JPH06226257A - Device for forming electrolytic ionized water - Google Patents

Abstract

PURPOSE:To always keep the ion concentration of an electrolyzer within a specified range and to effectively form acidic water excellent in sterilizing power by measuring the electric resistance of water passing through the electrolyzer and controlling the flow rate of an injection pump by a control unit according to the measured results. CONSTITUTION:A device for forming electrolytic ionized water has an electrolyzer 3 which is connected to a DC power source 4 and where water is passed between positive and negative electrodes 3B to ionize it into acidic water and alkaline water, and mixed water of highly concentrated ionized water contg. positive and negative ions and city water are fed into the electrolyzer 3 from a mixer 10 by the operation of an injection pump 2. The highly concentrated ionized water contg. positive and negative ions is formed in a feed tank 1 into which an electrolytic melt is fed. In this case, a resistance sensor 5 for measuring the electric resistance of water passing through the electrolyzer 3 from a feeding tank 1 is provided and the rotation of the injection pump 2 is controlled by a control unit 6 based on the measurement signal to keep the ion concentration of the electrolyzer 3 within a specified range.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to ionized water which is alkaline ionized water (referred to as alkaline water in the present specification).
And acidic ionized water (described as acidic water in this specification)
A device for separating into and. In particular, the electrolytic ionized water generator of the present invention relates to an electrolytic ionized water generator that can be conveniently used to discharge high-concentration acidic water as sterilizing water.

[0002]

Acidic water containing chlorine has bactericidal power. Chloride ions can be contained by dissolving in sodium hypochlorite in water.
It is also possible to ionize water to obtain sterilized water containing chlorine ions. Ionized sterilizing water has an extremely excellent sterilizing power than sterilizing water in which chlorine is simply dissolved. Sterilized water obtained by ionizing water has strong acidity in addition to the sterilizing power of chlorine.
Moreover, the reason is that the redox potential is high.

In order to ionize water to separate it into alkaline water and acidic water, a pair of electrodes facing each other is energized. If a + -electrode plate is provided facing the water channel,
Acidic water collects near the electrodes and alkaline water collects near the electrodes. The acidic water collected at the + electrode contains − ions.
-The alkaline water that collects at the electrode contains + ions. Water contains chlorine and the like as ions. In addition, + ions include calcium ions, sodium ions, magnesium ions, potassium ions and the like.

In this way, the device for ionizing water is
A separator is arranged between the negative electrodes. The separator is a sheet material having ion permeability and prevents the ionized water from mixing with the alkaline water and the acidic water. Therefore, for the separator, a sheet material having fine voids through which water cannot freely pass is used. The pair of electrodes is connected to a DC power supply. In the electrolytic ionized water generator of this structure, water is introduced between the electrode and the separator, and a DC voltage is applied to the + and-electrodes. The inflowing water becomes alkaline water with a high + ion concentration in the vicinity of the − electrode, and becomes acidic water with a high − ion concentration in the vicinity of the + electrode.

When the tap water is ionized by this apparatus, the acidic water contains chlorine. The chlorine contained in the acidic water is chlorine added to tap water. Tap water has a small amount of chlorine added to prevent bacterial contamination. Therefore, acidic water containing chlorine can be obtained by ionizing tap water. However, the amount of chlorine added to tap water is considerably small, and acidic water obtained by ionization cannot contain a large amount of chlorine.

In order to increase the bactericidal activity by adding a large amount of chlorine to the acidic water, a high concentration of ionic water in which sodium chloride is dissolved in water may be added to the tap water for ionization. When the water in which sodium chloride is dissolved is ionized, chlorine becomes acidic water,
Sodium is separated into alkaline water. Therefore, acidic water can contain a high concentration of chlorine. The present inventor has developed the device shown in FIG. 1 to achieve this. This apparatus comprises a supply tank 1 for dissolving an ionized melt such as salt. The high-concentration ionized water obtained in the supply tank 1 is supplied to the electrolytic cell 3 by the injection pump 2. Electrolyzer 3
Can ionize a high concentration of ionized water to obtain a high concentration of acidic water. This device can obtain acidic water having a very low pH and containing a large amount of chlorine and having a strong sterilizing power.

