JP3936467B2 - Electrolyzed water generator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electrolyzed water generating apparatus for continuously supplying water to be treated, in which a predetermined electrolysis promoter is added to raw water, to an electrolyzer and electrolyzing the electrolyzer to obtain acidic water and alkaline water.
[0002]
[Prior art]
Conventionally, a predetermined electrolysis promoter is added to the raw water to continuously supply the water to be treated, which contains more chlorine ions than the raw water, to the electrolytic cell, and using a constant current source or a constant voltage source There is known an electrolyzed water generating device that electrolyzes water to be treated by passing a current in a predetermined direction between a pair of electrodes in an electrolyzer. In this type of electrolyzed water generating apparatus, when a current in a certain direction flows between the electrodes over a long period of time, scales such as calcium and magnesium contained in the water to be treated adhere to the electrodes, and the electrolyzed water generating ability decreases. For this reason, the scale is removed and cleaned by reversing the current direction between the electrodes.
[0003]
This reversal of the current direction is effective for removing the scale, but if it is performed too frequently, there are adverse effects such as reducing the life of the electrode. Therefore, it can be said that it is desirable to reverse the current direction when the amount of scale adhesion reaches a predetermined amount (allowable limit amount). Therefore, in the apparatus disclosed in Japanese Utility Model Publication No. 2-7676, when the integrated amount of current (electrolytic current) flowing between the electrodes reaches a predetermined amount, control is performed to reverse the voltage application direction to the electrodes. ing.
[0004]
[Problems to be solved by the invention]
However, the conventional control device has a problem that the inversion timing in the current direction is not necessarily the optimum timing. This does not take into account the concentration of calcium, magnesium, etc. contained in the water to be electrolyzed, so the amount of scale adhesion at the time when the integrated amount of electrolysis current reaches a predetermined amount is not always constant. It is.
Accordingly, an object of the present invention is to integrate the amount reflecting the concentration of calcium or the like in the water to be treated, that is, the amount corresponding to the chlorine ion, and reverse the current direction at the optimal timing based on the integrated amount. An object of the present invention is to provide an electrolyzed water generating apparatus that does not have a decrease in electrolyzed water generation capability and a decrease in electrode life.
[0005]
SUMMARY OF THE INVENTION
The treated water that is electrolyzed by the electrolyzed water generating device of the present invention is obtained by adding an electrolysis promoter to raw water. Electrolysis promoters are those that dissolve in raw water (solvent) to increase the electrical conductivity of the raw water, but in the present invention, such as sodium chloride (salt) or potassium chloride dissolves in the raw water and chloride ions It will cause. Since these electrolysis promoters contain impurities such as magnesium and calcium, the scales attached to the electrodes differ depending on the concentration of the electrolysis promoter.
[0006]
On the other hand, the electrolytic current is due to the movement of ions in the water to be treated, but the ions that move (adsorbed on the anode) are chloride ions (Cl ⁻ ), hydroxide ions (OH ⁻ ), and other impurity ions. It is. The higher the concentration of the electrolysis promoter, the higher the concentration of chlorine ions, and the greater the contribution of chlorine ions to the same electrolysis current. Therefore, the amount corresponding to chlorine ions adsorbed on the anode under the same electrolysis current has a strong correlation with the concentration of the electrolysis promoter. For this reason, if the amount corresponding to the chlorine ions adsorbed on the electrode is known, the amount of scale adhering to the electrode (particularly the cathode) can also be known. Further, in the case where the concentration of the electrolysis promoter is constant, the larger the electrolysis current, the larger the amount corresponding to chlorine ions adsorbed on the anode, and the larger the amount of scale attached to the electrode.
[0007]
Based on the above knowledge, the present invention continuously supplies treated water containing a predetermined amount of electrolytic promoter to raw water and containing more chlorine ions than raw water to an electrolytic cell containing a pair of electrodes. In an electrolyzed water generating apparatus that electrolyzes water to be treated by passing a current in a predetermined direction between electrodes, integrating means for integrating the amount of effective chlorine adsorbed on an electrode serving as an anode of a pair of electrodes, The present invention is characterized by comprising current direction reversing means for switching the current flowing between the electrodes in a direction opposite to the predetermined direction when the amount of effective chlorine exceeds a predetermined value.
