KR101116569B1 - Electrolyzed water generation apparatus - Google Patents

Abstract

Provided is an electrolytic water generating device capable of miniaturizing an electrolytic cell.

The electrolyzed water generator 1 includes a main body portion 3 having a reservoir 4, an electrolyzer 2 for generating electrolyzed water from water, and a circulation flow passage 14 via the reservoir 4 and the electrolyzer 2. ) And a circulation device 15 for circulating water in the circulation flow passage 14, and generates electrolytic water while circulating water between the reservoir 4 and the electrolytic cell 2, and generates the electrolytic water. 4) stored in.

Description

Electrolyzed Water Generator {ELECTROLYZED WATER GENERATION APPARATUS}

The present invention relates to an electrolytic water generating device.

DESCRIPTION OF RELATED ART The electrolytic water production | generation apparatus which has conventionally been known is provided with the water storage part which stores water, the electrolyzer which produces | generates electrolyzed water from the water supplied from this water reservoir, and the discharge port which discharges electrolyzed water produced | generated in this electrolyzer to the outside. (For example, patent document 1)

(Patent Document 1) Japanese Patent Application Laid-Open No. 2004-216349

In the conventional electrolytic water generator, since only one water can pass through the electrolyzer, there is a problem that the electrolyzer must be enlarged in order to reliably obtain electrolyzed water having a specified pH value.

Accordingly, an object of the present invention is to provide an electrolytic water generating device capable of miniaturizing an electrolytic cell in view of the above problems.

The electrolytic water generating device of the present invention is provided in a main body portion having a reservoir for storing water, an electrolytic cell for generating electrolytic water from water, a circulation passage through the reservoir and the electrolytic cell, and a bottom wall of the reservoir. It constitutes a circulation flow path, it is provided in the supply port which supplies the water in the said reservoir part to the said main body part, and is installed in the bottom wall of the said reservoir part, and stops the inflow of water to the said supply port when the quantity in the said reservoir part becomes below a prescribed quantity. And a distribution device for distributing water in the circulation passage, the electrolytic cell and the distribution device, generating electrolytic water while circulating water between the reservoir and the electrolytic cell, and storing the generated electrolytic water in the reservoir. And a control unit for executing the electrolytic water generation process.

In the present invention, the height of the partition wall is lower than the water level stored in the reservoir before the electrolytic water generation process, which is necessary to obtain electrolytic water having a prescribed pH by the electrolytic water generation process.

In this invention, the water level reference display part which shows the standard of the water level stored in the said water storage part is provided.

In the present invention, the water storage unit includes a raw water chamber through which water is supplied from the outside, and a water purification cartridge for filtering water flowing from the raw water chamber to the supply port, wherein the water level indication display indicates a water level reference in the raw water chamber.

In the present invention, the electrolytic cell and the distribution device operate by electric power, and the control unit stops the electrolytic water generation process when the current value flowing to either the electrolytic cell or the distribution device is not normal.

According to the present invention, electrolyzed water is generated while water is circulated between the reservoir and the electrolytic cell, and the generated electrolytic water is stored in the reservoir, whereby the water of the reservoir can be passed through the electrolytic cell a plurality of times. Compared with the structure which cannot pass water, an electrolytic cell can be miniaturized. In addition, according to the present invention, when the quantity in the reservoir is less than the specified quantity, the partition blocks the inflow of water into the supply port. Thus, electrolytic water satisfying the specified pH value can be obtained by stopping the water from passing through the electrolytic cell. .

One Embodiment of this invention is described, referring drawings.

As shown in Figs. 1 to 3, the electrolyzed water generating device 1 is free to be attached to and detached from the main body 3 having an electrolytic cell 2 for generating electrolyzed water from water, and an upper surface of the main body 3. A water storage portion 4 connected to store water, a drainage portion 5 for storing and draining the water discharged from the main body portion 3, which is freely connected to the lower portion of the main body portion 3, and the device 1 The control part 6 which drives and controls each part of () is provided. In the state where the water storage part 4 is connected to the main body part 3, the supply port 10 provided in the water storage part 4 and the water supply hole 11 provided in the main body part 3 communicate, and the water storage part ( The return port 12 provided in 4) and the water discharge port 13 provided in the main body 3 communicate with each other, whereby a circulation flow passage 14 through the reservoir 4 and the electrolytic cell 2 is formed. do. The water in this circulation flow path 14 is distributed by the pump 15 as a distribution apparatus provided in the main-body part 3. The electrolyzed water generator 1 controls each unit by the controller 6, generates electrolyzed water while circulating water between the reservoir 4 and the electrolyzer 2, and stores the generated electrolyzed water in the reservoir 4. At the same time, the wastewater generated in the main body 3 is drained to the drainage portion 5. Here, water is tap water, well water, river water, etc., for example.

Hereinafter, each part of the electrolytic water generator 1 will be described in detail.

