JP2698955B2 - Electrolytic ionic water generator - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrolytic ionic water generator for electrolyzing treated water such as water or saline to produce acidic ionic water and alkaline ionic water.

[0002]

2. Description of the Related Art This type of apparatus is disclosed in, for example,
No. 0987, and if the DC voltage applied to both electrodes has been used for a long time without switching between positive and negative,
There is a problem that calcium, sodium, etc. adhere to the surface of the minus side electrode in a layered manner, lowering the electrical conductivity and making it impossible to obtain the desired electrolytic ionized water. It is common practice to switch the forward and reverse directions to peel off the above-mentioned deposits from the electrodes (hereinafter, this is referred to as reverse cleaning).

[0003]

In an electrolytic ionized water generator, an electrode is used in which the surface of a titanium substrate is reinforced by burning platinum plating or platinum iridium in consideration of the catalytic function and durability. However, for example, when switching from the ionized water generation state (positive voltage applied state) to the reverse voltage cleaning state (reverse voltage applied state), the electrode that is switched from plus to minus may be significantly affected and the duty ratio may decrease. . This is because the concentration of hydrogen ions H ^{+ in} the electrode chamber in which the plus side electrode is housed is high when a positive voltage is applied before backwashing, and this hydrogen ion H ⁺ switches from plus to minus during backwashing. Hydrogen dissolves into the platinum film and reacts with the internal titanium substrate by adsorbing on the surface of the deposited electrode and platinum-plating the surface of the titanium Ti substrate, and is non-metallic and poorly conductive. This produces titanium hydride TiH ₄ that expands in volume due to the lifting of the platinum plating at the interface between the platinum plating and the titanium substrate, thereby peeling off the platinum plating, and firing platinum iridium on the surface of the titanium substrate. In this method, iridium oxide IrO ₂ in the fired product reacts with hydrogen and is reduced to produce metal iridium which is easily soluble in water, which is eluted to expose the titanium base material and expose the exposed titanium base. This is because the material reacts with hydrogen to produce non-metallic titanium hydride having poor electrical conductivity. This phenomenon, that is, hydrogen embrittlement, occurs in any case as long as the electrode is made of a metal material. SUMMARY OF THE INVENTION The present invention has been made to address the above-described problem, and has as its object the hydrogen ion concentration in an electrode chamber accommodating an electrode that can be switched from plus to minus when switching from an ionized water generation state to a backwashing state, for example. And to prevent the electrode from being attacked.

[0004]

In order to achieve the above object, according to a first aspect of the present invention, there is provided an electrolytic ionized water generating apparatus in which a pair of electrodes made of a metal material are provided inside and a pair of electrodes are opposed to each other. An electrolytic cell in which a diaphragm is disposed between the electrodes to form a pair of electrode chambers for accommodating the respective electrodes, and that the treated water flows into and out of the two electrode chambers, and that a DC voltage applied to both the electrodes is positive. An electrode switching means for switching the reverse, a voltage application stopping means for stopping the application of voltage to both electrodes for a set time when the voltage application is switched by the electrode switching means, and an electrode for accommodating an electrode which is a positive electrode before the voltage application is switched The chamber is provided with alkaline ionized water introducing means for supplying alkaline ionized water when the voltage application is stopped by the voltage application stopping means. In this case, the supply amount of the alkaline ionized water supplied through the alkaline ionized water introduction means is desirably an amount that neutralizes or alkalizes the electrode chamber.

In the second aspect of the present invention, the electrolytic ionized water generator is provided with a pair of electrodes made of a metal material facing each other and a diaphragm disposed between the two electrodes to accommodate each electrode. An electrolytic cell in which a pair of electrode chambers are formed to allow treated water to flow into and out of the two electrode chambers; electrode switching means for switching forward and reverse of a DC voltage applied to both electrodes; A voltage application stopping means for stopping voltage application to both electrodes for a set time at the time of voltage application switching, and a reverse ion water introducing means for supplying reverse ion water to each of the electrode chambers when the voltage application is stopped by the voltage application stopping means. The configuration was adopted. In this case, it is preferable that the supply amount of the reverse ionic water supplied through the reverse ionic water introduction means is such that the inside of each electrode chamber is substantially neutralized.

[0006]

In each electrolytic ionic water generating apparatus according to the present invention, when treated water, such as water or saline, flows through both electrode chambers of the electrolytic cell in a state where a positive voltage is applied, the treated water in the electrolytic cell is treated. Is electrolyzed to discharge acidic ionized water having increased hydrogen ions from the electrode chamber of the positive electrode, and alkaline ionized water having increased hydroxyl ions is discharged from the electrode chamber of the negative electrode.