[0008]
In the present invention, it is integrating detects the effective chlorine amount as an amount corresponding to the chlorine ion adsorbed on the electrode. The effective chlorine amount here is the amount (number of moles) of hypochlorous acid (HOCl) and chlorine (Cl ₂ ) produced by electrolysis, and has a good correlation with the amount of chlorine ions adsorbed on the anode. .
[0009]
According to the feature of the present invention, it is possible to accurately estimate the amount of scale adhering to the electrode even when the electrolytic water concentration, the electrolytic current value, etc. fluctuate. Therefore, the electrode life can be improved without reducing the electrolyzed water generating ability of the electrolyzed water generating device.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
The electrolyzed water generating apparatus according to the embodiment of the present invention shown in FIG. 1 includes a concentrated salt water tank 10 that stores saturated salt water in a saturated state, and a diluted salt water tank 20 that is provided below the tank 10 and stores diluted salt water. , An electrolytic cell 30 for electrolyzing the diluted salt water supplied from the diluted salt water tank 20, a switching valve 40, a control circuit 50, a power source 60, and the like.
[0011]
The concentrated salt water tank 10 is replenished with a large amount of electrolysis promoter such as sodium chloride and potassium chloride, and raw water is pumped from an unillustrated external water source (for example, tap water) through a water supply pipe 11. . The water supply pipe 11 is provided with an electromagnetic water supply valve 12. The valve 12 receives an ON signal from the control circuit 50, opens the flow path of the water supply pipe 11, and supplies raw water from an external water supply source to the concentrated salt water tank 10. To supply.
[0012]
A water level switch 13 for measuring the level of concentrated salt water is accommodated in the concentrated salt water tank 10. The water level switch 13 detects when the water level of the concentrated salt water is equal to or higher than the predetermined upper limit water level, when it is between the upper limit water level and the lower limit water level lower than the upper limit water level, and when it is lower than the lower limit water level, and the detection results thereof. A signal corresponding to is generated.
[0013]
In the concentrated salt water tank 10, a concentrated salt water supply pipe 14 for supplying concentrated salt water to the diluted salt water tank 20 penetrates upward at the bottom of the tank 10. The upper end portion of the concentrated salt water supply pipe 14 opens at a position lower than the above-described lower limit water level, and the lower end portion opens downward at a predetermined position in the diluted salt water tank 20. The concentrated salt water supply pipe 14 is provided with a pinch valve (electromagnetic) 15. The pinch valve 15 receives an ON signal from the control circuit 50 and opens the flow path of the concentrated salt water supply pipe 14. The concentrated salt water is supplied dropwise to the diluted salt water tank 20.
[0014]
In addition to the concentrated salt water supplied from the concentrated salt water tank 10, raw water is pumped to the diluted salt water tank 20 through a water supply pipe 21 from an external water supply source (not shown). The water supply pipe 21 is provided with an electromagnetic water supply valve 22. The valve 22 receives an ON signal from the control circuit 50, opens the flow path of the water supply pipe 21, and supplies raw water to the diluted salt water tank 20. A concentration sensor 23 and a water level switch 24 are provided in the diluted salt water tank 20. The concentration sensor 23 detects the concentration of the diluted salt water in the diluted salt water tank 20. The water level switch 24 is the same as the water level switch 13, when the dilute salt water level in the dilute salt water tank 20 is equal to or higher than the predetermined upper limit water level, when it is between the upper limit water level and the lower limit water level lower than the upper limit water level, and the lower limit Each case where the water level is lower than the water level is detected, and a signal corresponding to the detection result is generated.
[0015]
An overflow pipe 16 is connected to each side wall of the concentrated salt water tank 10 and the diluted salt water tank 20, and the pipe 16 is in the tank 10, 20 at a position slightly higher than the upper limit water level detected by the water level switches 13, 24. Is open. Thereby, when the salt water in each tank 10 and 20 overflows, it is discharged | emitted outside.
[0016]
The interior of the electrolytic cell 30 is divided into first and second electrode chambers 32 and 33 by a diaphragm 31, and each electrode chamber 32 and 33 is connected to the bottom wall of the diluted salt water tank 30 by the operation of the electric pump 25. Further, dilute salt water is continuously supplied through the supply pipe 26. The supply pipe 26 is provided with a flow rate sensor 27 so that the flow rate of the diluted salt water in the supply pipe 26 is measured.
