JP2003251347A - Ionized water generating device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ionized water generating device capable of effectively conducting reverse-voltage cleaning without conducting useless reverse-voltage cleaning. <P>SOLUTION: Whether the reverse-voltage cleaning is necessary or not is judged according to the operating time of an electrolytic cell 12 which is measured by a timer. That is, when the energized time to first to third electrodes 14a, 15a and 16a which is measured by the timer reaches the preset predetermined time, the polarity of the applied voltage to the first to third electrodes 14a, 15a and 16a is reversed and the reverse-voltage cleaning is conducted. When the energized time to the first to third electrodes 14a, 15a and 16a does not reach the preset predetermined time, the polarity of the applied voltage to the first to third electrodes 14a, 15a and 16a is not reversed and the application of the voltage to the first to third electrodes 14a, 15a and 16a is stopped. As a result, the reverse-voltage cleaning can effectively conducted without conducting useless reverse-voltage cleaning. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to an ion water generator for electrolyzing water to produce acidic water and alkaline ionized water.

[0002]

2. Description of the Related Art The following structure is known as this type of ionized water generator. That is, an electrolytic cell for electrolyzing water supplied from a water source such as a water supply through a water supply path is housed in the main body case of the ionized water generator. The electrolytic cell is divided into two ionization chambers by a diaphragm that allows ions to pass therethrough, and electrodes are arranged in each of the ionization chambers. By applying a predetermined DC voltage between both electrodes, the water in the electrolytic cell is electrolyzed.

With the use of ionized water generators, electrodes,
In particular, there is a problem that calcium or the like is deposited on the surface of the cathode, in the ionization chamber on the cathode side, in the passage of the alkaline ionized water, etc., and the electrolysis capacity gradually decreases. In order to solve this problem, after the water supply to the electrolytic cell is stopped, the polarity of the voltage applied to the electrodes is reversed while the water is stored in the electrolytic cell to perform reverse electrolysis cleaning. Has been proposed in the past. By this reverse electrolysis cleaning, the calcium and the like deposited on the surface of the electrode are electrolyzed, and the calcium and the like deposited in the cathode side ionization chamber and the passage of the alkaline ionized water are dissolved by the acidic water generated by the reverse charge. To be removed.

[0004]

However, the above-mentioned conventional ion water generator has the following problems. That is, it has been configured that the reverse electrolysis cleaning is always performed after using the alkaline ionized water and the acidic water. For this reason,
For example, even when the usage time (strictly speaking, the electrode usage time) is short (for example, when water is mistakenly passed through the water and water is stopped immediately), reverse electrolysis cleaning is performed and a reverse voltage is applied to the electrodes. It Therefore, there is a possibility that the electrodes may be contaminated or damaged due to the reverse voltage being applied even if the electrodes are not contaminated.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an ionized water producing apparatus capable of effectively performing reverse electrolysis cleaning without performing unnecessary reverse electrolysis cleaning. To provide.

[0006]

The invention according to claim 1 is an ion water generator for electrolyzing water supplied to an electrolytic cell to produce acidic water and alkaline ionized water.
After stopping the water supply to the electrolyzer, in the ion water generator that reverses the polarity of the voltage applied to the electrodes in the state where water is stored in the electrolyzer to perform reverse electrolysis, It is the gist of the present invention to provide a control means for determining whether or not the reverse electrolysis cleaning is necessary.

According to a second aspect of the present invention, in the ionized water producing apparatus according to the first aspect, there is provided a time measuring means for measuring a use time of the electrolytic cell, and the control means is an electrolyzer measured by the time measuring means. The point is that the necessity of reverse electrolysis cleaning is judged based on the usage time of the bath.

According to a third aspect of the present invention, in the ionized water generator according to the second aspect, the time measuring means measures an energization time to the electrode as a use time of the electrolytic cell, and the control means controls the time. If the electrode energization time measured by the time measuring means has reached a predetermined time set in advance, it is judged that reverse electrolysis cleaning is necessary. Similarly, if the electrode energization time has not reached the predetermined time, the reverse operation is performed. The gist is that it was decided that electro-cleaning was unnecessary.

