 is provided so as to dilute the electrolyzed water generated by the electrolysis unit 5 with water. As a result, electrolyzed water having an appropriate effective chlorine concentration can be generated, and this electrolyzed water can be discharged from the discharge port 29.
Further, by diluting the electrolyzed water generated by the electrolyzing unit 5 with the diluting unit 18, the amount of electrolyzed water to be manufactured can be increased. The water used for dilution is, for example, tap water, well water, or stored water. When the electrolyzed water is diluted with tap water, the tap water can be supplied to the diluting section 18 by the valve 16 connected to the faucet. Further, when the electrolytic water is diluted with well water or stored water, the well water or the stored water can be supplied to the dilution unit 18 by a pump that pumps the well water or the stored water. It is possible to electrolyze after diluting the electrolyte, but mineral components etc. contained in the diluting water are deposited on the electrode for electrolysis and the electrolysis ability is reduced, or the components contained in the diluting water are electrolyzed. The concentration and pH of the electrolyzed water may vary. Therefore, it is preferable to dilute with a diluting water such as tap water after the electrolytic solution is electrolyzed in the electrolysis section as in this embodiment.

The dilution unit 18 may be provided so that the flow of electrolyzed water generated by the electrolysis unit 5 merges with the flow of water to be diluted. In this case, the diluting part 18 can be provided so that the flow of electrolyzed water generated by the electrolyzing part 5 merges with the flow of water flowing in a substantially horizontal direction. Moreover, the dilution part 18 may be provided so that the electrolyzed water produced | generated in the electrolysis part 5 may be attracted | sucked by the venturi effect produced by the flow of the water to dilute.
Moreover, the dilution part 18 may be provided so that it may dilute in the dilution tank into which the electrolyzed water produced | generated by the electrolysis part 5 and the water to dilute flow. The dilution unit 18 may be a dilution tank, and the electrode pair 1 may be provided in the dilution tank. In this case, the electrolytic solution diluted in the dilution tank can be stored, and the stored electrolytic solution can be electrolyzed by the electrode pair 1 to generate electrolytic water.

An electrolyzed water generator 25 may be provided so that the amount of water diluted in the dilution section 18 can be changed. For example, a valve 16 or a pump can be provided so that the amount of water supplied to the dilution unit 18 can be changed. Thus, electrolyzed water having different effective chlorine concentrations can be generated, and the effective chlorine concentration of the electrolyzed water can be changed depending on the use of the electrolyzed water.
Moreover, a control part can be provided so that normal concentration electrolyzed water and high concentration electrolyzed water can be switched. The control unit can switch the concentration of the electrolyzed water by controlling the valve 16 or the pump. For example, the effective chlorine concentration of electrolyzed water having a normal concentration can be 15 to 25 ppm, and the effective chlorine concentration of high concentration electrolyzed water can be 45 to 55 ppm.
Further, it is more preferable to provide a needle valve instead of the switching type electromagnetic valve. In the case of a needle valve, the flow rate can be changed continuously, so that an electrolyzed water having an arbitrarily higher concentration can be generated continuously from the lowest concentration at the maximum flow rate.

  The cooling part 34 which cools the electrolysis part 5 with the water which dilutes electrolyzed water can be provided. As a result, it is possible to suppress the temperature of the electrolysis unit 5 from being increased due to heat generated by the electrical resistance of the electrode or the liquid resistance of the electrolytic solution or reaction heat of various chemical reactions occurring in the electrolysis unit. It is possible to suppress variations in concentration and a decrease in the life of the electrolysis unit and the electrode due to heat. The cooling unit 34 can be, for example, a cooling water flow path 33 through which diluted water flows. Thereby, the flow path through which the cooling water flows can be integrally manufactured as an electrolysis part, and an increase in extra parts and attachment work can be suppressed, which is preferable.

