JP3694107B2 - Electrolyzed water generator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electrolyzed water generating apparatus that electrolyzes treated water such as water or saline to generate acidic ion water and alkaline ion water.
[0002]
[Prior art]
A conventional electrolyzed water generating apparatus includes a pair of electrodes in an electrolytic cell, and the pair of electrodes is separated by a diaphragm to constitute an anode chamber serving as a first electrode chamber and a cathode chamber serving as a second electrode chamber. To do. When treated water such as water or saline is supplied to the inlet of each electrode chamber configured as described above and a predetermined DC voltage is applied to each electrode, hydrogen ions (H ⁺ are applied to the anode chamber to which a positive voltage is applied. ) Is generated, and alkaline ionized water with increased hydroxide ions (OH ⁻ ) is generated in the cathode chamber to which a negative voltage is applied. It is made to flow out from the outlet.
[0003]
In such an electrolyzed water generating device, when a DC voltage is always applied to each electrode with the same polarity during each ionic water generating operation, the first electrode chamber is always an anode chamber and the second electrode chamber is always a cathode. Since it becomes a chamber, calcium oxide or magnesium oxide or the like becomes a scale on a long-term use and deposits on the electrode of the second electrode chamber that generates alkaline ionized water. There arises a problem that the life of the electrode is shortened due to deterioration or damage of the electrode.
[0004]
Therefore, a first discharge pipe connected to the outlet for discharging the alkaline ionic water generated in the electrolytic cell and a second discharge pipe connected to the outlet for discharging the acidic ionic water generated in the electrolytic tank are provided. The first lead-out pipe and the second lead-out pipe that are selectively connected to each of these discharge pipes via the flow path switching valve are provided, and the first when the flow path switching valve is in the first switching state. A negative voltage is applied to the electrode of the second electrode chamber and a positive voltage is applied to the electrode of the second electrode chamber. When the flow path switching valve is in the second switching state, the negative electrode is applied to the electrode of the first electrode chamber. Applies a positive voltage while applying a negative voltage to the electrodes of the second electrode chamber so that only alkaline ionized water flows out of the first outlet tube and only acidic ionized water flows out of the second outlet tube. There has been proposed an electrolyzed water generating apparatus that is allowed to flow out.
[0005]
In this way, each time the flow path switching valve is switched, the first electrode chamber is switched from the generation of the alkaline ionic water to the generation of the acidic ionic water, and the second electrode chamber is switched from the generation of the acidic ionic water to the alkaline ionic water. As a result, it is possible to prevent calcium oxide or magnesium oxide from adhering to and depositing on the electrodes in the electrode chamber that generates alkaline ionized water, thereby preventing deterioration of the electrodes. Damage is prevented, and the electrode of this type of electrolyzed water generator has a long life.
[0006]
[Problems to be solved by the invention]
However, in the electrolyzed water generating apparatus provided with the above-described flow path switching valve, only the alkaline ionized water is allowed to flow out from the first outlet pipe and only the acidic ionized water is allowed to flow out from the second outlet pipe. Calcium oxide, magnesium oxide, etc. become scale and adhere to the surface in the first outlet pipe for deriving alkaline ionized water after long-term use, and eventually the outlet pipe becomes clogged. Become.
[0007]
As described above, when the outlet pipe is clogged, excessive water pressure is applied to the piping for supplying the treated water to the electrolytic bath and the electrolytic bath, and these piping and the electrolytic bath are damaged. and cause cracks in the pipe and the electrolytic cell arising a problem of such water leakage occurs.