As shown in FIG. 3, the water storage part 4 has the port case 16 formed in the substantially cylindrical shape with a bottom. In the cylinder of this port case 16, the bottomed substantially cylindrical partition body 17 is accommodated, and the partition inside of the cylinder of the port case 16 is about half of the upper side by this partition body 17. As shown in FIG. It is divided into a raw water chamber (18) which forms a part, and the water purification chamber (19) which forms about half of the lower side. Water is supplied to the raw water chamber 18 from the outside, and the water supplied to the raw water chamber 18 passes through the purified water cartridge 20 to the purified water chamber 19 and flows to the supply port 10. The port case 16 and the partition 17 are made of a transparent material so that the inside can be seen from the outside thereof.

In the bottom wall 17a of the partition 17, a substantially cylindrical recess 17b is formed which is recessed downward. The clean water cartridge 20 is fitted to this recess 17b from the top to the inside. The opening 17c is formed in the bottom wall of the recessed part 17b.

The water purification cartridge 20 has a case 20a formed in a substantially cylindrical shape. An inlet is provided in an upper portion of the case 20a, and an outlet is provided in a lower portion thereof. The purified water cartridge 20 contains an adsorbent such as granular or powdered activated carbon and a filter medium such as a hollow fiber membrane, for example, inside the case 20a. In the state where the purified water cartridge 20 is attached to the recessed portion 17b, the upper portion of the purified water cartridge 20 is exposed in the raw water chamber 18, and a water tap formed in the upper portion of the purified water cartridge 20 is supplied to the raw water chamber 18. It is to be avoided. In this state, the lower end of the purified water cartridge 20 is exposed from the opening 17c into the water purification chamber 19 so that the outlet port formed at the lower end thereof faces the water purification chamber 19. In this state, the raw water in the raw water chamber 18 is introduced into the purified water cartridge 20 from the tap of the purified water cartridge 20, and the purified water cartridge 20 adsorbs the impurities contained in the introduced raw water with the adsorbent. Impurities contained in the water are filtered by the filter medium to purify the water, and the purified water (purified water) is discharged from the outlet into the water purification chamber 19. This distribution of water is caused by the action of gravity.

Above the raw water chamber 18, the ceiling wall 22 in which the water supply port 22a was formed is arrange | positioned. The water supply port 22a is covered by the top opening lid 23 attached to the ceiling wall 22 so as to be openable and openable. Raw water is supplied into the raw water chamber 18 via the water supply port 22a in the state which opened the cover 23 upward.

Between the side wall of the partition body 17 and the port case 16, a flow path 24 extending upward from the water purification chamber 19 is formed, and a flow path (in the port case 16 or the ceiling wall 22) is formed. The water injection hole 24a is formed in the position used as the upper end of 24. In this embodiment, the pot case 16 separated from the main body 3 is made to be so hard that the water inlet 24a is lowered, so that the purified water stored in the water purification chamber 19 is passed through the flow path 24. It can be discharged from the water port 24a. In addition, in this embodiment, the spout 24a is covered by the top open lid 25 rotatably supported by the port case 16 or the ceiling wall 22 so that opening and closing is possible. In this case, when the pot case 16 is inclined, the lid 25 can be rotated by its own weight, the dynamic pressure of water, or the like, so that the water injection port 24a can be opened.

As shown in FIG. 4 and FIG. 5, the circulation flow path 14 which locates the water in the water purification chamber 19 of the water storage part 4 in the main body part 3 in the bottom wall of the water purification chamber 19 of the port case 16 is shown. ) And a return port 12 through which water is returned from the circulation flow path 14 located in the main body 3.

The supply port 10 communicates with the water supply port 11 of the main body 3, while the return port 12 communicates with the water discharge port 13 of the main body 3. The water supply port 11 is provided upstream of the circulation passage 14 in the main body portion 3 to receive water from the water storage portion 4. Moreover, the water discharge port 13 is provided in the downstream part of the circulation flow path 14 in the main-body part 3, and returns water to the water storage part 4. As shown in FIG. Between the supply port 10 and the water supply port 11, and between the return port 12 and the water discharge port 13 is sealed by the O-ring 26 as a sealing member to ensure watertightness. In addition, a water stop valve 27 is provided at the supply port 10 and the return port 12.

Since the supply port 10 and the return port 12 have the same structure, the water stop valves 27 provided in them have the same structure, and the water supply port 11 and the water discharge port 13 also have the same structure. As an explanation, the supply port 10, the water stop valve 27 provided in the supply port 10, and the water supply port 11 are demonstrated to an example. As shown in FIGS. 5-7, the water stop valve 27 can be seated with respect to the valve seat part 27a formed in the supply port 10, and this valve seat part 27a. For example, a rubber valve body 27b, a rod body 27c fixed to the valve body 27b, and an elastic member 27d for seating the valve body 27b on the valve seat 27a. Have The rod 27c is supported by the support member 27e disposed in the supply port 10 so as to vertically traverse the opening of the supply port 10 in a vertical direction. In the figure, since the cross section of the support member 27e is shown, it is a figure in which the supply port 10 was closed by the support member 27e, but the support member 27e in the supply port 10 is shown. The part other than the part where () is arrange | positioned is open. The elastic member 27d is, for example, a coil spring or the like, and the valve body 27b is attached to the valve seat 27a by biasing the valve body 27b toward the valve seat 27a via the rod 27c. Seat on. The water stop valve 27 closes the supply port 10 in a state where the valve body 27b is seated on the valve seat portion 27a (closed state of the water stop valve 27). Each of the water supply port 11 and the water discharge port 13 of the main body 3 is provided with a pin member 29 which is an opening member for opening the water stop valve 27. And when the water storage part 4 is attached to the main-body part 3, the pin member 29 pushes up the valve main body 27b through the rod 27c, and resists the pressing force of the elastic member 27d, and the valve main body ( 27b) is moved back from the valve seat part 27a, and the water stop valve 27 is opened. In this modified state, the supply port 10 and the water supply port 11 communicate with each other, and the return port 12 and the water jetting port 13 communicate with respect to the return port 12. Here, the O-ring 26 is a supply port 10 and the water supply port when the water stop valve 27 is in a modified state in the process of mounting and detaching the reservoir 4 relative to the main body 3. It is arrange | positioned in the position which always seals between the return port 12 and the water jetting port 13 between (11).