[0017]
In each of the electrode chambers 32 and 33, first and second electrodes 34 and 35 to which a DC voltage is applied from a power supply 60 are accommodated in opposition. The power source 60 is a constant current source, and applies a voltage so that a constant current flows between the first and second electrodes 34 and 35. The power supply 60 is configured to be able to switch the direction of voltage application (= direction of current flowing between the electrodes) to the first and second electrodes 34 and 35. That is, when a positive voltage is applied to the first electrode 34 to make it an anode, the second electrode 35 becomes a negative potential (referred to as a positive direction) to become a cathode, and a positive voltage is applied to the second electrode 35. A voltage is applied so that the first electrode 34 becomes a negative potential (referred to as a negative direction) to become a cathode when applied to form an anode. By the voltage application (interelectrode current), the supplied diluted salt water is electrolyzed to generate electrolyzed water. An ammeter 61 is connected to the voltage application path (current path) from the power source 60 to the electrodes 34 and 35, and the current value (electrolytic current value) of the path is measured. In addition, a voltmeter (not shown) is incorporated in the power source 60 and the applied voltage value to both electrodes 34 and 35 is measured.
[0018]
One end of each of the first and second outlet pipes 36 and 37 is connected to each electrode chamber 32 and 33. The other ends of the first and second outlet pipes 36 and 37 are connected to the first and second inflow ports 43a and 43b of the switching valve 40, respectively. The first and second outlet pipes 41 and 42 are connected to the first and second outlet ports 43c and 43d of the switching valve 40, respectively.
[0019]
As the voltage application direction of the switching valve 40 is switched to the electrodes 34 and 35, for example, the electrolytic water in the first outlet pipe 36 changes from acidic water to alkaline water, and the electrolytic water in the second outlet pipe 37 changes to alkaline water. Even if the water is changed from acidic water to acidic water, acidic water is always discharged from the outlet of the first outlet pipe 41, and alkaline water is always discharged from the outlet of the second outlet pipe 42. It is a valve. In order to achieve this function, the switching valve 40 is provided with an impeller 44 that rotates along the inner periphery of the valve housing, and the impeller 44 is rotated 90 degrees by the electric motor 45, thereby The connection state of the outflow port can be switched. That is, in the first state indicated by the solid line in the drawing, the impeller 44 communicates the first inflow port 43a with the first outflow port 43c and communicates the second inflow port 43b with the second outflow port 43d. In the second state indicated by the two-dot chain line, the first inflow port 43a is communicated with the second outflow port 43d, and the second inflow port 43b is communicated with the first outflow port 43c.
[0020]
The control circuit 50 is composed of an electric circuit including a microcomputer. The control circuit 50 is connected to various switches and sensors 13, 23, 24, 27, 60 (voltmeters) and 61 as detectors of the electrolyzed water generator, and receives detection signals generated by the detectors. To do. Further, a pH setting switch 51 is connected to the control circuit. The pH setting switch is operated by an operator to set the pH value of the generated electrolyzed water to a desired value. Further, the control circuit 50 is connected to the electromagnetic water supply valves 12 and 22, the pinch valve 15, the electric pump 25, the electric motor 45, and the power source 60, and outputs control signals (operation instructions) for these.
[0021]
When the power switch (not shown) is turned on, the microcomputer in the control circuit 50 starts the program shown in the flowchart of FIG. In step 205, the microcomputer clears an effective chlorine amount integrated value S, which will be described later, to "0". Next, in step 210, the operation of the electric motor 25 is started, and in the subsequent step 215, the power source 60 is turned on and a constant current in the positive direction is passed between the first and second electrodes 34 and 35. Therefore, in this state, the first electrode 34 becomes an anode and the second electrode becomes a cathode. The generation of electrolyzed water is started by the above treatment. The control circuit 50 monitors the detection values of the water level switches 13 and 24 by a separately provided program (not shown), and when the water levels in the concentrated salt water tank 10 and the diluted salt water tank 20 are below the lower limit water level, Each of the electromagnetic water supply valves 12 and 22 is turned on (opened) until the water level is equal to or higher than the upper limit water level, and raw water is supplied to the tanks 10 and 20.
[0022]
The microcomputer proceeds to Step 220 and inputs the salt concentration of the diluted salt water in the diluted salt water tank 20 from the concentration sensor 23. In the following step 225, the necessary salt concentration is calculated based on the set pH (target pH) input from the pH setting switch 51, and the actual salt concentration input in step 220 is pinched so as to be the calculated salt concentration. The salt concentration in the diluted salt water tank 20 is adjusted by controlling the valve 15.
