KR100341131B1 - Electrolytic water generation method and electrolytic water generation device - Google Patents

Abstract

The present invention relates to an electrolytic water generating method and an electrolyzed water generating apparatus for automatically removing precipitates deposited on a negative electrode plate. In the batch electrolytic water generating method, the first electrolysis is performed to extract electrolytic water, and then the following electrolysis is performed. Before doing this, reverse the polarity of the DC power supply connected to the electrode plate. Since the electrode plate which was the negative electrode plate in the previous electrolysis becomes the positive electrode plate in the next electrolysis, the precipitate attached to the electrode plate is ionized and eluted to the electrolyzed water.

Description

Electrolyzed water generation method and electrolyzed water generator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for generating electrolytic water and an electrolytic water generating device for electrolyzing electrolyzed water such as water and generating acidic electrolytic water and alkaline electrolyzed water, and more particularly, to a method for producing a batch type electrolytic water and an electrolytic water generating device.

Alkaline electrolyzed water obtained by electrolyzing drinking water contains minerals such as calcium, sodium, magnesium, and potassium as cations in the drinking water, so if you drink this alkaline electrolyzed water, abnormal fermentation, indigestion, diarrhea, excessive stomach acid, etc. There is a medical effect of suppressing.

On the other hand, the acidic electrolyzed water obtained at the same time as the generation of alkaline electrolytic water has the effect of shrinking the skin after washing by an astringent action. In particular, strong acidic electrolyzed water having a pH of 2.7 or less has recently been shown to have a bactericidal effect against AIDS wills, methicillin resistant Staphylococcus aureus (MRSA), etc.

In this type of electrolyzed water generating device, when a direct current flows between both electrodes while supplying tap water, for example, tap water, electrolysis of water is performed in the electrolyzer. Then, cations such as calcium ions, sodium ions, magnesium ions and potassium ions contained in (or deliberately added) in the tap water are concentrated on the cathode side, that is, the cathode chamber. On the other hand, anions such as chlorine ions contained in tap water are concentrated on the anode side, that is, the anode chamber. At this time, since the anode chamber and the cathode chamber are divided by the diaphragm, only the acidic electrolyzed water is discharged from the outlet of the acidic electrolytic water formed in the anode chamber, and only the alkaline electrolyzed water is discharged from the outlet of the alkaline electrolytic water formed in the cathode chamber.

Conventional electrolyzed water generators include a continuous type electrolytic water generator that continuously supplies electrolyzed water for electrolysis while supplying electrolyzed water to the electrolyzer, and electrolysis in a state where electrolyzed water is temporarily stored in the electrolyzer. It can be classified into a batch type electrolytic water generating device which supplies the electrolyzed water thus obtained.

The continuous pass-through electrolyzed water generating device is better in that it can supply electrolyzed water continuously. However, in order to continuously obtain strong acidic or strong alkaline electrolytic water using this continuous water flow electrolytic water generating device, a large number of electrode plates are required in the relationship between the flow and the electrode plate area. For this reason, there is a drawback that the cost of the electrolytic water generator is increased.

In addition, in the continuous flow type electrolytic water generating device, the internal pressure of the electrolytic cell is increased. Therefore, there is also a problem that the seal structure of the electrolytic cell becomes complicated to withstand this internal pressure, or the counting parts such as valves increase. Therefore, inexpensive batch type electrolytic water generating devices are frequently used depending on the application.

However, in the conventional batch type electrolytic water generating device, cations such as calcium and magnesium contained in water precipitate on the negative electrode plate during electrolysis. This precipitate becomes a scale and there exists a problem of reducing electrolytic ability. Therefore, it is necessary to replace the negative electrode plate regularly, and the user must always pay attention to the frequency of exchange of the negative electrode plate. If this exchange is neglected, electrolytic water of a desired pH value cannot be obtained. In the electrolytic water generator, the cost ratio of the electrode plate is very large, and using such expensive electrode plates as consumables has hindered the spread of the electrolytic water generator.

In addition, the conventional batch type electrolytic water generating device is configured to obtain electrolytic water of a desired pH value by controlling the electrolysis time. For example, the electrolyzed water generating device is provided with a timer for adjusting the electrolyzed time, so that the user selects the electrolyzed time according to the taste to generate electrolyzed water having a desired pH value.

However, the conventional dispatched electrolyzed water generating apparatus can electrolyze electrolyzed water after completing electrolysis, so that the user electrolyzes the electrolyzed water which has been electrolyzed by intention or error in many cases. Therefore, in the conventional batch type electrolytic water generating device, it was difficult to accurately maintain the pH value of the electrolyzed water.

