JPH07108272A - Method and apparatus for continuous preparation of ion rich water - Google Patents

Abstract

PURPOSE:To obtain ion rich water having an optional pH value without using a pH meter by determining the electric conductivity of clean water, determining required electric power of electrolysis based on the determined electric conductivity, and supplying the electric power of electrolysis to an electolyzer. CONSTITUTION:When the power source of an apparatus for generating ion rich water is turned on, a microcomputer 64, after being initialized, sets up an appropriate initial value of required power, calculates the flow rate of water supplied to an electrolyzer 12 based on the output of a flow sensor 52, takes in an aimed pH value set by an operator from a pH setting switch 86 to display on LED 88, confirms that the detected flow rate is not zero, and supplies power corresponding to the initial value of the required power to the electrolyzer 12. The electric conductivity of clean water is calculated from the electric potential of the junction between a resistor 82 for detecting electric current and a resistor 84 for detecting voltage so that the power is calculated with the pH set value. The power is supplied to the electrolyzer 12 to obtain ion rich water with a desired pH value.

Description

Detailed Description of the Invention

[0001]

[Object of the Invention]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention broadly relates to a technique for reforming tap water by electrolysis to adjust the hydrogen ion concentration (pH) of tap water. More specifically, the present invention relates to a method and apparatus for continuously producing hydrogen ion-rich acidic water and / or hydroxide ion-rich alkaline water by electrolysis of tap water. The present invention particularly relates to a method and an apparatus capable of obtaining ion-rich water having any desired pH value regardless of the quality of tap water.

[0002]

2. Description of the Related Art Hydroxide (OH ^- ) ^- rich alkaline water is conventionally called "alkali ionized water".
It is considered that when it is used as a drink, it has an effect of promoting health, and when it is used for tea, coffee, or the like, it has an effect of enhancing the taste. In addition, hydrogen ions (H ⁺ )
Rich acidic water is known to be suitable for boiling and washing the face of noodles, and strong acidic water with high hydrogen ion concentration is particularly useful for sterilizing and sterilizing kitchen cutting boards and cloths. Attention has been paid.

Therefore, various types of ion-rich water generators (often referred to in the industry as ion water generators) have been commercially available or proposed. The ion-rich water generator uses the electrolysis of water. At the interface between the anode and water, OH ⁻ existing in water due to ionization of water gives electrons to the anode and is oxidized to become oxygen gas. Removed from the system. As a result, the H ⁺ concentration is increased at the interface between the anode and water, and H ⁺ rich acidic water is generated. On the other hand, at the interface between the cathode and water, H ⁺ receives electrons from the cathode plate, is reduced to hydrogen, and is removed as hydrogen gas, so that the OH ⁻ concentration is increased and O ⁺ is present on the cathode side.
H ^- rich alkaline water is produced.

The initial ion-rich water generator was a batch treatment type, but today, a continuous treatment type apparatus for electrolyzing the tap water while passing the tap water through the electrolytic cell is generally used. The continuous ion-rich water generator has a diaphragm having an ion-permeable and impermeable membrane for preventing the acidic water generated on the anode side and the alkaline water generated on the cathode side from being mixed by electrolysis. Type device (for example, SHOkai 56-8
0292, JP-A-58-189090, JP-B-58-47985),
Non-diaphragm-type ion-rich water generation in which acidic water and alkaline water are separated without using a diaphragm by flowing water in a laminar flow form in a water passage between a pair of electrode plates arranged facing each other Device (for example, Japanese Utility Model Publication No. 57-8957, JP-A-4-284
889, Sankaihei 4-110189, and Japanese Patent Application No. 5-59498).

When producing ion-rich water, it is desirable to obtain ion-rich water (acidic water or alkaline water) having a desired pH value depending on the application. By the way, as described above, since the generation of ion-rich water is due to the electrolysis of water, in the continuous ion-rich water generator, the pH of the obtained ion-rich water is basically:
It is determined by the electrolytic strength and the flow rate of water flowing to the electrolytic cell. Therefore, in order to obtain the ion-rich water having a desired pH value, first, the electrolytic strength must be variably adjusted according to the target pH value and the water flow rate.

