JP4629860B2 - Electrolyzed water generator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electrolyzed water generating apparatus.
[0002]
[Prior art]
As one type of electrolyzed water generating device, as proposed in Japanese Patent Application Laid-Open No. 11-253934, an electrolyzer having a pair of electrolyzers partitioned by a diaphragm and connected to each electrolyzer of the electrolyzer A pair of supply pipes having flowing water detecting means for supplying electrolyzed water to each of the electrolysis chambers, and electrolyzed water generated in the electrolysis chambers connected to the electrolysis chambers of the electrolysis tank. A pair of extraction pipes each having a faucet to be extracted, a pair of discharge pipes connected in the middle of each of the extraction pipes and having a discharge valve for discharging the accumulated water staying in each of the electrolysis chambers, and controlling the electrolysis operation There is an electrolyzed water generating device of a type provided with a control device.
[0003]
In the electrolyzed water generating apparatus of this type, during electrolysis operation, water to be electrolyzed is continuously supplied to each electrolysis chamber and electrolyzed in each electrolysis chamber. Generated water is generated, and electrolyzed water such as alkaline water is generated in the other electrolysis chamber. Electrolytically generated water generated in one electrolytic chamber is selectively or simultaneously opened from one extraction tube, and electrolytically generated water generated in the other electrolytic chamber is selectively or simultaneously opened from the other extraction tube. It is configured so that it can be extracted.
[0004]
When extracting electrolytically generated water from one extraction pipe, one drain pipe connected in the middle of the extraction pipe is closed by a drain valve, and the other extraction pipe is closed by a water tap. In this case, if the other drain pipe connected in the middle of the other extraction pipe is closed by the drain valve, the electrolyzed water in the middle of electrolysis stays in the other electrolysis chamber, and the gas generated during electrolysis is bubbled. This causes a change in the electrolysis conditions by inhibiting current flow between the electrodes, adversely affecting the properties of the electrolyzed water being poured out, and setting values such as pH values immediately after the closed faucet is opened. Such as the discharge of electrolytically generated water with different characteristics
In order to cope with such a problem, in the electrolyzed water generating device proposed in the above publication, when extracting electrolyzed water from one extraction pipe, the other discharge pipe is opened by a drain valve. Then, the electrolysis operation is controlled in which the accumulated water staying in the other electrolysis chamber is discharged from the other discharge pipe by an amount corresponding to the extraction amount of the electrolyzed water extracted from the one extraction pipe.
[0005]
In such an electrolysis operation, when the entire amount of staying water that remains without extracting the electrolyzed water during the electrolysis operation is drained from the drain pipe as it is, the electrolyzed water is compared with the amount of electrolyzed water extracted. There is a problem that the amount of water used is greatly increased.
[0006]
For this reason, in the electrolyzed water generating device, the control device that controls the electrolysis operation outputs an opening / closing signal that outputs a signal for opening and closing each drain valve independently based on the flowing water state detected by the flowing water detecting means. And when the open / close signal output means outputs a signal for closing both the drain valves, the flow of the electrolyzed water is detected when only one of the water flow detecting means detects the flow of the electrolyzed water. Instruct the open / close signal output means to open and close the drain valve of the electrolysis chamber side drain pipe in which the flow of the electrolyzed water is not detected while keeping the drain valve of the electrolysis chamber side drain pipe closed It is configured with forced drainage means.
[0007]
As a result, in the electrolyzed water generating apparatus, the staying water staying in the other electrolyzing chamber can be discharged immediately before the gas bubbles or pH value fluctuations exceed the permissible level and stay in the electrolyzing chamber. By allowing the water to stay to some extent, wasteful consumption of the electrolyzed water is reduced, and at the same time, the electrolysis operation is stopped when the supply of the electrolyzed water is abnormal (when water is shut off, etc.). The electrolytic operation is controlled so as to wait until the normal supply state.
[0008]
[Problems to be solved by the invention]
By the way, in the electrolyzed water generating apparatus, since both drainage valves are alternately opened and closed until the return of the electrolyzed water supply abnormality (such as water shutoff), the electrolyzed water supply abnormality When (water cutoff etc.) continues for a long time, each drain valve is repeatedly opened and closed, and each drain valve impairs its durability at an early stage. Therefore, an object of the present invention is to cope with such a problem that occurs before the return of an abnormality in the supply of electrolyzed water (such as water outage).
[0009]
[Means for Solving the Problems]
The present invention relates to an electrolyzed water generating apparatus, and includes an electrolyzer having a pair of electrolyzing chambers partitioned by a diaphragm, and a flowing water detecting means connected to the electrolyzing chambers of the electrolyzer so that these electrolytic chambers are covered. A pair of supply pipes for supplying electrolyzed water and a faucet for extracting electrolyzed water are connected to the electrolyzer chambers of the electrolyzer to extract electrolyzed water produced in the electrolyzer chambers. A pair of extraction pipes, a pair of discharge pipes having a discharge valve for discharging the accumulated water in each of the electrolysis chambers, connected to the middle of each of the extraction pipes and discharging the accumulated water in each of the electrolysis chambers, and electrolysis The application target is an electrolyzed water generating device having a control device for controlling operation.
[0010]
Thus, in the electrolyzed water generating apparatus according to the present invention, the control device includes an opening / closing signal output means, forced drainage means, forced drainage end means, and detection operation interruption means described below. It is.