The present invention has been made in view of the above problems of the prior art, and an object thereof is to provide an electrolytic water generating method and an electrolytic water generating apparatus capable of automatically removing precipitates on an electrode plate. In addition, an object of the present invention is to provide an electrolyzed water generation method and an electrolyzed water generation device capable of accurately maintaining the pH value of electrolyzed water by preventing re-electrolysis of electrolyzed water that has completed electrolysis.

According to the present invention to achieve the above object, the step of putting the electrolyzed water into at least two electrolytic chambers formed in the electrolytic cell; Connecting a positive electrode of a DC power supply to an electrode plate disposed in the inner electrolytic chamber, and simultaneously connecting a negative electrode of the DC power supply to an electrode plate disposed in the other electrolytic chamber, and applying a voltage to the electrolyzed water; Taking out the electrolyzed water produced in the electrolytic chamber; Injecting new electrolytic water into the electrolytic chamber; Connecting the cathode of the DC power supply to the electrode plate disposed in the other electrolytic chamber, connecting the anode of the DC power supply to the electrode plate provided with the one electrolytic chamber, and applying a voltage to the electrolyzed water. A method of generating an excited electrolyzed water is provided.

In this case, it is preferable to have a process which shows whether the electrolyzed water produced in each said electrolytic chamber is acidic electrolyzed water or alkaline electrolyzed water at least before the process of taking out the electrolyzed water produced | generated in the said electrolysis chamber.

The time for applying the voltage to the electrolyzed water is variable, and the time for applying the voltage to the electrolyzed water is preferably determined according to the pH value of the electrolyzed water generated in the electrolytic chamber.

Further, the step of applying a voltage to the electrolyzed water for the time determined according to the pH value, and the step of preventing the application of voltage to the electrolyzed water between the steps of taking out the electrolyzed water generated in the electrolytic chamber. It is desirable to have.

In order to achieve the above object, according to the present invention, at least two electrolytic chambers are provided by disposing a diaphragm between a first electrode plate to which one of the positive electrode or the negative electrode is connected and a second electrode plate to which the other of the positive or negative electrode is connected. An electrolytic cell formed; An inlet for injecting electrolyzed water into the electrolytic chamber; Outlets formed in each of the electrolytic chambers for taking out electrolyzed water; A valve formed at each of said outlets; An electrolytic water generating device having a polarity inversion circuit for inverting polarities of a DC power source connected to the first electrode plate and the second electrode plate at predetermined intervals is provided.

In this case, it is preferable to further have a display part for indicating the kind of electrolyzed water which is taken out from each of the booties to the outlet.

In addition, detection means for detecting the open state of the valve, an integrated circuit for integrating the total time of the open state of the valve, and the total time accumulated by the integrating circuit does not reach a predetermined reference time. In this case, it is preferable to further have a determination circuit for preventing the supply of current to the electrodes.

The present invention provides a so-called batch electrolyzed water producing method and a batch electrolyzed water generating device.

First, a predetermined amount of the electrolyzed water is put into the electrolyte formed in the electrolytic cell while the valve of the outlet port is closed, the positive electrode is brought into contact with the inner electrode plate, and the negative electrode is connected to the other electrode plate to apply voltage to the electrolyzed water. As a result, electrolysis of the electrolyzed water is performed so that the acidic electrolytic water is concentrated in the anode chamber and the alkaline electrolytic water is concentrated in the cathode chamber. Thus, the valve is opened and the acidic electrolytic water and the alkaline electrolytic water are taken out from the respective outlets. In addition, the application time of a voltage is determined according to the pH value of target electrolytic water.

In the present invention, the polarity of the voltage applied to the electrode plate is inverted at predetermined intervals (for example, every time). Therefore, when electrolytic water is generated after reversing the polarity of the voltage applied to the electrode plate, the electrode plate which was the positive electrode plate before the inversion becomes the negative electrode plate, and the electrode plate that was the negative electrode plate before the inversion becomes the positive electrode plate.

As a result, even if a portion of the cations contained in the electrolyzed water precipitates on the negative electrode plate, the negative electrode plate becomes a positive electrode plate and undergoes electrolysis, so that the precipitate emits electrons and then cations and elutes into the electrolyzed water. The eluted cations are concentrated in a cathode chamber (electrolytic chamber that was an anode chamber before inversion) and provided in a state of being contained in alkaline electrolytic water. As described above, according to the present invention, since the precipitate on the electrode plate is ionized and removed, it is possible to prevent a decrease in electrolytic capacity. In addition, since the removed cation is concentrated in the cathode chamber and used in the state of being contained in alkaline electrolytic water, it is not necessary to discard the water from which the precipitate has eluted.