[0008]
In order to solve the above-mentioned problem , the present invention provides alkaline water by electrolyzing treated water supplied through a water supply pipe provided with a pair of electrodes therein and connected to the inlet when a DC voltage is applied to the electrodes. generates ionized water and acidic ionized water, in these electrolytic water generator with electrolysis cell derived through ionized water outlet pipe connected to the outlet, the water supply to be opened when the water supply is interposed in said feed pipe A valve, a flow rate detecting means disposed in the water supply pipe downstream of the water supply valve for detecting the flow rate of the treated water supplied into the electrolytic cell through the water supply pipe, and downstream of the flow rate detecting means A drain valve that is interposed in a drain pipe connected to the feed water pipe and is closed when the treated water is supplied, and controls the feed valve as an electrical control means for controlling opening and closing of the feed valve and the drain valve Open below The water supply valve is closed when the flow rate of the treated water flowing through the feed water pipe does not reach a predetermined level or more and the flow rate detecting means does not output the treated water detection signal in a state where the water supply to the electrolytic cell is started. Then, an electrolyzed water generating apparatus is provided, which employs a control means for controlling the drain valve to open and then close the drain valve when a predetermined set time has elapsed .
[0009]
In carrying out the present invention, in the electrolyzed water generating apparatus configured as described above,
It is desirable to provide notifying means for issuing an alarm when the control means does not output a detection signal even if the control valve performs the opening / closing operation of the water supply valve and the drain valve a predetermined number of times or more. Furthermore, the control means closes the water supply valve and stops the operation of the electrolytic cell when the flow rate detection means does not output a detection signal even when the water supply valve and the drain valve are opened and closed a predetermined number of times or more. It is desirable to provide
[0010]
[Operation and effect of the invention]
In the electrolyzed water generating device of the present invention configured as described above, if the clogging occurs in the outlet pipes of the alkaline ion water and acidic ion water generated in the electrolytic cell , the water supply pipe is provided downstream of the water supply valve. Since the provided flow rate detection means does not output the detection signal of the treated water, even if the water supply valve is opened and the supply of the treated water is started under the control of the control means , the drainage is performed after the water supply valve is closed. The valve is opened and the residual water stored in the electrolytic cell is discharged. Thus, the water supply tube and does not take excessive water pressure in the electrolytic cell, it decreases damage to supply water pipe and the electrolytic cell.
[0012]
In addition, by providing a notification means for issuing an alarm when the flow rate detection means does not output a detection signal even if the control means controls the opening / closing operation of the water supply valve and the drain valve for a predetermined number of times or more, the operator of the device based on alert the notification means is emitted, Ru can stop the generation operation of the electrolytic water.
[0013]
Furthermore, the control means closes the water supply valve and stops the operation of the electrolytic cell when the flow rate detection means does not output a detection signal even when the water supply valve and the drain valve are opened and closed a predetermined number of times or more. By providing this, useless power consumption can be eliminated.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows an electrolyzed water generating apparatus according to the present invention. This electrolyzed water generating device is provided with a water supply valve V1 for supplying treated water (tap water) through the water supply pipe 11 to both electrode chambers of the electrolytic cell 20, and this water supply valve V1 is a normally closed electromagnetic open / close valve. The operation is controlled by the device 100. The water supply pipe 11 includes a connecting portion 11a interposing the above-described water supply valve V1 and a flow sensor (flow rate detecting means) S, a rising portion 11b extending upward from the tip of the connecting portion 11a, and a tip of the rising portion 11b. It is constituted by a branch part 11c that branches and extends upward and is connected to both inlets 21a and 21b of the electrolytic cell 20, and a water supply hose 12 is connected to the connection part 11a via a known water purifier F, A drain pipe 13 with a drain valve V2 interposed is connected to the lower end of the upright portion 11b. The water supply hose 12 extends outside the machine and is connected to a water pipe (not shown).
[0015]
The flow sensor S detects the flow of water in the connection portion 11 a in the water supply pipe 11, and the detection signal is input to the control device 100. The drainage pipe 13 is disposed along the bottom of the machine and extends outside the machine, and can drain into a drainage groove (not shown). The drain valve V <b> 2 is a normally closed electromagnetic on-off valve, and the operation is controlled by the control device 100.