FIG. 3 is a schematic sectional view of a part of the electrolyzed water generator 25 of the seventh embodiment. In the cooling water flow path 33, for example, tap water flows into the cooling water flow path 33 from the cooling water inlet 36 provided in the upstream part of the dilution section 18 as in the seventh embodiment of FIG. After the tap water flows, the tap water can be provided so as to flow out from the cooling water outlet 37 provided in the downstream portion of the dilution section 18. Thus, by providing the cooling water flow path 33, the electrolysis part 5 can be cooled using the tap water used for dilution of electrolyzed water.
The cooling water flow path 33 may be provided in the structural member 20 of the electrolysis unit 5 as shown in FIG. 3, or may be a pipe provided around the electrolysis unit 5.

  The electrolyzed water generator 25 can include a stirring unit 19. The agitating unit 19 is provided so that the electrolyzed water diluted by the diluting unit 18 flows into the agitating unit 19 and the electrolyzed water flowing out from the agitating unit 19 is supplied to the discharge port 29. By providing such a stirring unit 19, the chlorine gas that could not be converted into hypochlorous acid by the electrolysis unit 5 and the dilution unit 18 can be converted into hypochlorous acid. As a result, the pH and effective chlorine concentration of the electrolyzed water discharged from the discharge port 29 can be stabilized, and electrolyzed water having a stable quality can be generated. The stirring unit 19 may be a water tank in which a turbulent flow is generated, or may be a stirring tank provided with a stirring bar.

Experiment for Measuring Effective Chlorine Concentration An electrolysis apparatus such as the electrolysis unit 5 included in the electrolyzed water generator 25 shown in FIG. 1 was produced, and an electrolysis experiment was performed by changing the inclination angle of the electrode pair 1 with respect to the vertical direction. The electrode pair 1 is made by sintering platinum and iridium on an electrode made of a 1 mm thick titanium plate having a long side of 8 cm and a short side of 3 cm (referred to as a Ti electrode) and a 1 mm thick titanium plate having a long side of 8 cm and a short side of 3 cm. (Hereinafter referred to as “Pt—Ir-coated Ti electrode”). The electrode pair 1 was fixed to the structural member 20 made of vinyl chloride resin so that the Ti electrode and the Pt—Ir-coated Ti electrode were substantially parallel and the distance between the electrodes was in the range of 1 mm to 5 mm, and an electrolytic device was produced. Further, the power supply device and the electrode pair 1 were connected so that the Ti electrode became a cathode and the Pt—Ir-coated Ti electrode became an anode.
An electrolytic device produced by changing the installation angle was installed so that the inclination angle of the electrode pair 1 with respect to the vertical direction was about −80 degrees to about +80 degrees, and 2-4% sodium chloride and A mixed aqueous solution of 0.3 to 0.4% hydrochloric acid was supplied from the lower side at a constant flow rate. When the electrode pair 1 is vertical, the inclination angle is 0 degree, and when the electrode pair 1 is inclined so that the Pt—Ir-coated Ti electrode (anode) is on the upper side, the inclination angle is a positive angle. When the electrode pair 1 is tilted so that the Pt—Ir-coated Ti electrode is on the lower side, the tilt angle is a negative angle.
Then, a constant current of 5 A was supplied to the electrode pair 1 by the power supply device, and the mixed aqueous solution of sodium chloride and hydrochloric acid was subjected to electrolytic treatment. The applied voltage was between about 4-5V. Moreover, the effective chlorine concentration (mg / L) of the aqueous solution after electrolytic treatment was measured. Since the measurement method of the effective chlorine concentration was evaluated by a color reaction by oxidation, the effective chlorine concentration in the present example refers to a value obtained by evaluating the amount of all reactive substances having oxidizing power as the effective chlorine concentration.