However, since the polarity of the electrode plate is reversed, the electrolytic water extracted from the outlet port also reverses the acidic electrolytic water and the alkaline electrolytic water. For this reason, in the present invention, the display unit shows the kind of electrolytic water extracted from each outlet (either acidic or alkaline electrolyzed water) to prevent user's mistake.

In addition, after the electrolysis of the electrolyzed water is completed, voltage is not applied to the electrolyzed water until the electrolyzed water is completely taken out. That is, in order to prohibit re-electrolysis, the detection means detects the open state of the valve of the outlet, and outputs this detection signal to the integration circuit. In the integration circuit, the total time in which the valve is open is accumulated, and the total time accumulated by the integration circuit is output to the determination circuit. In the determination circuit, the total time is compared with the predetermined reference time, and when the reference time is not reached, the supply of current is stopped between the electrodes.

This reference time is defined as the time from the start of extraction of the electrolyzed water to the emptying of the electrolytic cell, and it is determined whether or not electrolyzed water exists in the electrolyzer using the determination result by the judging circuit. As a result of this determination, when electrolytic water is present in the electrolytic cell, energization to the electrode plate is prevented and reelectrolysis of the electrolytic water can be prevented.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment of this invention is described based on drawing.

1 to 6 are conceptual views for explaining a method of generating electrolytic water according to the present invention, FIG. 7 is a configuration diagram showing an electrolytic water generating device according to the present invention, and FIG. 8 is an embodiment of an electrolytic water generating device according to the present invention. 9 is a cross-sectional view showing the internal structure of the electrolytic water generating device shown in FIG. 8, FIG. 10 is a sectional view taken along the line XX-XX of FIG. 9, and FIG. 11 and FIG. An enlarged cross-sectional view showing a rotary valve, FIG. 13 is a conceptual view showing another embodiment of the electrolytic water generating device according to the present invention, FIG. 14 is a front view showing the appearance of the electrolytic water generating device shown in FIG. Fig. 13 is a side view showing the appearance of the electrolytic water generating device shown in Fig. 13, Fig. 16 is a front view showing a display portion formed inside the electrolytic water generating device shown in Fig. 14, and Fig. 17 is an electrolytic water generating device according to the present invention. Flow showing control sequence of 18 is an electric circuit diagram showing a specific example of the polarity inversion circuit.

As shown in Fig. 7, the electrolytic water generator of this embodiment is equipped with an electrolytic cell 4 in the so-called batch electrolytic water generator. The positive electrode plate 1 and the negative electrode plate 2 are arranged inside the electrolytic cell 4, and the diaphragm 3 is disposed between these two electrode plates 1 and 2, so that the two electrolytic chambers 5 in the electrolytic cell are arranged. (6) is formed. The electrode plates 1 and 2 are, for example, coated with platinum or an alloy of platinum and iridium in a thin film on the surface of a titanium plate (also by firing), and the diaphragm 3 is, for example, polyethylene. It is composed of an ion exchange resin film made of a resin or a microporous thin film made of a synthetic resin.

In addition, in the electrolytic water generating device of this embodiment, the polarity (anode or cathode) connected to the electrode plate from the power source is switched each time one electrolysis is completed. That is, in FIG. 12, a state where the anode is connected to the left electrode plate 1 and the cathode is connected to the right side and the electrode plate 2 is shown. The left electrolytic chamber 5 becomes the anode chamber, and the right side The electrolytic chamber 6 is a cathode chamber. However, when electrolysis is performed by injecting new electrolytic water into the electrolytic chamber, the cathode is connected to the left electrode plate 1 as shown in FIG. Since the positive electrode is connected to the right electrode plate 2, the left electrolytic chamber 5 becomes a cathode chamber, and the right electrolytic chamber 6 becomes an anode chamber.

Outflow pipes 7 and 8 are provided in each of the electrolytic chambers 5 and 6, and the valves 7a and 8a respectively formed in the outflow pipes 7 and 8 are opened. The electrolyzed water generated in the electrolytic chamber is discharged from the water jets 7b and 8b by its own weight. The valves 7a and 8a are rotary valves, and as shown in Figs. 9 and 10, one rod 22a is inserted into the main body of the two valves 7a and 8a. As shown in FIG. 11 and FIG. 12, the through hole 26 is formed. When the valve lever 22b attached to one end of the rod 22a is turned, the two valves 7a and 8a are opened and closed at the same time. For example, when the valve lever 22b shown in FIG. 8 is turned clockwise, the valves 7a and 8a are closed (see FIG. 12). On the contrary, when the valve lever 22b is turned counterclockwise, the valve 7a is closed. 8a is opened (see FIG. 11).