(Operation) According to the invention described in claim 1,
The water supplied to the electrolytic cell is electrolyzed to produce acidic water and alkaline ionized water. After the water supply to the electrolytic cell is stopped, it is judged whether or not the reverse electrolysis cleaning is necessary. When it is determined that the reverse electrolysis cleaning is necessary, the polarity of the voltage applied to the electrodes is inverted while the water is retained in the electrolytic cell, and the reverse electrolysis cleaning is performed. If it is determined that the reverse electrolysis cleaning is unnecessary, the reverse electrolysis cleaning is not performed.

According to the invention of claim 2, claim 1
In addition to the action of the ionized water generator described in (1), the necessity of reverse electrolysis cleaning is determined based on the usage time of the electrolytic cell measured by the time measuring means.

According to the invention of claim 3, claim 2
In addition to the action of the ionized water generator described in (1), the time for energizing the electrodes is measured as the time of use of the electrolytic cell. When the energization time to this electrode has reached a predetermined time set in advance, it is determined that back electrolysis cleaning is necessary, and when the energization time to the electrode has not reached the predetermined time, back electrolysis cleaning is unnecessary. To be judged.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment in which the present invention is embodied in a continuous water flow type electrolytic ion water producing apparatus is shown in FIGS. 1 and 2.
Follow the instructions below.

As shown in FIG. 1, an ionized water generator 11 is provided.
Is equipped with an electrolytic cell 12. The electrolytic cell 12 includes a first ionization chamber 14, a second ionization chamber 14 and a second diaphragm 13 having ion permeability.
It is divided into three chambers, an ionization chamber 15 and a third ionization chamber 16. The first electrode 1 is provided in each of the ionization chambers 14 to 16.
4a, the 2nd electrode 15a, and the 3rd electrode 16a are arrange | positioned via the terminal (not shown). First electrode 14a and third
The electrodes 16a are a set. First and third electrodes 14
A direct current voltage can be applied to the a and 16a and the second electrode 15a so that one becomes an anode and the other becomes a cathode by a regulator 32 described later, and the polarities thereof can be reversed. For example, a DC voltage is applied so that the first electrode 14a and the third electrode 16a are anodes and the second electrode 15a is a cathode, and conversely, the first electrode 14a and the third electrode 16a are
A DC voltage inverted so that the electrode 16a serves as a cathode and the second electrode 15a serves as an anode is applied.

Two inflow ports are formed at the bottom of the electrolytic cell 12, and the first ionization chamber 14 and the second ionization chamber 1 are respectively formed.
It corresponds to 5. A bifurcated water supply pipe 21 is connected to both inlets, and a manifold 22 and a flow sensor 23 are provided on the water supply pipe 21. Outflow ports are provided on the upper wall of the electrolytic cell 12 at positions corresponding to the second ionization chamber 15 and the third ionization chamber 16, respectively. A drainage pipe 24 and a water intake pipe 25 are connected to the two outlets, and a drainage electromagnetic valve 26 is provided on the drainage pipe 24.

A standing portion 24a having a predetermined length is formed on the base end side of the drainage pipe 24 so as to extend at a right angle to the upper surface of the electrolytic cell 12 and above the electrolytic cell 12. There is. A standing portion 25 having a predetermined length is provided on the base end side of the water intake conduit 25.
a is formed so as to be perpendicular to the upper surface of the electrolytic cell 12 and extend above the electrolytic cell 12.

In the water supply conduit 21, one end of a drainage conduit 27 is connected between the manifold 22 and the flow rate sensor 23, and the other end of the drain conduit 24 penetrates the manifold 22 and is also connected to the drain conduit 24. It is connected to the upstream side of the drainage electromagnetic valve 26.

In the manifold 22, the water supply pipe line 21 is connected in the middle of the drainage pipe line 27 so as to cross and communicate with each other. Further, in the manifold 22, a pair of manifold valves 28,
28 is provided so as to sandwich the water supply pipe line 21 therebetween. The manifold valve 28 is provided with a water flow control ball and a valve seat, and the water flow control ball is pressed against the valve seat by the pressure of water supplied into the manifold 22 via the water supply pipe line 21, and the water drain pipe line 27 is provided. To close. When the water supply is stopped, the water flow control ball separates from the valve seat, and the drainage pipe 2
7 communicate.