[0011]
Among the above-described means, the open / close signal output means has an opening / closing signal output means having a function of outputting a signal for opening and closing each drain valve independently based on a running water state detected by the running water detection means. It is.
[0012]
Further, when the open / close signal output means outputs a signal for closing both of the drain valves, the forced drain means only detects the flow of the electrolyzed water when one of the flowing water detection means. The drain valve of the drain pipe on the electrolysis chamber side where the flow of electrolyzed water is detected is kept closed, and the drain valve of the drain pipe on the electrolysis chamber side where the flow of electrolyzed water is not detected is intermittent Forced drainage means having a function of instructing the opening / closing signal output means to open and close.
[0013]
Further, when the drainage valve that is opened and closed intermittently by the operation of the forced drainage means is closed, when both the water flow detection means detect the flow of the electrolyzed water, Forced drainage end means having a function of instructing the open / close signal output means to stop the operation of the forced drainage means and keep both the drainage valves closed.
[0014]
In addition, the detection operation interruption means interrupts the forced water discharge means when the flow detection operation reaches a predetermined time, interrupts the water discharge detection operation of the forced drainage means, and restarts the same water detection operation after a predetermined time elapses. This is detection operation interruption means having a function of instructing the drainage means.
[0015]
[Operation and effect of the invention]
In the electrolyzed water generating apparatus according to the present invention, in the operation control for detecting an abnormality in the supply of electrolyzed water (such as water outage), if the supply of electrolyzed water (such as water outage) continues for a long time, a predetermined amount The detection operation is temporarily interrupted when time elapses, and the detection operation is resumed when the detection operation interruption time reaches a predetermined time. For this reason, the opening / closing operation of both drain valves is also interrupted during the interruption time of the detection operation. Thereby, useless opening / closing operation | movement of each drain valve is eliminated, and the durability can be improved.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
The present invention will be described below with reference to the drawings. FIG. 1 shows an electrolyzed water generating apparatus according to an example of the present invention. The electrolyzed water generating apparatus is proposed in Japanese Patent Laid-Open No. 11-253934, which is a prior application of the present applicant. The basic structure of the electrolyzed water generator differs from the electrolyzed water generator in part of the function of the controller. The electrolyzed water generating apparatus includes the electrolytic cell 10, the supply pipes 21 and 22, the outlet pipes 31 and 32, the extraction pipes 41 and 42, the water taps 43 to 46, the flow path switching valve 50, and the drain pipes 61. , 62, drain valves 71, 72, water flow sensors 81, 82, main body 90, and control device 100.
[0017]
The electrolytic cell 10 is accommodated in a main body 90, and is a known electrolytic cell in which electrodes 14 and 15 are disposed in a pair of electrolytic chambers 12 and 13 partitioned by a diaphragm 11, respectively. Both electrodes 14 and 15 are connected to the control device 100, and the control device 100 controls the application and stop of the DC voltage and the reversal of the polarity of the applied voltage. Further, the electrolytic cell 10 is provided with inlets 16 and 17 and outlets 18 and 19 at positions opposed to each other with the diaphragm 11 interposed therebetween, and the supply pipes 21 and 22 are connected to the inlets 16 and 17, respectively. The outlet ports 31 and 32 are connected to the outlet ports 18 and 19, respectively.
[0018]
The supply pipes 21 and 22 gather on the upstream side and are connected to a water supply pipe 24 having a pressure reducing valve 23 interposed in the main body 90. The water supply pipe 24 is connected to a water pipe 27 which is an external water supply source through a water purifier 25 and a main plug 26 arranged outside the main body 90, and is also opened with a safety valve (opened at a set pressure or higher) provided in the main body 90. The main drain pipe 63 is connected via a relief valve 28. In each of the supply pipes 21 and 22, electrolyzed water (tap water) supplied through the water supply pipe 24 is supplied to the electrolytic chambers 12 and 13 in substantially the same amount. The flowing water sensors 81 and 82 are disposed in the supply pipes 21 and 22, respectively.
[0019]
The outlet pipes 31 and 32 lead out alkaline water and acidic water generated in the electrolytic chambers 12 and 13 of the electrolytic cell 10 to the flow path switching valve 50, respectively. 12 and 13 and the first and second inlet ports 51a and 51b of the flow path switching valve 50, respectively. Each extraction pipe 41, 42 guides alkaline water and acidic water from the flow path switching valve 50 to a use location outside the main body 90, and the first and second outflow ports 52a, 52b of the flow path switching valve 50. The faucets 43, 44, 45, 46 that manually open and close the flow paths are disposed at the distal ends of the portions that extend to the outside of the main body 90.
[0020]
The flow path switching valve 50 is connected to the control device 100 and is controlled to switch to the first position (state shown by a solid line in FIG. 1) and the second position (state shown by a two-dot chain line in FIG. 1). Are switched so as to function to switch the connection state between the respective extraction pipes 41 and 42 and the respective outlet pipes 31 and 32. In the present specification, connection of the outlets 18 and 19, outlet pipes 31 and 32, and outlet pipes 41 and 42 of the electrolytic cell 10 when the flow path switching valve 50 is in the first position and the second position. The states are referred to as a first connection state and a second connection state. The first position and the second position, which are the switching states of the flow path switching valve 50, are detected by a position detection sensor (not shown) and recognized by the control device 100.