In addition, the inner diameters of the two outflow pipes 7 and 8 are formed in the same order. When the valve lever 22b is turned, the same amount of acidic electrolytic water and alkaline electrolytic water are respectively discharged from the water discharge port 7b and 8b. It is jetted. As a result, the liquid level of the two electrolytic chambers 5, 6 is always at the same position only by turning the valve lever after the completion of electrolysis, and the electrolytic chambers 5, 6 are emptied at the same time. Therefore, it is possible to prevent electrolytic water from entering the other electrolytic chamber from the one electrolytic chamber through the diaphragm. Incidentally, the means for making the water discharge amount of this electrolytic water uniform is not limited to the embodiment shown in FIG. 9 and FIG.

However, in the electrolytic water generating apparatus shown in FIG. 9 and FIG. 10, when the valve lever is turned, electrolyzed water always comes out from the two water jetting holes 7b and 8b. Similarly, it is necessary to prepare the respective containers 25 and 25 of the two jetting ports 7b and 8b. Therefore, when electrolytic water is to be taken out from either of the electrolytic chambers 5 or 6, the valves 7a and 8a are not connected to the rods 22a, and the valves are connected to the respective valves 7a and 8a. You may comprise so that a lever may be installed. For example, in another embodiment of the present invention shown in FIGS. 13 to 15, a rotary valve 7a is provided to each of two outflow pipes 7 and 8 connected to the bottom surface of the electrolytic cell 1. ) 8a is provided, and the water jet nozzles 7b and 8b which are rotatable with the rotary valves 7a and 8a as a point are provided. The structures of the rotary valves 7a and 8a are shown in FIGS. 11 and 12, and as shown in solid lines in FIG. 15, the valve is closed when the jet nozzle is set up, and the dashed two-dot chain line in FIG. As shown, when the water jet nozzle is turned over, the water jet valve is opened. As shown in FIG. 13, when the tip of the jetting nozzle is formed higher than the liquid level of the electrolytic cell, the valves 7a and 8a can be omitted.

In addition, supply of the electrolyzed water into the electrolytic cell 4 is performed at the upper opening of the electrolytic cell 4. Although the lid 27 is provided in the electrolytic water generating apparatus of the present embodiment as shown in FIG. 8, the lid 27 is for preventing dust or the like from entering the electrolytic cell. There is no need to seal it.

As shown in FIG. 2, when the positive electrode of the DC power supply 9 is connected to the left electrode plate 1 and the negative electrode of the DC power supply 9 is connected to the right electrode plate 2, the electrolysis is performed. Acid electrolytic water is jetted from the water jetting port 7b formed in the chamber 5, and alkaline electrolytic water is jetted from the jetting port 8b formed in the cathode chamber 6. However, as shown in FIG. 5, inverting the polarity of the voltage applied to the electrode plates 1 and 2 also reverses the electrolytic water (acidic electrolytic water or alkaline electrolytic water) supplied from the respective water discharge ports 7b and 8b. Done.

As described above, the DC voltage from the DC power supply 9 obtained by rectifying and smoothing the AC power supply to the diode rectifier is applied to the two electrode plates 1 and 2. When the electrolytic switch l2 formed on the display panel 11 shown in FIG. 8 is pressed, electrolysis is started, and when the time set by the first timer 13 elapses, electrolysis is stopped.

In addition, the power supply lamp 24 shown in FIG. 8 turns on when the AC (alternating current) plug is inserted into the outlet.

In the control circuit of this embodiment, the signals of the electrolytic switch 12 and the first timer 13 are turned on / off in order to reverse the polarity of the voltage applied to the electrode plates 1 and 2 whenever electrolysis is started. The circuit 14 receives the circuit 14 and stores it in the memory circuit 15, and outputs a signal for inverting the polarity to the polarity inversion circuit 16 and the display portions 17a and 17b.

The signal output from the on / off detection circuit 14 to the memory circuit 15 is either an on signal or an off signal, and the on signal of the electrolytic switch 12 and the on signal of the first timer 13 are detected by the detection circuit 14. ) Is an on signal. On the contrary, when the off signal from the first timer 13 is input, it becomes an off signal. The on / off detection circuit 14 is inputted even if the on-signal from the electrolytic switch 12 is inputted to the detection circuit 14 while the on-signal is input from the first timer 13. Clear the on signal of the electrolytic switch. In this way, even if the electrolytic switch 12 is pressed repeatedly during electrolysis, this on-signal is deleted and is not output to the first timer 13. Therefore, the electrolysis time initially set by the first timer 13 is not extended.

If the on / off detection circuit 14 outputs an on signal to the memory circuit 15 while the on signal is output from the first timer 13 to the on / off detection circuit 14, the on / off detection circuit ( The off signal is output from the 14 to the memory circuit 15.