(Electrical Structure) Next, the ion water generator 1
The electrical configuration of No. 1 will be described. As shown in FIG. 2, the ionized water generator 11 includes a controller 31 including a CPU (central processing unit) and the like. The regulator 32, the flow rate sensor 23, and the drainage electromagnetic valve 26 are connected to the control device 31 via input / output interfaces (not shown).

The regulator 32 is an AC voltage (100V)
Is converted into a DC voltage, and the control device 31 and the drainage solenoid valve 26 are converted.
A DC operation power source is supplied to each part of the ionized water generation device 11, such as. Further, the regulator 32 is the control device 31.
Based on various current control signals output from the first to third electrodes 14a to 1 having a value corresponding to each current control signal.
A predetermined DC voltage is applied between the terminals of the electrolytic cell 12 so as to flow to 6a.

The regulator 32 has a switching relay 33. The switching relay 33 is based on the relay switching signal output from the control device 31, and the first to third electrodes 14a to 14a.
The polarity (positive / negative) of the DC voltage applied to each of 16a is reversed.

The control device 31 includes a ROM (Read On).
ly Memory), RAM (Random acc)
Ess Memory) and a timer 34.
The ROM stores various control programs for centrally controlling the entire ionized water generation device 11.
The RAM is a data storage area for expanding the control program of the ROM and executing various processes by the control device 31, that is, a work area.

The timer 34 includes electrodes 14a, 15a, 16
The energization time to a and the reverse processing time described below are measured. When the flow rate of water supplied to the electrolytic cell 12 detected by the flow rate sensor 23 reaches a predetermined value set in advance and this continues for a predetermined time set in advance, the control device 31 determines that the water is flowing (water passing). Detection). Further, when the flow rate detected by the flow rate sensor 23 falls below a preset predetermined value and this continues for a preset time,
Judge as water stopped (water stop detection).

The control device 31 constitutes a control means for judging the necessity of reverse electrolysis cleaning. Regulator 32 has each electrode 1
A power supply for applying or stopping a predetermined voltage to each of 4a, 15a and 16a is configured. The switching relay 33 constitutes a polarity switching means for switching the polarity of the voltage applied to each electrode 14a, 15a, 16a. The timer 34 constitutes a time measuring means for measuring the energization time to the electrode as the usage time of the electrolytic cell.

(Operation of the Embodiment) Next, the operation of the ionized water producing apparatus configured as described above will be described. In the present embodiment, the alkaline mode and the acidic mode can be selected by a selection switch (not shown). When the alkaline mode is selected, the alkaline ionized water can be taken out through the water intake conduit 25. When the acidic mode is selected, acidic water can be taken out via the water intake conduit 25. Further, after the use in the alkaline mode and the acidic mode, if the preset predetermined conditions are satisfied, the reverse electrolysis cleaning is automatically performed.

(Alkaline Mode) First, the alkaline mode will be described. In the alkaline mode, the control device 31 keeps the drainage electromagnetic valve 26 open. Further, the control device 31 controls the switching relay 33 so that the positive voltage is applied to the second electrode 15a and the negative voltage (ground voltage) is applied to the first electrode 14a and the third electrode 16a, respectively. In this state, when the user opens a faucet (not shown), water is supplied into the electrolytic cell 12 via the water supply conduit 21 and the manifold 22. At this time, the water supply line 2
Since the manifold valve 28 operates by the pressure of the water flowing through 1 to close the water drain pipe 27, the water in the water supply pipe 21 does not flow into the water drain pipe 27.

The electrolytic cell 1 detected by the flow sensor 23
The amount of water supply to 2 is a preset value (for example, 0.5 L
/ Min), which continues for a predetermined time (for example, 10 seconds) set in advance, the control device 31 determines that the water is flowing, and outputs a current control signal for alkaline mode to the regulator 32. The regulator 32 applies a negative voltage (ground voltage) to the first electrode 14a and the third electrode 16a, respectively, so that the electrolytic current according to the current control signal flows between the first to third electrodes 14a to 16a. Two
A positive voltage is applied to the electrode 15a.