[0021]
Each drain pipe 61, 62 is connected to the middle of each extraction pipe 41, 42 in the main body 90, and is located between the flow path switching valve 50 and each of the water taps 43, 44, 45, 46. In addition, each tip is connected to the main drain pipe 63. Drain valves 71 and 72 are disposed at the distal ends of the drain pipes 61 and 62, respectively. The drain valves 71 and 72 are normally closed electromagnetic on-off valves, and the opening and closing of the drain pipes 61 and 62 is opened and closed by the control device 100 controlling the opening and closing thereof.
[0022]
The water flow sensors 81 and 82 are disposed in the supply pipes 21 and 22, respectively, and detect the water flow in the pipes, and function as water flow detection means. Each flowing water sensor 81, 82 is a switch that operates “ON” when the flow rate of the electrolyzed water in each of the supply pipes 21, 22 is higher than the set flow rate, and operates “OFF” when the flow rate is lower than the set flow rate. The “off” signal is input to the control device 100 as a detection signal.
[0023]
The control device 100 includes a main switch 101, a switching manual switch 102, a lamp 103, a buzzer 104, and the like, and includes a microcomputer, an open / close signal output means, a forced drain means, a forced drain end means, and a detection operation interruption means. Is controlled according to the program shown in the flowcharts of FIGS. 2 to 5 to control the operation of the electrolysis apparatus as follows. In the following, (1) a mode in which both faucets are opened, (2) a mode in which one of the faucets is opened, (3) a mode in which pipeline clogging or a drain valve failure is detected, and (4) water shutoff and Although the control about the detection mode of the water shut-off will be described, (4) the control about the water shut-off and the detection mode of the water shut-off forms the main part of the present invention.
[0024]
(1) A mode in which both faucets are opened: First, after the operator opens all the faucets 26 with all the faucets 43, 44, 45, 46 closed, at least one of the faucets 43, 44 An embodiment in which at least one of the faucets 45 and 46 is opened and both alkaline water and acidic water are poured out simultaneously will be described.
[0025]
In this case, electrolyzed water that is tap water is supplied to the electrolysis chambers 12 and 13 of the electrolytic cell 10 through the supply pipes 21 and 22. For this reason, each flowing water sensor 81 and 82 operates from “off” to “on”. The driving operator turns on the main switch 101 to start the operation of the control device 100 in this state. As a result, the microcomputer mounted on the control device 100 operates, and the program shown in FIG.
[0026]
By the operation of the control device 100, the microcomputer determines that the “on” or “off” state of any of the running water sensors 81 and 82 is “on” in step 205 and advances the program to step 210. . In step 210, the microcomputer starts the electrolysis by applying a DC voltage to each of the electrodes 14 and 15, and advances the program to step 215. In step 215, the time measurement of the electrolysis time (the duration of electrolysis) is started. Then, the program is advanced to step 220, and the program is advanced to step 225 after the timing of the waiting time described later is started.
[0027]
In step 225, the microcomputer determines whether any of the running water sensors 81 and 82 is “ON”, as in step 205. At this time, the state of the faucets 43, 44, 45, and 46 is not changed, and the water flow sensors 81 and 82 are both “on”, so the microcomputer determines “Yes” in step 225, The program proceeds to step 230. In step 230, it is determined whether both the running water sensors 81 and 82 are “ON”. However, at this time, it is also determined as “Yes” in step 230, and the program is executed in step 235. Proceed to
[0028]
In step 235, the microcomputer determines whether the electrolysis time has reached a predetermined time T1 or more. The predetermined time T1 (electrode scale reference time T1) is a time shorter than the time required for the scale to adhere to the electrodes 14 and 15 during the electrolysis and the degradation of the electrolysis performance starts. I'm trying. Since the current time is immediately after the start of electrolysis, the electrolysis time is shorter than the predetermined time T1, and the microcomputer makes a “No” determination at step 235 to return the program to step 225. Thereafter, the microcomputer repeatedly executes Steps 225, 230 and Step 235 until the electrolysis time is equal to or longer than the predetermined time T1, and pours acidic water from the pour pipe 41 and alkaline water from the pour pipe 42. .
[0029]
When the electrolysis time is equal to or longer than the predetermined time T1, the microcomputer makes a “Yes” determination at step 235, advances the program to step 240, and temporarily stops counting the waiting time at step 240. Subsequently, the microcomputer executes a program based on steps 245 to 275 to switch the flow path switching valve 50 and to reverse the polarity of the applied voltage to the electrodes 14 and 15, A treatment is performed to prevent a decrease in electrolytic capacity due to scale adhesion.
[0030]
Specifically, the microcomputer temporarily stops the application of the DC voltage to the electrodes 14 and 15 in step 245. Subsequently, in step 250, both drain valves 71 and 72 are opened (valve opening signal is output), and in step 255, a switching signal is output to give an instruction to switch the flow path to the flow path switching valve 50, An operation for switching the connection state between the outlet pipes 31 and 32 and the extraction pipes 41 and 42 from the first connection state to the second connection state is started. In step 255, if the connection state immediately before execution of step 255 is the second connection state, the state is switched to the first connection state.