In the electrolytic ion water generating apparatus according to the first invention, the voltage application to both electrodes is stopped for a set time by the voltage application stopping means when the voltage application is switched by the electrode switching means. Before the voltage application is switched, the alkaline ionized water is supplied to the electrode chamber accommodating the electrode serving as the positive electrode by the water introducing means. For this reason, the concentration of hydrogen ions in the electrode chamber to which the alkaline ionized water is supplied quickly decreases, and it is possible to prevent the electrodes in the electrode chamber from being attacked by hydrogen ions when switching the voltage application by the electrode switching means. Therefore, the life of the electrode can be prolonged, and frequent backwashing can be performed, and desired ion water can be stably obtained without lowering the conductivity.

In the electrolytic ionic water generating apparatus according to the first aspect of the present invention, alkaline ionic water is supplied to an electrode chamber accommodating an electrode which can be switched from positive to negative when, for example, switching from the ion water generating state to the reverse cleaning state. In order to reduce the hydrogen ion concentration, the neutralization of the electrode chamber is completed in a shorter time and with a smaller amount of water than in the case of supplying neutral water to the electrode chamber and lowering the hydrogen ion concentration. can do.

On the other hand, in the electrolytic ionized water generator according to the second invention, the voltage application to the two electrodes is stopped for a set time by the voltage application stopping means when the voltage application is switched by the electrode switching means. Before the voltage application is switched by the water introducing means, the alkaline ionized water is supplied to the electrode chamber containing the positive electrode and the acidic ionized water is supplied to the electrode chamber containing the negative electrode. . For this reason, the electrolytic ion water in both electrode chambers is quickly neutralized together, and it is possible to prevent the electrodes from being attacked by hydrogen ions when switching the voltage application by the electrode switching means. Therefore,
The life of the electrode can be prolonged, and frequent backwashing is possible, so that desired ion water can be stably obtained without lowering the electrical conductivity.

Further, in the electrolytic ionic water generating apparatus according to the second invention, for example, when switching from the ionic water generating state to the backwashing state, the electrolytic ionic water in both electrode chambers is quickly neutralized. From the initial stage of washing, acidic ion water with increased hydrogen ions is generated in the electrode chamber of the positive electrode, and alkaline ion water with increased hydroxyl ions is generated in the electrode chamber of the negative electrode. Therefore, if the outflow passage of each ion water is switched in accordance with the backwashing, the electrolyzed ionic water can be generated and used in the same manner as the positive voltage application state in the reverse voltage application state during the backwashing. As a result, the ability to generate electrolytic ionic water can be significantly improved.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows an embodiment of the electrolytic ionized water generator according to the first invention, which comprises an electrolytic cell 10, an electrode switch 20, a power supply circuit 30, a storage tank 40, and a controller 50. It is constituted by. The electrolytic cell 10 includes a tank body 11 having a pair of inlets 11a and 11b and a pair of outlets 11c and 11d.
1, a pair of electrodes 12 and 13 disposed opposite to each other, and a diaphragm 16 disposed between the two electrodes 12 and 13 to form electrode chambers 14 and 15 for accommodating the electrodes 12 and 13, respectively. Each of the electrodes 12 and 13 is formed by platinum plating or baking platinum iridium on the surface of a titanium base material. The electrode chamber 14 communicates with the inlet 11a and the outlet 11c. Has an inflow port 11b and an outflow port 11d communicating with each other. In addition, each inflow port 11a, 11
b, a water valve V1 whose operation is controlled by the control device 50 and each of the manually adjustable flow rate adjustment valves V
A configuration is such that approximately the same amount of tap water is supplied through each of the introduction pipes P1 and P2 interposed with V2 and V3, and outlet pipes P3 and P4 are connected to each of the outlets 11c and 11d. . The water valve V1 is a well-known electromagnetic on-off valve, and its opening operation or closing operation is performed after receiving a valve opening signal or a valve closing signal from the control device 50.

The electrode switch 20 switches the direction of the DC voltage applied to both electrodes 12 and 13 in accordance with a signal from the control device 50, and switches the control device in the state shown by the phantom line in FIG. Power supply circuit 3 when receiving a positive signal from
The negative electrode of 0 is connected to the electrode 12, the positive electrode is connected to the electrode 13, and the power supply circuit 3 is connected when a reverse signal is received from the control device 50 in the state shown by the solid line in FIG.
The negative electrode of 0 is connected to the electrode 13 and the positive electrode is connected to the electrode 12. The power supply circuit 30 converts an AC voltage into a DC voltage having a predetermined value. When an OFF signal is received from the control device 50, the DC voltage between the negative electrode and the positive electrode becomes zero, and When an ON signal is received, a DC voltage of a predetermined value is applied between the negative electrode and the positive electrode.