[0007]

In order for this apparatus to ionize the acidic water containing a high concentration of chlorine, it is necessary to supply high concentration ionic water having a high chlorine concentration to the electrolytic cell 3. However, when this device is actually used, the supply tank 1
It is difficult to maintain a constant ion concentration. For example, even if a large amount of sodium chloride is supplied to the supply tank 1, the concentration difference may partially occur. Therefore, even if the injection pump 2 supplies the high-concentration ionized water from the supply tank 1 to the electrolytic cell 3 at a constant flow rate, the chlorine ion concentration contained in the acidic water fluctuates and the pH also fluctuates. Equipment that uses acidic water as sterilizing water is mainly used in food factories,
Restaurants, restaurants, etc. Therefore, the acidic water used is always required to have excellent sterilizing power. Even temporarily
If acidic water with low sterilizing power is discharged, it cannot be sterilized reliably.

The electrolytic ionized water generator is also used to obtain alkaline water for drinking. Alkaline water has the property of being excellent in dissolving power and penetrating power, in addition to the enriching action to soften things. Further, when tap water is ionized into alkaline water and acidic water, the alkaline water can reduce the content of chlorine. Therefore, alkaline water is used for drinking water, water for watering, coffee and tea water. Furthermore, alkaline water contains calcium ions that are important for the human body. Calcium is ionized as alkaline water contained in tap water. Therefore, the calcium concentration of alkaline water is determined by the calcium concentration of tap water. To increase the calcium concentration of alkaline water, add an ionized melt that becomes calcium ions when dissolved in the supply tank,
From here, high-concentration calcium ion water may be supplied to the electrolytic cell in the supply tank. However, this device also has difficulty in discharging alkaline water containing a constant concentration of calcium ions. This is because it is difficult to make the calcium ion concentration uniform in the supply tank.

The present invention was developed for the purpose of eliminating these drawbacks. The important object of the present invention is to
An object of the present invention is to provide an electrolyzed ionized water generator capable of constantly discharging acidic water having an excellent sterilizing power or discharging alkaline water of a constant concentration.

[0010]

The electrolytic ionized water producing apparatus of the present invention has the following constitution in order to achieve the above-mentioned object. The electrolyzed ionized water production apparatus includes an electrolyzer 3, a DC power supply 4, an injection pump 2, and a supply tank 1. The electrolytic cell 3 passes water between the positive and negative electrodes to ionize the water into acidic water and alkaline water. The DC power supply 4 supplies DC to the electrodes of the electrolytic cell 3. The injection pump 2 supplies highly concentrated ionized water containing + -ions to the electrolytic cell 3. The supply tank 1 is connected to the suction side of the injection pump 2 and supplies the ionized melt. This apparatus supplies the ionization melt to the supply tank 1. The high-concentration + -ion water generated in the supply tank 1 is
It is supplied to the electrolytic cell 3 by the injection pump 2. The electrolytic cell 3 separates the supplied water into acidic water and alkaline water and discharges the separated water.

Further, the electrolytic ionized water producing apparatus of the present invention comprises a resistance sensor 5 for measuring the electric resistance of water passing from the supply tank 1 to the electrolytic cell 3. Resistance sensor 5
Is provided in the flow path between the electrolytic tank 3 and the supply tank 1 and the electrolytic tank 3. The output of the resistance sensor 5 is input to the control unit 6. The control unit 6 controls the flow rate of the infusion pump 2 with the signal from the resistance sensor 5. The control unit 6 controls the flow rate of the injection pump 2 to supply the ionized water having a constant concentration from the supply tank 1.

[0012]