In addition, the water supply port 11 and the return port 12 are provided with a filter 30. This filter 30 is a metal mesh, for example.

3, the partition 31 is provided in the upper surface (lower surface) of the bottom wall of the water purification chamber 19 of the pot case 16. As shown in FIG. The partition wall 31 surrounds the supply port 10 and prevents the inflow of water into the supply port 10 when the amount of water in the reservoir 4 becomes less than the prescribed amount. The height of the partition 31 is placed in the water purification chamber 19 of the water storage part 4 before the electrolytic water generation process, which is necessary for obtaining electrolytic water having a specified pH by the electrolytic water generation process. It is below the level of the stored water. Preferably, it is lower than the water level which the following 1st water level reference display part 32 shows.

In addition, as shown in FIG. 2, on the peripheral surface of the port case 16, the first water level reference display unit 32 as a water level reference display unit indicating a standard of the water level stored in the water purification chamber 19 of the storage unit 4. ) Is formed. The first water level reference display unit 32 is a line drawn by, for example, ink. In addition, on the upper part of the partition 31, the 2nd level reference display part 33 as a level reference display part which shows the reference of the water level in the raw water chamber 18 is formed. The second water level reference display portion 33 is a step portion formed in the partition wall body 17.

As shown in FIG. The main body portion 3 has a housing body 41, which includes a pump 15, an electrolytic cell 2, a water supply port 11, a water discharge port 13, a control unit 6, and an operation unit ( 42) and the like.

The electrolytic cell 2 generates alkaline ionized water (anode water) and acidic water (anode water) as electrolytic water. As shown in FIG. 1, the electrolytic cell 2 is equipped with the cathode chamber 2a and the anode chamber 2b, and these cathode chambers 2a and the anode chamber 2b are partitioned by the diaphragm 2c. In the cathode chamber 2a, a cathode plate 2d serving as an electrode is disposed, while an anode plate 2e serving as an electrode is disposed in the anode chamber 2 '. As the negative electrode plate 2d and the positive electrode plate 2e, for example, a flat plate electrode formed in a rectangular shape is used. This electrode is formed by plating or baking Pt and Ir on Ti, for example.

The diaphragm 2c is formed in rectangular shape, for example. As the diaphragm 2c, a nonwoven fabric composed of polyethylene terephthalate or the like is used in a porous membrane such as polyethylene or tetrafluoroethylene.

As shown in FIG. 1, the inlets 2f and 2g of the cathode chamber 2a and the anode chamber 2b communicate with the water supply port 11. Specifically, the water supply port 11 is passed through the first pipe part 45a, the pump 15, the second pipe part 45b, the first flow path switch 46 as the flow path switcher, and the third pipe part 45c. Communicate with). The outlet 2h of the cathode chamber 2a communicates with the water discharge port 13 via the second flow path switch 47 as the flow path switch and the fourth pipe part 45d. The outlet 2i of the anode chamber 2b communicates with the drainage portion 5 via the fifth pipe portion 45e.

In this electrolytic cell 2, the first pipe part 45a, the pump 15, the second pipe part 45b, the first flow path switch 46 and the third are connected to the cathode chamber 2a and the anode chamber 2b. Water is introduced from the water supply port 11 via the pipe portion 45c. When voltage is applied between the negative electrode plate 2d and the positive electrode plate 2e, water in the negative electrode chamber 2a and the positive electrode chamber 2k is electrolyzed. In the negative electrode chamber 2a, alkaline ionized water is generated at the interface between the negative electrode plate 2d and water, and acidic water is generated at the interface between the positive electrode plate 2e and water in the positive electrode chamber 2b. Alkaline ionized water generated in the cathode chamber 2a flows out from the outlet 2h and reaches the water discharge port 13 via the second flow path converter 47 and the fourth pipe part 45d. The acidic water generated in the anode chamber 2b flows out of the outlet 2i and is discharged to the drainage portion 5 via the fifth pipe portion 45e.