In the electrolytic cell 12, magnesium ion (Mg ²⁺ ), sodium ion (Na ⁺ ), potassium ion (K ⁺ ) and calcium ion (Ca ²⁺ ) in the water.
Etc. are attracted to the first electrode 14a and the third electrode 16a, which are cathodes, respectively. Similarly, hydroxide ion (O
H ^-), sulfate ion (SO ₄ ^2-), nitrate ion (N
O ₃ ²⁻ ), chlorine ions (Cl ⁻ ) and the like are attracted to the second electrode 15a, which is a positive electrode. As a result, alkaline ionized water is produced in the first ionization chamber 14 and the third ionization chamber 16, respectively, and acidic water is produced in the second ionization chamber 15.

With the supply of water into the electrolytic cell 12, the acidic water in the second ionization chamber 15 is discharged to the outside via the drainage pipe 24. The alkaline ionized water in the first ionization chamber 14 and the third ionization chamber 16 is taken out to the outside via the water intake conduit 25.

The faucet is closed by the user, the amount of water supplied to the electrolytic cell 12 detected by the flow rate sensor 23 falls below a preset value (for example, 0.5 L / min), and this is set for a preset time. When it has continued for only 10 seconds (for example, 10 seconds), the control device 31 determines that it is in the water stop state.
Then, the control device 31 outputs a current stop signal to the regulator 32 to stop the voltage application to the first to third electrodes 14a to 16a, respectively.

In the water-stopped state, the pressure of the water flowing through the water supply pipe line 21 is lowered, so that the manifold valve 28 is opened and the drainage pipe line 27 is communicated. Therefore, the residual water in the electrolytic cell 12 joins the drainage pipe 24 through the drainage pipe 27 and is discharged to the outside.

(Acidic Mode) Next, the acidic mode will be described. In the acid mode, the control device 31 keeps the drainage electromagnetic valve 26 open. In addition, the control device 31
Outputs a relay switching signal to the switching relay 33, and the second
The switching relay 33 is controlled so that a negative voltage is applied to the electrode 15a and a positive voltage is applied to each of the first electrode 14a and the third electrode 16a. That is, the first electrode 14a, the second
The polarities of the electrode 15a and the third electrode 16a are opposite to those in the alkaline mode.

In this state, the faucet is opened by the user to start the supply of raw water, and the amount of water supplied to the electrolytic cell 12 detected by the flow rate sensor 23 is set to a predetermined value (for example, 0.5 L / min). ) Is reached and continues for a predetermined time (for example, 10 seconds) set in advance, the control device 31 determines that water is passing. Then, the control device 31 outputs a current control signal for the acidic mode to the regulator 32. The regulator 32 applies a positive voltage to each of the first electrode 14a and the third electrode 16a so that the electrolytic current corresponding to the current control signal flows between the first to third electrodes 14a to 16a, and the second electrode 15a. Apply a negative voltage.

In the electrolytic cell 12, hydroxide ion (OH ⁻ ), sulfate ion (SO ₄ ²⁻ ), nitrate ion (NO
₃ ²⁻ ) and chlorine ions (Cl ⁻ ) are attracted to the first electrode 14a and the third electrode 16a, respectively. Similarly, magnesium ion (Mg ²⁺ ) and sodium ion (N
a ⁺ ), potassium ion (K ⁺ ), calcium ion (Ca ²⁺ ) and the like are attracted to the second electrode 15a. As a result, acidic water is generated in the first ionization chamber 14 and the third ionization chamber 16, and alkaline ionized water is generated in the second ionization chamber 15.

As the water is supplied into the electrolytic cell 12, the acidic water in the first ionization chamber 14 and the third ionization chamber 16 is taken up by the intake pipe line 25.
It is taken out via. The alkaline ionized water in the second ionization chamber 15 is discharged to the outside via the drainage pipe 24.