The storage tank 40 stores a required amount of alkaline ionized water, and stores the alkaline ionized water stored therein in the electrolytic chamber 14 or 15 of the electrolytic cell 10 depending on the head.
Valve V that is disposed at a higher position than the electrolytic cell 10 so that the
5 is connected to the introduction pipe P1 through a connection pipe P6 interposed therebetween, and is connected to the introduction pipe P2 through a connection pipe P7 interposed with an open / close valve V6 controlled by the control device 50. In the storage tank 40, a part of the alkaline ionized water discharged through the outlet pipe P3 when a positive voltage is applied is pumped up by means such as a pump (not shown) and stored. An overflow pipe 42 is provided. Open / close valve V
Reference numerals 5 and V6 denote valves that are resistant to acid and alkali, and are driven by an electric motor (not shown). The opening or closing operation is performed after receiving a valve opening signal or a valve closing signal from the control device 50. This is performed in a predetermined time (approximately 5 seconds).

The control device 50 includes an ion water generation switch 5.
1, a reverse cleaning switch 52 and a stop switch 53, and based on the operations of the switches 51, 52, 53, the water valve V1, the electrode switch 20, and the power supply circuit 30.
The operation of the on-off valves V5, V6 and the like is controlled, and the respective operations described below can be obtained by operating the switches 51, 52, 53.

When the electrolytic ionized water generator is stopped, the water valve V1 and the on-off valves V5, V6
Is closed, the electrode switch 20 is held in the state shown by the solid line in the drawing,
When the DC voltage between the negative electrode and the positive electrode of the power supply circuit 30 is set to zero, and the ion water generation switch 51 of the control device 50 is operated in such a state, a valve opening signal is sent from the control device 50 to the water valve V1. The water valve V1 is output and the water valve V1 is opened, and an ON signal is output from the control device 50 to the power supply circuit 30 to apply a predetermined DC voltage between the negative electrode and the positive electrode of the power supply circuit 30. Through both electrodes 12 of the electrolytic cell 10,
13 is applied with a positive voltage.

For this reason, tap water as treated water is supplied to each of the electrolysis chambers 14 and 15 of the electrolytic cell 10 through the water valve V1, the respective flow control valves V2 and V3, and the respective introduction pipes P1 and P2. The acidic ionized water in which the hydrogen ions have been increased is discharged from the electrode chamber 15 of the plus side electrode 13 through the outlet pipe P4 and becomes usable. Alkaline ionized water with increased ions is discharged from the outlet pipe P3
And is ready for use. When used in this state for a long time, calcium, sodium and the like contained in tap water adhere to the surface of the negative electrode 12.

By the way, when the reverse cleaning switch 52 of the control device 50 is operated in the above-mentioned ionized water generation state,
An OFF signal is output from the control device 50 to the power supply circuit 30, a valve opening signal is output to the opening / closing valve V 6, a reverse voltage signal is output to the electrode switch 20, and a direct current between the negative electrode and the positive electrode of the power supply circuit 30 is output. When the voltage is reduced to zero, the on-off valve V6 is opened at a predetermined time, and the connection of the electrodes is switched from the solid line state to the virtual line state in the electrode switch 20 by the electrode switch 20, and the electrode 12 of the electrolytic cell 10 is turned off. Is connected to the plus electrode of the power supply circuit 30 and the electrode 13 is connected to the minus electrode.

Therefore, when the open / close valve V6 is open, the voltage application is stopped, and the electrode chamber 1 is removed from the storage tank 40.
The alkaline ionized water is sequentially supplied to the electrode chamber 5, and the concentration of hydrogen ions remaining in the electrode chamber 15 is quickly reduced and neutralized. Thereafter, an ON signal is output from the control device 50 to the power supply circuit 30 and a valve closing signal is output to the opening / closing valve V6, so that a predetermined DC voltage is applied between the negative electrode and the positive electrode of the power supply circuit 30 and the switching operation is performed. The valve V6 is closed for a predetermined time, so that the electrode 13 is not exposed to ion water having a high hydrogen ion concentration when switching from the application of the positive voltage to the application of the reverse voltage.
The deposits such as calcium and sodium are peeled off from the tank and discharged together with the treated water to the outside of the electrolytic cell 10 to carry out reverse-current cleaning.

When the ionic water generation switch 51 of the control device 50 is operated in the above-described reverse cleaning state, an OFF signal is output from the control device 50 to the power supply circuit 30 and a valve opening signal is output to the on-off valve V5. Then, a positive signal is output to the electrode switch 20 to reduce the DC voltage between the negative electrode and the positive electrode of the power supply circuit 30 to zero, and the opening / closing valve V5 is opened for a predetermined time. The connection of the electrodes is switched from the state of the virtual line to the state of the solid line in the figure, and the electrode 12 of the electrolytic cell 10 is connected to the negative electrode of the power supply circuit 30 and the electrode 13 is connected to the positive electrode.