[0016]
The electrolytic bath 20 is a water-flowing electrolytic bath that electrolyzes treated water supplied to an inlet to generate alkaline ion water and acidic ion water and flows out from each outlet, and a pair of inlets 21a and 21b, A tank body 21 having a pair of outlets 21c and 21d, first and second electrodes 22 and 23 disposed opposite to each other in the tank body 21, and each electrode disposed between the electrodes 22 and 23. The first and second electrode chambers 24 and 25 accommodate the first and second electrode chambers 24 and 25. The first electrode chamber 24 communicates with an inflow port 21a and an outflow port 21c. 25 is in communication with an inlet 21b and an outlet 21d. Each of the electrodes 22 and 23 is formed by firing platinum plating or platinum iridium on the surface of a titanium base material, and applying / stopping DC voltage to both the electrodes 22 and 23 and switching the applied voltage polarity (forward voltage, Switching of the reverse voltage) is controlled by the control device 100. Moreover, the 1st and 2nd discharge pipes 31 and 32 are connected to each outflow port 21c and 21d, and both the discharge pipes 31 and 32 are the 1st and 2nd derivation | leading-out pipes via the flow-path switching valve V3. 33, 34. Each lead-out pipe 33, 34 is for guiding each ionic water to each large-capacity storage tank (not shown), and has rising portions 33a, 34a that rise above the electrolytic cell 20, and have tips at the ends. It opens to the atmosphere and is connected to the flow path switching valve V3 at the lower end of each upright portion 33a, 34a.
[0017]
The flow path switching valve V3 is a 4-port 2-position switching valve that is resistant to acid and alkali, and is switched by an electric motor (not shown). The second switching state indicated by the phantom line in FIG. When the signal is received from the control device 100 in a state where the discharge pipe 31 is connected to the lead-out pipe 34 and the discharge pipe 32 is connected to the lead-out pipe 33 and communicates in the direction indicated by the broken line arrow in FIG. 1 in a first switching state (a state where the discharge pipe 31 is connected to the lead-out pipe 33 and the discharge pipe 32 is connected to the lead-out pipe 34 and communicates in the direction indicated by the solid line arrow in FIG. 1). In addition, when a signal is received from the control device 100 in the first switching state indicated by the solid line in FIG. 1, the switching state is switched to the second switching state indicated by the phantom line in FIG. The solid line indicates whether or not the second switching state indicated by the virtual line Whether the first switching state is adapted to be detected by a sensor (not shown).
[0018]
The control device 100 includes a power switch 101 (a changeover switch that is turned on / off by an on / off operation) and a generation switch 102 (a changeover that is turned on / off by an on / off operation and turned off by an off signal from the control device 100). Switch), a first timer 106, and a first setting device 104 for variably setting the first setting time ta of the first timer 106, and corresponding to the flowcharts shown in FIGS. And a microcomputer (not shown) for executing the program, the operation of each switch 101, 102, 103, the signal from the flow sensor S, the signal from the sensor for detecting the state of the flow path switching valve V3, and the first Based on the time value of the timer 106 and the second timer built in the microcomputer, the water supply valve V1 and the drainage V2 opening / closing operation, flow path switching valve V3 switching operation, application / stop of DC voltage to both electrodes 22 and 23 in the electrolytic cell 20, and switching of applied voltage polarity (switching of forward voltage and reverse voltage). In addition to controlling, the operation of the voice notification device (not shown) and the lighting / extinguishing of the display lamps (not shown) provided at the outlets of the outlet pipes 33 and 34 are controlled. Each operation is performed.
[0019]
In the present embodiment configured as described above, the power switch 101 is turned on while the electrolyzed water generating device is usable, and the microcomputer of the control device 100 executes the program in step 200 of FIG. In step 202, it is determined whether or not the generation switch 102 is turned on. At this time, if the generation switch 102 is not turned on, it is determined as “No” in Step 202 and the process of Step 202 is repeatedly executed. If the generation switch 102 is turned on, the process is performed in Step 202. It determines with "Yes" and progresses to the next step 204. FIG.