[0031]
In step 260, the microcomputer monitors the detection signal of the position detection sensor of the flow path switching valve 50 to determine whether or not the flow path switching has been completed, and the flow path switching valve is switched to the normal position. The program is advanced to step 270 at the time of completion (at the end of switching). In step 270, a valve closing signal is sent to both drain valves 71 and 72 to close both valves. In step 275, the polarity of the applied voltage to the electrodes 14 and 15 is reversed. Thereafter, the microcomputer returns the program to step 210 and repeats the above operations.
[0032]
Next, when all the faucets 43, 44, 45, 46 are closed from the state where any one or both of the faucets 43, 44 and either one or both of the faucets 45, 46 are opened. Will be described.
[0033]
In this case, since all the faucets 43, 44, 45, and 46 are closed, both the running water sensors 81 and 82 are turned off, so that the microcomputer becomes “No” when executing step 225 in FIG. If so, the program proceeds to step 280. In step 280, the microcomputer stops applying voltage to the electrodes 14 and 15 to stop the electrolysis, stops the electrolysis time in step 285, and stops the standby time in step 290. Thereafter, the program is returned to step 205, and monitoring of whether or not any of the water flow sensors 81, 82 is turned on, that is, monitoring of the open / closed state of the faucets 43, 44, 45, 46 is started again. . With the above operation, the electrolyzed water generating device stops electrolysis and stops the electrolysis water pouring.
[0034]
(2) A state in which only one faucet is opened: In order for the operator to pour only acidic water, either or both of the faucets 43 and 44 are opened, and both faucets 45 and 46 are opened. The case where is closed will be described. It is assumed that the flow path switching valve 50 is in the first connection state.
[0035]
In this case, since the running water sensor 81 is “ON”, the microcomputer determines “Yes” in Step 205 following Step 200 in FIG. 2. Subsequently, steps 210, 215, 220, and 225 are executed in the same manner as described above to start the voltage application to the electrodes 14 and 15 and the measurement of the electrolysis time and the standby time, and then the running water sensors 81 and 82 are turned on. The process proceeds to step 230 where it is determined whether or not.
[0036]
At this time, since the faucets 43 and 44 are in the “open” state, the faucets 45 and 46 are in the “closed” state, and the drain valves 71 and 72 are both in the “closed” state, the water flow sensor 81 is “on”. However, the running water sensor 82 is “off”. Therefore, the microcomputer makes a “No” determination at step 230 and advances the program to step 295.
[0037]
In step 295, the flowing water sensor that is “ON” is recognized as the first flowing water sensor 81, and the flowing water sensor that is “OFF” is recognized as the second flowing water sensor 82, and the first flowing water sensor 81 is interposed. The drainage valve of the drainage pipe branched and connected to the extraction pipe in which the electrolyzed water flowing in the supply pipe 21 flowing out through the electrolysis chamber 12 of the electrolytic cell 10 is opened. Is a step of recognizing the drain valve of the first drain valve and the other drain pipe branched and connected to the outlet pipe whose faucet is closed as the second drain valve. Therefore, under the current situation (the flow path switching valve 50 is in the first position), the microcomputer recognizes the water flow sensors 81 and 82 as the first and second water flow sensors, respectively, and sets the drain valves 71 and 72 as the first and second water flow sensors. Recognized as first and second drain valves, respectively.
[0038]
Next, the microcomputer advances the program to step 305 shown in FIG. 3 to determine whether or not the standby time is equal to or greater than the reference standby time TA. Since the waiting time has just been started in step 220, the microcomputer determines “No” at the present time, and in step 310, determines whether or not the electrolysis time has reached a predetermined time T1 or more ( The same processing as step 235). Since the current time is immediately after the start of electrolysis, the microcomputer makes a “No” determination at step 310 and returns the program to step 225 in FIG. Thereafter, the microcomputer repeatedly executes steps 225, 230, 295, 305, and 310 until it determines "Yes" in step 305 or step 310. In this state, both drain valves 71 and 72 are kept closed, and acidic water continues to be poured out from the dispensing pipe 41 alone.
[0039]
The reference waiting time TA is such that either one of the faucets 43, 44, 45, 46 is closed but the other is opened, so that the electrolysis is started, and both drain valves 71, 72 are The pH value when air bubbles are generated in the water in the middle of the electrolysis staying in the electrolytic chamber on the side not connected to the open extraction pipe because it is closed, obstructing the electrolysis current, or the accumulated water is poured out. Is set to a time slightly shorter than the time required for the state to be over or under (the reference waiting time TA in this embodiment is 10 seconds). This reference waiting time TA is sufficiently shorter than a predetermined time T1 that is selected to be approximately equal to the time required for reducing the electrolytic capacity due to the scale adhesion to the electrodes 14 and 15.
[0040]
Therefore, the microcomputer normally determines “Yes” in step 305 prior to the “Yes” determination in step 310, and advances the program to step 315. In step 315, the microcomputer stops measuring the waiting time, and proceeds to step 320 to output a valve opening signal to the second drain valve 72 so as to open the second drain valve (in this case, the drain valve 72). Thereby, the electrolyzed water staying in the electrolysis chamber 13 is diluted with new electrolyzed water and drained through the drain pipe 62.