In this way, the main body portion 3 is provided with a first pipe portion 45a, a pump 15, a second pipe portion 45b, a first flow path switch 46, and a third pipe portion 45c from the water supply port 11. ), An electrolytic flow passage 48 that reaches the water discharge port 13 via the electrolytic cell 2, the second flow path switch 47, and the fourth pipe portion 45d. The electrolytic flow path 48 forms a circulation flow path 14 together with the reservoir 4.

In addition, the main body portion 3 includes a sixth pipe portion 45f serving as a drainage flow passage branching from the electrolytic flow passage 48 up to the drainage section 5 on the upstream side of the electrolytic cell 2 in the electrolytic flow passage 48. It is prepared. Specifically, the sixth pipe portion 45f is connected to the first flow path switch 46 and communicates with the second pipe portion 45b via the first flow path switch 46. The first flow path switch 46 is, for example, a solenoid valve, and opens and closes the circulation flow path 14. The 1st flow path switch 46 opens the circulation flow path 14 by being energized (ON) as shown to (a) in FIG. 8, and opens the 2nd pipe part 45b and the 3rd pipe part 45c. At the same time as the communication, the communication between the circulation flow path (second pipe part 45b) on the upstream side of the flow path switching unit 46 and the sixth pipe part 45f serving as the drainage flow path are blocked. On the other hand, in the state where current is not energized (OFF) as shown to (b) in FIG. 8, the 1st flow path switch 46 closes the circulation flow path 14 by the pressing force of a biasing member, and this flow path switcher The circulation flow path (third pipe part 45c) and the sixth pipe part 45f on the downstream side of 46 communicate with each other and the communication between the second pipe part 45b and the third pipe part 45c is blocked. do.

Moreover, as shown in FIG. 1, the main-body part 3 is branched from the electrolytic flow path 48 in the downstream of the cathode chamber 2a of the electrolytic cell 2 in the electrolytic flow path 48, and the 5th pipe part A seventh pipe portion 45g as a drain flow passage communicating with 45e is provided. Specifically, the seventh pipe portion 45g is connected to the second flow path switch 47 and communicates with the outlet of the cathode chamber 2a via the second flow path switch 47. The second flow path switch 47 is, for example, a solenoid valve to open and close the circulation flow path 14. As shown in (c) of FIG. 8, this 2nd flow path switch 47 opens the circulation flow path 14 so that it is energized (on state), and the outlet 2h and the 4th pipe of the cathode chamber 2a are opened. While communicating the portion 45d, the communication between the circulation flow path (outlet 2h of the cathode chamber 2a) on the upstream side of the flow path switch 47 and the seventh pipe portion 45g serving as the drainage flow path is cut off. . On the other hand, in the state which is not energized (off state) as shown to (d) in FIG. 8, the 2nd flow path switch 47 closes the circulation flow path 14 by the pressing force of a biasing member, and this flow path switch 47 While communicating with the circulation flow path (outlet 2h of the cathode chamber 2a) and the seventh pipe portion 45g on the upstream side thereof, the outlet 2h and the fourth pipe portion 45d of the cathode chamber 2a are connected. ) To block communication.

As shown in FIG. 3, the mounting part 49 in which the water storage part 4 is mounted is provided in the upper part of the housing | casing 41 of the main-body part 3, The water supply port 11 and A water jet port 13 is provided.

Moreover, the cover 50 which covers the water supply port 11 and the water discharge port 13 is provided in this main-body part 3 as shown to FIG. 3, FIG. 9, and FIG. The cover 50 is attached to the housing body 41 so as to be rotatable, and the water supply port 11 and the water jetting port 13 are opened and closed in a state where the water storage part 4 is separated.

Moreover, the storage chamber 51 which accommodates the drain part 5 is provided in the lower part of the housing body 41 of the main-body part 3 as shown to FIG. 4 and FIG. The entrance and exit 51a is formed in the side part of the storage chamber 51, and the drain part 5 can be taken out and pressed in from this entrance and exit 51a.

The drain part 5 has the case 52 of an upper surface opening, and the ceiling plate 53 which closes the upper surface of this case 52. As shown in FIG.

As for the top plate 53, as shown in FIG. 12, the 5th pipe part 45e And an inlet 53a communicating with the outlet of the sixth pipe 45f, and the fifth pipe portion 45e. And the wastewater discharged from the sixth pipe 45f is introduced into the case 52 from the inlet 53a. In addition, a drain hole is formed in the ceiling plate 53, and the drain hole is covered with a top open type lid 54 attached to the ceiling plate so as to be openable and openable. In this embodiment, by draining the drain part 5 separated from the main body part 3 so that a drain hole may become downward, the waste water stored in the case 52 can be discharged | emitted from a drain hole.

In addition, as shown in FIG. 4, the electrolytic water generating device 1 is provided with a storage unit detection unit 61 as a first detection unit that detects a connection state of the storage unit 4 to the main body unit 3. The reservoir detection unit 61 is provided with a first permanent magnet 61a provided in the reservoir 4 and a first magnetic force detection circuit 61b provided above the main body 3 to detect the first permanent magnet 61a. Has In the state where the water storage portion 4 is attached to the main body portion 3, the water storage portion detection portion 61 detects the magnetic force of the first permanent magnet 61a by the first magnetic force detection circuit 61b. While 4) outputs a signal indicating that the main body part 3 is attached to the control part 6, while the water storage part 4 is separated from the main body part 3, the first permanent magnet 61a of the first permanent magnet 61a is removed. Since the magnetic force is not detected by the first magnetic force detection circuit 61b, the first magnetic force detection circuit 61b outputs a signal to the controller 6 indicating that the water storage portion 4 is separated from the main body portion 3. It is supposed to be done.