The operation when the faucet is closed by the user is the same as in the alkaline mode described above. (Back Electrode Cleaning) Next, back electrolysis cleaning will be described. After use in the alkaline mode or the acidic mode, the energization time to each electrode 14a, 15a, 16a measured by the timer 34 is a preset predetermined time (5 seconds in this embodiment).
If above, reverse electrolysis cleaning is performed, and if it is less than the predetermined time, no reverse electrolysis cleaning is performed. The case where the time is less than the predetermined time is assumed to be, for example, a case where the water is mistakenly passed and the water is stopped immediately. The predetermined time is assumed to be the time when the water in the electrolytic cell 12 is replaced when passing water.

At the start of the reverse electrolysis cleaning process, that is, immediately after the detection of the water stop (for example, less than 1 second after the water stop is detected), the control device 31.
Closes the drainage electromagnetic valve 26. As a result, the accumulated water in the electrolytic bath 12 remains in the electrolytic bath 12 without being drained through the drainage pipe 27 and the drainage pipe 24. At this time, the inside of the electrolytic cell 12 is kept almost full, and the first electrode 14a, the second electrode 15a, and the third electrode 16a are each immersed in the accumulated water in the electrolytic cell 12.

(After Using Alkaline Mode) When the energization time measured by the timer 34 is continuously 5 seconds or more after the use in the alkaline mode, the controller 31 controls the first electrode 14a, the second electrode 15a and the second electrode 15a. The polarity of the voltage applied to the third electrode 16a is reversed, and reverse electrolysis cleaning is started. That is, the controller 31 controls the regulator 32 so that the positive voltage is applied to the first electrode 14a and the third electrode 16a, and the negative voltage is applied to the second electrode 15a.

Then, the deposits such as calcium deposited on the surfaces of the cathode side electrode in the alkaline mode, that is, the first electrode 14a and the third electrode 16a are electrolyzed. Further, in the alkaline mode, precipitates such as calcium deposited in the first ionization chamber 14 and the third ionization chamber 16 are dissolved by the acidic water generated in the first ionization chamber 14 and the third ionization chamber 16. At this time, the accumulated water in the electrolysis tank 12, that is, the reverse electrolysis cleaning drainage, is discharged into the drain line 24 and the intake line 25.
It does not flow in.

When the preset reverse charging time elapses, the controller 31 stops the voltage application to the first to third electrodes 14a to 16a, respectively. The range of the reverse charging time is 10 to 60 seconds, and the desirable range is 20 to 50 seconds.
The optimum range for the second is 30 to 40 seconds, and is 30 seconds in the present embodiment. If this range is exceeded, the electrode that will become the cathode during reverse electrolysis (in this case, the second electrode 1
Calcium or the like is deposited on the surface of 5a). Below this range, precipitates such as calcium adhered to the surfaces of the electrodes (in this case, the first electrode 14a and the third electrode 16a) that will become cathodes in the alkaline mode are not sufficiently removed.

When the reverse charging time has elapsed, the controller 31 stops the voltage application to the electrodes 14a, 15a, 16a and opens the drainage electromagnetic valve 26.
Then, the accumulated water in the electrolytic cell 12 joins the drainage pipe 24 through the drainage pipe 27 and is discharged to the outside. Above,
The reverse electrolysis cleaning after use in the alkaline mode is completed.

(After use in acidic mode) When the energization time measured by the timer 34 is continuously 5 seconds or more after use in the acidic mode, the control device 31 controls the first electrode 14a,
The polarities of the voltages applied to the second electrode 15a and the third electrode 16a are reversed, and reverse electrolysis cleaning is started. That is, the second
The controller 31 controls the regulator 32 so that a positive voltage is applied to the electrode 15a and a negative voltage is applied to the first electrode 14a and the third electrode 16a, respectively.

Then, deposits such as calcium deposited on the surface of the cathode side electrode, that is, the second electrode 15a in the acidic mode are electrolyzed. In addition, precipitates such as calcium deposited in the second ionization chamber 15 in the acidic mode are dissolved by the acidic water generated in the second ionization chamber 15. After the reverse electrolysis time has elapsed, the first to third electrodes 1
When the voltage application to 4a to 16a is stopped and the accumulated water in the electrolytic cell 12 is discharged by opening the drainage electromagnetic valve 26, the reverse electrolysis cleaning after use in the acidic mode is completed.