[0041]
Next, the microcomputer advances the program to step 325, and determines whether or not the second flowing water sensor (in this case, the flowing water sensor 82) is turned on. At this time, since the second drainage valve (drainage valve 72) has just been opened, the second flowing water sensor remains “off”, so that the microcomputer determines “No” in step 325 and the program is executed. To step 330. Step 330 is a step of determining whether or not a flag F for controlling time measurement of a failure detection time described later is “1”. Since the flag F is set to “0” in the initial routine (not shown) when the electrolyzed water generating apparatus is turned on (main switch is turned on), the microcomputer determines that step 330 is “No”, and in step 335. Start measuring the failure detection time.
[0042]
The microcomputer sets the flag F to “1” in step 340 and determines in step 345 whether or not the failure detection time is equal to or greater than the reference failure detection time TF. Since the present time is immediately after the start of the failure detection time measurement, the microcomputer determines that step 345 is “No” and returns the program to step 325, and then determines “Yes” in step 325 or step 345. Steps 325, 330, and 345 are repeatedly executed while it is determined as “Yes”.
[0043]
By the way, the reference failure detection time TF is slightly larger than the time required for the corresponding second flowing water sensor to change from “off” to “on” after the second drain valve is opened (in consideration of variation). ). The reason why the change of the flow sensor is delayed with respect to the opening of the drain valve is that the water flow is delayed based on the volume of each pipeline from the drain valve to the flow sensor, the flow path switching valve 50 and the electrolytic cell 10. is there. Therefore, since the second running water sensor is normally turned “ON” before the failure detection time becomes equal to or greater than the reference failure detection time TF, the microcomputer determines “Yes” in step 325 and executes the program. Proceed to step 350.
[0044]
The microcomputer clears the previously used flag F to “0” in step 350, and then starts counting the forced drainage time in step 355. That is, the measurement of the duration of the “forced drainage state” that the second drainage valve is opened in the previous step 320 and “on” of the second flowing water sensor has been confirmed in step 325 is started.
[0045]
Next, the microcomputer advances the program to step 360 to determine whether or not the forced drainage time has become equal to or greater than the reference forced drainage time TB. Immediately after the second flowing water sensor is changed to “ON”, the forced drainage time is shorter than the reference forced drainage time TB, so the microcomputer determines “No” in step 360, and the first in step 365. It is determined whether or not the water flow sensor (flow water sensor 81) is “ON”. This step is a step for determining whether or not the state where only the faucets 43 and 44 are opened (single pouring state) is still continued.
[0046]
Since the open / closed state of the faucets 43, 44, 45, 46 has not been changed at this time, the microcomputer determines "Yes" in step 365, and whether the electrolysis time has exceeded the predetermined time T1 in step 370 It is determined whether or not (the same processing as step 235). Since the current time is immediately after the start of electrolysis, the microcomputer makes a “No” determination at step 370 and returns the program to step 360. Thereafter, the microcomputer repeatedly executes these steps until it determines “Yes” in step 360, “No” in step 365, or “Yes” in step 370.
[0047]
The standard forced drainage time TB is obtained by electrolyzing the stagnant water that is staying in the electrolysis chamber and generating gas bubbles, or the stagnant water just before the pH value becomes too large or too small when poured out. The time required for draining from the tank 10 is set. This reference forced drainage time TB is sufficiently shorter than the predetermined time T1 (10 minutes), and is 20 seconds in this embodiment.
[0048]
Therefore, if the predetermined time elapses without changing the open / close state of the faucets 43, 44, 45, 46, the forced drainage time becomes equal to or greater than the reference forced drainage time TB. In step 375, the time for forced drainage time is stopped. Next, the microcomputer outputs a valve closing signal in order to close the second drain valve (drain valve 72) in step 380, and again determines whether or not the electrolysis time has exceeded the predetermined time T1 in step 385 ( The same processing as step 235). In most cases, the microcomputer determines that step 385 is “No” (if “Yes” is determined later), and returns the program to step 220 in FIG. Thereafter, if the open / close state of the faucets 43, 44, 45, 46 is not changed, the microcomputer starts measuring the standby time in step 220, and after the reference standby time TA has elapsed, the second drain valve (drain valve) 72) is opened (steps 305 and 320), and the valve is closed (steps 360 and 380) after the reference forced drainage time TB has elapsed.
[0049]
Next, in a state where only the faucets 43 and 44 are opened, when either one or both of the faucets 45 and 46 are opened (change from the single pouring state to the both electrolyzed water pouring states) ).
[0050]
As described above, in the state where only the faucets 43 and 44 are opened, the microcomputer intermittently opens and closes the second drain valve. In this case, the second flowing water sensor is in the “on” state in the state where the second drain valve is open (forced drainage period), but the second flowing water is within the standby time when the second drain valve is closed. The sensor is in the “off” state. Therefore, when the second flowing water sensor is in the “on” state within the waiting time when the second drain valve is closed, it means that the water taps 45 and 46 that have been closed are opened. To do.
[0051]
When the microcomputer detects such a state (a state in which the second flowing water sensor is in the “on” state within the standby time when the second drain valve is closed), the microcomputer intermittently detects the second drain valve. The general open / close control is stopped, and the control proceeds to control for keeping the second drain valve (and the first drain valve) closed. Specifically, during the standby time for repeatedly executing steps 225, 230, 295, 305, and 310 (during the period when the second drain valve is closed), the microcomputer detects that both the water flow sensors are “ If it is determined to be “ON”, that is, if it is determined that the second flowing water sensor is also “ON”, Steps 235, 225, and 230 are repeatedly executed to close the second drainage that is closed. The operation of opening the valves is not executed (step 320 is not executed), and both drain valves are kept closed.