On the other hand, the memory circuit 15 stores the signal (on signal or off signal) up to that time after receiving the input signal from the on / off detection circuit 14 until the next signal is input. When the off signal is stored in the memory circuit 15, when the next on signal is inputted from the on / off detection circuit 14 to the memory circuit 15 and recorded, the polarity inverting circuit 16 in the memory circuit 15 is recorded. ), A signal for inverting polarity is output. In response to this signal, the polarity inversion circuit 16 inverts the polarity of the applied voltage applied to the positive electrode plates 1 and 2 from the DC power supply with respect to the polarity applied up to that time. As the polarity inversion circuit 16, for example, the relay 28 shown in FIG. 18 can be used. The relay 28 has movable terminals 29a and 29b and fixed terminals 30a, 30b, 30c and 30d, and the movable terminals 29a and 29b are interlocked and switched. The fixed terminals 30b and 30c are connected to one electrode plate 1, and the fixed terminals 30a and 30d are connected to the other electrode plate 2.

Incidentally, the timing of inverting the applied voltage polarity to the electrode plates 1 and 2 may be performed every time the electrolysis is completed, or may be reversed after the electrolysis is performed with the same polarity by n times. However, in order to completely elute the metal scale, it is preferable to make the time of connecting to the anode and the time of connecting to the cathode as possible as possible.

However, if the polarity of the voltage applied to the electrode plates 1 and 2 is reversed in this manner, the type of electrolyzed water discharged from the water jetting holes 7b and 8b is reversed each time. Therefore, when the memory circuit 15 outputs a signal for inverting the polarity to the polarity inversion circuit 16, the signal for inverting the display from the memory circuit 15 to the control circuit of the display portions 17a and 17b. Outputs

As shown in FIG. 8, the display portions 17a and 17b are composed of LEDs installed in the display panel 11, and are used to display the type of electrolyzed water discharged from the respective water discharge ports 7b and 8b. Four LEDs 18a, 18b, 19a, 19b are provided. As shown in the figure, the left display portion 17a is composed of two LEDs 18a and 18b, and in the case where the electrolyzed water discharged from the left water discharge port 7b is an acidic electrolyzed water, it displays an acidic electrolyzed water. LED 18a lights up, and in the case of alkaline electrolyzed water, LED 18b for displaying alkaline electrolyzed water lights up. Similarly, the right display unit 17b is composed of two LEDs 19a and 19b. When the electrolyzed water discharged from the right water discharge port 18b is acidic electrolyzed water, the LED 19a for displaying the acidic electrolyzed water is turned on. In the case of alkaline electrolyzed water, LED 19b for displaying alkaline electrolyzed water is turned on. Accordingly, the user can determine at a glance the type of electrolyzed water discharged from each of the water discharge ports 7b and 8b by looking at the lighting state of the display units 17a and 17b.

In addition, the signal for inverting the display from the memory circuit 15 to the control circuit of the display units 17a and 17b outputs a signal for inverting the polarity from the memory circuit 15 to the polarity inversion circuit 16. The output signal may be output at the same time, or the polarity inversion circuit 16 may receive the actual applied voltage polarity into the memory circuit 15 and send a display command signal to the display portions 17a and 17b so as to conform to the actual polarity. do. In this way, more reliable and appropriate types of electrolyzed water can be displayed.

The signal output from the memory circuit 15 to the display portions 17a and 17b need not be at the same time as inverting the polarity of the electrode plate, but at least after the electrolyzed water has been drained.

In the display by the LED, the light is turned off when the power switch is turned off. Therefore, when the electrolytic switch 12 is turned on again, the type of electrolyzed water when the power switch is turned off is stored as it is.

The display unit of the present invention is not limited to the embodiment shown in FIG.

For example, in the embodiment shown in FIG. 8, LEDs are used to make electrical display, but as shown in FIG. 14, windows 20a and 20b are opened on the display panel 11, From the window, two gears 21a and 21b shown in FIG. 16 may be disposed so that any character is displayed whether it is acidic electrolyzed water or alkaline electrolyzed water. Then, by rotating the drive gear 22 engaged with the two gears 21a and 21b with the actuator, the electrolyzed water discharged from the left water discharge port 7b is discharged from the left window 20a to the right pitcher 8b. The electrolyzed water discharged from) rotates the two gears 20a and 20b so that an indication appears in the right window 20b, respectively. In this manner, when the display is performed by mechanical means, the display continues even if the power switch 12 is turned off. In addition, a signal for operating the actuator is output from the memory circuit 15 shown in FIG.