[0023]
Next, the microcomputer proceeds to step 230 to determine whether or not the flag F is “1”. This flag F is set to “1” by the routine executed by interruption every one minute shown in FIG. Since the flag F is currently “0”, the microcomputer repeatedly executes steps 220, 225, and 230 until the flag F becomes “1” (until one minute elapses).
[0024]
When the flag F changes to “1”, the microcomputer makes a “YES” determination at step 230 to proceed to step 235 and obtains the effective chlorine amount at that time according to the salt concentration input at step 220. Specifically, the microcomputer stores the “relationship between the salt concentration obtained by experiment and the amount of effective chlorine” shown in FIG. 4B, and the actual salt concentration obtained in step 220. From this relationship, the amount of effective chlorine is obtained and substituted for the value C of the RAM. The relationship in FIG. 4B is that the amount of effective chlorine is measured by the DPD colorimetric method or the like under the same constant current as the current that the power source 60 gives between the electrodes 34 and 35 during electrolysis.
[0025]
Here, the reaction at the cathode during electrolysis will be described. At the cathode, a reaction of 2Cl ⁻ → Cl ₂ + 2e ⁻ , Cl ₂ + H ₂ O → HOCl + HCl or Cl ₂ + H ₂ O ← HOCl + HCl occurs. Since HOCl and HCl are generated at a predetermined ratio (because HCl is considered to be generated at a predetermined ratio with respect to the effective chlorine amount (Cl ₂ and HOCl)), the effective chlorine amount is at the anode. There is a strong correlation with the amount of adsorbed chlorine ions. Therefore, if the amount of effective chlorine produced is known, the amount of chlorine ions adsorbed on the anode can be estimated. Moreover, if the chlorine ion amount can be estimated, the amount of scale attached to the cathode can also be estimated. This is because the adhering scale is considered to be contained in the electrolytic promoter at a predetermined ratio, and it is considered that there is a strong correlation (proportional relationship) with the adsorption amount of chlorine ions.
[0026]
Returning to FIG. 2 again, the description will be continued. In step 240 following step 235, the value C obtained in step 235 is added to the current effective chlorine amount integrated value S to obtain a new effective chlorine amount integrated value S. In this way, the integrated value S of the effective chlorine amount is calculated.
[0027]
In the next step 245, the effective chlorine amount integrated value S is compared with the predetermined value S0. The predetermined value S0 is selected as a value indicating that the amount of scale attached to the electrode has increased and reached the amount to be removed when the effective chlorine amount integrated value S reaches the predetermined value S0. Immediately after the start of electrolysis by the electrolytic current in a predetermined direction, the effective chlorine amount integrated value S is smaller than the predetermined amount S0. Therefore, the microcomputer determines that step 245 is “No” and proceeds to step 270. After F is cleared to “0”, the process returns to step 220.
[0028]
If the electrolysis is continued thereafter, the effective chlorine amount integrated value S obtained in step 240 becomes larger than the predetermined value S0. In this case, the microcomputer makes a “Yes” determination at step 245 and proceeds to step 250 where an instruction is given to the power source 60 to invert the direction of the current flowing through both electrodes 34 and 35. At the present time, the current is switched from the positive direction (the first electrode 34 is the anode and the second electrode 35 is the cathode) to the negative direction (the first electrode is the cathode and the second electrode is the anode). At the same time, in step 255, the electric motor 45 is rotated 90 degrees to switch the switching valve 40 from the first state to the second state. Next, the routine proceeds to step 260 where the effective chlorine amount integrated value S is cleared to “0” and the routine proceeds to step 270. In step 270, the flag F is cleared to "0", and the process proceeds to step 220 again.
[0029]
As described above, the electrolyzed water generating apparatus according to the present embodiment has an effective chlorine amount integrated value that the scale attached to the electrode has exceeded the allowable amount due to the continuous action of the electrolysis current in a predetermined direction. It detects by having become above, and reverses the direction of the electrolysis current at the time of the detection. Therefore, scale removal is performed at an appropriate timing in consideration of the concentration of impurities such as magnesium, and it is possible to maintain the electrolyzed water generation capability without deteriorating the electrode life.