Therefore, when the open / close valve V5 is open, the voltage application is stopped and the electrode chamber 1 is removed from the storage tank 40.
The alkaline ionized water is sequentially supplied to the electrode chamber 4, and the concentration of hydrogen ions remaining in the electrode chamber 14 is quickly reduced and neutralized. Thereafter, an ON signal is output from the control device 50 to the power supply circuit 30 and a valve closing signal is output to the opening / closing valve V5, so that a predetermined DC voltage is applied between the negative electrode and the positive electrode of the power supply circuit 30 and the switching operation is performed. The valve V5 is closed for a predetermined time, so that the electrode 12 is not exposed to ionized water having a high hydrogen ion concentration when switching from reverse voltage application to positive voltage application.

When the stop switch 53 of the control device 50 is operated in the above-described ionic water generation state, an OFF signal is output from the control device 50 to the power supply circuit 30 and a valve closing signal is output to the water valve V1. Then, the DC voltage between the negative electrode and the positive electrode of the power supply circuit 30 is reduced to zero, the water valve V1 is closed, and the electrolytic ionic water generator is stopped.

Further, when the stop switch 53 of the control device 50 is operated in the above-described reverse power cleaning state, the control device 50 is operated.
, An OFF signal is output to the power supply circuit 30, a valve closing signal is output to the water valve V1, a valve opening signal is output to the opening / closing valve V5, and the electrode switching device 2
0, a positive signal is output, the DC voltage between the negative electrode and the positive electrode of the power supply circuit 30 is reduced to zero, the water valve V1 is closed, and the open / close valve V5 is opened for a predetermined time and the electrode is switched. The connection of the electrodes is switched from the state of the virtual line to the state of the solid line in the vessel 20, and the electrode 12 of the electrolytic cell 10 is connected to the minus electrode of the power supply circuit 30 and the electrode 13 is connected to the plus electrode.

Therefore, when the opening / closing valve V5 is open, the voltage application is stopped and the electrode chamber 1 is removed from the storage tank 40.
The alkaline ionized water is sequentially supplied to the electrode chamber 4, and the concentration of hydrogen ions remaining in the electrode chamber 14 is quickly reduced and neutralized. Thereafter, a valve closing signal is output from the control device 50 to the on-off valve V5, and the on-off valve V5 is closed for a predetermined time.
The electrolyzed ionized water generator enters a stopped state. Therefore, even if the ion generation switch 51 of the control device 50 is operated after the operation of the stop switch 53, the electrode 12 connected to the negative electrode of the power supply circuit 30 is not exposed to ionized water having a high hydrogen ion concentration.

In short, in the present embodiment, the voltage application to both electrodes 12 and 13 is stopped for a set time by the cooperative action of the control device 50 and the power supply circuit 30 when the voltage application is switched by the electrode switch 20. At the time of stoppage, the alkaline ionized water is supplied from the storage tank 40 to the electrode chamber for accommodating the positive electrode before the voltage application is switched. For this reason, the concentration of hydrogen ions in the electrode chamber to which the alkaline ionized water is supplied quickly decreases and is neutralized, and when the voltage application is switched by the electrode switch 20,
Electrodes in the electrode chamber can be suppressed from being attacked by hydrogen ions. Therefore, the life of the electrode can be prolonged, and frequent backwashing can be performed, and desired ion water can be stably obtained without lowering the conductivity.

Also, for example, when the alkaline ionized water is supplied to the electrode chamber 15 accommodating the electrode 13 which is switched from plus to minus when switching from the ionized water generation state to the reverse cleaning state, the hydrogen ion concentration is reduced. Therefore, the electrode chamber 15 can be neutralized in a shorter time and with a smaller amount of water than in the case where neutral water is supplied to the electrode chamber 15 to lower the hydrogen ion concentration.

In the above embodiment, the tap water is directly treated water, but it is also possible to use salt water contained in a tank and supplied to each electrode chamber by an electric pump as treated water. Further, in the above embodiment, the electrode chamber where the hydrogen ion concentration is high is substantially neutralized when the voltage application is switched by the electrode switch 20.
It may be carried out in such a manner that the inside of the electrode chamber is alkalized, or it may be carried out such that hydrogen ions slightly remain in the same electrode chamber. In the above embodiment, the alkaline ionized water is supplied to the electrode chamber when the water valve V1 is open. However, when the alkaline ionized water is supplied to the electrode chamber, the water valve V1 is supplied.
Can be closed.