Further, it is known that the pH of the ion-rich water produced varies depending on the region. This is considered to be due to the fact that the water quality of the raw water, especially the content of bicarbonate ion (HCO ₃ ⁻ ) differs depending on the region. Graph of Figure 1 (horizontal axis is logarithmic scale)
In the case of pure water as the raw water, the pH of the produced water is linear according to the amount of H ⁺ (or OH ⁻ ) generated by electrolysis, as shown by the straight line A. Changes to. However, carbon dioxide in the atmosphere is actually dissolved in tap water such as tap water, and this dissolved carbon dioxide depends on the pH of the tap water such as bicarbonate ion (HCO ₃ ⁻ ) and carbonate ion (CO 2 ₃ ^2- ) and the following equilibrium state.

The CO ₂ ⇔ HCO ₃ ^- ⇔ CO ₃ ^2- equilibrium state changes depending on pH as shown in the graph of FIG. 2, and the abundance ratio of these carbonate radicals changes depending on pH. That is, at pH 8.3, all carbonate radicals are present in the form of bicarbonate ions, but when the pH becomes more alkaline than this, bicarbonate ions liberate hydrogen ions as in the following equation, and carbonate ions are generated.

HCO ₃ ⁻ → CO ₃ ² + + H ⁺ (1) On the contrary, when the pH is on the acidic side, carbon dioxide and water are produced while consuming hydrogen ions in the tap water as shown in the following formula.

H ⁺ + HCO ₃ ⁻ → CO ₂ + H ₂ O (2) Therefore, the bicarbonate ion (HCO ₃ ⁻ ) dissolved in tap water acts as a buffer component in the electrolysis of water, and the electrolysis is performed. The relationship between the amount of H ⁺ (or OH ⁻ ) generated by the above and the actually obtained pH is as shown by the curve B in the graph of FIG. That is, when the acidic water is to be generated, H ⁺ generated by electrolysis is consumed by the reaction of the formula (2) as shown by the shaded area C, and therefore, compared with the case where pure water is electrolyzed. H ⁺ cannot be increased without increasing the amount of electrolysis. Further, when alkaline water is to be obtained, as shown by the shaded region D, bicarbonate ions generate H ⁺ by the reaction of the formula (1), and therefore, similarly,
H ⁺ cannot be reduced unless the electrolysis is enhanced and the amount of OH ⁻ generated is increased as compared with the case of pure water.

Therefore, in order to obtain ion-rich water having a desired pH value, it is necessary to adjust the electrolytic strength according to the quality of raw water, more specifically, the amount of dissolved bicarbonate ion.

[0011]

DISCLOSURE OF THE INVENTION In the prior art,
It has been proposed that the pH value of ion-rich water flowing out of the electrolytic cell be detected by a pH sensor, and that the applied voltage or electrolytic power to the electrolytic cell be feedback-controlled so that the pH of the ion-rich water reaches a desired value. (For example,
5-22093, JP-A-5-64785). According to this method, the electrolytic power is feedback-controlled according to the pH value of the ion-rich water, so that ion-rich water having a desired pH value can be obtained regardless of the quality of the raw water.

However, the problem with this method is that the pH measuring technology available today has not realized a pH sensor that can be used for feedback control of the pH of ion-rich water. For example, a pH sensor based on the ion electrode method generates a considerable amount of noise due to the influence of the electric field in the electrolytic cell of the ion-rich water generator, and therefore cannot detect pH with the accuracy required for practical use. In addition, other types of pH sensors are not suitable for feedback control because they have poor responsiveness.

An object of the present invention is to provide a continuous ion-rich water producing method and apparatus capable of obtaining ion-rich water having a desired pH irrespective of fluctuations in water quality without using a pH sensor. That is.

[0014]

[Constitution of the invention]

Summary of Means and Actions for Solving the Problems The present inventor has found that there is a close correlation between bicarbonate ions dissolved in tap water and electric conductivity of tap water. The present invention is based on such findings, and the method and apparatus for producing ion-rich water of the present invention first determine the electrical conductivity of tap water, and determine the required electrolysis power based on the determined electrical conductivity. Then, the electrolytic power thus determined is supplied to the electrolytic cell to generate ion-rich water by electrolysis of clean water. Since there is a correlation between the electrical conductivity of tap water and bicarbonate ion, the electrolysis power is determined by determining the required electrolysis power based on the measured electroconductivity. It is a value considering the amount of. That is, when the electric conductivity of tap water is high, it is considered that the amount of bicarbonate ions is large, and the electrolysis power is increased accordingly.