In the electrolytic water generating device of this embodiment, electrolyzed water that has once been electrolyzed is not electrolyzed again. That is, as shown in FIG. 7, the valve lever switch 10 which detects the rotation position of the valve lever 22b is arrange | positioned, and the valve lever 22b is rotated to the position which valve 7a, 8a closes. The lower signal is output to the second timer 23 and the integration circuit 20, and the valve lever 22b is rotated to the position where the valves 7a and 8a are opened. The OFF signal is output to the timer 23 and the integration circuit 20.

When the OFF signal of the valve lever switch 10 is input to the second timer 23 and the integration circuit 20 (that is, detecting that the valves 7a and 8a are open), the second timer 23 It starts to operate and at the same time starts the integration of time in the integration circuit 20. However, integration is stopped when the ON signal of the valve lever switch 10, that is, the valves 7a and 8a is closed during integration.

Further, the determination circuit 21 compares at predetermined time intervals whether or not the time accumulated in the integration circuit 20 has reached a predetermined reference time T ₂ . The reference time T ₂ referred to here is the time from opening the valve lever 22b until all the electrolyzed water in the electrolytic cell is discharged, which actually includes an error at this time and is slightly larger.

In short, in the present embodiment, it is determined based on the on / off signal of the valve lever switch 10 whether the electrolytic cell is empty. Then, when the valve lever 22b is opened and the valve lever 22b is closed while the electrolyzed water is being jetted, the integration of time is stopped, and when the jet of the electrolyzed water is resumed, the integration of time is restarted to measure the total water discharge time.

When the integration result in the integration circuit 20 reaches the reference time T ₂ , an off signal is output from the determination circuit 21 to the display units 17a and 17b to inform the user that the jetting of the electrolyzed water is completed. On the contrary, when the integration result in the integration circuit 20 does not reach the reference time T ₂ , the electrode plate is transferred from the determination circuit 21 to the polarity inversion circuit 16 or the DC power supply 9 to prevent re-electrolysis. (1) A signal for interrupting the supply of current to (2) is output.

Next, a method of generating electrolytic water will be described with reference to FIGS. 1 to 6 and 17.

First, as shown in FIG. 1, the valve lever 22b is turned to close the valves 7a and 8a, and electrolytic water is transferred from the upper surface opening of the electrolytic cell 4 to the electrolytic chamber 5,6. It is injected to fill the electrolytic chambers 5 and 6 with electrolyzed water. When the AC plug is inserted into an AC power outlet (step 1), the first timer 13, the on / off detection circuit 14, the memory circuit 15, the second timer 23, the integration circuit 20, and the judgment Initialization of the circuit 21 is performed (step 2), and the power supply lamp 24 lights (step 3).

Next, after setting the first timer 13 provided on the display panel 11 to a desired time (step 4), the electrolytic switch 12 is pressed (step 5). The first timer 13 is disposed to determine the pH value of the obtained electrolyzed water, and when the electrolysis time is set longer, the electrolytic degree is increased (that is, the pH value becomes smaller for acidic electrolyzed water and the pH value becomes larger for alkaline electrolyzed water). . In addition, as shown in Step 5 of FIG. 17, when a solution having a large degree of dissociation, such as saline, is added to the electrolyzed water, electrolytic efficiency is increased, and electrolysis can be known in a short time.

When the electrolytic switch 12 is input in step 6 of FIG. 17, the voltage application polarity up to that time is reversed (step 7), and each of the LEDs 18a, 18b, 19a, and 19b blinks (step 8). As shown in FIG. 2, the first timer 13 is operated to start electrolysis (step 9), and a DC voltage is applied to the two electrode plates 1 and 2. When the application of this voltage is shown in FIG. 2, a positive voltage is applied to the left positive electrode plate 1, and a negative voltage is applied to the right electrode plate 20. FIG.

At the same time, after confirming that the valve lever 22b is closed (step 10), the countdown of the set time T ₁ is started (steps 11 and 12). As a result, the electrolyzed water of the electrolytic chamber is electrolyzed, anions are concentrated in the anode side electrolytic chamber 5, and cations are concentrated in the cathode side electrolytic chamber 6. Therefore, acidic electrolytic water is produced in the anode side electrolytic chamber 5 and alkaline electrolytic water is produced in the cathode side electrolytic chamber 6.

Further, for safety measures, if the valve lever 22b is opened during electrolysis, electrolysis is forcibly terminated (step 10 → 14). In addition, the set time of the 1st timer 13 set once can be changed only during electrolysis (step 12 → 13 → 9).

When the set time has elapsed and the OFF signal is output from the first timer 13 to the DC power supply, the DC power supply 9 is cut off and electrolysis is terminated (step 14), and the blinking of the display portion changes to lighting. The user turns the valve lever 22b, and the user turns the valve lever 22b, and the container 25 exists for each nozzle 7b and 8b, and extracts the generated acidic electrolytic water and alkaline electrolytic water, respectively, and electrolyzer 4 is carried out. Empty me (see Figure 3).