[0020]
In step 204, the microcomputer outputs an open signal to the water supply valve V1, and in step 206, the count value of the counter built in the microcomputer is reset (count value C → 0). Next, in step 208, it is determined whether or not the flow sensor S is outputting an ON signal. If the water supply valve V1 is normal, it opens with an open signal. Therefore, if there is no abnormality such as pipe clogging, tap water flows through the water supply pipe 11 and the flow sensor S is turned on. And proceed to step 210.
[0021]
In step 210, it is determined whether or not the flow path switching valve V3 is held in the first switching state shown by the solid line in FIG. A predetermined forward DC voltage (a negative voltage is applied to the electrode 22 and a positive voltage is applied to the electrode 23) is applied between the pair of electrodes 22 and 23 so that the electrode 22 becomes the cathode side and the electrode 23 becomes the anode side. . Thereby, the tap water that has passed through the water purifier F from the water supply hose 12 is supplied to the electrode chambers 24 and 25 of the electrolytic cell 20 through the water supply valve V 1, the flow sensor S, and the water supply pipe 11. Each ionized water is generated by the electrolysis of the alkaline ionized water from the electrode chamber 24 of the cathode side electrode 22 through the discharge pipe 31, the first switching state channel switching valve V 3 and the outlet pipe 33. Acid ionic water that has been sent to a large-capacity alkaline ionized water storage tank (not shown), and from which the hydrogen ions have increased from the electrode chamber 25 of the anode electrode 23, is connected to the discharge pipe 32 and the first switching state channel switching valve. It is sent to a large-capacity acidic ion water storage tank (not shown) through V3 and the outlet pipe 34.
[0022]
On the other hand, if the flow path switching valve V3 is held in the second switching state indicated by the phantom line in FIG. 1, “No” is determined in step 210, and a pair of electrodes in the electrolytic cell 20 is determined in step 214. A predetermined reverse DC voltage (electrode 22 is positive voltage and electrode 23 is negative voltage) is applied between 22 and 23, so that electrode 22 becomes the anode side and electrode 23 becomes the cathode side. Thereby, the tap water that has passed through the water purifier F from the water supply hose 12 is supplied to the electrode chambers 24 and 25 of the electrolytic cell 20 through the water supply valve V 1, the flow sensor S, and the water supply pipe 11. Each ionized water is generated by the electrolysis of the acidic ionized water having increased hydrogen ions from the electrode chamber 24 of the anode side electrode 22 through the discharge pipe 31, the second switching state flow switching valve V3 and the outlet pipe 34. From the electrode chamber 25 of the cathode-side electrode 23, alkaline ionized water having increased hydroxide ions is discharged to the discharge pipe 32 and the second switching state flow path switching valve. It will be sent to a large-capacity alkaline ionized water storage tank (not shown) through V3 and the outlet pipe 33.
[0023]
In step 216, the first timer 106 is reset and the measured value t1 is set to zero and restarted. In step 218, whether the measured value t1 of the first timer 106 reset in step 216 is equal to or greater than the first set time ta. Determine. When the time value t1 of the first timer 106 reset in step 216 is less than the first set time ta, it is determined as “No” in step 218 and the process of step 222 is executed, and the time value t1 described above is also executed. When the first set time ta is reached, “Yes” is determined in step 218, and the process proceeds to step 222. The first set time ta described above can be appropriately changed by, for example, a range of 50 hours to 500 hours by the first setting device 104 shown in FIG.
[0024]
In step 220, it is determined whether or not the generation switch 102 is turned off. If the generation switch 102 is not turned off at this time, “Yes” is determined in step 220 and the process returns to step 218 to repeat the above-described processing until the first set value ta is reached. If the generation switch 102 is turned off, “No” is determined in step 220 and the process proceeds to step 222.
[0025]
In step 222, the microcomputer sends a drive signal to the electric motor of the flow path switching valve V3. Then, since the electric motor rotates the flow path switching valve V3 by 90 degrees, if it is determined in step 210 that the flow path switching valve V3 is in the first switching state, the electric motor changes to the second switching state, and conversely step 210 When the flow path switching valve V3 is determined to be in the second switching state, the first switching state is changed. Thereafter, the process returns to step 202, and the processes from step 202 to step 222 described above are repeated.