The electrolytic ion water producing apparatus of the present invention discharges acidic water and alkaline water as follows. The ionization melt such as sodium chloride or calcium compound is put in the supply tank 1. The ionized melt dissolves in the supply tank 1 and has a high concentration of +
-It becomes the ionized water. The injection pump 2 supplies the high-concentration ionized water in the supply tank 1 to the electrolytic cell 3. Since tap water is supplied to the electrolytic cell 3, the high-concentration ionized water is mixed with tap water and flows into the electrolytic cell 3. The resistance sensor 5 measures the resistance of water flowing into the electrolytic cell 3. Water resistance is a function of ion concentration. When the ion concentration of water supplied to the electrolytic cell 3 is high, the electric resistance of water increases. On the contrary, when the ion concentration is high, the electric resistance of water becomes small. The reason why the resistance of water changes depending on the ion concentration is that the ions move and a current flows through the water. In other words, the ions serve as carriers for electric current. The control unit 6 controls the flow rate of the infusion pump 2 with the output of the resistance sensor 5. When the resistance of water becomes higher than the set value and the ion concentration of the electrolytic cell 3 decreases,
The flow rate of the infusion pump 2 is increased. When the flow rate of the injection pump 2 increases, a large amount of high-concentration ionized water is supplied to the electrolytic cell 3 to increase the ion concentration. On the contrary, when the water resistance becomes lower than the set value, the control unit 6
The flow rate of the infusion pump 2 is reduced. When the flow rate of the injection pump 2 decreases, the amount of high-concentration ionized water supplied to the electrolytic cell 3 decreases, and the ion concentration is adjusted to be low. In this way, the control unit 6 always supplies high-concentration ionized water to the electrolytic cell 3 at a constant concentration. The mixture of tap water and high-concentration ionized water that has flowed into the electrolytic cell 3 is ionized into acidic water and alkaline water and then discharged.

[0013]

Embodiments of the present invention will be described below with reference to the drawings. However, the examples shown below exemplify an electrolytic ion water generator for embodying the technical idea of the present invention, the electrolytic ion water generator of the present invention, the structure and arrangement of components, Or the usage etc. are not specified below. The electrolytic ionized water generator of the present invention,
Changes may be made without departing from the scope of the claims.

Further, in this specification, for easier understanding of the claims, the numbers corresponding to the members shown in the embodiments are referred to as "claims column", "action column", and "action column". It is added to the members shown in the section of "Means for Solving the Problems". However, the members shown in the claims are
It is by no means specific to the members of the examples.

The electrolytic ionized water generator shown in FIG. 2 has a filter 7 for water, a flow rate sensor 8 for detecting the flow rate of water flowing from the filter 7 into the electrolytic cell 3, and ionizes the water passing through the flow rate sensor 8. Then, the electrolytic cell 3 for separating acidic water containing − ions and alkaline water containing + ions
And a DC power supply 4 for applying a DC voltage to the electrodes of the electrolytic cell 3.
And an on-off valve 9 connected to the inflow side of the filter 7.
And a mixer 10 connected between the flow rate sensor 8 and the electrolytic cell 3 to supply high-concentration ion water to tap water, an infusion pump 2 for supplying the high-concentration ion water to the mixer 10, and an inhalation of the infusion pump 2. And a supply tank 1 connecting the sides.

The filter 7 filters the supplied tap water with activated carbon and supplies it to the electrolytic cell 3. The casing 7 contains granular or sheet-shaped activated carbon.

In the electrolytic cell 3, plate-shaped electrodes 3B are arranged to face each other in a casing. A separator 3A is arranged between the electrodes 3B. The electrode 3B and the separator 3A are arranged in parallel at a predetermined interval. One electrode 3
B is connected to the + output terminal of the DC power supply 4, and the other electrode 3B is connected to the-output terminal. The separator 3A uses a microporous sheet that can pass ions but not water.

In the electrolytic cell 3, the upper electrode 3B is connected to + and the lower electrode 3B is connected to a-DC power source 4 in the figure. Therefore, − ions are collected near the upper + electrode 3B to become acidic water, and + ions are collected near the lower − electrode 3B to become alkaline water. Therefore, the electrolytic cell 3 is
The upper side of the separator is the acid channel and the lower side of the separator is the alkaline channel. A three-way switching valve 11 is connected to the discharge side of the electrolytic cell 3. The three-way switching valve 11 has a drainage port A.
The acidic water and the alkaline water are switched to and B and drained.

The flow rate sensor 8 detects the flow rate of tap water flowing into the electrolytic cell 3. The flow rate sensor 8 inputs the detected signal to the control unit 6. The control unit 6 controls the current flowing between the electrodes 3B according to the flow rate of tap water. The current between the electrodes 3B is controlled by voltage. The higher the voltage, the higher the current. The current between the electrodes 3B is increased in proportion to the flow rate of tap water. By increasing the current in proportion to the amount of water flowing in, the pH of the drained acidic water and alkaline water can be made uniform.