In this way, every time the electrolytic cell 12 is used, that is, every time the electrodes 14a, 15a, 16a are continuously energized for the predetermined time (5 seconds) or more, the reverse electrolysis cleaning is performed. , The surface of each electrode 14a, 15a, 16a is
Almost no adhesion of calcium etc. is always maintained. Thereby, ionized water having a stable pH (hydrogen ion concentration) over a long period of time can be obtained.

When the electrolytic cell 12 is not used, that is, when the electrodes 14a, 15a and 16a are not continuously energized for the predetermined time (5 seconds) or more, the reverse electrolysis cleaning is performed. Absent. This is because when the electrolytic cell 12 is not used, calcium or the like does not deposit on the surfaces of the electrodes 14a, 15a, 16a, etc., and the electrodes 14a, 15a, 16a are not contaminated. For this reason, useless back electrolysis cleaning is not performed.

If the faucet is opened during the reverse electrolysis cleaning process, that is, if the controller 31 detects water flow, the reverse electrolysis cleaning process is stopped and is selected immediately before the last stop of the water. When the existing mode is, for example, the alkaline mode, the alkaline mode is automatically selected and the alkaline ionized water is discharged. On the other hand, in the case of the acidic mode immediately before the last stop of water, purified water is discharged without applying a voltage to each of the electrodes 14a, 15a, 16a.

(Effect of Embodiment) Therefore, according to this embodiment, the following effects can be obtained. (1) Whether or not the reverse electrolysis cleaning is necessary is determined based on the usage time of the electrolytic cell 12 measured by the timer 34. When it is determined that the reverse electrolysis cleaning is necessary, after the water supply to the electrolysis tank 12 is stopped, the first water is retained in the electrolysis tank 12 in the first state.
~ The polarity of the voltage applied to the third electrodes 14a, 15a, 16a is reversed and the reverse electrocleaning is performed. If it is determined that the reverse electrolysis cleaning is unnecessary, the reverse electrolysis cleaning is not performed. For this reason, it is possible to effectively perform the reverse electrolysis cleaning without performing the unnecessary reverse electrolysis cleaning.

(2) When the usage time of the electrolytic cell 12 measured by the timer 34, that is, the energization time to each electrode 14a, 15a, 16a has reached a preset predetermined time, reverse electrolysis cleaning is necessary. Similarly, when the energization time has not reached the predetermined time, it is determined that the reverse electrolysis cleaning is unnecessary. Therefore, it is possible to clarify the criterion for determining the necessity of reverse electrolysis cleaning.

(3) When it is judged that the reverse electrolysis cleaning is necessary, the polarities of the voltages applied to the first to third electrodes 14a, 15a and 16a are reversed, and the predetermined voltage is set for a predetermined proper time ( In this embodiment, the voltage is applied only for 30 seconds. Therefore, more effective reverse electrolysis cleaning can be performed.

(Other Example) The embodiment may be modified as follows. The timer 34 may measure the water flow time (the time from the detection of water flow until the detection of water stoppage) as the usage time. By the way, at the same time as water flow detection, each electrode 14a, 1
The energization of 5a and 16a is started, and the energization of the electrodes 14a, 15a and 16a is cut off at the same time when the water stop is detected.

In this embodiment, the electrolytic cell 12 has two diaphragms 3.
Although it is a tank type, it may be a one-membrane, two-tank type. (Supplementary Notes) Next, the technical ideas that can be understood from the above-described embodiment and other examples will be additionally described below.

A power source for applying or stopping a predetermined voltage to the electrodes and a polarity switching means for switching the polarity of the voltage applied to the electrodes are provided, and the control means judges that reverse electrolysis cleaning is necessary. At times, the polarity switching means is controlled so as to invert the polarity of the voltage applied to the electrode, and the power source is controlled so that a predetermined voltage is applied to the electrode for a preset appropriate time, and the reverse voltage is applied. 2. When it is determined that cleaning is unnecessary, the polarity switching means is controlled so as not to reverse the polarity of the voltage applied to the electrode, and the power supply is controlled so that the voltage application to the electrode is stopped. ~ The ionized water production | generation apparatus as described in any one of Claim 3. According to this configuration, more effective reverse electrolysis cleaning can be performed.