[0026]
As described above, when the flow path switching valve V3 is rotated 90 degrees in step 222, the water supply valve V1 is opened in step 204 and the generation operation is resumed. In step 210, the flow path switching valve V3 is thus restarted. Is in the first switching state, the flow path switching valve V3 is now in the second switching state, and a reverse DC voltage is applied to the electrodes 22 and 23 in the electrolytic cell 20, so that the first electrode chamber 24, acidic ionic water is generated, and alkaline ionic water is generated in the second electrode chamber 25. However, since the flow path switching valve V <b> 3 is in the second switching state, the acidic ionic water is discharged from the outlet pipe 34. The alkaline ionized water is led out from the lead-out pipe 33 and this processing operation is repeated. Thereby, even if the production | generation of each ionic water in each electrode chamber 24,25 is switched alternately every 1st setting time ta or every time the production | generation switch 102 is turned off, it always becomes alkaline ion from the derivation | leading-out pipe | tube 33. Water is led out, and acidic ion water is always led out from the lead-out pipe 34.
[0027]
The above explanation is an operation explanation when the outlet pipes 33 and 34 are normally operated without clogging of pipes. Here, as the electrolysis water is generated for a long period of time, the outlet pipes 33 and 34 are gradually clogged, and even if the water supply valve V1 is opened, the flow rate of treated water in the water supply pipe 11 exceeding a predetermined level. When the flow sensor S does not flow and the flow sensor S does not output the ON signal, the microcomputer makes a “No” determination at step 208 to execute the processing operations after step 230 in FIG.
[0028]
When the processing proceeds to step 230 and thereafter in FIG. 3, in step 230, a close signal is output to the water supply valve V1 to stop water supply. Next, in step 231, an open signal is output to the drain valve V2 to open the drain valve V2. As a result, the residual water stored in the outlet pipes 33 and 34, the flow path switching valve V3, the outlet pipes 31 and 32, the electrolytic cell 20, and the water supply pipe 11 is opened to the atmosphere of the outlet pipes 33 and 34. Air is taken in from the tip and drained from a drain pipe 13 into a drain groove (not shown).
[0029]
After the drain valve V2 is opened, the second timer built in the microcomputer is reset in step 232 to start counting the second time value t2. In step 233, it is determined whether or not the second timer value t2 of the second timer that started timing in step 232 is equal to or greater than a preset drainage set time tb. The drainage setting time tb is determined based on an actual measurement value obtained by experimentation of a time during which the remaining water is not substantially stored in the electrolytic cell 20, and is previously set to about 20 seconds (depending on the size of the drainage valve V2). It is set in the microcomputer.
[0030]
If it is determined as “No” in step 233, the processing of step 233 is repeatedly executed. When the predetermined time has elapsed and the drainage set time tb is reached, it is determined as “Yes” in Step 233, the process proceeds to Step 234, the drain valve V <b> 2 is closed, and the process proceeds to the next Step 235. When the process proceeds to step 235, it is determined whether or not the measured value t2 of the second timer that has started measuring in step 232 is equal to or greater than a preset third set time tc. Note that the third set time tc stops all the operations only for a certain time (for example, set to 2 to 3 seconds and becomes (tc-tb) time) after the above drainage operation is finished. For example, the above-mentioned second set time tb, which is set to 22 to 23 seconds, for example.
[0031]
After that, in step 236, an open signal is output to the water supply valve V1 to open the water supply valve V1, and water supply to the electrolytic cell 20 is started again. In step 237, timing is started in step 232 It is determined whether the measured value t2 of the second timer is equal to or longer than a preset fourth set time td. The fourth set time td is a predetermined time after the elapse of a fixed time for stopping all the operations described above (that is, (td−tc−tb) time, for example, set to 5 seconds) + The above-mentioned third set time tc time is set to 27 to 28 seconds, for example, and in order to supply treated water to the electrolytic cell 20 by opening the water supply valve V1 for this (td-tc-tb) time. Provided.