Thus, the electric conductivity of tap water is determined,
Since the required electrolysis power is determined based on this electric conductivity, ion-rich water having a desired pH can be obtained without using a pH sensor. The electric conductivity of tap water can be determined by measuring the electrolysis voltage and the electrolysis current applied to the electrolytic cell, and calculating the electric conductivity based on the measured voltage and current. When the electric conductivity is calculated based on the voltage and the current as described above, the control circuit can be extremely simple and inexpensive. The electrolysis power supplied to the electrolytic cell can be increased or decreased according to the target pH value and flow rate of the ion-rich water.

The continuous ion-rich water generator of the present invention comprises an electrolyzer, means for setting a target pH value of the ion-rich water, voltage detecting means for detecting an electrolysis voltage applied to the electrolyzer, and electrolyzer. Current detecting means for detecting an electrolytic current applied to the electrode, electric conductivity calculating means for calculating the electric conductivity of tap water based on the voltage and current detected by the detecting means, and the target set by the setting means. A power calculation means for calculating a theoretical required electrolysis power according to the pH value and the electric conductivity calculated by the electric conductivity calculation means, a power supply means for supplying electrolysis power to the electrolysis cell, and an electrolysis cell. Control means for controlling the power supply means so that the generated electric power becomes the theoretical electrolysis power. Preferably, this apparatus further comprises flow rate detection means for detecting the flow rate of the clean water flowing through the electrolytic cell, and the power calculation means is the target pH value set by the setting means and the electric conductivity calculated by the electric conductivity calculation means. The theoretical electrolysis power is calculated based on the flow rate and the flow rate detected by the flow rate detecting means.

The above features and effects of the present invention, as well as other features and advantages, will be described in more detail according to the description of the following embodiments.

[0018]

EXAMPLES First, an example of the electrolytic cell usable in the present invention will be described with reference to FIGS. The electrolytic cell 12 of the illustrated ion-rich water generator 10 is of a diaphragmless type,
Three electrode plates, a first anode plate 16, a cathode plate 18, and a second anode plate 20, are sequentially arranged in the recess of the resin pressure-resistant case 14 while sandwiching a plurality of resin spacers 22, and a cover 24 is provided.
Can be configured to be liquid-tightly screwed to the case 14. Terminals 16 are provided on the electrode plates 16, 18 and 20.
A, 18A, and 20A are fixed, and are connected to a DC power supply described later.

As can be seen from FIG. 4, the case 14 has a clean water inlet 26, an alkaline water outlet 28, and an acidic water outlet 30. The clean water inlet 26 is a clean water distribution passage 32.
As can be seen from FIG. 5, the clean water distribution passage 32 is formed by the case 14 and the cover 24 and extends over the entire length of the electrode plate in the vertical direction.

As can be seen from the enlarged sectional view of FIG.
A first water passage 34 is provided between the first anode plate 16 and the cathode plate 18.
And a second water passage 36 is formed between the cathode plate 18 and the second anode plate 20. These water passages 34 and 36 cooperate with the electrode plates 16, 18, and 20 to act as an electrolysis chamber. Each water passage 34 and 36 is divided into four upper and lower sub water passages by a spacer 22 extending in the horizontal direction. As shown in FIG. 5, these water channels 3
Since the upstream end portions of 4 and 36 are in communication with the clean water distribution passage 32, clean water flowing down along the distribution passage 32 from the clean water inlet 26 has four sub water passages of the respective water passages 34 and 36. , And flows in horizontally as shown in FIG. Since the space between the electrodes is sufficiently narrow and the capacity of the distribution passage 32 is large, the water flow flowing horizontally in the water passages 34 and 36 becomes a laminar flow, and the acidic water generated on the surface of the anode plate and the acidic water generated on the surface of the cathode plate are generated. The alkaline water can be recovered separately without the use of a diaphragm.

As shown in FIGS. 5 and 8, the downstream end portions of the water passages 34 and 36 acting as an electrolysis chamber are open to an alkaline water recovery passage 38 formed by the case 14 and the cover 24. . The alkaline water recovery passage 38 communicates with the alkaline water outlet 28, and, like the clean water distribution passage 32, extends over the entire vertical length of the electrode plate.

As can be seen from FIG. 5, the case 14 and the cover 24 are further formed with grooves 40 and 42 extending over the entire vertical length of the anode plates 16 and 20, respectively, and cooperate with the anode plates, respectively. Then acid water recovery passage 4
4 and 46 are formed. The lower ends of these acidic water recovery passages 44 and 46 merge at a communication port 48 (FIGS. 6 to 7) and further communicate with the acidic water outlet 30 (FIG. 4).