FIGS. 2, 3 and 4 show an embodiment of the electrolytic ionic water generator according to the second invention. This electrolytic ionic water generator comprises an electrolytic cell 110 and an electrode switch 120.
, A power supply circuit 130, storage tanks 140A and 140B, and a control device 150. Electrolytic cell 110
Are a pair of inlets 111a, 111b and a pair of outlets 1
A tank body 111 having 11c and 111d, a pair of electrodes 112 and 113 disposed in the tank body 111 to face each other,
Each electrode 11 is disposed between these two electrodes 112 and 113.
Each of the electrodes 112, 1 is constituted by a diaphragm 116 forming electrode chambers 114, 115 for accommodating the electrodes 112, 1
As 13, a material obtained by firing platinum plating or platinum iridium on the surface of a titanium base material is used, and an inflow port 111 a and an outflow port 111 c communicate with the electrode chamber 114.
An inflow port 111b and an outflow port 111d communicate with the electrode chamber 115. Further, a water valve V11 whose operation is controlled by the control device 150 and a manually adjustable flow rate adjusting valve V12,
Approximately the same amount of tap water is supplied through each of the introduction pipes P11 and P12 interposed with V13, and outlet pipes P13 and P14 are connected to the respective outlets 111c and 111d. The water valve V11 is a well-known electromagnetic on-off valve, and the opening or closing operation is performed after receiving a valve opening signal or a valve closing signal from the control device 150.

In this embodiment, the two inlet pipes P11 and P12 are connected by the connecting pipe P15 on the electrolytic tank 110 side from the two flow rate adjusting valves V12 and V13, and the connecting pipe P11 and the connecting pipe P15 are connected. And a connection portion between the introduction pipe P12 and the connection pipe P15 are provided with communication switching valves V14 and V15, respectively. In the middle of the connection pipe P15, an ON signal is received from the control device 150 to drive the OF pipe.
An electric pump PM11 that stops upon receiving the F signal is provided. On the other hand, both outlet pipes P13 and P14 are connected to connecting pipe P16.
The communication switching valves V16 and V17 are provided at the connection between the outlet pipe P13 and the connection pipe P15 and at the connection between the outlet pipe P14 and the connection pipe P15, respectively. Further, a flow path switching valve V18, an outlet side of each of the communication switching valves V16, V17 of the respective outlet pipes P13, P14.
V19 are provided.

Each communication switching valve V14, V15, V1
6, V17 is a valve resistant to acid and alkali,
Driven by an electric motor (not shown), the two electrode chambers 114, 115, the two inlet pipes P11, P12, the two outlet pipes P13, P14, and the two connection pipes P15, in response to a closed loop signal from the control device 150. The communication of the pipeline is switched so that a closed loop is formed by P16, and the switching operation is performed for a predetermined time (about 5 seconds) after receiving an open loop signal or a return signal from the control device 150.
It is to be performed in. On the other hand, each of the flow path switching valves V18 and V19 is a valve that withstands acid and alkali, is driven by an electric motor (not shown), and responds to a positive signal or a reverse signal from the control device 150 to each ion water. The switching operation is performed for a predetermined time (approximately 5 seconds) after receiving a positive signal or a reverse signal from the control device 150. FIG. The state after actuation in response to the signal is shown.

The electrode switch 120 switches the direction of the DC voltage applied to both the electrodes 112 and 113 in accordance with the signal from the control device 150, and switches between the forward and reverse directions in the state shown in FIG. When the negative electrode of the power supply circuit 130 is connected to the electrode 112 and the positive electrode is connected to the electrode 113 when a positive signal is received, and when a reverse signal is received from the control device 150 in the state shown in FIG. The negative electrode of the power supply circuit 130 is connected to the electrode 113 and the positive electrode is connected to the electrode 112. The power supply circuit 130 converts an AC voltage into a DC voltage having a predetermined value. When an OFF signal is received from the control device 150, the DC voltage between the negative electrode and the positive electrode becomes zero, and When an ON signal is received, a DC voltage of a predetermined value is applied between the negative electrode and the positive electrode.

The storage tank 140A on the left side of FIG. 2 is for storing a required amount of alkaline ionized water, and has a water level sensor 141A mounted therein.
A desired location can be supplied by a supply pipe P17 provided with an electric pump PM12 controlled by 50. On the other hand, the storage tank 140B on the right in FIG.
A required amount of acidic ion water is stored therein, and a water level sensor 141B is mounted inside the control unit.
Supply can be made to a desired location by a supply pipe P18 interposed with an electric pump PM13 controlled by zero. The storage tanks 140A and 140B are provided with overflow pipes 142A and 142B, respectively.

The control device 150 is a
1, reverse power operation switch 152 and stop switch 153,
And an alkaline ionized water supply switch 154 and an acidic ionized water supply switch 155.
51, 152, 153, 154, 155 and the water level sensors 141A, 141 of the storage tanks 140A, 140B.
1B, water valve V11, electrode switch 1
20, power supply circuit 130, each communication switching valve V14, V1
5, V16, V17, each flow path switching valve V18, V19
The operation of each of the electric pumps PM1, PM2, PM3, etc. is controlled.
By operating 2,153,154,155, each operation described below can be obtained.