In addition, the electrolytic water generator 1 is provided with a drainage detecting unit 62 as shown in Figs. 4, 14, and 15. This drainage part detecting part 62 functions as a second detection part which detects the connection state of the drainage part 5 with respect to the main body part 3, and also functions as a 3rd detection part which detects the quantity of the drainage part 5. do. The drainage detection unit 62 includes, for example, a resin float 62a provided in the drainage portion 5, a second permanent magnet 62b fixed to the upper portion of the float 62a, and a main body portion 3. ) And a second magnetic force detecting circuit 62c for detecting the second permanent magnet 62b. The float 62a has a plurality of air chambers 62d formed by a lower opening and accommodating air. These air chambers 62d are partitioned by walls. This float 62a is accommodated in the detection chamber 52b built up by the wall 52a which is erected on the bottom face of the case 52 of the drainage part 5, and is attached to the support shaft 62e with respect to the wall 52a. It is connected freely by rotation.

In the drainage detecting unit 62 having such a structure, when the water quantity of the drainage portion 5 is equal to or less than a prescribed amount in a state where the drainage portion 5 is attached to the main body portion 3, as shown in FIG. 62a is located at the initial position, and in this state, the second magnetic force detection circuit 62c detects the magnetic force of the second permanent magnet 62b, and the drainage portion 5 is attached to the main body portion 3. In addition, a signal indicating that the quantity of the drainage portion 5 is equal to or less than a prescribed value is output to the controller 6. On the other hand, when the drainage flows into the drainage portion 5 and the water level of the drainage rises, drainage flows into the detection chamber 52 'and the float 62a rises from the initial position due to the buoyancy with the rise of the water level in the detection chamber 52b. Start to rotate. When the total amount of the drainage portion 5 exceeds the prescribed value, the second permanent magnet 62b is positioned outside the detection area of the second magnetic force detection circuit 62c as shown in FIG. In this state, the second magnetic force detection circuit 62c outputs a signal to the controller 6 indicating that no detection is made. In addition, since the second permanent magnet 62b is positioned outside the detection area of the second magnetic force detection circuit 62c even in the state where the drain 5 is separated from the main body 3, the second magnetic force detection circuit 62c is provided. Outputs a signal indicating that there is no detection to the control unit 6.

In addition, the electrolytic water generating apparatus 1 is provided with the accommodating container 64 as shown to FIG. 16 and FIG. The storage container 64 is attached to the lower portion of the reservoir 4 in a state separated from the main body 3 to block the supply port 10 and the return port 12. The storage container 64 is free to attach and detach with respect to the water storage part 4. This storage container 64 has a container main body 64a and a pair of sealing members 64b attached to the container main body 64a. One sealing member 64b is inserted from outside of the supply port 10 into the supply port 10 to block the supply port 10, and the other sealing member 64b is provided from the lower side of the return port 12. The return port 12 is inserted outside to block the return port 12.

In addition, the electrolytic water generating device 1 is provided with an operation unit 42 that accepts a user's operation as shown in FIG. 1. This operation part 42 is provided with various buttons, such as an alkali button and a washing button, and the warning display part 42a which emits light with LED etc. as an abnormality notification means, for example.

The control part 6 is a structure which has the microcomputer which has a CPU, RAM, ROM, and a timer, for example. In addition, the control section 6 is provided with a power supply circuit for supplying power to each part of the apparatus 1, so that the power supply of each part can be controlled. 18, the pump 15, the electrolytic cell 2, the 1st flow path switch 46, the 2nd flow path switch 47, the operation part 42, and the storage part detection part 61 are included in this control part 6, as shown in FIG. ) And the drainage detection unit 62 are connected. The control section 6 is also connected with a first ammeter 71 for detecting a current flowing through the pump 15 and a second ammeter 72 for detecting a current flowing in the electrolytic cell 2.

Next, a process including the electrolytic water generation process executed by the control unit 6 will be described with reference to FIG. 19. The control part 6 maintains a standby state when an alkali button or a washing button is not pressed (NO in step S1).

The control part 6 judges that the alkali button or the washing button was pressed by inputting from the operation part 42 that the alkali button or the washing button was pressed (YES in step S1), and processes according to the pressed button. Start (step S2). Specifically, the control section 6 executes the electrolytic water generation process when the alkali button is pressed. In this electrolytic water generation process, the control part 6 energizes the 1st flow path switch 46 and the 2nd flow path switch 47, turns them ON, and also the negative electrode plate 2d and the positive electrode plate 2e of the electrolytic cell 2 A voltage (constant voltage) is applied between and the pump 15 is driven. Accordingly, water circulates between the reservoir 4 and the electrolytic cell 2 of the main body 3. In this circulation process, the electrolytic cell 2 generates alkaline ionized water and acidic water from the water as electrolytic water. Alkaline ionized water is returned from the electrolytic cell 2 to the water purification chamber 19 of the water storage part 4 by the circulation flow path 14, and is supplied to the electrolytic cell 2 again. On the other hand, the acidic water is drained from the fifth pipe portion 45e to the drain portion 5 and stored in the drain portion 5.