As best seen in FIGS. 3 and 8, the anode plates 16 and 20 have their downstream edges 16B.
Slits 16C and 20C that act as acidic water recovery ports are formed upstream of 20C and 20B, respectively, so that the acidic water that has passed through the slits 16C and 20C flows into the acidic water recovery passages 44 and 46. There is. The acidic water flowing out from the slits 16C and 20C is collected in the acidic water recovery passages 44 and 46, and is further sent to the acidic water outlet 30 from there.

When using the ion-rich water generator 10, the tap water inlet 26 can be connected to the tap of a water pipe by a hose or the like. The temperature and flow rate of clean water are detected by a temperature sensor 50 including a thermistor and a flow rate sensor 52 including an impeller and a pulse generator, respectively. Flow rate control valves 54 and 56 can be connected to the alkaline water outlet 28 and the acidic water outlet 30 of the electrolytic cell 12, respectively. When the acidic water obtained at the acidic water outlet 30 is used, the ratio of the flow rate of the alkaline water obtained at the alkaline water outlet 28 to the flow rate of the acidic water obtained at the acidic water outlet 30 is about 4: 1. When the alkaline water obtained at the alkaline water outlet 28 is used for controlling the flow rate control valve to, the flow rate controlling valve is adjusted so that the flow rate ratio between the alkaline water outlet 28 and the acidic water outlet 30 is, for example, about 3: 2. Can be controlled.

An embodiment of the power control circuit of this ion-rich water generator 10 is shown in FIG. In the illustrated embodiment, the control circuit 60 includes a switching power supply circuit 62 and a programmed microcomputer (hereinafter, microcomputer) 64 that controls the power supply circuit. In outline, the control circuit 60 causes the microcomputer 64 to theoretically calculate the required electrolysis power of the electrolytic cell 12 based on various parameters so that the electric power actually supplied to the electrolysis cell becomes the required electrolysis power. Further, the microcomputer 64 is configured to feedback control the switching power supply circuit 62. More specifically, the switching power supply circuit 62 includes a photocoupler 66, a capacitor 68 for smoothing the output of the photocoupler 66, a switching power supply IC 70 having a pulse width modulation function, a switching transistor 72, and a switching transformer 74.
Have. The current from the commercial AC power supply 76 is diode
It is full-wave rectified by the bridge 78, and its DC output is applied to the primary side of the switching transformer 74. The pulse width of the direct current flowing through the primary coil of the switching transformer 74 is controlled by the switching transistor 72 driven by the switching power supply IC 70, and the power corresponding to the duty ratio of the primary side pulse is the secondary power of the switching transformer 74. Induced by the coil. The secondary coil of the switching transformer 74 is connected to the anode plate and the cathode plate of the electrolytic cell 12 via the changeover switch 80 for reversing the polarity of the voltage. The changeover switch 80 is interlocked with a relay 81 driven by a microcomputer 64, and periodically removes deposits such as calcium carbonate adhering to the electrode plate by switching the polarity of the voltage applied to the electrolytic cell. belongs to.

Electrolytic cell 12 and switching transformer 74
A current detection resistor 82 for detecting the current flowing in the electrolytic cell is connected in series to the wiring connecting
A pair of voltage detecting resistors 84 for detecting the voltage applied to the electrolytic cell are connected in parallel. The connection of these resistors 82 and 84 is connected to the A / D conversion input terminal of the microcomputer, and the microcomputer 64 detects the current and voltage supplied to the electrolytic cell by periodically checking the potential of the connection. To do.

The control circuit 60 further provides a pH to allow the user to set a target pH for the ion rich water.
A setting switch 86 is provided, and its output is input to the input terminal of the microcomputer. The microcomputer 64 uses, for example, acidic water having a pH of 6.5 in the acidic water discharge mode, and pH 8.5, pH 9.0, or pH in the alkaline water discharge mode.
The alkaline water of 9.5 can be programmed to be selected, and the pH set value can be sequentially switched each time the pH setting switch 86 is pressed.
The microcomputer detects the target pH set by the user by periodically checking the pH setting switch 86. The set target pH value is displayed to the user by turning on any LED 88.

The microcomputer 64 is further supplied with the output of the thermistor 50 as a water temperature sensor at its A / D conversion input terminal and the output pulse of the flow rate sensor 52 via the input circuit 90.