The measurement result of the effective chlorine concentration experiment is shown in FIG. The effective chlorine concentration shown in FIG. 4 is the effective chlorine concentration when normalized to 1 L dilution. According to this result, when the electrode pair 1 is tilted so that the Pt-Ir-coated Ti electrode as the anode is on the upper side, the effective chlorine concentration of the aqueous solution after electrolytic treatment is increased within the tilt angle range of 20 to 80 degrees. I was able to. In particular, 50 to 80 degrees was high. Although not shown, a high density was shown even at 85 degrees, but there was a tendency for density variation to increase, for example, the density occasionally decreased.
Conversely, when the electrode pair 1 was tilted so that the Pt—Ir-coated Ti electrode as the anode was on the lower side, the effective chlorine concentration of the aqueous solution after the electrolytic treatment decreased.
Therefore, it was found that the effective chlorine concentration of the generated electrolyzed water can be increased by arranging the electrode pair 1 so that the anode is on the upper side and the cathode is on the lower side.

  In FIG. 4, the density increases roughly slowly on the positive angle side from 0 degrees or becomes almost constant at 50 degrees or more, and the density rapidly decreases on the minus angle side from 0 degrees, and almost decreases at minus 50 degrees or less. It is constant. Therefore, it is preferable that the electrode pair is tilted by 0 degree or more so that the anode side is on the upper side. However, even if the mounting accuracy of the electrode pair is a little sweet, or the generator itself equipped with this electrode pair is placed on a slightly inclined ground or the like, a margin of about 10 degrees is allowed so that the generated concentration does not decrease. It is preferable to attach it by tilting more than once. Conversely, if it is installed at 80 degrees, it will be 90 degrees if it is further tilted by 10 degrees, so it is preferable to keep it at 75 degrees. Therefore, it is preferable to arrange in the range of 10 to 75 degrees. For example, when it is considered to be used on an outdoor slope, etc., if it is further set to about 50 degrees, a concentration higher than 0 degrees will be obtained even if it is inclined ± 30 degrees. Can be discharged. Therefore, the electrolyzed water generator should be placed horizontally when it is used for spraying plants or sanitizing soils on steep slopes of 30 degrees, such as mandarin oranges and vineyards, and other slopes. Can be used without having to worry about each and every time. In the case of using for such a plant, it is preferable to use an aqueous potassium chloride solution, hydrochloric acid or a mixture thereof as an electrolytic solution.

Electrolyzed water detection experiment An electrolysis unit 5 as shown in FIG. 2C was prepared, and an experiment was performed in which the electrolyzed water generated by the electrode pair 1 was detected by the detection electrode 28. If the depth direction in the drawing is the width of the flow path, the portion with the electrode for electrolysis is about 50 mm, which is almost the same as the width of the electrode for electrolysis, but the width of the portion with the electrode for detection is about 3 mm. It is a narrow channel. This is based on the basic principle of detecting gas and liquid in this embodiment, as will be described later. Therefore, if the flow path is not relatively thin, the gas and liquid will be separated, or the interval between the gas and liquid will be too short. This is because it becomes difficult. Electrode for detection The size of the effective surface of the electrode for detection is 3 mm × 3 mm, and the distance between the electrodes is 2 mm. Moreover, the same material as the electrode for electrolysis was used as an electrode material. Experimental results are shown in FIGS.
FIG. 5 is a graph showing a change in detection current of the detection electrode 28 when the electrolytic solution 12 supplied to the electrolysis unit 5 is electrolyzed by the electrode pair 1 to generate electrolyzed water. It was found that when the electrolyzed water is normally generated, the detection current of the detection electrode 28 moves up and down. Further, it was found that the time during which the detection current is small is 5 seconds or less. This is considered to be because bubbles of chlorine gas or hydrogen gas generated by electrolysis and electrolytic water alternately pass through the detection electrode 28. Therefore, it has been found that whether or not the electrolyzed water is normally generated can be detected by detecting whether or not the detection current is moving up and down. Further, it was found that it is possible to detect that the electrolytic solution 12 is not supplied to the electrolysis unit 5 by detecting that the state where the detection current is small continues for 5 seconds or more.