During the electrolytic water generation process, the current flowing through the pump 15 and the current flowing through the electrolytic cell 2 are monitored by the first ammeter 71 and the second ammeter 72 (step S3), and when those currents are normal. Next (YES in step S3), the electrolytic water generation process is continued, and the electrolytic water generation process is performed for a prescribed time (NO in step S4) to generate alkaline ionized water having a specified pH.

When the prescribed time has elapsed (YES in step S4), the control unit 6 executes an end process of the electrolytic water generation process (step S5). Specifically, the driving of the pump 15 is stopped, the voltage application to the electrolytic cell 2 is stopped, the energization of the first flow path switch 46 and the second flow path switch 47 is stopped, and they are turned off. Shall be. By this electrolytic water generation process, alkaline ionized water of predetermined pH is stored in the purified water chamber 19 of the storage part 4.

Here, the control part 6 is to perform a pre-drain process before this electrolytic water generation process. In the pre-drainage treatment, the control unit 6 turns the first flow path switch 46 to the ON state, while the second flow path switch 47 is turned OFF, and drives the pump 15 in this state for a prescribed time. As a result, the residual water in the circulation flow passage 14 is discharged from the fifth pipe portion 45e and the seventh pipe portion 45g to the drain portion 5.

On the other hand, in step S3, the control unit 6 executes an abnormality notification process when either of the current flowing in the pump 15 and the current flowing in the electrolytic cell 2 is abnormal (NO in step S3) (step S6). ). This abnormality notification process turns on the warning display part 42a of the operation part 42. FIG. The flow then advances to step S5 to finish the electrolytic water generation process.

Moreover, when the washing | cleaning button is pressed (YES of step S1), the control part 6 performs a washing | cleaning process for a prescribed time (step S2-step S5). In the cleaning process, the control part 6 energizes the 1st flow path switch 46 and the 2nd flow path switch 47, turns them ON, and inverts the polarity of the negative electrode plate 2d and the positive electrode plate 2e. A prescribed time voltage (reverse voltage) is applied between these electrodes to drive the pump 15. When the prescribed time elapses, the application of the voltage to the electrolytic cell 2 is stopped, the driving of the pump 15 is stopped, and the energization of the first flow path switch 46 and the second flow path switch 47 is stopped and they are stopped. Turn off. Thereby, the water in the circulation flow path 14 communicating with the electrolytic cell 2 and the electrolytic cell 2 is discharged from the fifth pipe part 45e and the sixth pipe part 45f to the drainage part 5. The control part 6 performs the process of step S3 and step S6 also in this washing process similarly to the said electrolytic water production | generation process.

In addition, the control part 6 detects that the water storage part detection part 61 does not have the water storage part 4 attached to the main-body part 3, or the drainage detection part 62 is a drainage part in the main-body part 3, In the case where (5) is not attached and the drainage detection unit 62 detects that the amount of the drainage part 5 has reached the prescribed amount, the electrolytic water generation process and the washing process are not executed. Forbid). Specifically, even when the alkali ion button or the washing button is pressed in the standby state, when the water storage part 4 or the drainage part 5 is not attached to the main body part 3 or the quantity of the drainage part 5 When the prescribed quantity is reached, the electrolytic water generation process or the washing process is not started. In addition, when the water storage part 4 or the drainage part 5 is separated from the main body part 3 during the electrolytic water generation process or the washing process, or the quantity of the drainage part 5 during the electrolytic water generation process or the washing process depends on the prescribed quantity. When it reaches | attains, electrolytic water production | generation process and a washing process are stopped.

In addition, when the current value flowing to either of the electrolyzer 2 or the pump 15 is not normal, the controller 6 stops the electrolyzed water generation process.

As described above, in the present embodiment, the electrolytic water is generated while circulating water between the reservoir 4 and the electrolytic cell 2, and the generated electrolytic water is stored in the reservoir 4, thereby storing the reservoir 4. Water can be passed through the electrolytic cell 2 a plurality of times, so that the electrolytic cell 2 can be downsized as compared with a structure in which water can only pass through the electrolytic cell 2 once.

In addition, in this embodiment, pH of electrolyzed water can be adjusted by adjusting the execution time of an electrolytic water production | generation process.

In addition, in this embodiment, since the water storage part 4 is freely attached and detached with respect to the main body part 3, since the main body part 3 and the water storage part 4 can be stored separately, the degree of freedom of their storage location is Increase. For example, only the storage part 4 which stored alkaline ionized water can be stored in narrow storage places, such as a refrigerator.