[0052]
In addition, although the flowing water sensors 81 and 82 are arrange | positioned like this embodiment, the conventional electrolysis which always opened the drain valve of the drain pipe connected to the non-pour-out water pipe side in the single pouring state. In the water generation device, since the water flow sensors 81 and 82 are both “on”, even if the closed faucet is opened, it cannot be detected. For this reason, the conventional electrolyzed water generating device has to keep the drain valve on the discharge side so far open, and the amount of electrolyzed water poured out from the side where the faucet is newly opened is insufficient. was there. The electrolyzed water generating apparatus according to the present embodiment has no such problem, and has an advantage that a sufficient amount of electrolyzed water can be poured out from a pour pipe provided with a newly opened faucet. .
[0053]
Next, the operation of reversing the polarity of the voltage applied to the electrodes 14 and 15 when the electrolysis time exceeds the predetermined time T1 in a state where only the water taps 43 and 44 are opened will be described.
[0054]
As described above, the measurement of the electrolysis time is started in step 215, and the microcomputer monitors whether the electrolysis time has exceeded the predetermined time T1 in step 310, 370 or step 385. If it is determined in any step that the electrolysis time is equal to or longer than the predetermined time T1, the process proceeds to step 245, and the processing from step 245 to step 275 described above is executed to determine the polarity of the applied voltage and the flow path switching valve 50. After switching the connection state, the program returns to step 210.
[0055]
As described above, in the case where only one or both of the faucets 43 and 44 and either one or both of the faucets 45 and 46 are open, how the drain valve works Even if the second drain valve is closed because it is within the reference waiting time TA, or the second drain valve is open because it is within the standard forced drain time TB. Both drain valves 71 and 72 are forcibly opened in step 250, and at the same time, voltage application is stopped (step 245), and then the flow path switching valve 50 is switched (step 255). Further, when the switching operation of the flow path switching valve 50 is finished (when switching between the first and second connection states is finished), both drain valves 71 and 72 are closed (steps 260 and 270).
[0056]
In other words, even when only one of alkaline water or acidic water is poured out and the other is intermittently drained, when the accumulation of electrolysis time has elapsed for a predetermined time T1, All the drain valves (drain valves 71 and 72) are opened to switch the flow path of the flow path switching valve 50 and reverse the polarity of the applied voltage, thereby preventing a decrease in the electrolytic water generating ability of the electrode. After this switching control, the standby time is started from the beginning regardless of the state of the drain valves 71 and 72 before the switching control (standby time, forced drain time) (steps 310, 370, (See step 220 following steps 210 and 215 executed after 385).
[0057]
Next, a case where the faucets 43 and 44 are closed in a state where only the faucets 43 and 44 are opened will be described.
[0058]
In the state where only the faucets 43 and 44 are open, the microcomputer repeatedly executes steps 225, 230, 295, 305, and 310 during the period when the second drain valve is closed (within the reference waiting time TA). is doing. Therefore, if the faucets 43 and 44 are closed within this period, the microcomputer makes a “No” determination in step 225 (because both water flow sensors are “off”), and in steps 280, 285 and 290. Stop production of electrolyzed water. In this state, since both the first and second drain valves are closed, it is not necessary to change the instructions for both drain valves.
[0059]
On the other hand, in the state where only the faucets 43 and 44 are opened, the microcomputer repeatedly executes steps 360, 365 and 370 during the period when the second drain valve is opened (within the standard forced drainage time TB). ing. Therefore, if the faucets 43 and 44 are closed within this period, the microcomputer makes a “No” determination at step 365, stops the time for forced drainage at step 375, and continues to the second at step 380. Close the drain valve. Next, the microcomputer advances the program to steps 385, 220 and 225, determines “No” in step 225 (because both flowing water sensors are “off”), and in steps 280, 285 and 290, the electrolyzed water is determined. Stop generation. As described above, when shifting from the single water injection state to the water injection stop state, intermittent forced drainage operation is stopped and both drainage valves are kept closed.
[0060]
(3) Detection mode of clogged pipe or drain valve failure: Next, when a fault occurs in the drain valve 72 when only the faucets 43 and 44 are opened, or the drain pipe 62 and its upstream A case where clogging has occurred in the dispensing pipe 42 will be described.
[0061]
In this case, even after the second drain valve (drain valve 72) is opened in step 320 of the program shown in FIG. 3, the second flowing water sensor (flow sensor 82) does not turn “ON”. Therefore, when the microcomputer repeatedly executes Steps 325 to 345 and a predetermined time has elapsed, the failure detection time that started timing in Step 335 exceeds the reference failure detection time TF, and “Yes” is determined in Step 345. .