[0032]
Next, in step 238, the count value C of the counter reset in step 206 of FIG. 2 is incremented (C → C + 1). In step 239, whether or not the count value C has reached n (for example, 3 to 5). Judgment is made. Here, the value of n is preset in the microcomputer. If the count value C is not n, the process returns to step 208 to determine whether the flow sensor S is outputting an ON signal. In this determination, if it is determined as “No”, the flow sensor S does not flow in the water supply pipe 11 and the flow sensor S does not output an ON signal, so the above steps 230 to 239 are not performed. Repeat the process.
[0033]
If the count value C reaches n while the processing from step 230 to step 239 is repeatedly executed, the microcomputer determines that the pipe is clogged, determines “Yes” in step 239, and proceeds to step 240. The microcomputer sends a signal to an alarm device (not shown) and sends a signal to a display device (not shown). Then, the alarm device sounds an alarm, and the display device displays that the pipe is clogged. Next, in step 241, a close signal is sent to the water supply valve V1, and in step 242, an off signal is sent to the generation switch. As a result, the water supply valve V1 is closed, the generation switch is turned off, and the execution of the above-described processing operation is terminated in step 243.
[0034]
As is clear from the above description, in the present embodiment, even when the outlet pipes 33, 34, etc. are clogged, the flow sensor can be opened even if the water supply valve V1 is opened and the water supply operation is started. Since S does not output the flow rate detection signal, the control device 100 performs the closing operation of the water supply valve V1 that closes the water supply valve V1, so that excessive water pressure is not applied to the water supply pipe 11 and the electrolytic cell 20. It becomes possible, and the damage given to the water supply pipe 11 and the electrolytic cell 20 can be reduced.
[0035]
Further, after the flow sensor S does not output the flow rate detection signal and the control device 100 performs the closing operation of the water supply valve V1 that closes the water supply valve V1, the residual water stored in the electrolytic cell 20 by opening the drain valve V2 Therefore, it is possible to prevent excessive water pressure from being applied to the water supply pipe 11 and the electrolytic cell 20 as compared to simply stopping the water supply. Further, even if the valve opening operation and the valve closing operation of the water supply valve V1 are repeated a predetermined number of times (for example, 3 to 5 times), if the flow sensor S does not output a flow rate detection signal, the control device 100 notifies an alarm or the like. At the same time, since the alarm is displayed, the operator of the electrolyzed water generating device can stop the electrolyzed water generating operation based on the notification.
[0036]
Further, if the flow sensor S does not output a flow rate detection signal even if the valve opening operation and the valve closing operation of the water supply valve V1 are repeated a predetermined number of times, the control device 100 closes the water supply valve V1, and thus wasteful power is consumed. It is no longer consumed and no excessive water pressure is applied to the electrolyzed water generator.
[0037]
In a normal state where the outlet pipes 33, 34, etc. are clogged and water breakage does not occur, when the microcomputer of the control device 100 executes the program shown in FIGS. 2 and 3, for example, the flow path switching valve V3 is In the case of one switching state, a forward DC voltage is applied to the electrodes 22 and 23 in the electrolytic cell 20, and alkaline ionized water is generated in the first electrode chamber 24, and in the second electrode chamber 25. Acidic ionic water is generated, alkaline ionic water is led out from the outlet pipe 33, and acidic ionic water is led out from the outlet pipe 34.
[0038]
After this state is continued for a first set time ta (for example, 100 to 500 hours), when the flow path switching valve V3 is rotated by 90 degrees to the second switching state, each electrode in the electrolytic cell 20 is now turned on. A reverse DC voltage is applied to 22 and 23, acidic ion water is generated in the first electrode chamber 24, and alkaline ion water is generated in the second electrode chamber 25. Since V3 is in the second switching state, the acidic ion water is led out from the outlet pipe 34 and the alkaline ion water is led out from the outlet pipe 33, and this processing operation is repeated. Thereby, even if the production | generation of each ionic water in each electrode chamber 24,25 is switched alternately every 1st setting time ta or every time the production | generation switch 102 is turned off, it always becomes alkaline ion from the derivation | leading-out pipe | tube 33. Water is led out, and acidic ion water is always led out from the lead-out pipe 34.