In addition, in this embodiment, since the water stop valve 27 closes the supply port 10 and the return port 12 in the state in which the water storage part 4 separated from the main body part 3, the water storage part 4 It is possible to prevent the water in the reservoir 4 from leaking out from the supply port 10 and the return port 12 in the state where it is separated from the main body portion 3.

In addition, in this embodiment, when the water stop valve 27 is in a modified state in the process of attaching and detaching the water storage part 4 from the main body part 3, the o-ring 26 serving as a sealing member is the main body part 3. ) Is always sealed between the reservoir 4 and the reservoir 4, so that the water in the reservoir 4 is supplied to the supply port 10 and the return port in the process of mounting and detaching the reservoir 4 from the main body 3. Leaking from (12) can be prevented.

In addition, in this embodiment, when the prescribed time elapses, the control part 6 stops the pump 15 which is a distribution apparatus and stops voltage application to the electrolytic cell 2, so that electrolyzed water of the specified pH is carried out. You can certainly get it.

In addition, in this embodiment, since the drain part 5 is connected to the main body part 3 freely by attachment | attachment, it isolate | separates the drain part 5 from the main body part 3, and the place where the main body part 3 is provided, Since it can drain to another place, the freedom degree of the installation place of the main-body part 3 increases. In addition, the user can use the drainage (acidic water) of the drainage portion 5 when necessary.

In addition, in this embodiment, when the water storage part detection part 61 which is a 1st detection part detects that the water storage part 4 is not connected to the main-body part 3, the control part 6 does not perform electrolytic water production | generation process. As a result, the idle operation of the apparatus 1 can be prevented.

In addition, in this embodiment, when the drain part detection part 62 which is a 2nd detection part detects that the drain part 5 is not connected to the main body part 3, the control part 6 does not perform electrolytic water production | generation process. As a result, the idle operation of the apparatus 1 can be prevented.

In addition, in this embodiment, when the drain part detection part 62 which is a 3rd detection part detects that the quantity of the drain part 5 reached the prescribed quantity, the control part 6 does not perform electrolytic water production | generation process, It is possible to prevent the wastewater stored in the portion 5 from overflowing from the drain portion 5.

In addition, in this embodiment, since the supply port 10 and the return port 12 of the water storage part 4 separated from the main body part 3 can be blocked by the water stop valve 27 and the accommodation container 64, It is possible to more reliably prevent water from leaking from the supply port 10 and the return port 12.

In addition, in this embodiment, the 1st flow path switch 46 and the 2nd flow path switch 47 are used for the circulation flow path 14 and the drainage flow path (sixth pipe part 45f, 7th pipe part 45g). Since the communication state can be set variably, the water of the circulation flow path 14 can be prevented from flowing in a drain flow path, or the water of the circulation flow path 14 can flow into a drain flow path.

In addition, in this embodiment, since the filter 30 is provided in the water supply port 11 and the water discharge port 13, when a foreign material mixes in the water in the water storage part 4, the foreign material is returned to the main-body part 3; Inflow can be prevented by the filter 30. In addition, the filter 30 can prevent foreign matter from entering the main body portion 3 with the water storage portion 4 separated from the water supply port 11 and the water discharge port 13.

In addition, in this embodiment, the water storage part 4 is isolate | separated by covering the water supply port 11 and the water discharge port 13 with the cover 50 in the state in which the water storage part 4 was isolate | separated from the main-body part 3. The cover 50 can prevent the foreign matter from entering the main body portion 3 in the closed state from the water supply port 11 and the water discharge port 13.

In addition, in this embodiment, the purified water cartridge 20 is provided in the water storage section 4, whereby electrolytic water can be generated from the purified water.

Here, when the electrolytic water generation process is performed twice with respect to the water stored in the water storage part 4, alkaline ionized water of pH more than a predetermined pH (for example, pH10) may generate | occur | produce. Therefore, in this embodiment, even when it becomes such a use form, the partition 31 prevents generation | occurrence | production of alkali ion of pH exceeding a prescribed pH (for example, pH10). Specifically, in the electrolytic water generation process, since the acidic water is drained, the amount of water in the reservoir 4 decreases as the process proceeds. The height of the partition 31 is set to the height which prevents the inflow of water into the supply port 10 before alkali ion of pH exceeding a predetermined pH (for example, pH10) is produced | generated by the 2nd electrolytic water production | generation process. . As a result, the supply of water to the main body 3 (electrolyzed water) is stopped before alkali ions having a pH exceeding the specified pH (for example, pH 10) are generated.

In addition, in this embodiment, since the height of the partition 31 is lower than the level of the water stored in the water storage part 4 before the electrolytic water production | generation process required for obtaining electrolytic water of a predetermined pH (for example, pH7-10) by electrolytic water production | generation process, It is possible to prevent the supply of water to the electrolytic cell 2 to stop during the electrolytic water generation process.

In addition, in this embodiment, since the 1st water level reference display part 32 as the water level reference display part which shows the reference of the water level stored in the water storage part 4 is provided in the water storage part 4, the user is sent to the water storage part 4 Appropriate amount of water can be promoted, thus producing an appropriate amount of electrolyzed water.