[0062]
If the microcomputer determines “Yes” in step 345, the program proceeds to step 390 to determine whether or not the first water flow sensor (flow water sensor 81) is still “on” in order to distinguish from the water break described later. judge. At this time, the second water flow sensor is “off” because the second drainage valve is not closed (does not open while closed) or the drainage pipe 62 and the outlet pipe 42 upstream thereof are clogged. This is because the electrolyzed water flows into the electrolysis chamber 12, so that the first water flow sensor (flow water sensor 81) is “ON”. Accordingly, the microcomputer makes a “Yes” determination at step 390 to proceed to step 395, and sounds the buzzer 104 at step 395 to notify the occurrence of an abnormal state. (4) Detection mode of water shutoff and water shutoff: Next, the case of water shutoff (a state in which electrolyzed water cannot be supplied) will be described. The (running water sensor 81) is also “off”. Accordingly, the microcomputer continues to determine “No” in Step 325 of FIG. 3, then determines “Yes” in Step 345, determines “No” in Step 390, and sets the program to Step 400. Proceed and turn on the lamp 103 to inform that it is in a water-stopped state. Subsequently, the microcomputer executes a water failure return detection routine in step 405. The water failure recovery detection routine is shown in detail in the flowchart of FIG.
[0063]
The microcomputer starts the subroutine of FIG. 4 from step 410 and stops applying voltage to the electrodes 14 and 15 in step 415. Subsequently, in step 420, a valve closing signal is output to the first and second drain valves (drain valves 71 and 72) to temporarily close both valves, and in step 425, timing of the detection operation time is started. The program proceeds to step 430. In step 430, the microcomputer outputs a valve opening signal to the first drain valve (drain valve 71) to open the first drain valve, and then in step 435, the time during which the first drain valve is open ( The timing of the first drain valve opening time) is started.
[0064]
Next, in step 440, the microcomputer determines whether or not the first flowing water sensor (flowing water sensor 81) is “ON”. At the present stage, since the first drain valve is immediately after opening, the first flowing water sensor is “off” regardless of whether or not the water shutoff has ended. The microcomputer determines “No” in step 440 and advances the program to step 445. At the present stage, since the opening time of the first drainage valve has not reached the predetermined time TH1 because it is immediately after the first drainage valve is opened, the microcomputer determines “No” in step 445. Determine and return the program to step 440, and then repeatedly execute steps 440 and 445 until the water shut-off ends before the predetermined time TH1 elapses or until the predetermined time TH1 elapses without water being stopped, It is monitored whether or not the first flowing water sensor is “ON”.
[0065]
The predetermined time TH1 is set to a time slightly longer than the time required from when the first drain valve is opened in a state where water is not shut off until the valve opening result appears at the first flowing water sensor. Accordingly, when the first drainage valve is opened under the condition that the water shutoff is completed and then a predetermined time TH1 has elapsed, a water flow is generated in the supply pipe 21 to which the first flow water sensor is attached. The sensor should be “on”.
[0066]
Therefore, if the microcomputer determines “Yes” in step 440 before the predetermined time TH1 has elapsed, the microcomputer determines that the water stop has ended, proceeds to step 450, turns off the lamp 103, and shuts off the water. Informs that has ended. Next, the microcomputer advances the program to step 210 in FIG. 2 and restarts the electrolyzed water pouring operation according to the state of the faucets 43, 44, 45, 46 again.
[0067]
If the water break continues, the microcomputer continues to determine “No” at step 440, and when the predetermined time has elapsed, determines “Yes” at step 445 and advances the program to step 455. In step 455, the microcomputer outputs a valve closing signal to the first drain valve, and advances the program to step 460 and subsequent steps.
[0068]
Steps 460, 465, 470, 475, 480 are the points where the first drainage valve and the first flowing water sensor in the previous steps 430, 435, 440, 445, 455 are replaced with the second drainage valve and the second flowing water sensor. Only the operation is the same. That is, the microcomputer opens the second drain valve in step 460, and if the second flowing water sensor is “ON” within a predetermined time TH2 after the valve is opened, the program proceeds to step 450 on the assumption that the water has returned from the water stop. If the second flowing water sensor is not “on” within a predetermined time TH2 after the valve is opened, the program proceeds to step 510 shown in FIG.
[0069]
In step 510, the microcomputer determines whether or not the operation time (detection operation time) from the start of detection in the water interruption return detection routine is the reference detection operation time TH3, and the detection operation time has reached the reference detection operation time TH3. If not, it is determined as “No”, the program is returned to step 430, and further, a water failure return detection routine is executed. On the other hand, if the detection operation time has reached the reference detection operation time TH3, the microcomputer determines “Yes” in step 510 and advances the program to step 515, step 520, and step 525. In step 515, the microcomputer outputs a valve closing signal for closing the first and second drain valves, closes both drain valves, temporarily stops the detection operation, and starts measuring the detection operation interruption time in step 520. In step 525, it is determined whether or not the detection operation interruption time is the reference detection operation interruption time TH4.
[0070]
If the microcomputer determines “Yes” in step 525, the microcomputer advances the program to step 530 to stop measuring the detection operation interruption time, stops measuring the detection operation time in step 535, and Then, the program is returned to step 425 shown in FIG. 4 to resume the execution of the water failure return detection routine.
[0071]
The above operation is continued until the water stop is completed. In addition, the first and second drain valves 71 and 72 are alternately opened for a predetermined period of time TH1 and TH2 to detect the return from water shutoff. The drain valves 71 and 72 are kept open (solenoid valves). In this case, the durability of the valve due to the continuous power supply to the valve is prevented, and the sticking of the valve that occurs when the valve is kept open is prevented.