Assuming that the current between the electrodes 3B is constant,
When the flow rate of tap water is increased, the amount of electricity per unit flow rate decreases. Then, tap water is not sufficiently separated into + -ions, and the pH of acidic water and alkaline water approaches 7.5, which is neutral. By increasing the current as the flow rate increases, the amount of electricity per unit flow rate can be made equal.
When the amount of electricity is the same, the ratio of electricity to separate + -ions contained in water is made equal, and the pH of acidic water and alkaline water is adjusted.
Can be made uniform. Therefore, the flow sensor 8
The device for controlling the electric current between B has the feature that it can drain highly concentrated acidic water and alkaline water regardless of the flow rate of tap water.

The DC power source 4 controls the voltage applied to the electrode 3B by the signal from the control unit 6. The control unit 6 receives a signal from the flow sensor 8,
When the flow rate increases, the voltage of the electrode 3B increases. That is, the control unit 6 controls the output voltage of the DC power supply 4 so that the current between the electrodes 3B has a value proportional to the flow rate.

Further, the control unit 6 calculates the signal from the resistance sensor 5 to control the operation of the infusion pump 2. The resistance sensor 5 measures the electric resistance of water passing from the supply tank 1 to the electrolytic cell 3. In the device shown in FIG. 2, the electrode 3B of the electrolytic cell 3 is also used as the resistance sensor 5. The resistance sensor 5 measures the electric resistance of water by detecting the voltage and current applied to the electrode 3B. The electric resistance R of water can be calculated by the following formula. R = E / I However, in this formula, E is the voltage between the electrodes 3B, and I is the current between the electrodes 3B. Thus, by using the electrode 3B together with the resistance sensor 5, the electrical resistance of water can be measured with a simple structure.

To measure the current in electrode 3B, electrode 3
A current detection resistor R is connected in series between B and the DC power supply 4. The current detection resistor R causes a voltage drop proportional to the current. Therefore, the current across the electrode 3B can be measured by detecting the voltage across the current detection resistor R. The control unit 6 includes an amplifier that amplifies the voltage across the current detection resistor R, an A / D converter that converts the output signal of the amplifier into a digital signal, and a micro that calculates the current by calculating the output of the A / D converter. Built-in computer.

The microcomputer incorporated in the control unit 6 also detects the voltage of the electrode 3B. The electrical resistance of water is calculated from the detected voltage and current. The rotation speed of the infusion pump 2 is controlled from the calculated electric resistance of water. When the electric resistance of water increases, the rotation speed of infusion pump 2 increases, and when the electric resistance of water decreases, the rotation speed of injection pump 2 decreases. In this way, the control unit 6 controls the rotation of the infusion pump 2 to adjust the electric resistance of water within a certain range.

The injection pump 2 supplies a large amount of high-concentration ionized water from the supply tank 1 to the mixer 10 when the rotation speed is increased. When the supply amount of high-concentration ionized water increases, the electric resistance of water decreases. This is because the water flowing into the electrolytic cell 3 contains a large amount of + -ions. When the rotation speed of the injection pump 2 decreases, the high-concentration ionized water supplied to the mixer 10 decreases, and the +-
The ion concentration becomes low and the electric resistance becomes high. Therefore, the resistance sensor 5 detects the electric resistance of water, and the control unit 6 controls the rotation speed of the infusion pump 2 by this output signal, whereby the ion concentration of the electrolytic cell 3 can be controlled within a certain range.

The above apparatus measures the electric resistance of water flowing into the electrolytic cell 3 by detecting the voltage and current between the electrodes 3B of the electrolytic cell 3. The electrical resistance of water can be measured by, for example, providing a resistance sensor between the mixer 10 and the electrolytic cell 3 regardless of the voltage and current of the electrode 3B. The reason why the control unit 6 controls the rotation of the injection pump 2 by the output of the resistance sensor 5 is to keep the ion concentration in the electrolytic cell 3 constant.
The resistance of water between 0 and the electrolytic cell 3 can be measured.