In addition, in this embodiment, since the 2nd water level indication display part 33 which is a water level indication display shows the reference | standard of the water level in the raw water chamber 18, the user can promote the water supply of the appropriate quantity of water to the water storage part 4 to the user. Thus, it is possible to generate an appropriate electrolyzed water.

In addition, in this embodiment, the control part 6 stops electrolytic water production | generation process, when the electric current value which flows in either the electrolyzer 2 or the pump 15 is not normal, and produces electrolytic water whose pH value is not appropriate. You can prevent it. In addition, at this time, since the user is notified of the abnormality by the lighting of the warning display part 42a of the operation part 42, the user can recognize that the abnormality has occurred and can cope with it.

In addition, this invention is not limited to this embodiment, A various other embodiment can be employ | adopted in the range which does not deviate from the summary of this invention. For example, the second water level indication display, which is the water level indication display, may be a rod-shaped member or the like provided extending downward from the lid 23. The abnormality notification means may also notify the abnormality by voice.

1 is a configuration diagram schematically showing an electrolytic water generating device according to an embodiment of the present invention.

2 is an external view of an electrolytic water generating device according to an embodiment of the present invention.

3 is a cross-sectional view of an electrolyzed water generating device according to an embodiment of the present invention.

4 is a cross-sectional view showing a lower portion of an electrolytic water generating device according to one embodiment of the present invention.

5 is a cross-sectional view showing a connection state between a supply port and a water supply port in the electrolytic water generating device according to one embodiment of the present invention.

6 is a cross-sectional view showing a separation state between a supply port and a water supply port in the electrolytic water generating device according to one embodiment of the present invention.

7 is a cross-sectional view showing a step during connection of a supply port and a water supply port in the electrolytic water generating device according to one embodiment of the present invention.

8 is an explanatory diagram for explaining the operation of the flow path switcher in the electrolytic water generating device according to one embodiment of the present invention.

9 is a cross-sectional view showing a main body part in a state where a cover is opened in the electrolytic water generating device according to one embodiment of the present invention.

10 is a cross-sectional view showing a main body part in a state where a cover is closed in the electrolytic water generating device according to one embodiment of the present invention.

11 is a cross-sectional view showing a separation state of a main body portion and a drainage portion in the electrolytic water generating device according to one embodiment of the present invention.

12 is a plan view showing a drainage part in the electrolytic water generating device according to one embodiment of the present invention.

It is a perspective view which shows the case of a drain part in the electrolytic water production | generation apparatus which concerns on one Embodiment of this invention.

It is sectional drawing which shows the detection part for drainage parts in the electrolytic water generation apparatus which concerns on one Embodiment of this invention.

15 is a cross-sectional view showing a state in which the float of the detection unit for drainage part rotates in the electrolytic water generating device according to one embodiment of the present invention.

It is sectional drawing which shows a water storage part and a storage container in the electrolytic water production | generation apparatus which concerns on one Embodiment of this invention.

17 is a cross-sectional view showing a state in which an accommodating container is attached to a reservoir in the electrolytic water generating device according to one embodiment of the present invention.

18 is a block diagram showing an electric system in the electrolytic water generating device according to one embodiment of the present invention.

It is a flowchart which shows the process which a control part performs in the electrolytic water generation apparatus which concerns on one Embodiment of this invention.

(Explanation of symbols for the main parts of the drawing)

1: Electrolyzed Water Generator

2: electrolyzer

3: main body

4: water reservoir

6: control unit

10: supply port

14: circulation flow path

15: pump (distributor)

18: enemies

20: water purification cartridge

31: bulkhead

32: first water level reference display section (water level reference display section)

33: second water level reference display section (water level reference display section)

Claims (5)

A reservoir for storing water, A main body having an electrolytic cell that generates electrolyzed water from water, A circulation passage through the reservoir and the electrolytic cell; A supply port provided on the bottom wall of the reservoir to constitute the circulation passage and supplying water in the reservoir to the main body; A partition wall provided on the bottom wall of the reservoir to prevent the inflow of water into the supply port when the quantity of water in the reservoir becomes less than a prescribed quantity; A distribution device for distributing water in the circulation passage; A control unit for controlling the electrolytic cell and the circulation device to generate electrolyzed water while circulating water between the reservoir and the electrolytic cell, and to perform electrolytic water generation processing for storing the generated electrolytic water in the reservoir. Electrolyzed water generator. The method of claim 1, And the height of the partition wall is lower than the water level stored in the reservoir before the electrolytic water generation process, which is necessary to obtain electrolytic water having a predetermined pH by the electrolytic water generation process. The method according to claim 1 or 2, Electrolyzed water generating device having a water level reference display unit for indicating the standard of the water level stored in the water storage. The method of claim 3, wherein The water storage section includes a raw water chamber through which water is supplied from the outside, and a purified water cartridge for filtering water flowing from the raw water chamber to the supply port, The water level reference indication indicates the water level reference in the raw water chamber. Electrolyzed water generator. The method according to claim 1 or 2, The electrolyzer and the distribution device are powered by electric power, The control unit stops the electrolytic water generation process when the current value flowing to either the electrolytic cell or the distribution device is not normal. Electrolyzed water generator.

Images