In the state where the electrolytic ionized water generator is stopped, for example, the water valve V11 is closed, and the communication switching valves V14, V15, V16, V17 and the flow path switching valves V18, V19 are shown in FIG. State, and the electric pumps PM1, PM2, PM3 are stopped,
Further, the electrode switch 120 is held in the state shown in FIG.
The DC voltage between the negative electrode and the positive electrode of the power supply circuit 130 is zero, and the controller 15
When the positive-electrode operation switch 151 of “0” is operated, a valve opening signal is output from the control device 150 to the water valve V11 to open the water valve V11.
An ON signal is output from the power supply circuit 130 to the power supply circuit 130, and a predetermined DC voltage is applied between the negative electrode and the positive electrode of the power supply circuit 130, and this is applied to both electrodes 112 and 113 of the electrolytic cell 110 via the electrode switch 120. A positive voltage is applied.

For this reason, the water valve V11, the respective flow control valves V12 and V13, and the respective communication switching valves V1
4, V15 and each introduction pipe P11, P12, electrolytic cell 1
Tap water is supplied to each of the electrolysis chambers 114 and 115 of FIG. 10, and acidic ionized water in which hydrogen ions have been increased is electrolyzed in the electrolysis tank 110 and hydrogen ions are increased from the electrode chamber 115 of the plus side electrode 113. Flow path switching valve V1
9 and the outlet pipe P14, flows into the storage tank 140B and is stored therein.
From there, the alkaline ionized water with an increased amount of hydroxyl ions is supplied with the communication switching valve V16, the flow path switching valve V18 and the outlet pipe P
13 and flows into the storage tank 140A to be stored.

When the water level in each of the storage tanks 140A, 140B reaches the upper limit set value, this becomes the water level sensor 141A,
141B, and the control device 150
A signal is output from the controller 150 to the water valve V11 to close the valve.
And the DC voltage between the negative electrode and the positive electrode of the power supply circuit 130 is reduced to zero. Each ion water stored in each storage tank 140A, 140B is
Alkaline ionized water supply switch 15 of control device 150
By operating the electric pump PM12 or PM13 by operating the 4 or the acidic ion water supply switch 155, the electric pump PM12 or PM13 can be supplied to a desired location and used, and the water level in each of the storage tanks 140A and 140B can be reduced by such use. When it falls to the lower limit set value, this
41A and 141B, the control unit 150 outputs a valve opening signal to the water valve V11 based on the detection signal to open the water valve V11, and outputs an ON signal from the control unit 150 to the power supply circuit 130 to supply power. A DC voltage of a predetermined value is applied between the negative electrode and the positive electrode of the circuit 130, and each ion water is generated as described above and stored in each of the storage tanks 140A and 140B.

By the way, in the above-described state where the positive voltage is applied and the ionized water is generated, the reverse operation switch 152 of the control device 150
Is operated, the control device 150 outputs an OFF signal to the power supply circuit 130, and the communication switching valves V14, V1
5, V16 and V17 output a closed loop signal, an electric pump PM11 outputs an ON signal, and the electrode switch 120
And a reverse voltage signal is output to both flow path switching valves V18 and V19, the DC voltage between the negative electrode and the positive electrode of the power supply circuit 130 is made zero, and the respective communication switching valves V
14, V15, V16, V17 and both flow path switching valves V1
8 and V19 are switched from the state of FIG. 3 to the state of FIG. 4 at a predetermined time, the electric pump PM11 is driven, and the connection of the electrodes is switched from the state of FIG. The state is switched to the state of FIG.
The ten electrodes 112 are connected to the positive electrode of the power supply circuit 130, and the electrodes 113 are connected to the negative electrode.

Therefore, in the state where the voltage application is stopped, the alkaline ionized water in the electrode chamber 114 is supplied to the electrode chamber 115 by the action of the electric pump PM11 and the electrode chamber 1
The acidic ion water in 15 is supplied to the electrode chamber 114, and the ion water in both electrode chambers 114 and 115 is mixed and neutralized. After that, the control device 150 sends each communication switching valve V1
4, a return signal is output to V15, V16, and V17, and an OFF signal is output to the electric pump PM11.
0, an ON signal is output, and each communication switching valve V14,
V15, V16 and V17 are switched from the state of FIG. 4 to the state of FIG.
1 is stopped, and a predetermined DC voltage is applied between the negative electrode and the positive electrode of the power supply circuit 130. Thus, when switching from the application of the positive voltage to the application of the reverse voltage, the electrode 1
13 is not exposed to ionized water having a high hydrogen ion concentration, and in the initial stage of the application of the reverse voltage, deposits such as calcium and sodium adhered from the electrode 112 when a positive voltage is applied are peeled off and discharged out of the electrolytic cell 10 together with the treated water. Then, the backwashing is performed.