An ion water generator for electrolyzing the water supplied to the electrolyzer to produce acidic water and alkaline ionized water, wherein the water is stored in the electrolyzer after the water supply to the electrolyzer is stopped. In the reverse-electrolytic cleaning method of the ionized water generator in which the polarity of the voltage applied to the electrodes is reversed in this state to perform the reverse-electrolytic cleaning, when the water supply to the electrolytic cell is stopped, the current is supplied to the electrodes. When the time has reached the preset predetermined time, the polarity of the voltage applied to the electrode is reversed to carry out reverse electrolysis cleaning, and the time for energizing the electrode has not reached the preset predetermined time Is a method for reverse electrolysis cleaning of an ionized water generator in which the voltage application to the electrode is stopped without reversing the polarity of the voltage applied to the electrode. According to this configuration, whether or not the reverse electrolysis cleaning is necessary is determined based on the usage time of the electrolytic cell, so that the reverse electrolysis cleaning can be effectively performed without performing the unnecessary reverse electrolysis cleaning.

An ion water generator for electrolyzing the water supplied to the electrolytic cell to produce acidic water and alkaline ionized water, wherein the water is stored in the electrolytic cell after the water supply to the electrolytic cell is stopped. In the method of reverse electrolysis cleaning of the ionized water generator in which the polarity of the voltage applied to the electrodes is reversed in the state where the reverse electrolysis cleaning is performed, after the water supply to the electrolytic cell is stopped, the reverse electrolysis cleaning is required. A method for reversely cleaning an ionized water producing device, which makes a determination as to whether or not to perform reversely cleaning based on this result.

The ion water generator according to any one of claims 1 to 4, wherein the control means stops the reverse electrolysis cleaning process when water flow is detected during the reverse electrolysis cleaning process. . According to this configuration, water can be taken out from the water intake conduit 25 by opening the faucet even during the reverse electrolysis cleaning process.

[0055]

According to the present invention, when performing the reverse electrolysis cleaning, it is determined whether or not the reverse electrolysis cleaning is necessary. Therefore, the reverse electrolysis cleaning can be effectively performed without wasteful reverse electrolysis cleaning. be able to.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of an ionized water generator according to this embodiment.

FIG. 2 is a block diagram showing an electrical configuration of the ionized water generator according to the present embodiment.

[Explanation of symbols]

11 ... Ion water generator, 12 ... Electrolyzer, 14a ... 1st
Electrode, 15a ... second electrode, 16a ... third electrode, 31 ... control device that constitutes control means, 32 ... regulator that constitutes power supply, 33 ... switching relay that constitutes polarity switching means,
34 ... A timer which constitutes a time measuring means.

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Claims (3)

[Claims] 1. An ion water generator for producing acidic water and alkaline ionized water by electrolyzing water supplied to an electrolytic cell, wherein water is supplied to the electrolytic cell after the water supply to the electrolytic cell is stopped. In an ionized water generator in which the polarity of the voltage applied to the electrodes is reversed to perform reverse electrolysis cleaning in a stored state, when performing the reverse electrolysis cleaning, a control unit that determines whether or not the reverse electrolysis cleaning is necessary Ionized water generator equipped with. 2. A time measuring means for measuring the use time of the electrolytic cell is provided, and the control means judges whether or not the reverse electrolysis cleaning is necessary based on the use time of the electrolytic cell measured by the time measuring means. The ionized water generator according to claim 1. 3. The time measuring means measures the energization time to the electrode as the use time of the electrolytic cell, and the control means sets the energization time to the electrode measured by the time measuring means to a preset predetermined time. The ion water generation according to claim 2, wherein when the current has reached the counter, it is determined that the back electrolysis cleaning is necessary, and when the time for energizing the electrodes does not reach the predetermined time, it is determined that the back electrolysis cleaning is unnecessary. apparatus.