[0039]
As described above, the polarity of the voltage applied to the pair of electrodes 22 and 23 in the electrolytic cell 20 is switched every first set time ta or every time the generation switch 102 is turned off. The scale adhering to each of the electrodes 22 and 23 in 20 can be accurately removed, and electrolytic ion water having a substantially uniform pH can be continuously obtained.
[0040]
In the above embodiment, the forward voltage is applied when the flow path switching valve V3 is in the first switching state, and the reverse direction is applied when the flow path switching valve V3 is in the second switching state. The example in which only the alkaline ionized water is derived from the outlet tube 33 and only the acidic ion water is derived from the outlet tube 34 by applying a voltage has been described. Each time it is used, a forward voltage is applied when the flow path switching valve V3 is in the second switching state, and a reverse voltage is applied when the flow path switching valve V3 is in the first switching state. Thus, if the acidic ion water is led out from the outlet pipe 33 and the alkaline ion water is led out from the outlet pipe 34, it adheres to the inner wall of the outlet pipe 33 by the circulation of the alkaline ion water. Product to calcium oxide, scales such as magnesium oxide by acidic ionized water, it becomes possible to automatically washed.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram showing an embodiment of an electrolyzed water generating apparatus according to the present invention.
FIG. 2 is a flowchart showing a part of a control program for generating ionic water that is executed by a microcomputer included in the control device of the electrolyzed water generating device shown in FIG. 1;
FIG. 3 is a flowchart showing a part of the flowchart shown in FIG. 2;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 11 ... Water supply pipe, 20 ... Electrolyzer, 21a, 21b ... Inlet, 21c, 21d ... Outlet, 22, 23 ... Electrode, 24, 25 ... Electrode chamber, 26 ... Diaphragm, 31, 32 ... Discharge pipe, 33, 34 ... Lead-out pipe, 100 ... Control device, 101 ... Power switch, 102 ... Generation switch, 106 ... First timer, V1 ... Water supply valve, V2 ... Drain valve, V3 ... Flow path switching valve.

Claims (3)

When a direct current voltage is applied to the electrodes, the treated water supplied through a water supply pipe provided with a pair of electrodes inside and connected to the inflow port is electrolyzed to generate alkaline ionized water and acidic ionized water. in electrolytic water generator with electrolysis cell derived through outlet tube connected to ion water to the outlet,
A water supply valve that is opened during water supply via the water supply pipe;
A flow rate detecting means disposed in the water supply pipe downstream of the water supply valve for detecting the flow rate of the treated water supplied to the inside of the electrolytic cell through the water supply pipe;
A drainage valve that is closed when the treated water is supplied via a drainage pipe connected to the water supply pipe downstream of the flow rate detection means;
As an electrical control means for controlling opening and closing of the water supply valve and the drain valve, the flow rate of treated water flowing through the water supply pipe in a state where the water supply valve is opened under the control and water supply to the electrolyzer is started If the flow rate detection means does not output a detection signal for treated water without reaching a predetermined level or more, the water supply valve is closed and then the drain valve is opened, and when the predetermined set time has elapsed, the drain valve is closed. An electrolyzed water generating apparatus characterized by adopting a control means for controlling. Claim 1, wherein the control means, wherein said flow rate detecting means even if the opening and closing operations carried out over a predetermined number of times of the water supply valve and the water discharge valve is provided with a notification means for issuing an alarm when no output a detection signal electrolytic water generation apparatus according to. The control means includes means for closing the water supply valve and stopping the operation of the electrolytic cell when the flow rate detection means does not output a detection signal even when the water supply valve and the drain valve are opened and closed a predetermined number of times or more. it is electrolytic water generation apparatus according to claim 1, wherein the.

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