By the way, at the time of switching from the application of the positive voltage to the application of the reverse voltage, the two flow path switching valves V18 and V19 are switched from the state of FIG. 3 to the state of FIG. Since ion water is mixed and neutralized, the positive electrode 11
The acidic ionized water in which the hydrogen ions are increased is generated in the electrode chamber 114 of the negative electrode 113 and the electrode chamber 1 of the negative electrode 113.
At 15, alkaline ionized water with increased hydroxyl ions is generated, and the acidic ionized water flows from the electrode chamber 114 to the storage tank 140B through the communication switching valve V16, the flow path switching valve V18, and the outlet pipe P14, and the alkaline ionized water is discharged from the electrode chamber 114 to the storage tank 140B. The storage tank 140 passes from the chamber 115 through the communication switching valve V17, the flow path switching valve V19, and the outlet pipe P13.
Flow to A.

When the positive-electrode operation switch 151 of the control device 150 is operated in the above-described state where the reverse voltage is applied to the ionized water, the control device 150 sends an OF signal to the power supply circuit 130.
F signal is output, and each communication switching valve V14, V15,
A closed loop signal is output to V16 and V17, an ON signal is output to the electric pump PM11, a positive signal is output to the electrode switch 120 and both flow path switching valves V18 and V19, and a negative electrode and a positive electrode of the power supply circuit 130 are output. The DC voltage between the electrodes is reduced to zero, and each communication switching valve V1
4, V15, V16 and V17 are changed from the state of FIG. 3 to the state of FIG.
9 is switched from the state of FIG. 4 to the state of FIG. 3 at a predetermined time, and the electric pump PM11 is driven.
The electrode connection is changed from the state of FIG. 4 to the state of FIG.
, The electrode 112 of the electrolytic cell 110 is connected to the negative electrode of the power supply circuit 130, and the electrode 113 is connected to the positive electrode.

Therefore, when the voltage application is stopped, the acidic ion water in the electrode chamber 114 is supplied to the electrode chamber 115 by the action of the electric pump PM11, and the alkaline ion water in the electrode chamber 115 is supplied to the electrode chamber 114. The ion water in both electrode chambers 114 and 115 is mixed and neutralized. After that, the control device 150 sends each communication switching valve V1
4, a return signal is output to V15, V16, and V17, and an OFF signal is output to the electric pump PM11.
0, an ON signal is output, and each communication switching valve V14,
V15, V16 and V17 are switched from the state of FIG. 4 to the state of FIG.
1 is stopped, and a predetermined DC voltage is applied between the negative electrode and the positive electrode of the power supply circuit 130. Thus, when switching from reverse voltage application to positive voltage application, the electrode 1
12 is not exposed to the ionized water having a high hydrogen ion concentration, and at the initial stage of the application of the positive voltage, the deposits such as calcium and sodium adhered from the electrode 113 when the reverse voltage is applied are peeled off and discharged out of the electrolytic cell 10 together with the treated water. Then, the backwashing is performed.

When switching from reverse voltage application to positive voltage application, both flow path switching valves V18 and V19 are switched from the state shown in FIG. 4 to the state shown in FIG. Since ion water is mixed and neutralized, the positive electrode 11
In the third electrode chamber 115, acidic ion water with increased hydrogen ions is generated, and the electrode chamber 1 of the negative electrode 112 is formed.
At 14, alkaline ionized water having increased hydroxyl ions is generated, and the acidic ionized water flows from the electrode chamber 115 to the storage tank 140 </ b> B through the communication switching valve V <b> 17, the flow path switching valve V <b> 19 and the outlet pipe P <b> 14. The storage tank 140 passes from the chamber 114 through the communication switching valve V16, the flow path switching valve V18, and the outlet pipe P13.
Flow to A.

When the stop switch 153 of the control device 150 is operated in each of the above-described ionized water generation states, an OFF signal is output from the control device 150 to the power supply circuit 130 and a valve closing signal is output to the water valve V11. Is output, the DC voltage between the negative electrode and the positive electrode of the power supply circuit 130 becomes zero, and the water valve V
11 is closed, and the electrolyzed ionic water generation device enters a stopped state. Therefore, when the state is changed from the state in which the positive voltage is applied to the ionized water generation to the stopped state, the electrode switch 120 and the two flow path switching valves V18 and V19 are stopped in the state of FIG. When the state is changed from the state to the stop state, the electrode switch 120 and the two flow path switching valves V18 and V19 are stopped in the state of FIG.