Next, the operation of the microcomputer 64 will be described based on the flowchart of FIG. When the ion-rich water generator 10 is powered on by connecting the power outlet, the microcomputer is initialized (S10).
1). When the initialization is completed, an appropriate initial value is set as the required power (S102). This is because the required power value is learned as will be described later, but the learned value does not exist immediately after the power is turned on. Next, the output of the flow rate sensor 52 is input (S103), and the water flow rate to the electrolytic cell 12 is calculated (S104). Next, the pH setting switch 86 is checked (S105), and the target pH value set by the user is displayed on the LED 88 (S106). Next, it is determined whether the flow rate is zero (S107), and if it is zero, the output of the electric power value to the photocoupler 66 is stopped (S108),
A learning flag indicating whether or not the required power value has been learned is reset to zero (S109).

When the use of the apparatus is detected by detecting the flow rate in the flow rate determination (S107), it is determined whether the required power value has already been learned (S110). If not completed, the required power initial value set in S102 is read (S111), and a signal having a pulse width corresponding to the initial value is output from the power control terminal to the photocoupler 66 (S112). As a result, power supply to the anode plate and the cathode plate of the electrolytic cell 12 is started, and the electrolysis of tap water is started. The current I flowing between the electrode plates of the electrolytic cell and the voltage V applied between the electrode plates are detected by detecting the potential of the connection portion of the current detecting resistor 82 and the voltage detecting resistor 84.
Is detected (S113 to 114), and the electric conductivity κ of the tap water is calculated (S115).

The electric conductivity κ can be calculated based on the detected current I and voltage V as follows. First, the conductivity coefficient χ of clean water is calculated. The conductivity coefficient χ is expressed by the following equation.

Χ = S · d / A (3) (where S is the conductance of water, d is the electrode interval, and A is the electrode area) S = I / (V−V ₀ ) (V ₀ is hydrogen overvoltage ) Is substituted into the equation (3), χ = I · d / {(V−V ₀ ) A} (4) The equation (4) can be rewritten as follows.

Χ = K · I / (V−V ₀ ) (5) (where K is a constant) The conductivity coefficient χ of water substantially corresponds to the electrical conductivity κ (χ
= Κ), κ = K · I / (V−V ₀ ) (6) The electrical conductivity κ thus obtained is stored as a learning value in the memory of the microcomputer 64 (S116). Then pH
The set value and the flow rate Q are read (S117), and the required electrolysis power required to obtain ion-rich water having a desired pH is calculated (S118). The required power W can be calculated by the following equation.

W = K ₁ + K ₂ · Q + K ₃ · κ + K ₄ (pH−7) ² (7) (where K ₁ , K ₂ , K ₃ , and K ₄ are constants) The electric conductivity and bicarbonate ion concentration of tap water in various places were measured, and the results shown in FIG. 11 were obtained. This shows that there is a close correlation between the electrical conductivity of water and the concentration of dissolved bicarbonate ions. Therefore, the electric conductivity κ obtained by the equation (6) is used as an amount of bicarbonate ion, and the required electrolysis electric power W is theoretically calculated by the equation (7) and this electric power is supplied to the electrolytic cell. As a result, the ion-rich water having the pH value set by the user can be obtained.

The theoretical required electrolysis power W calculated in this way is stored in the memory as a learning value (S119),
The learning flag is set to "1" (S120), and the learning value is set to PI.
Photo coupler 66 by D control (proportional integral derivative control)
(S121). As a result, the switching power supply circuit 62 is feedback-controlled so that the electric power actually supplied to the electrolytic cell becomes the required electrolysis electric power W.

As described above, in the above-described embodiment, the electrolysis power corresponding to the electric conductivity of water, the target pH value set by the user, and the flow rate is supplied to the electrolytic cell. The ion-rich water having a desired pH value can be obtained irrespective of the fluctuation of the flow rate and the fluctuation of the flow rate.

[0037]

As described above, according to the present invention,
Electrolytic power that considers the amount of bicarbonate ions is supplied to the electrolytic cell based on the electrical conductivity of tap water, so ion-rich water with a desired pH value can be used in any region without using a pH sensor. Can be obtained.

When the electric conductivity is calculated by detecting the voltage and current applied to the electrolytic cell, the circuit structure can be made extremely simple and inexpensive.

Further, when the electrolysis power is determined in consideration of the flow rate, ion-rich water having a desired pH value can be obtained regardless of fluctuations in the flow rate.