At this time, the left display portion 17a of the display panel 11 shown in FIG. 8 lights the LED 18a indicating the acidic electrolyzed water, and the right display portion 17b lights the LED 19b indicating the alkaline electrolytic water. There is little concern about the user misunderstanding the type of electrolyzed water.

When the valve lever 22b is opened (step 16), the valve lever switch 10 disposed on the valve lever 22b outputs an off signal to the second timer 23 and the integration circuit 20. The two-timer 23 starts operation (step 17). At this time, as long as the valve lever 22b is not closed while the electrolytic water is being injected into the container, the time measured by the second timer 23 is accumulated in the integration circuit 20 and sequentially output to the determination circuit 21. This integration time is compared with the reference time T ₂ in the determination circuit 21 (step 20), and when the reference time is reached, the LEDs 18a, 18b, 19a and 19b are turned off (step 21). .

When the valve lever 22b is closed while the electrolytic water is being injected into the container 25, the integration process in the integration circuit 20 is stopped until the valve lever is opened next, regardless of the number of times of closing. (From step 18 to 19).

As described above, in the electrolytic water generating device of the present embodiment, electrolysis cannot be started unless the electrolyzed water in the electrolytic cell is emptied. Therefore, electrolysis of the electrolyzed water once electrolyzed is prevented. As a result, the electrolysis time initially set, ie, electrolytic water of a desired pH value, can be obtained.

At the same time as the first timer 13 is turned off, an off signal is output from the first timer 13 to the on / off detection circuit 14, and the memory circuit 15 is supplied from the on / off detection circuit 14. ) Off signal is output. As a result, the off information is recorded in the memory circuit 15.

As shown in FIG. 3, when all the electrolyzed water generated in the electrolytic chambers 5 and 6 is taken out, new electrolytic water is put into the electrolytic chambers 5 and 6, as shown in FIG. When the electrolytic switch 12 is pressed and the first timer 13 is operated, an on signal is output from the on / off detection circuit 14 to the memory circuit 15 so that the on information is recorded in the memory circuit 15. .

At the same time, a signal for inverting polarity is output from the memory circuit 15 to the polarity inversion circuit 16, and the polarity of the voltage applied from the DC power supply 9 to the electrode plates 1 and 2 is inverted. That is, as shown in FIG. 5, the electrode plate 1 is a negative electrode plate, and the electrode plate 2 is a positive electrode plate. In this state, when electrolysis is performed in the above-described order, alkaline electrolytic water is generated in the left electrolytic chamber 5 and acidic electrolyzed water is produced in the right electrolytic chamber 6. Therefore, as shown in FIG. 6, alkaline electrolytic water is supplied from the left nozzle 7b, and acidic electrolytic water is supplied from the right nozzle 8b.

In the last electrolysis shown in FIG. 2, a part of the cations contained in the electrolyzed water is precipitated on the negative electrode plate 2, thereby reducing the electrolytic capacity. However, in the method of producing electrolytic water of the present embodiment, the polarity applied to the electrode plates 1 and 2 is reversed in the case of the next electrolysis, so that the negative electrode plate 2 deposited with cations becomes a positive electrode plate. As a result, the precipitate of the electrode plate releases electrons and cations again, and elutes into the electrolyzed water. The eluted cations are concentrated in a cathode chamber (electrolyzer chamber, which was the anode chamber last time), and are supplied to the nozzle 7b as alkaline electrolytic water.

At this time, a signal for inverting polarity is also output from the memory circuit 15 to the display portions 17a and 17b, and the display of the display panel 11 shown in FIG. 8 is reversed. That is, the LED 18b which radiates alkaline electrolytic water is lighted in the left display part 17a, and the LED 19a which shows acidic electrolyzed water is lighted in the right display part 17b. This eliminates the possibility that the user may confuse the type of electrolyzed water. In addition, in this embodiment, since the precipitates of the negative electrode plate are ionized, this cation is concentrated in the negative electrode chamber and used in alkaline electrolytic water, thus eliminating the need to discard the water containing the precipitates.

In addition, the Example described above was described in order to make understanding of this invention easy, and was not described in order to limit this invention. Accordingly, each element disclosed in the above embodiment also includes all design changes and equivalents falling within the technical scope of the present invention.

As described above, according to the present invention, it is possible to simplify the removal of precipitates on the electrode plate, thereby preventing the drop in the electrolytic capacity. In addition, since the removed precipitate is ionized and used in alkaline electrolytic water, water for removing the precipitate does not need to be discarded. Further, according to the present invention, it is specified whether the electrolyzed water taken out from each outlet is acidic electrolytic or alkaline electrolyzed water, and thus, even if the electrolyzed water obtained from the outlet is inverted due to the polarity being reversed, no mistake is generated. In addition, according to the present invention, since electrolysis is again prevented for the electrolyzed water once electrolyzed, it is possible to accurately maintain the pH value of the electrolyzed water.