[0030]
In the above embodiment, since the power source 60 is a constant current source and the salt concentration is variable, the amount of effective chlorine was determined using the relationship shown in FIG. 4B, but the constant current source was used. 4A, since the salt concentration and the voltage between the electrodes 34 and 35 have the relationship shown in FIG. 4A, the voltage is detected and the relationship between the voltage and the relationship between FIG. 4A and FIG. The effective chlorine amount (and the effective chlorine amount integrated value) can also be obtained based on this.
[0031]
When the salt concentration is controlled to be constant and the voltage applied between the electrodes 34 and 35 or the current (electrolytic current) flowing between the electrodes 34 and 35 is variable, the electrolytic current and effective chlorine amount in FIG. The actual effective chlorine amount (and the effective chlorine amount integrated value) is obtained based on the electrolytic current value measured by the ammeter 61 using the above relationship. In this case, since there is a relationship shown in FIG. 5A between the electrolytic current and the voltage between the electrodes 34 and 35, the voltage between the electrodes 34 and 35 measured by the voltmeter in the power source 60 is It is also possible to use a format for obtaining the effective chlorine amount from the relationship of FIG. 5 (A) and FIG. 5 (B).
[0032]
Further, in the case where both the salt concentration and the electrolytic current (applied voltage) are variable, the effective chlorine amount for the combination of the salt concentration and the electrolytic current value is experimentally measured, and these relationships are so-called. It is stored in the microcomputer in the form of a two-dimensional map (two-dimensional table), and effective from the salt concentration, electrolytic current value (salt concentration and applied voltage) detected during actual electrolysis, and the two-dimensional map. It is good also as a form which asks for the amount of chlorine.
[Brief description of the drawings]
FIG. 1 is an overall schematic diagram of an electrolyzed water generating apparatus according to an embodiment of the present invention.
FIG. 2 is a flowchart showing a program executed by a microcomputer in the control circuit of FIG.
FIG. 3 is a flowchart for operating a flag F in the flowchart of FIG. 2;
4 shows the relationship between the salt concentration and the voltage between the electrodes when a constant current is passed between the electrodes in the electrolyzed water generating device shown in FIG. 1, and the relationship between the salt concentration and the amount of effective chlorine obtained by electrolysis. FIG.
FIG. 5 is a diagram showing the relationship between the electrolysis current and the interelectrode voltage and the relationship between the electrolysis current and the amount of effective chlorine when the salt concentration is constant in the electrolyzed water generator shown in FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Concentrated salt water tank, 11 ... Water supply pipe, 12 ... Electromagnetic water supply valve, 13 ... Water level switch, 15 ... Pinch valve, 20 ... Diluted water tank, 21 ... Water supply pipe, 22 ... Electromagnetic water supply valve, 23 ... Concentration sensor , 24 ... Water level switch, 25 ... Electric pump, 26 ... Supply pipe, 30 ... Electrolyzer, 32 ... First electrode chamber, 33 ... Second electrode chamber, 34 ... First electrode, 35 ... Second electrode, 40 ... Switching Valve, 50 ... control circuit, 60 ... power supply

Claims (3)

A predetermined electrolysis promoter is added to raw water and electrolyzed water containing more chlorine ions than the raw water is continuously supplied to an electrolytic cell containing a pair of electrodes, and a constant current in a predetermined direction is applied to the pair of electrodes. In the electrolyzed water generating device for flowing and electrolyzing the electrolyzed water,
Integrating means for integrating the amount of effective chlorine adsorbed on the electrode serving as the anode of the pair of electrodes;
Electrolytic water generation apparatus accumulated the effective chlorine content is characterized by comprising a current direction reversing means from the predetermined direction current flowing between the front Symbol electrodes can became a predetermined value or more switches in the opposite direction. The integrating means for integrating the effective chlorine amount is an integrating means for integrating the effective chlorine amount that varies depending on the salt concentration of the electrolyzed water electrolyzed in the electrolytic cell. Item 4. The electrolyzed water generating device according to Item 1. As an integration means for integrating the effective chlorine amount, a voltage detection means for detecting a voltage between the pair of electrodes, and a change in the voltage between the pair of electrodes detected by the voltage detection means in the electrolytic cell. The integration means for calculating the salt concentration contained in the electrolyzed water produced by electrolysis and integrating the effective chlorine amount that changes according to the calculated salt concentration is employed. Electrolyzed water generator.

Images