[Brief description of drawings]

FIG. 1 is a graph showing the relationship between the amount of hydrogen ions generated by electrolysis of water and pH, and the horizontal axis is a logarithmic scale.

FIG. 2 is a graph showing changes in pH and abundance ratios of various carbonate groups.

FIG. 3 is an exploded perspective view of an electrolytic cell of the diaphragmless continuous ion-rich water generator of the present invention.

4 is a partially cutaway rear view of the electrolytic cell shown in FIG.

5 is a cross-sectional view taken along line VV of FIG. 4,
The electrode plates and spacers are omitted for simplification of the drawing.

6 is a cross-sectional view taken along the line VI-VI of FIG.

7 is a cross-sectional view taken along the line VII-VII of FIG.

FIG. 8 is an enlarged view of a portion inside a circle A in FIG.

FIG. 9 shows a power control circuit of the device of the invention.

FIG. 10 is a flowchart showing the operation of the microcomputer.

FIG. 11 is a graph showing the relationship between electrical conductivity and bicarbonate ion concentration.

[Explanation of symbols]

 10: Continuous ion-rich water generator 12: Electrolyzer 16, 18, 20: Electrode plate 62/64: Power control means 64: Electric conductivity calculation means, Power calculation means 76/78: Power supply means 82/64: Current detection means 84/64: Voltage detection means 86/64: pH setting means

Front page continued (72) Inventor Hiroshi Takamatsu 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu, Fukuoka Totoki Equipment Co., Ltd. (72) Inventor Shigeru Ando 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu, Fukuoka No. 1 Totoki Equipment Co., Ltd.

Claims (7)

[Claims] 1. The electrical conductivity of tap water is generated when electrolyzing the tap water while passing the tap water through the electrolytic cell to generate hydrogen ion-rich acidic water and / or hydroxide ion-rich alkaline water. And determining the required electrolysis power considering the amount of bicarbonate ions dissolved in tap water based on the electrical conductivity thus determined, and supplying the electrolysis cell thus determined electrolysis power. Continuous ion-rich water generation method. 2. The electric conductivity of tap water is determined by measuring an electrolysis voltage and an electrolysis current applied to an electrolytic cell, and calculating the electric conductivity based on the measured voltage and current. The method for producing ion-rich water according to claim 1, wherein 3. The method for producing ion-rich water according to claim 1, wherein the electrolysis power supplied to the electrolytic cell is adjusted according to the target pH value of the ion-rich water. 4. The method for producing ion-rich water according to any one of claims 1 to 3, wherein the electrolysis power supplied to the electrolytic cell is increased according to the flow rate of clean water flowing through the electrolytic cell. 5. The electroconductivity of tap water is generated when the tap water is electrolyzed while passing the tap water through the electrolytic cell to generate hydrogen ion-rich acidic water and / or hydroxide ion-rich alkaline water. A method for producing continuous ion-rich water, characterized in that the amount of electrolytic buffer component dissolved in tap water is determined by detection, and the electrolytic power supplied to the electrolytic cell is increased according to the amount of electrolytic buffer component. 6. A continuous ion-rich water, which is adapted to generate hydrogen ion-rich acidic water and / or hydroxide ion-rich alkaline water by electrolyzing the tap water while passing the tap water through the electrolytic cell. In the production apparatus, means for setting a target pH value of ion-rich water, voltage detection means for detecting an electrolysis voltage applied to the electrolytic cell, current detection means for detecting an electrolysis current applied to the electrolytic cell, and An electric conductivity calculating means for calculating the electric conductivity of the tap water based on the voltage and the current detected by the detecting means, a target pH value set by the setting means, and the electric conductivity calculating means. The power calculation means for calculating the theoretical required electrolysis power according to the electric conductivity, the power supply means for supplying the electrolysis power to the electrolysis cell, and the power supplied to the electrolysis cell are the theoretical electrolysis cells. And a control unit that controls the power supply unit so that the power is supplied to the continuous type ion-rich water generator. 7. The flow rate detecting means for detecting the flow rate of the clean water flowing through the electrolytic cell is further provided, and the electric power calculating means calculates the target pH value set by the setting means and the electric conductivity calculated by the electric conductivity calculating means. The ion-rich water generator according to claim 6, wherein the theoretical electrolysis power is calculated based on the conductivity and the flow rate detected by the flow rate detecting means.