[0072]
In the water cutoff return detection routine, both drain valves 71 and 72 are alternately opened and closed during execution of the water cutoff return detection routine. When the water cutoff continues for a long time, the drain valves 71 and 72 are opened and closed. If it repeats, each drain valve 71,72 will impair the durability at an early stage. For this reason, in the water cutoff return detection routine, when the water cutoff is continued for a long time, the water cutoff detection operation is temporarily interrupted and then restarted, and the wasteful opening / closing operations of the drain valves 71 and 72 are omitted. Therefore, the durability is improved. The continuous open / close operation time and the open / close operation interruption time of each drain valve 71, 72 in the water break return detection routine are, for example, a continuous open / close operation time of 1 minute and an open / close operation interruption time of 90 minutes.
[0073]
In the water break return detection routine, the detection operation time is adopted as a reference for determining the interruption of the detection operation. Instead of this detection operation time, the number of times each drainage valve is opened and closed is detected. It can also be used as a criterion for judging.
[0074]
In the above description, the case of the single dispensing state in which only the faucets 43 and 44 are opened has been described, but the same operation is performed in the case of the single dispensing state in which only the faucets 45 and 46 are opened. That is, in this case, the only difference is that the flow sensors 81 and 82 are recognized as the second and first flow sensors in FIG. 2 and the drain valves 71 and 72 are recognized as the second and first drain valves, respectively. Others operate in exactly the same way as if only the faucets 43, 44 were opened according to this recognition.
[0075]
In addition, the said electrolyzed water generating apparatus is an electrolyzed water generating apparatus which concerns on an example of this invention, Comprising: Various deformation | transformation are possible. For example, although the flowing water sensors 81 and 82 of the electrolyzed water generating apparatus have been described as sensors that are “on” at a set flow rate or higher, a flow rate sensor that detects the flow rate may be used. In the case of using a flow rate sensor, a step of recognizing “on” above the set flow rate and “off” above the set flow rate is added compared to the sensor output and the set flow rate. Further, in the electrolyzed water generating apparatus, tap water supplied from a tap water as an external water supply source is electrolyzed, but a dilute aqueous solution that dissolves inorganic salts such as salt water supplied from a diluted salt water tank or the like is used. It can also be electrolyzed water.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of an electrolyzed water generating apparatus according to an example of the present invention.
FIG. 2 is a flowchart showing a part of a program executed by a control device constituting the electrolyzed water generating device.
FIG. 3 is a flowchart showing another part of the program executed by the control device.
FIG. 4 is a flowchart showing a part of a program for detecting a water return that is another part of the program executed by the control device;
FIG. 5 is a flowchart showing another part of the program for detecting the water break return.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Electrolytic cell, 11 ... Diaphragm, 12, 13 ... Electrolytic chamber, 14, 15 ... Electrode, 16, 17 ... Inlet, 18, 19 ... Outlet, 21, 22 ... Supply pipe, 23 ... Pressure reducing valve, 24 ... Water supply pipe, 25 ... Water purifier, 26 ... Main plug, 27 ... Water pipe, 28 ... Relief valve, 31, 32 ... Outlet pipe, 41, 42 ... Outlet pipe, 43, 44, 45, 46 ... Water faucet, 50 ... Flow path switching valve, 51a, 51b ... Inflow port, 52a, 52b ... Outflow port, 61, 62 ... Drain pipe, 71, 72 ... Drain valve, 81, 82 ... Flowing water sensor, 90 ... Main body, 100 ... Control device, 101 ... Main switch, 102 ... Manual switching switch, 103 ... Lamp, 104 ... Buzzer.

Claims (1)

An electrolyzer having a pair of electrolysis chambers partitioned by a diaphragm, and a pair of supply pipes having flowing water detection means connected to the electrolyzers of the electrolyzer and supplying electrolyzed water to the electrolyzers, respectively A pair of extraction tubes each having a faucet for extracting electrolytically generated water and connected to each electrolytic chamber of the electrolytic cell to extract the electrolytically generated water generated in each electrolytic chamber, and staying in the electrolytic chamber Electrolyzed water comprising a pair of discharge pipes that have a discharge valve that discharges the accumulated water and that is connected in the middle of each extraction pipe and discharges the accumulated water that stays in each electrolysis chamber, and a control device that controls the electrolysis operation In the generation device, the control device includes:
An open / close signal output means for outputting a signal for opening and closing each drain valve independently based on the flowing water state detected by the flowing water detection means;
When the opening / closing signal output means outputs a signal for closing both the drain valves, when only one of the pair of flowing water detection means detects the flow of the electrolyzed water, the flow of the electrolyzed water is The open / close signal output to keep the drain valve of the drain pipe on the electrolysis chamber side detected closed and to open and close the drain valve of the drain pipe on the electrolysis chamber side where the flow of electrolyzed water is not detected Forced drainage means to instruct the means,
When the drainage valve that is opened and closed intermittently by the operation of the forced drainage means is closed, the operation of the forced drainage means is stopped when both of the pair of flowing water detection means detect the flow of the electrolyzed water. And a forced drain end means for instructing the open / close signal output means to keep both the drain valves closed,
Detecting operation for instructing the forced drainage means to temporarily stop the running water detection operation of the forced drainage means and resume the same flowing water detection operation after a lapse of a predetermined time when the running water detection operation of the forced drainage means reaches a predetermined time An electrolyzed water generating apparatus comprising an interruption means.

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