FIG. 6 is a graph showing changes in the detection current of the detection electrode 28 when the supply of the electrolytic solution 12 to the electrolysis unit 5 is stopped. When the supply of the electrolyte solution 12 was stopped, the vertical movement of the detected current was not measured about 5 seconds after the supply stop. From this, it was found that the supply stop of the electrolyte solution 12 can be detected early by the detection electrode 28.
Similarly, as shown in FIG. 2 (a), a structure in which a detection electrode is provided in a pipe from the electrolytic cell to the discharge port may be employed. When the experiment was conducted with the inner diameter of the pipe being about 3 mm, similar results were obtained.

  1: Electrode Pair 3: Anode 4: Cathode 5: Electrolysis Unit 7: Electrolyte Flow Channel 8: Anode Electrode Surface 9: Cathode Electrode Surface 11: Tank 12: Electrolyte 13: Electrolyte Supply Unit 15: Pump 16: Valve 18 : Dilution section 19: Stirring section 20: Structural member 22: Housing 23: Supply flow path 24: Electrolytic water flow path 25: Electrolyzed water generator 26: Tap water flow path 27: Detection section 28: Electrode for detection 29: Discharge port 33 : Cooling water flow path 34: Cooling part 36: Cooling water inlet 37: Cooling water outlet

Claims (9)

An electrolysis unit, and an electrolyte supply unit,
The electrolysis unit includes an electrode pair having an anode and a cathode disposed opposite to the anode, and a diaphragm-type electrolyte flow path between the anode and the cathode,
The electrolyte channel is a channel composed of a single line of linear channels inclined in one direction,
The electrode pair is arranged so that the plate-like anode and the cathode are inclined such that the anode is on the upper side and the cathode is on the lower side,
The electrode pair is arranged so that an inclination angle with respect to a vertical direction is not less than 10 degrees and not more than 85 degrees,
The electrode pair is provided such that a ratio of a distance between the anode and the cathode and a length in a longitudinal direction of the electrode surface is 1: 100 to 1:10.
The electrolytic solution generator, wherein the electrolytic solution supply unit includes a pump that supplies the electrolytic solution to the electrolytic solution flow path.   The electrolyzed water generator according to claim 1, wherein the electrode pair is disposed so that an inclination angle with respect to a vertical direction is not less than 50 degrees and not more than 80 degrees.   2. The anode and the cathode have a substantially rectangular electrode surface, and are arranged so that one end in the longitudinal direction of the electrode surface is on the upper side and the other end is on the lower side. Or the electrolyzed water generator of 2.   The electrolyzed water generator according to claim 1, wherein the cathode is a Ti electrode.   The electrolyzed water generator according to any one of claims 1 to 4, wherein the electrolytic solution is an aqueous solution containing an acidic substance and an alkali metal chloride.   The electrolyzed water generator according to any one of claims 1 to 5, further comprising a dilution unit that dilutes the electrolyzed water generated by the electrolysis unit. A cooling unit for cooling the electrode pair;
The electrolyzed water generator according to claim 6, wherein the cooling unit is provided to cool the electrode pair with water for diluting electrolyzed water. A detection unit;
The detection unit includes a detection electrode for measuring electrical characteristics of the electrolytic solution or electrolytic water or a mixture of both, and a decrease in the amount of electrolytic solution supplied to the electrolytic unit or from the electrolytic unit The electrolyzed water generator as described in any one of Claims 1-7 which detects the fall of the discharge | emission amount of the electrolyzed water discharged | emitted. A detection unit;
The detection unit according to any one of claims 1 to 7, wherein the detection unit detects a decrease in the supply amount of the electrolytic solution supplied to the electrolysis unit based on a change amount with time of a current-voltage characteristic applied to the electrode pair. An electrolyzed water generator.