In short, in the present embodiment, when the voltage application is switched by the electrode switch 120, the control unit 15
0 and the power supply circuit 130 cooperate to form the two electrodes 112, 1
13 is stopped for a set time, and when the voltage is stopped, the communication switching valves V14, V15, V16, V1
Before the voltage application is switched, alkaline ionized water is supplied to an electrode chamber for accommodating an electrode serving as a positive electrode and an electrode for accommodating an electrode serving as a negative electrode by a reverse ionized water introducing means comprising a motor 7 and an electric pump PM11. The chamber is supplied with acidic ionized water. For this reason, the electrolytic ion water in both electrode chambers is quickly neutralized together, and the electrode switch 120
When the voltage application is switched by the electrodes 112 and 113,
Can be suppressed from being attacked by hydrogen ions. Therefore, the life of the electrode can be prolonged, and frequent backwashing can be performed, and desired ion water can be stably obtained without lowering the conductivity.

When switching the voltage application state from the application of the positive voltage to the application of the reverse voltage or vice versa, the two flow path switching valves V18 and V19 are switched from the state of FIG. 3 to the state of FIG. 4 or vice versa. And both electrode chambers 114,
Since the ionized water in 115 is mixed and neutralized, acidic ionized water with increased hydrogen ions is generated in the electrode chamber of the plus side electrode from the initial stage of voltage application, and hydroxyl ion is generated in the electrode chamber of the minus side electrode. Alkaline ionized water with increased ions is generated, and the acidic ionized water flows to the storage tank 140B, and the alkaline ionized water flows to the storage tank 140A. Therefore, not only the ionic water generated when the positive voltage is applied but also the ionic water generated when the reverse voltage is applied can be stored in the storage tanks 140A and 140B and used effectively, and the generation capacity of the electrolytic ionic water can be greatly increased. Can be improved.

In the above embodiment, the communication switching valve V
14, V15, V16, V17 and the electric pump PM11 constitute reverse ionized water introduction means, and the power supply circuit 130
The counter ion water is supplied to the electrode chambers 114 and 115 when the voltage application is stopped by the cooperation of the controller 150 and the controller 150, for example.
A reverse ionized water introducing means is configured so that ion water can be supplied to each of the introduction pipes P11 and P12 from B by an electric pump, and each of the introduction pipes P11 from the storage tanks 140A and 140B to the electrode chambers 114 and 115 when voltage application is stopped. , P1
It is also possible to carry out the process in such a manner that the reverse ionized water is supplied to each of the two.

[Brief description of the drawings]

FIG. 1 is a diagram showing one embodiment of an electrolytic ionized water generator according to the first invention.

FIG. 2 is a diagram showing one embodiment of an electrolytic ionized water generator according to the second invention.

FIG. 3 is an enlarged view of a portion S in FIG. 2;

FIG. 4 is an operation explanatory view of a portion corresponding to FIG. 3;

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 10 ... Electrolyzer, 12, 13 ... Electrode, 14, 15 ... Electrode chamber, 16 ... Diaphragm, 20 ... Electrode switcher, 30 ... Power supply circuit,
40: storage tank, 50: control device, V4, V5, V6
... open / close valve, 110 ... electrolytic cell, 112, 113 ... electrode, 114, 115 ... electrode chamber, 116 ... diaphragm, 120 ...
Electrode changer, 130 ... power supply circuit, 140A, 140B ...
Storage tank, 150 ... Control device, V14, V15, V1
6, V17: communication switching valve, V18, V19: flow path switching valve, PM11: electric pump.

Claims (4)

(57) [Claims] 1. A pair of electrodes made of a metal material are opposed to each other, and a diaphragm is provided between the two electrodes to form a pair of electrode chambers for accommodating the respective electrodes. And an electrode switching means for switching the DC voltage applied to both electrodes between positive and negative, and suspending the application of voltage to both electrodes for a set time when the voltage is switched by the electrode switching means. Electrolytic ion comprising voltage application stopping means, and alkaline ionized water introducing means for supplying alkaline ionized water to the electrode chamber accommodating the electrode which is a plus electrode before switching the voltage application when the voltage application stopping means stops applying voltage. Water generator. 2. The electrolytic ionized water generation according to claim 1, wherein the supply amount of the alkaline ionized water supplied through the alkaline ionized water introducing means is an amount that neutralizes or alkalizes the electrode chamber. apparatus. 3. A pair of electrodes made of a metal material are disposed inside to face each other, and a diaphragm is provided between the two electrodes to form a pair of electrode chambers for accommodating the respective electrodes. And an electrode switching means for switching the DC voltage applied to both electrodes between positive and negative, and suspending the application of voltage to both electrodes for a set time when the voltage is switched by the electrode switching means. An electrolytic ionic water generator comprising: a voltage application stopping means; and a reverse ionic water introducing means for supplying reverse ionic water to each of the electrode chambers when the voltage application is stopped by the voltage application stopping means. 4. The electrolytic ionized water generator according to claim 3, wherein the supply amount of the reverse ionized water supplied through the reverse ionized water introduction means is an amount that substantially neutralizes each electrode chamber.