The mixer 10 mixes the high-concentration ionized water supplied from the injection pump 2 with tap water and supplies it to the electrolytic cell 3. The injection pump 2 sucks high-concentration ionized water from the supply tank 1. The supply tank 1 is charged with an ionized melt that is dissolved in water and ionized in order to produce high-concentration ionized water. In the electrolytic ionized water producing apparatus for producing acidic water having a strong sterilizing power, sodium chloride is put into the supply tank 1. Sodium chloride is dissolved in the water in the supply tank 1 and ionized into negative chloride ions and positive sodium ions. The negative chloride ions are collected by the positive electrode 3B and drained as acidic water. A large amount of sodium chloride is added to the supply tank 1 in order to obtain a high-concentration ion water having a concentration as high as possible. A large amount of sodium chloride is dissolved from a saturated state to a supersaturated state and becomes highly concentrated ionized water. The supply tank 1 is charged with a larger amount of sodium chloride than is dissolved in water. In this state, the chlorine ion concentration in the supply tank 1 is kept considerably high. However, it does not always have a constant concentration of chlorine ions. It is not possible to eliminate partial uneven density. Even if the high-concentration ionized water in the supply tank 1 has uneven concentration, the supply amount of the injection pump 2 is controlled, so that the ion concentration in the electrolytic cell 3 can be adjusted uniformly.

In the electrolytic ionized water generator using alkaline water containing calcium, a calcium compound is added to the supply tank 1. As the calcium compound, any compound that is dissolved in water to form calcium ions can be used. The calcium ions dissolved in water in the supply tank 1 are supplied to the electrolytic cell 3 by the injection pump 2. The electrolytic cell 3 is
The supplied calcium ions are separated into alkaline water and discharged.

[0029]

The electrolytic ionized water producing apparatus of the present invention measures the electric resistance of water and controls the operation of the injection pump for supplying high concentration ionized water from the supply tank to the electrolytic cell. The injection pump supplies a large amount of high-concentration ionized water to the electrolytic cell when the ion concentration in the electrolytic cell decreases and the resistance increases. On the contrary, when the ion concentration in the electrolytic cell becomes high, the flow rate of the injection pump is reduced to control the ion concentration in the electrolytic cell to be low. In this way, the electrolytic ionized water production apparatus of the present invention, which controls the supply amount of high-concentration ionized water with the electrolytic cell and the control unit, can always ionize the water with a constant ion concentration in the electrolytic cell, and the constant It has the feature that it can stably discharge pH water. Therefore, in the apparatus of the present invention, when sodium chloride is supplied to the supply tank to discharge the acidic water, the acidic water having a strong sterilizing power and a small pH can be stably discharged. Further, even when used in a device for discharging alkaline water containing calcium ions, it has the feature that alkaline water containing calcium at a constant concentration can always be discharged.

[Brief description of drawings]

FIG. 1 is a schematic sectional view showing an example of a conventional electrolytic ionized water generator.

FIG. 2 is a schematic cross-sectional view of an electrolytic ionized water generator showing an embodiment of the present invention.

[Explanation of symbols]

1 ... Supply tank 2 ... Injection pump 3 ... Electrolyzer 3A ... Separator 3B ...
Electrode 4 ... DC power supply 5 ... Resistance sensor 6 ... Control unit 7 ... Filter 8 ... Flow rate sensor 9 ... Open / close valve 10 ... Mixer 11 ... 3-way switching valve R ... Current detection resistance

Claims (1)

[Claims] 1. An electrolytic cell (3) for passing water between positive and negative electrodes (3B) to ionize water into acidic water and alkaline water, and an electrolytic cell (3).
DC power supply (4) connected to the electrode (3B) and electrolyzer (3) +
-Injection pump for supplying highly concentrated ionized water containing ions
(2) and the ionization melt supply tank (1) connected to the suction side of the injection pump (2), the ionization melt is supplied to the supply tank (1), and is generated in the supply tank (1). In the electrolyzed ionized water generator configured to supply high-concentration ionized water to the electrolyzer (3) with the injection pump (2), and the electrolyzer (3) separates and discharges acidic water and alkaline water. , A resistance sensor (5) that measures the electrical resistance of water passing from the supply tank (1) to the electrolytic cell (3), and a control unit that controls the flow rate of the infusion pump (2) with the output of the resistance sensor (5).
(6) and the control unit (6) is an infusion pump.
An electrolytic ionized water generator characterized in that the flow rate of (2) is controlled to control the ion concentration of the electrolytic cell (3) within a certain range.