1 to 6 is a conceptual diagram illustrating a method of generating electrolytic water according to the present invention

7 is a block diagram showing an electrolytic water generating device according to the present invention,

8 is a perspective view showing an embodiment of an electrolytic water generating device according to the present invention;

9 is a cross-sectional view showing the internal structure of the electrolytic water generating device shown in FIG.

10 is a cross-sectional view taken along the line XX-XX of FIG.

11 and 12 are enlarged cross-sectional views showing the rotary valve of FIG.

13 is a conceptual diagram showing another embodiment of the electrolytic water generating device according to the present invention.

14 is a front view showing the appearance of the electrolytic water generating device shown in FIG.

FIG. 15 is a side view showing the appearance of the electrolytic water generating device shown in FIG. 13;

FIG. 16 is a front view showing a display unit formed inside the electrolytic water generating device shown in FIG. 14;

17 is a flowchart showing a control procedure of the electrolytic water generating device according to the present invention;

18 is an electric circuit diagram showing a specific example of the polarity inversion circuit.

1,2: electrode plate 3: diaphragm

4: electrolyte tank 5, 6: electrolyte chamber

7, 8: outlet pipe 7a, 8a: valve

7b, 8b: Nozzle 9: DC power

10: valve lever switch 11: display panel

12: Electrolytic switch 13: First timer

14: ON / OFF detection circuit 15: Memory circuit

16: polarity inversion circuit 17a, 17b: display section

18a, 18b, 19a, 19b: LED 20: Integrating circuit

21: judgment circuit 23: second timer

24: power supply lamp

Claims (6)

In the production method of electrolytic water in which acidic ionized water and alkaline ionized water are produced by electrolyzing the electrolyzed water to be discharged, and separately taken out without mixing them. Injecting electrolyzed water into each of the two electrolytic chambers which are partitioned with a diaphragm through which hydrogen ions and hydroxide ions can permeate; A positive voltage is applied to the electrolyzed water in one electrolytic chamber and a negative voltage is applied to the electrolyzed water in the other electrolytic chamber, so that a DC current flows in the electrolyzed water, and acidic ionized water is supplied to one electrolyzed chamber to which the anode voltage is applied. And generating alkaline ionized water in the other electrolytic chamber to which the cathode voltage is applied; Detecting whether the electrolyzed water generated in the two electrolytic chambers is acidic or alkaline ionized water by detecting the polarity of the power supply of the DC current; Extracting acidic ionized water and alkaline ionized water from each of the two electrolytic chambers; Newly injecting the electrolyzed water into each of the two electrolytic chambers; A cathode voltage is applied to the electrolyzed water of the electrolytic chamber of one side and an anode voltage is applied to the electrolyzed water of the other electrolytic chamber, respectively, so that a DC current flows into the electrolyzed water, and alkaline ionized water is supplied to one electrolytic chamber to which the cathode voltage is applied. And generating acidic ionized water in the other electrolytic chamber to which the anode voltage is applied. The method of claim 1, wherein the time for applying a voltage to the electrolyzed water is variable. The method of claim 2, wherein the time for applying the voltage to the electrolyzed water is determined corresponding to the pH value of the electrolyzed water generated in the electrolytic chamber. 4. The method of claim 3, wherein the voltage is applied to the electrolyzed water between the step of applying a voltage to the electrolyzed water for the predetermined time corresponding to the pH value and the step of taking out the electrolyzed water generated in the electrolytic chamber. Electrolytic water generation method characterized in that it further comprises a step of preventing. At least two electrolysiss by designing a diaphragm through which hydrogen ions and hydroxide ions can permeate between a first electrode plate to which one of the positive or negative electrodes is connected and a second electrode plate to which the other of the positive or negative electrodes are connected An electrolytic cell in which a thread is formed, An inlet for injecting electrolyzed water into the electrolytic chamber; An outlet for taking out electrolytic water designed in each of the electrolytic chambers, Valves designed for each of the outlets, A polarity inversion circuit for reversing the polarity of the DC power supply connected to the first electrode plate and the second electrode plate at predetermined intervals; And a display unit for displaying the type of electrolyzed water taken out from the outlets, respectively. The method of claim 5, Detecting means for detecting a state in which the valve is opened; Integrating means for integrating the total time of the valve open state; And a determination circuit for preventing the supply of current between the electrodes when the total time accumulated by the integration circuit does not reach a predetermined reference time.